Alle Meldungen https://idiv-biodiversity.de/ en Alle Meldungen https://idiv-biodiversity.de/typo3conf/ext/tt_news/ext_icon.gif https://idiv-biodiversity.de/ 18 16 TYPO3 - get.content.right http://blogs.law.harvard.edu/tech/rss Thu, 21 Nov 2024 00:00:00 +0100 iDiv researchers at the Convention on Biological Diversity's COP16 https://idiv-biodiversity.de//en/news/news_single_view/5426.html Addressing biodiversity challenges with science-based strategies Addressing biodiversity challenges with science-based strategies

by Julia Prawitz

COP16, under the Convention on Biological Diversity (CBD), saw iDiv researchers presenting new research and strategies for biodiversity conservation and restoration. Their participation highlighted the urgency to foster collaboration on a global scale as well as with local communities to tackle both biodiversity protection and climate change.

The 2024 COP16 aimed to accelerate the translation of the Kunming-Montreal Global Biodiversity Framework (GBF) into national targets and develop robust national biodiversity monitoring systems. 

Held from October 21 to November 1, COP16’s discussions sought to progress the development of fair and equitable benefit-sharing from genetic data, align National Biodiversity Strategies and Action Plans (NBSAPs) with the GBF, and mobilise financial resources to close the biodiversity finance gap, among other issues. The theme “Paz con la Naturaleza” (Peace with Nature) emphasised prioritising sustainable conservation efforts and peacebuilding. 

Two years earlier, COP15 marked the adoption of the GBF with goals to protect 30% of global land and marine areas, restore 30% of degraded ecosystems, and close the biodiversity funding gap. This achievement was crucial for setting the stage for COP16, where the focus shifted to practically implementing these targets.

While some of the goals were reached and agreements adopted, the conference ended early with big questions unanswered regarding financing and monitoring.

iDiv’s role at COP16

At COP16, iDiv experts highlighted the importance of monitoring for effective target implementation and inclusive approaches. Four iDiv researchers contributed on-site by organising and participating in three side-events. iDiv researchers also discussed and helped edit the opening and closing statements of the Academia and Research caucus, a meeting of members from global universities and scientific organisations, advocating the crucial role of science and education in achieving biodiversity targets.

Side-events with iDiv involvement included:

  • a research presentation on local communities and biodiversity;
  • a session introducing FAIR biodiversity monitoring data;
  • a session introducing;
  • a presentation showcasing a joint biodiversity observation system and;
  • a pavilion event on protecting Latin America’s dry forests.

Presentation: Research on local communities and biodiversity

iDiv associate member Solveig Richter (Leipzig University), Pablo Palacios and Pablo Ramos (both Pontificia Universidad Javeriana Bogotá) presented their work at a side-event titled “Justicia Ambiental en las transiciones hacia la sostenibilidad” (environmental justice in the transition to sustainability) in the negotiation area, or blue zone.

The discussion centred on their recent research, which examined intercultural approaches to ecosystem protection among Indigenous and Afro-descendant communities and strategies to link livelihoods and biodiversity management.

Colombia, in particular, has biodiversity hotspots threatened by illegal mining and deforestation, where “it is often environmental activists or Indigenous groups at the local level that protect nature but engage under high risks,” Richter, a political scientist and conflict scholar, explained. 

These communities develop their own, sometimes informal, ways of adapting to ecosystem changes, which may differ from national or international frameworks, according to Richter. 

Live Session: FAIR biodiversity monitoring using EBV’s Cube Ecosystem

iDiv’s Lina Estupiñán-Suárez (MLU) and Yanina Sica from Senckenberg Nature Research led a live demonstration and training session as part of a side-event hosted by GEO BON, a global network of researchers. The event, “Advancing NBSAP Reporting Using GEO BON’s EBV Data Ecosystem”, tackled one of the most-pressing issues facing countries: access to reliable data for developing and reporting on National Biodiversity Strategies and Action Plans (NBSAPs).

The session introduced several tools based on the Essential Biodiversity Variables (EBVs) framework, that complement GEO BON’s objective of harmonising biodiversity data. GEO BON’s tools and data ecosystem, which include the EBV Data Portal and the EBV Cube Format, aim to streamline data standards for geospatial dataset collections useful for reporting and supporting countries in meeting GBF targets. At the same time, the EBV-ecosystem facilitates biodiversity data sharing by making it more Findable, Accessible, Interoperable, and Reusable (FAIR), according to the researchers.

“Data availability and accessibility emerged as central topics [...] essential for creating effective, evidence-based policies,” Estupiñán-Suárez shared. These tools enable governments and organisations to improve data transparency and usability, driving science-informed biodiversity action.

Presentation: A unified biodiversity observation system to drive the GBF progress

Estupiñán-Suárez also participated as a speaker in the pavilion event, “A Global Biodiversity Observing System (GBiOS) to support the implementation and monitoring of the Kunming-Montreal Global Biodiversity Framework by Parties”. 

GBiOS, developed by GEO BON and its partners, aims to integrate and coordinate existing biodiversity monitoring tools and networks, such as regional Biodiversity Observation Networks (e.g., Asia BON, EuropaBON), the EBV Data Portal, and global data repositories,  to track global biodiversity changes effectively.

Integrating these systems stands to help countries track biodiversity trends, guide policy, and ultimately meet the GBF targets.

Side-event by DryFlor Network: Protecting Latin America’s dry forest

iDiv’s Karina Banda-R (UFZ) moderated, participated in, and helped organise a discussion on safeguarding Latin America’s endangered dry forests characterised by long dry seasons.

With representatives from the IUCN, Flora & Fauna International, the World Bank, the Humboldt Institute, which hosted the event, and other international organisations, the panel explored collaborative approaches to protect these critical ecosystems. 

Panellists addressed the need for science-based policy development, financial support, and locally tailored solutions to tackle the conservation challenges facing these forests.

This side-event was part of more extensive dialogues with different actors from academia, NGOs, and intergovernmental organisations. By addressing the specific needs of dry-forest regions, the event highlighted how coordinated efforts can create a specific dry-forest fund to advance biodiversity protection and sustainable development across Latin America. 

iDiv researchers reflect on COP16 outcomes

While expectations for COP16 were high, and delegates adopted important decisions on biodiversity and health, benefit sharing, and the roles of Indigenous Peoples, local communities, and people of African Descent, many iDiv researchers were left with mixed feelings.

“We are particularly worried that progress on the Kunming-Montreal Framework was limited and that key funding mechanisms remain unresolved”, said iDiv Speaker Henrique Miguel Pereira (MLU), noting that COP16 fell short of its goals. “In truth, the COP wasn’t closed; it was suspended because final negotiations failed to reach agreement on these critical issues.”

Richter noted some positive developments: “[there was an] unprecedented mobilisation of stakeholders and issues that were previously being discussed at the margins but are now central to biodiversity protection.” She recognised Colombia’s leadership in spotlighting essential topics and putting them on the global agenda.

“iDiv researchers underscored the need for basic biodiversity research to close gaps in monitoring, and COP16 set the foundation for establishing clear national targets, supporting the monitoring framework, and bolstering accountability across sectors,” explained Leonie Friedrich, iDiv Science-Policy Coordinator, who helped facilitate iDiv’s involvement at COP16. “But discussions need to resume urgently.”

 

More information and additional materials related to iDiv’s involvement at COP16 can be found here:

 

Contact:

Leonie Friedrich, Science-Policy Coordinator & Scientific Employee (Biodiversity and People)
Science-Policy Coordinator & Scientific Employee (Biodiversity and People)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Helmholtz Centre for Environmental Research – UFZ
Phone: +49 341 9739174
Email: leonie.friedrich@idiv.de

 

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TOP NEWS Thu, 21 Nov 2024 00:00:00 +0100
Soil ecosystem more resilient when land managed extensively https://idiv-biodiversity.de//en/news/news_single_view/5425.html Effects of land use on soil biodiversity in cropland and grassland Researchers studied the effects of intensive and extensive land use on soil biodiversity in cropland and grassland.

Based on a media release by Leipzig University

Compared to intensive land use, extensive land use allows better control of underground herbivores and soil microbes. As a result, the soil ecosystem is more resilient and better protected from disturbance under extensive management than under intensive land use. Researchers from Leipzig University, the German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and other research institutions found that the total energy flux and the activities of so-called decomposers, herbivores and predators in the soil food web remained stable. They have just published their paper in the journal Global Change Biology.

However, compared to intensive land use, extensive land use led to higher activity of microbivores and greater control of microorganisms by them. This means that small predators such as nematodes regulate the populations of microorganisms and keep them in balance. Using the experimental design of the Global Change Experimental Facility (GCEF) at the Helmholtz Centre for Environmental Research (UFZ), the researchers were able to show that this regulation was also maintained under future climate conditions. In addition, the control of herbivores by natural predators was generally more pronounced in extensively managed cropland and grassland areas. This is important because excessive reproduction by herbivores can significantly affect plant growth and therefore productivity. “Our findings show the potential benefits of less intensive and more extensive land management for the functioning of soil food webs – both today and in a changing climate,” says the first author of the paper, Marie Sünnemann, from the Institute of Biology at Leipzig University and iDiv. 

Climate change and more intensive land use are threatening soil organisms and their important tasks – known as ecosystem functions. To understand how intensive and extensive land use affects the diversity of soil organisms in cropland and grassland – now and in the future in the context of climate change – the researchers studied these influences in a field experiment.

In their experiment, they analysed the effects of warming and summer drought on soil organisms under both intensive and extensive land use. These included microorganisms such as bacteria and fungi, but also nematodes, springtails, mites and larger animals such as beetles, spiders, millipedes and centipedes. “Our focus was on the energy cycles in the soil food web – meaning the energy that is passed on from decomposers and herbivores to small predators,” says co-author Professor Nico Eisenhauer from iDiv. This energy transfer was used by the researchers as an indicator of how well the main groups such as decomposers, microbivores, herbivores and predators were performing their respective functions in the ecosystem: decomposers break down organic matter and make the soil fertile. The role of microbivores includes preventing harmful fungi from multiplying en masse. For their part, predators control the numbers of herbivores such as aphids, helping to prevent crop losses.

 

Original publication
(iDiv researchers and alumni bolded)

Marie Sünnemann, Andrew D. Barnes, Angelos Amyntas, Marcel Ciobanu, Malte Jochum, Alfred Lochner, Anton M. Potapov, Thomas Reitz, Benjamin Rosenbaum, Martin Schädler, Anja Zeuner, Nico Eisenhauer (2024). Sustainable land use strengthens microbial and herbivore controls in soil food webs in current and future climates, Global Change Biology. DOI: 10.1111/gcb.17554

 

Contact:

Dr Marie Sünnemann
Postdoctoral researcher at the
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and
Leipzig University
Phone: +49 341 9733193
Email: marie.suennemann@idiv.de
Web: https://www.idiv.de/en/profile/1072.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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Media Release TOP NEWS Experimental Interaction Ecology Tue, 19 Nov 2024 00:00:00 +0100
Evidence for Widespread Thermal Acclimation of Canopy Photosynthesis https://idiv-biodiversity.de//en/news/news_single_view/5422.html New study in Nature Plants Canopy photosynthesis responds to increasing temperatures by boosting maximum photosynthetic rates

Based on a blog post by the University of Reading

A new study published in the journal Nature Plants reveals insights into how plants adapt to temperature changes over time at the canopy scale.

Recent research has uncovered that plants adjust their photosynthetic capabilities over weeks to months, a process known as thermal acclimation. While previous studies have primarily focused on individual leaves, this new study – to which iDiv and Leipzig University contributed – shifts the focus to the whole canopy, providing a broader perspective. Using data from more than 200 eddy covariance sites across the globe, the researchers show that canopy photosynthesis (Amax) responds to increasing temperatures by boosting maximum photosynthetic rates, especially when water availability is not a limiting factor.

By pinpointing a 14-day period as the key timeframe for plants to acclimate, the study highlights how different ecosystems, from croplands to grasslands, vary in their thermal acclimation responses. Croplands exhibit the quickest acclimation, while grasslands have slower rates. This discovery offers vital information for refining models that predict plant responses to climate change and emphasises the importance of understanding photosynthesis at the larger, canopy scale.

Understanding Thermal Acclimation of Canopy Photosynthesis

The ability of ecosystems to absorb carbon through photosynthesis varies significantly across different regions and seasons, and one of the biggest drivers of this variation is air temperature. While scientists have long studied the immediate impacts of temperature on photosynthesis, the slower process of thermal acclimation, where plants adjust to sustained temperature increases, has received less attention. This process is increasingly relevant as global temperatures continue to rise.

Thermal acclimation involves biochemical changes in plants, such as adjustments to electron transport and carboxylation, as well as how stomata respond to atmospheric conditions. Previous research primarily examined individual leaves, but this study explores how entire plant canopies—comprising many leaves—adapt to increasing temperatures. It specifically focuses on whether the maximum rate of photosynthesis under high light conditions (Amax) can adjust to higher average temperatures over time.

By using data from the extensive FLUXNET2015 network of eddy covariance sites, this study measures canopy-scale photosynthetic rates across a wide range of ecosystems. Jiangong and the team aimed to identify the specific window of time in which canopy-level photosynthesis acclimates to temperature changes and to assess how well current models of photosynthesis capture these acclimation processes. Incorporating recent advances in understanding temperature dependence and leaf physiology, this research significantly enhances the understanding of ecosystem-wide thermal acclimation.

Evidence for Thermal Acclimation of Canopy Photosynthesis

The study provides evidence that canopy photosynthesis thermally acclimates, showing a strong positive correlation between Amax and growth temperature, particularly when water is sufficiently available. By carefully controlling for variables such as temperature and canopy foliage quantity, the researchers found that 87% of the data bins used for analysis showed positive thermal acclimation rates, with 65% of these being statistically significant.

This acclimation response was observed across various ecosystems, with croplands displaying the highest acclimation rates and grasslands the lowest. Even when accounting for other environmental factors such as light levels and vapour pressure deficit, the acclimation signal remained strong. 

One interesting finding was that ecosystems with more stable thermal environments, like tropical evergreen forests, showed reduced acclimation capacity. This suggests that plants in these regions may have limited ability to adjust their photosynthesis to changing temperatures. Nevertheless, the overall results strongly indicate that thermal acclimation is a widespread mechanism, helping plants increase their carbon carboxylation potential under a warming future. 

The Time Scale of Thermal Acclimation

One of the key aspects of the study was determining the time scale for canopy photosynthesis to acclimate to changes in growth temperature. The researchers found that this time scale varied across different plant functional types (PFTs). For example, grasslands and croplands showed the shortest acclimation periods (12 and 16 days, respectively), while evergreen needle-leaf forests, deciduous broadleaf forests, and wetlands required longer periods, up to 25 days. On average, across all ecosystems, the acclimation period was about 14 days.

Interestingly, evergreen broadleaf forests did not show a clear acclimation time when measured by photosynthetic capacity. However, using remote-sensing data, the researchers estimated an acclimation time of around 13 days. The length of these acclimation periods reflects a balance between the benefits of increasing carbon uptake and the resource costs of making the necessary physiological adjustments.

The findings underscore the importance of considering PFT-specific acclimation times when improving models of plant responses to climate change. Fast-growing ecosystems like croplands and grasslands may adjust more quickly, while slower-growing ecosystems like forests and wetlands might take longer but potentially reap greater benefits from acclimation over time.

Future Implications: Thermal Acclimation and Climate Change

This study has major implications for predicting how ecosystems will respond to future warming. The thermal acclimation ability of canopy photosynthesis suggests that plants could increase their carbon uptake potential in response to rising temperatures when water is not a limiting factor. However, as climate change also brings greater variability in water availability, plants in many regions may need to reduce their photosynthetic capacity to conserve water, especially during periods of drought.

Accurately representing this acclimation process in land surface models is essential for forecasting ecosystem responses to global warming. Incorporating seasonal acclimation of key photosynthetic processes—like the maximum carboxylation and electron transport rates—will improve the accuracy of models simulating plant responses to temperature changes on weekly to monthly timescales.

As water availability becomes an increasingly important limiting factor, especially in warmer growing seasons, understanding canopy-scale thermal acclimation in the context of both temperature and water availability will be crucial for predicting future ecosystem behaviour.

 

Original publication
(iDiv researchers bolded)
Liu, J., Ryu, Y., Luo, X., Dechant, B., Stocker, B.D., Keenan, T.F., Gentine, P., Li, X., Li, B., Harrison, S.P., & Prentice, I.C. (2024). Evidence for widespread thermal acclimation of canopy photosynthesis. Nature Plants. https://doi.org/10.1038/s41477-024-01846-1

 

Contact:

Dr Benjamin Dechant
Postdoctoral researcher at the
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and
Leipzig University
Phone: +49 341 9733248
Email: benjamin.dechant@idiv.de
Web: https://www.idiv.de/de/profile/1368.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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sDiv TOP NEWS Mon, 18 Nov 2024 00:00:00 +0100
Diverse and diverging demands on forests in Germany https://idiv-biodiversity.de//en/news/news_single_view/5421.html Biodiversity, ecosystems and economics of enriching beech forests with conifers Research team analyse biodiversity, ecosystems and economics of enriching beech forests with conifers

Based on a media release by the University of Göttingen

Forests provide biodiversity, ecosystem functions, income and much more. How can these diverse and seemingly diverging demands be met? An international research team led by the University of Göttingen and with the participation of the German Centre for Integrative Biodiversity Research (iDiv) and the Friedrich Schiller University Jena addressed this question by analysing the effects of enriching beech forests in Germany with commercially valuable native (to mountainous regions of Europe) and non-native conifer species, in this case, the Norway spruce and Douglas fir, respectively. Their study showed that enriching beech forests which naturally have few tree species does not necessarily reduce species richness or ecosystem functioning. In fact, their results showed that there were positive gains at many levels including biodiversity, ecosystems and economic viability, especially for the combination of beech with Douglas fir. The research was published in Science Advances

The scientists used a unique empirical dataset, taking data from 40 plots of mature European beech forests across the state of Lower Saxony in Germany. The research team combined data from 11 projects, each of which analysed many different research aspects of European beech forests enriched with conifers. These aspects included: seven biodiversity indicators, considering arthropods and birds in the canopy to fungi and creatures in the soil; eight ecosystem functions, including processes involved in nutrient cycling, such as the amount of carbon or nitrogen in the soil or the biomass of the trees aboveground; and six economic functions, such as current and short-term economic return, tree survival and volume of wood in the future. The research gave a unique and comprehensive perspective by integrating these multiple perspectives.

The results showed that mixed forests with beech and Douglas fir have enhanced biodiversity and ecosystem functioning while improving the economic performance compared to monocultures of beech. “There are, of course, major concerns about the potential risks to the environment of introducing non-native species,” explains Dr Larissa Topanotti, “but our research showed it can be possible to do this to the benefit of biodiversity, ecosystems and economics: it was a win-win-win situation. However, the right species for the environment, the spatial scale and the existing forest need to be carefully considered.” 

“However, it is important to note that while we observed win-win-win situations in mixed forests, monospecific non-native Douglas fir stands partly reduced the local biodiversity,” says co-author Dr Benjamin Wildermuth, a researcher at iDiv and the University of Jena.

“Increasing the range of species to include more native species and trees species that can adapt to climate change is essential for the future,” explains co-author and iDiv alumna Dr Nathaly Guerrero-Ramírez. Professor Carola Paul adds: “Our study has contributed to finding compromise solutions to manage the increasingly diverse demands on forests and forest management by society.”

 

Original publication
(iDiv researchers and alumnae bolded)

Larissa Topanotti, …, Benjamin Wildermuth, …, Nathaly Rokssana Guerrero Ramírez (2024). Enhancing economic multifunctionality without compromising multidiversity and ecosystem multifunctionality via forest enrichment. Science Advances. DOI: 10.1126/sciadv.adp6566

 

Contact

Dr. Nathaly Rokssana Guerrero Ramírez 
University of Göttingen
email: nathaly.guerrero-ramirez@forst.uni-goettingen.de 

Dr. Benjamin Wildermuth
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Friedrich Schiller University Jena
email: E-Mail: benjamin.wildermuth@idiv.de

 

Contact:

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TOP NEWS Media Release iDiv Members Tue, 12 Nov 2024 00:00:00 +0100
Aletta Bonn appointed to German Advisory Council on Global Change https://idiv-biodiversity.de//en/news/news_single_view/5419.html Research group leader to advise the German government Research group leader to advise the German government for at least four years

Prof Aletta Bonn has been appointed by the federal government to the German Advisory Council on Global Change (WBGU).

Bonn heads the Biodiversity and People research group at the Helmholtz Centre for Environmental Research (UFZ), the German Centre for Integrative Biodiversity Research (iDiv) and the Friedrich Schiller University Jena. She combines research on biodiversity and ecosystem functions with human well-being. Her research aims to build bridges between science, politics and society.

An important aspect of Aletta Bonn's work is the promotion of co-design and joint knowledge production in nature conservation research. She is involved in numerous citizen science projects and played a key role in the development of the Citizen Science Strategy 2030 for Germany.

Commenting on her appointment, she says: “I am very much looking forward to working together in the German Advisory Council on Global Change and hope that we can actively support the effective achievement of the global biodiversity and sustainability goals by 2030.”

iDiv Speaker Prof. Henrique Pereira acknowledges Bonn’s appointment as an excellent decision: “At iDiv we were delighted to learn about the appointment of our colleague Aletta Bonn to the WBGU. Professor Bonn is a world-leading scientist in the field of biodiversity. Her research has uncovered the importance of engaging people in citizen science to raise societal awareness of environmental problems. She is an interdisciplinary scientist whose ground-breaking work includes colleagues from multiple disciplines. For instance, she has worked with psychologists to look at the positive impacts of biodiversity on mental health. Her scientific expertise and her collaborative spirit make her an excellent appointee to this important body that advises the German government.”

Bonn is one of three new members of the nine-member WBGU. The appointment begins today and is valid until 31 October 2028.

 

Contact:

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TOP NEWS Biodiversity and People Fri, 01 Nov 2024 00:00:00 +0100
Scientific backing for the join-in campaign ”Unsere Flüsse“ on German television https://idiv-biodiversity.de//en/news/news_single_view/5413.html Read interview with the researchers Researchers investigate the habitat quality of Germany's streams

 

The full text is only available in German.

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TOP NEWS Biodiversity and People Mon, 21 Oct 2024 00:00:00 +0200
European forest plants are migrating westwards, nitrogen main cause https://idiv-biodiversity.de//en/news/news_single_view/5408.html New study published in Science

Based on a press release by Ghent University

New research reveals nitrogen deposition, and to a lesser extent climate change, unexpectedly as the key driver behind surprising westward shifts in the distribution of plants.

These are the results of a study published in the journal Science, in which three researchers from the German Centre for Integrative Biodiversity Research (iDiv) were involved. The study defies the common belief that climate change is the primary cause of species moving northward. This finding reshapes our understanding of how environmental factors, and in particular nitrogen deposition, influence biodiversity.

While it is widely assumed that rising temperatures are pushing many species toward cooler, northern areas, this research shows that westward movements are 2.6 times more likely than northward shifts. The primary driver? High levels of nitrogen deposition from atmospheric pollution, which allows a rapid spread of nitrogen-tolerating plant species from mainly Eastern Europe. The establishment of these highly competitive species in areas with high nitrogen deposition rates often comes at the expense of the more specialised plant species.

The results highlight that future biodiversity patterns are driven by complex interactions among multiple environmental changes, and not due to the exclusive effects of climate change alone. 

“Climate change is often seen as the main culprit behind range shifts in plant species, but key interactions with historically important drivers are frequently overlooked”, says co-author Dr Ingmar Staude, researcher at iDiv and Leipzig University. “In recent decades, most range shifts in European forest plants are attributed to nitrogen deposition, and only to a lesser extent to climate change. This raises an important question: How can ecosystems adapt to rising temperatures while biodiversity shifts are mostly driven by other environmental changes, particularly atmospheric pollution?” Understanding these complex interactions is critical for land managers and policymakers to protect biodiversity and ecosystem functioning, according to the researchers.

Key findings:

  • European forest plants shift their distributions at an average velocity of 3.6 kilometer per year.
  • 39% of the plant species shift westward. Northward shifts are only observed for 15% of the species.
  • Nitrogen deposition rather than climate change is surprisingly the main factor behind westward distribution shifts in European forest plants.
  • The study analysed the shifts in the distribution area of 266 forest plant species across Europe over several decades, with the first measurements being taken in the year 1933 at some locations.
  • Several of Europe’s most emblematic forests were included in this study, such as the primeval forest Białowieża in Poland. 

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118). It is a product of the sDiv working group sREplot. iDiv’s synthesis centre sDiv supports working group meetings where international scientists work together on scientific issues.

 

Original publication
(iDiv researchers and alumni bolded)

Sanczuk, P., …, Bernhardt-Römermann, M., …,  Bjorkmann, A., …, Jandt, U., …, Staude, I., …, De Frenne, P. (2024). Unexpected westward range shifts in European forest plants link to nitrogen deposition. Science. DOI: science.org/doi/10.1126/science.ado0878

 

Contact:

Dr Pieter Sanczuk
Forest & Nature Lab
Department of Environment
Ghent University
Phone: +32 (0)9 264 90 37; +32 (0)499 20 58 65
Email: Pieter.sanczuk@ugent.be

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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iDiv Members sDiv TOP NEWS Media Release Thu, 10 Oct 2024 00:00:00 +0200
Julia von Gönner wins Research Award for Citizen Science https://idiv-biodiversity.de//en/news/news_single_view/5411.html The Citizen Science project FLOW mobilised over 900 citizens to contribute to the ecological... The Citizen Science project FLOW mobilised over 900 citizens to contribute to the ecological monitoring of small streams.

 

The full text is only available in German.

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Biodiversity and People TOP NEWS Thu, 10 Oct 2024 00:00:00 +0200
'Life on the edge': A new toolbox to predict global change impact on wildlife https://idiv-biodiversity.de//en/news/news_single_view/5406.html New climate change prediction tool provides insight into population-level vulnerability to global... New climate change prediction tool provides insight into population-level vulnerability to global change through combining genomic, geographic and environmental data.

Report by Chris Barratt, postdoctoral researcher at Wageningen University and iDiv alumnus 

The toolbox, published in the journal in Methods in Ecology and Evolution, will enable researchers and conservation practitioners to understand and predict how global environmental change may impact wildlife populations by integrating genomic, geographic and environmental data. This research was led by the German Centre for Integrative Biodiversity Research (iDiv) in Leipzig and an international team from across Europe (UK, the Netherlands, Germany) and the US.

We created Life on the edge to address one of the main limitations of most climate change vulnerability assessments that typically focus at the species level and do not account for intraspecific populations, which are often the first early warning signals of species declines. Life on the edge leverages population-level genomic data and spatially explicit models in a highly flexible way, and can be applied to any species or geographic area. Predictions using the toolbox can help to provide crucial population level information and guide conservation prioritisation efforts to halt population declines.

Four metrics providing unique population information

To build our framework, we created a standardised toolbox that firstly predicts the ‘Exposure’ of each population using known occurrences of the species in species distribution models (SDMs) and changes in environmental conditions between current and future climate scenarios. Secondly, georeferenced population-level genomic data is used to quantify neutral genetic diversity (‘neutral sensitivity’) and to identify and quantify the genomic regions involved in climate adaptation to estimate the ‘adaptive sensitivity’ of the population. Thirdly, genomic data is used to make predictions of movement between populations under current and future scenarios to assess any potential barriers for the population to shift its distribution to track suitable climate (‘spatial barriers’). 

Each of the four metrics provide unique information about each sampled population, and can be combined to represent an overall measure of ‘Population vulnerability’, which can be used for prioritising populations in need of conservation efforts. To demonstrate its utility, we apply the Life on the edge toolbox to three East African frog species to predict population vulnerability across Tanzania, Kenya, Malawi and Mozambique, and to two European bat species.

A major leap forward

With its flexibility, Life on the edge represents a major leap forward in understanding population vulnerability within species. Its standardisation, modular construction and high level of species-specific parameterisation makes it possible to plug in data from any species to see what’s going on in wild populations, which is an important starting point to fight against population declines and begin to halt the biodiversity crisis. We will now see how we can use Life on the edge in real-world systems, and move towards monitoring changes at the population level.

"Life on the edge provides an accessible, holistic tool for understanding how climate change will affect wildlife population and guiding targeted conservation efforts. Incorporating genomic information can improve our predictions of wildlife vulnerability to climate change. Such tools are essential for enabling researchers and conservation practitioners to use new emerging genomic approaches in their research and management decisions," says Orly Razgour at the University of Exeter in the UK, and senior author of the study.

The study was funded by the German Research Foundation (DFG; FZT-118), among others. Alumnus Dr Chris Barratt was a postdoctoral at iDiv's synthesis centre sDiv, which helps bring together existing but disparate data, methods, theories, and tools in new and sometimes unexpected ways.

 

Original publication
(Researchers with iDiv affiliation and alumni bolded)

Barratt, C.D., Onstein, R.E., Pinsky, M.L., Steinfartz, S., Kühl, H.S., Forester, B.R., & Razgour, O. (2024). Life on the edge: a new toolbox for population-level climate change vulnerability assessments. Methods in Ecology and Evolution, doi: 10.1111/2041-210X.14429

 

Contact:

Dr Chris Barratt
Animal Breeding & Genomics group
Wageningen University & Research
Alumnus of the German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: chris.barratt@wur.nl

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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TOP NEWS sDiv Tue, 08 Oct 2024 00:00:00 +0200
New Phase for iDiv: Biodiversity Research Consolidated in Central Germany https://idiv-biodiversity.de//en/news/news_single_view/5404.html Today, the German Centre for Integrative Biodiversity Research (iDiv) enters a new phase with new... Today, the German Centre for Integrative Biodiversity Research (iDiv) enters a new phase with new funding, a new COO, and a new research group.

October 1 marks a milestone for iDiv: As of today, permanent funding for the Central German research centre will be provided by the federal states of Saxony-Anhalt, Thuringia, and Saxony, alongside the hosting institutions Martin Luther University Halle-Wittenberg, Friedrich Schiller University Jena, and Leipzig University, in cooperation with the Helmholtz Centre for Environmental Research (UFZ). Since iDiv’s founding in 2012, primary funding has been provided solely by the Deutsche Forschungsgemeinschaft (DFG), which will continue to provide phase-out funding through 2025. Over the past 12 years, the research centre has established an international reputation as a leader in biodiversity research. A new funding model and the centre’s structural transition to a recognised association (e.V.) pave the way for iDiv to continue its important work.

German federal states provide primary funding

With the end of primary funding from the DFG, a new funding model is now in place. In addition to iDiv’s hosting institutions, the three hosting federal states are set to contribute to funding, with the science ministers of Saxony-Anhalt, Thuringia, and Saxony already having signed a declaration of intent in 2019. Project grants will also remain an important part of the iDiv funding model.

With more than 4,000 publications, iDiv has gained a reputation as one of the world’s hotspots for biodiversity research, attracting international researchers and has become a beacon for Central Germany. The centre has grown to include 310 staff from 43 nations, nine professors, and three junior research groups, who are helping create the scientific foundation for the sustainable management of biodiversity.

Legal expert takes over administrative management

Dr Anne Wesemann is taking over the administrative management of iDiv today. Wesemann has many years of experience in academic management, most recently as head of the Rector’s Office at Chemnitz University of Technology. She holds a doctorate in EU law from the University of Sussex in the UK.  

Anne Wesemann succeeds Dr Sabine Matthiä, who served as COO of iDiv from 2016 to 2024.

New research group “Biodiversity in the Anthropocene”

Professor Dr Susanne Fritz will take up a new “Biodiversity in the Anthropocene” professorship at Friedrich Schiller University Jena today. She will join the core research group of the same name at iDiv. From 2018 to 2024, Susanne Fritz held a joint professorship at Goethe University Frankfurt with the Senckenberg Biodiversity and Climate Research Centre (BiK-F). There, she investigated how geological climate changes have influenced the extinction and evolution of mammal and bird species and what conclusions can be drawn for current climate change and biodiversity loss. At iDiv, her research will continue to help better predict the future of biodiversity.

“In twelve years, iDiv has become an internationally renowned centre for integrative biodiversity research. The Central German universities in Halle, Jena and Leipzig, the Helmholtz Centre for Environmental Research and the federal states of Saxony-Anhalt, Thuringia and Saxony are paving the way for iDiv’s future”, says iDiv Speaker Professor Dr Martin Quaas. “We look forward to continuing to provide important insights into biodiversity in the coming decades.”

 

Since 2012, the German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig has been researching the global change of ecosystems and biodiversity as a DFG research centre. The new core research building at Alte Messe in Leipzig was completed in 2020 and today, more than 300 employees are building the scientific foundations for the sustainable use of our planet’s biodiversity. In addition, more than 170 members and their research groups at various locations in Central Germany contribute their expertise to iDiv research.

Kati Kietzmann

 

Contact:

Prof Dr Martin Quaas
Head of the research group Biodiversity Economics
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Email: martin.quaas@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/biodiversity-economics.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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iDiv TOP NEWS Media Release Tue, 01 Oct 2024 00:00:00 +0200
Faktencheck Artenvielfalt shows the state of biodiversity in Germany https://idiv-biodiversity.de//en/news/news_single_view/5405.html More than half of Germany’s habitat types have an ecologically unfavourable status More than half of Germany’s habitat types have an ecologically unfavourable status

This press release is only available in German.

 

The full text is only available in German.

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TOP NEWS Research Media Release Tue, 01 Oct 2024 00:00:00 +0200
Pollen affects cloud formation and precipitation patterns https://idiv-biodiversity.de//en/news/news_single_view/5390.html New study shows climate impact New study shows climate impact

Based on a media release of Leipzig University

Pollen not only plays a role in allergies, but also influences the local weather. Especially in spring, when large amounts are released, it contributes to the formation of ice in clouds, which can increase rainfall. A recent study published in Environmental Research Letters is the first to prove this outside the laboratory.

Ground-based and satellite observations in the United States show that increased pollen concentrations in spring lead to more cloud ice and more precipitation – even at temperatures between minus 15 and minus 25 degrees Celsius. “This is supported by laboratory results showing that pollen acts as an ice nucleus, influencing the freezing temperature of water in clouds and promoting precipitation,” says meteorologist Dr Jan Kretzschmar, lead author of the study. Without these ice-nucleating particles (INPs), water in clouds only freezes at temperatures below minus 38 degrees Celsius. “In the Breathing Nature Cluster of Excellence project, we therefore asked whether this effect could be detected outside the laboratory, and how climate change and biodiversity loss affect it,” says co-author Professor Johannes Quaas, Professor of Theoretical Meteorology at Leipzig and Member at the German Centre for Integrative Biodiversity Research (iDiv).

Regional and seasonal significance

On a global scale, the effect of pollen on ice formation is relatively small compared to, for example, dust, but it is significant on a regional and seasonal scale. Particularly in spring, large amounts of pollen are released, rising into the atmosphere and entering cold air layers. Kretzschmar explains: “Because of its size, pollen stays in the atmosphere for only a short time. Our study highlights the importance of smaller pollen fragments, which are produced when pollen ruptures under humid conditions. These smaller particles remain in the air longer and, in sufficient quantities, can enter cold atmospheric layers, where they trigger ice formation.”

Climate change intensifies pollen impact – biodiversity a key factor

Anthropogenic climate change is shifting the start of the pollen season, lengthening it and increasing pollen concentrations in the air. These trends are expected to intensify by the end of the century, which could lead to more frequent and intense local precipitation.

A further aspect of the study is the importance of biodiversity. Many plant species release large amounts of pollen at the same time each spring, which affects cloud formation and the amount of ice particles in the atmosphere. These interactions require further research to better understand the role of pollen in climate evolution and to incorporate this into future climate models. “If we can correctly simulate the effect of pollen and how it interacts with the climate, we will be able to make more accurate predictions,” says Kretzschmar.


The Institute for Meteorology at Leipzig University, the Leibniz Institute for Tropospheric Research (TROPOS), the German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and the Max Planck Institute for Biogeochemistry were involved in the study.

Katrin Henneberg


Original publication
(Researchers with iDiv affiliation are bolded)

Jan Kretzschmar, Mira Pöhlker, Frank Stratmann, Heike Wex, Christian Wirth, Johannes Quaas (2024). From trees to rain: enhancement of cloud glaciation and precipitation by pollen. Environmental Research Letters, DOI 10.1088/1748-9326/ad747a

 

Contact:

Dr Jan Kretzschmar
Institute for Meteorology / Theoretical Meteorology
Leipzig University
Phone: +49 341 97 - 32933
Email: jan.kretzschmar@uni-leipzig.de

 

Prof Dr Johannes Quaas
Institute for Meteorology / Theoretical Meteorology
Leipzig University
Phone: +49 341 9732931
Email: johannes.quaas@uni-leipzig.de

 

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Media Release iDiv Members TOP NEWS Tue, 17 Sep 2024 00:00:00 +0200
Plants, Ecosystems and Climate Change: International Conference of the German Society for Plant Sciences in Halle https://idiv-biodiversity.de//en/news/news_single_view/5388.html Botanik-Tagung takes place from 15 to 19 September at Martin Luther University Halle-Wittenberg Botanik-Tagung takes place from 15 to 19 September at Martin Luther University Halle-Wittenberg

 

The full text is only available in German.

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MLU News Media Release TOP NEWS Mon, 16 Sep 2024 00:00:00 +0200
Cloud cover reduced by large-scale deforestation https://idiv-biodiversity.de//en/news/news_single_view/5386.html Serious impact on climate, say researchers Serious impact on climate, say researchers

Based on a media release of Leipzig University

Researchers from iDiv, Leipzig University and Sun Yat-sen University in China have found that large-scale deforestation has a greater warming effect on the climate than previously thought. Their analysis of computer simulations and observations showed a decrease in cloud cover in these deforested areas. Deforestation has a warming effect by releasing carbon dioxide, but at the same time forests are darker than cleared areas. This effect causes cooling because less sunlight is absorbed. The new study shows that the reduction in cloud cover almost halves this cooling effect. These new findings have just been published in the journal Nature Communications.

“We found decreases in global low-level clouds and tropical high-level clouds from deforestation,” says lead author Dr Hao Luo from the Institute for Meteorology at Leipzig University, who co-authored the paper with his institute colleague Professor Johannes Quaas and Professor Yong Han from Sun Yat-sen University in China. Johannes Quaas adds: “Low-level clouds have a cooling effect on the climate because they reflect a lot of sunlight.” 

The researchers analysed idealised deforestation simulations using climate models and reanalyses, and on this basis provided insights into local decreases in global low-level clouds and tropical high-level clouds as a result of large-scale deforestation. “The decreased cloud cover can be explained by alterations in surface turbulent heat flux, which diminishes uplift and moisture to varying extents,” says Professor Quaas, who is also an iDiv Member.

According to the researchers, the impact of the different meteorological processes in forests and deforested areas on clouds and the associated radiative balance has not yet been sufficiently studied. For example, researchers in meteorology and biodiversity science are currently investigating the role of forest biodiversity and its impact on clouds.

Susann Sika

 

Original publication
(Reseachers with iDiv affiliation bolded)

Luo, H., Quaas, J. & Han, Y. (2024). Decreased cloud cover partially offsets the cooling effects of surface albedo change due to deforestation”, Nature Communications, DOI: 10.1038/s41467-024-51783-y

 

Contact:

Prof Dr Johannes Quaas
Institute for Meteorology / Theoretical Meteorology
Leipzig University
Phone: +49 341 9732931
Email: johannes.quaas@uni-leipzig.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Media Release TOP NEWS iDiv Members Tue, 10 Sep 2024 00:00:00 +0200
Island life slows animals down https://idiv-biodiversity.de//en/news/news_single_view/5383.html Birds and mammels on islands have a slower metabolism than their closest relatives on the mainland Birds and mammels on islands have a slower metabolism than their closest relatives on the mainland

Based on a media release of Martin Luther University Halle-Wittenberg (MLU)

When birds and mammals live on islands, they also have offspring later. This slow way of life makes it difficult for them to adapt to rapid changes such as those caused by humans. This is the finding of a new study led by an international team from the German Centre for integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and Martin Luther University Halle-Wittenberg (MLU), the Chinese Academy of Sciences and Sichuan Agricultural University. For the study, the team analysed data from around 2,800 animal species on islands and the mainland. The results were published in the journal Science Advances.

Islands are unique habitats due to their geographic location: "On islands, animals find a limited food supply, but also less predators as well as competitors. They adapt to these peculiar conditions in order to maximize their success at surviving and reproducing. This leads to unique evolutionary adaptations," says palaeontologist Dr Roberto Rozzi from MLU and alumnus from iDiv. For example, animals that are significantly larger or smaller than their mainland counterparts can be found on islands. These phenomena are known as island dwarfism or gigantism. "Along these and other morphological changes, insular vertebrates can also show changes in life history and metabolism," continues Rozzi.

According to Rozzi, little was previously known about the differences in metabolism between island and mainland dwellers. The team therefore analysed data, including metabolic data, from 2,813 vertebrate species: these included 2,118 species with the same temperature, including birds and mammals, and 695 species with alternating temperatures, such as reptiles and amphibians. According to the study, birds and mammals on islands tend to have a slower metabolism and have offspring later. "This adaptation helps them to thrive in pristine island environments. However, it also makes these animals particularly vulnerable after human colonization. While dwarfism and gigantism predispose island biotas to direct hunting and predation by introduced species, a slower pace of life makes it harder for them to bounce back after environmental disturbances such as invasive species or lost habitats," summarises Rozzi.

The results of the study provide important information for effective species conservation on islands: particularly vulnerable species can be identified. "To better protect the remaining island species conservation prioritization should also take into account their unique morphological and physiological differences from their mainland counterparts," concludes Rozzi.

The study was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) and the Scientific Research Foundation as well as the Nature Science Foundation in China.


Original publication

(Researchers with iDiv affiliation and alumni bolded)

Xiong, Y., Rozzi, R., Zhang, Y., Fan, L., Zhao, J., Li, D., ... & Lei, F. (2024). Convergent evolution toward a slow pace of life predisposes insular endotherms to anthropogenic extinctions. Science Advances. DOI: 10.1126/sciadv.adm8240

 

Contact:

Dr Roberto Rozzi
Central Repository for Natural Science Collections
Martin Luther University Halle-Wittenberg
Phone: +49 345 55-26073
Email: roberto.rozzi@zns.uni-halle.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Media Release TOP NEWS MLU News Biodiversity Synthesis Mon, 09 Sep 2024 00:00:00 +0200
Research Training Group ECO-N has started https://idiv-biodiversity.de//en/news/news_single_view/5381.html Early career researchers study sustainable development Early career researchers study sustainable development

Based on a media release of Leipzig University

A new Research Training Group, called Economics of Connected Natural Commons (ECO-N), has begun to explore the complex interactions between the economy, human behaviour and natural resources. A welcome week for the first doctoral researchers will be held from 23 to 27 September 2024.

The first cohort of 14 doctoral researchers will study approaches to the sustainable use of common natural resources in the areas of atmosphere and biodiversity. They will gain expertise in their respective fields – economics, meteorology and integrative biodiversity research – and develop a systemic perspective on the challenges of sustainable development.

The doctoral researchers will be supervised by experts from Leipzig University's Faculty of Economics and Management Science, the Faculty of Physics and Earth System Sciences, the Faculty of Life Sciences, the German Centre for Integrative Biodiversity Research (iDiv) and the non-university research institutions Helmholtz Centre for Environmental Research (UFZ) and the Leibniz Institute for Tropospheric Research (TROPOS).

Nina Vogt


Related news articles
DFG gives green light for new Research Training Group

 

Contact:

Prof Dr Martin Quaas
Head of the research group Biodiversity Economics
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Email: martin.quaas@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/biodiversity-economics.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Biodiversity Economics Media Release TOP NEWS Fri, 06 Sep 2024 00:00:00 +0200
Environmental stressors weaken ecosystem resistance to change https://idiv-biodiversity.de//en/news/news_single_view/5379.html The higher the environmental stress, the lower the resistance to global change. The higher the environmental stress, the lower the resistance to global change.

Based on a press release by Manuel Delgado-Baquerizo, Instituto de Recursos Naturales y Agrobiología de Sevilla (CSIC)

The international study, led by Spain’s IRNAS-CSIC with the Biodiversity and Ecosystem Functioning Laboratory (BioFunLab) and the German Center for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig, analysed 1,023 global change experiments worldwide in collaboration with ten other international institutions.
 
“Terrestrial ecosystems are subject to a myriad of climate change and environmental degradation factors, including global warming, drought processes, atmospheric pollution, fires, or overgrazing, among many others,” explains Manuel Delgado-Baquerizo, BioFunLab leader and senior author of the paper.
 
These so-called global change factors impact the ability of ecosystems to provide services such as carbon sequestration or soil fertility, which are important for mitigating climate change and ensuring food production, respectively. The researchers’ analysis covered seven ecosystem services.
 
Overburdened ecosystems
The analysis shows that as the number of global change factors to which the ecosystems are subject increases, these ecosystems become more and more sensitive, reducing their natural capacity to resist the impacts of environmental perturbations.
 
Using 15 years of data from the Jasper Ridge Global Change Experiment in California, the study further found that this sensitivity is especially pronounced when the stress (for example, warming) is sustained over time, affecting the ecosystems’ ability to provide services.
 
“As various environmental changes interact and collectively reduce the stability of ecosystems, it becomes considerably more challenging for researchers to predict future ecosystem services,” explains Prof. Nico Eisenhauer from iDiv and Leipzig University.
 
In contrast, biodiversity showed a higher resistance to multiple global changes, with the researchers noting a less pronounced effect compared to ecosystem functions, explains Guiyao Zhou, first author of the paper, who is a former Humboldt Fellow at iDiv and a member of the BioFunLab.
 
“Our findings show that the sustainability of our ecosystems depends on reducing the number of global drivers of change associated with human activity,” Zhou concludes.
 
Original publication:

(Researchers with iDiv affiliation and alumni bolded)


Zhou, G., Eisenhauer, N., Terrer, C., Eldridge, D.J., Duan, H., Guirado, E., Berdugo, M., Zhou, L., Liu, S., Zhou, X., Delgado-Baquerizo, M. (2024) Resistance of ecosystem services to global change weakened by increasing number of environmental stressors. Nature Geoscience. DOI: https://doi.org/10.1038/s41561-024-01518-x

 

Contact:

Prof Dr Nico Eisenhauer
Head of the research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 97 33167
Email: nico.eisenhauer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/eisenhauer_nico.html

 

Christine Coester
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: christine.coester@idiv.de

 

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TOP NEWS Research Experimental Interaction Ecology Tue, 27 Aug 2024 00:00:00 +0200
Healthier honey bees found near organic fields and flower strips https://idiv-biodiversity.de//en/news/news_single_view/5378.html A new study reveals how farming practices affect colony health. A new study reveals how farming practices affect colony health.

Based on a media release by Martin Luther University Halle-Wittenberg (MLU)

 

Organic farming and flower strips promote the health of honey bees, with colonies growing stronger and generally being healthier when living in their vicinity. This is most likely because these areas provide bees with a diverse and continuous food supply, and there is less exposure to pesticides, according to a new study published in the Journal of Applied Ecology

The team of researchers from the German Centre for Integrative Biodiversity Research (iDiv), Martin Luther University Halle-Wittenberg (MLU) and the University of Göttingen analysed data from 32 bee colonies in 16 locations across Germany with differing proportions of organic fields, flower strips, and semi-natural habitats.

“The way that farmers cultivate their land has a major impact on nature. Intensively farmed fields, pesticides and monocultures pose a threat to many animal and plant species,” says Professor Robert Paxton, a bee researcher at MLU and iDiv Member. “This is particularly true for pollinators, which include honey bees.”

Around half of Germany’s land is used for agriculture, according to the German Environment Agency (UBA). Prominent measures counteracting this development have included increasing the proportion of organic farming, planting more flower strips, and creating perennial semi-natural areas near crop fields. “In theory, these measures all make sense. However, we know little about how each of these measures affects insects, especially honey bees,” continues Paxton.

To find out more, the team carried out their study in 16 locations across Lower Saxony, in eastern Germany. Honey bee colonies at each of these sites had access to differing proportions of organic fields, flower strips, and perennial semi-natural habitats for about a year. The researchers analysed, for example, colony growth and parasite infestation, paying special attention to the Varroa mite. Varroa mites are a particularly dangerous honey bee pest because they transmit viruses that are fatal to the bees. 

The data gathered about the bee colonies was then compared. “Organic farming had the greatest impact – the larger the proportion of these areas, the lower the parasite infestation of a colony. This improved colony growth,” explains lead author Patrycja Pluta from MLU. One reason for this could be that organic farming uses fewer pesticides and opts for other plant protection measures. Flower strips were also advantageous to honey bees: Varroa mites were lower in areas with many flower strips. “This could be due to the fact that a diverse and rich food supply strengthens the honey bees’ immune system,” reasons Pluta. 

Perennial semi-natural habitats, on the other hand, tended to be disadvantageous for honey bees. Larger areas generally meant a greater infestation of Varroa mites. And, unlike flower strips, the areas are not designed to provide an abundant supply of food for honey bees and other pollinators. “Perennial semi-natural landscapes are an important tool for promoting biodiversity, and they serve as a habitat for many animals. Honey bees, which are managed by humans, are the exception,” says Paxton. The study’s findings could help to improve agricultural landscape management for honey bees and other pollinators.

The study was funded by the Federal Ministry of Food and Agriculture on the basis of a decision by the German Bundestag as part of the Federal Organic Farming Programme and by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation).

 

Original publication
(Researchers with iDiv affiliation and alumni bolded)

Pluta, P., Czechofsky, K., Hass, A., Frank, L., Westerhoff, A., Klingenberg, H., Theodorou, P., Westphal, C., Paxton, R. (2024) Organic farming and annual flower strips reduce parasite prevalence in honey bees and boost colony growth in agricultural landscapes. Journal of Applied Ecology, DOI: 10.1111/1365-2664.14723

 

Contact:

Prof Dr Robert Paxton
Head of General Zoology
Martin Luther University Halle-Wittenberg (MLU)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 345 55 26451
Email: robert.paxton@zoologie.uni-halle.de
Web: https://www.zoologie.uni-halle.de/allgemeine_zoologie/staff/prof._dr._robert_paxton/?lang=en

 

Christine Coester
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: christine.coester@idiv.de

 

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Media Release TOP NEWS iDiv Members Research Wed, 21 Aug 2024 00:00:00 +0200
Unlocking the Wealth of Biodiversity Knowledge: Amplifying Diverse Voices Through Collective Responsibility https://idiv-biodiversity.de//en/news/news_single_view/5367.html Researchers developed a comprehensive framework to promote diversity, equity, and inclusion in... Researchers developed a comprehensive framework to promote diversity, equity, and inclusion in global biodiversity research

Report by Jose Valdez, postdoctoral researcher of Biodiversity Conservation at iDiv and Martin Luther University Halle-Wittenberg (MLU)

The global biodiversity crisis demands comprehensive, collaborative solutions that draw upon diverse knowledge and perspectives from around the world. Yet, a critical gap exists in biodiversity research, where the expertise and insights of local scientists and communities in biodiversity-rich regions are frequently overlooked and undervalued.

Local experts in these underrepresented regions possess invaluable knowledge but face significant barriers to having their research recognized and integrated into global conservation efforts. This disconnect leads to conservation priorities being set by individuals detached from the source environments and cultures, resulting in strategies that fail to account for critical local contexts, ultimately undermining the effectiveness of biodiversity conservation.

To address this challenge, we - an international team of researchers from underrepresented backgrounds and biodiversity-rich regions - developed a comprehensive framework to promote diversity, equity, and inclusion in global biodiversity research. Published in the journal Conservation Biology, this holistic approach of collective responsibility provides tangible strategies for researchers, institutions, publishers, and funders to work together in dismantling systemic barriers.

In our article, we identify four key challenges hindering equitable participation in biodiversity research:

●       Linguistic bias: The dominance of English in scientific publishing creates barriers for non-native speakers and limits the dissemination of research conducted in other languages.

●       Undervalued research contributions: Important research from underrepresented regions and non-English publications is often overlooked, leading to a skewed representation of global biodiversity knowledge.

●       Parachute science and extractive practices: External researchers conducting studies without meaningful local collaboration fail to account for cultural context and local needs.

●       Capacity constraints: Researchers from underrepresented regions often face limited access to funding, resources, and training opportunities, hindering their ability to participate fully in global research efforts.

To overcome these systemic barriers, our framework calls for coordinated, cross-stakeholder efforts. Achieving meaningful progress requires everyone involved in biodiversity research to recognize their role and take action. As interconnected participants, we all share the responsibility to cultivate a more inclusive and equitable research environment.

For researchers, this means expanding literature searches to non-English languages, fostering local partnerships, and actively promoting knowledge exchange. Institutions are encouraged to establish specialized liaison roles, implement equitable policies, and provide greater support for international collaborations. Publishers can facilitate multilingual dissemination and ensure equitable representation in peer review. Funding bodies, in turn, must start to remove systemic barriers and prioritize equitable resource allocation.

Regardless of our roles, we must promote good scientific practices that amplify underrepresented voices and dismantle biases. Inclusivity is not just an ethical imperative; diverse collaborations yield more robust science that directly informs locally relevant and culturally sensitive conservation action.

With this framework of shared responsibility, the biodiversity research community can empower underrepresented voices, integrate local and Indigenous knowledge, and maximize our collective impact for effective global conservation—unlocking new possibilities to address the biodiversity crisis.

 

Original publication
(Researchers with iDiv affiliation and alumni are bolded)

Valdez, J., Damasceno, G., Oh, R. R. Y., Quintero Uribe, L. C., Barajas Barbosa, M. P., Amado, T. F., Schmidt, C., Fernandez, M., & Sharma, S. (2024). Strategies for advancing inclusive biodiversity research through equitable practices and collective responsibility. Conservation Biology, DOI: 10.1111/cobi.14325

Español: DOI 10.1590/SciELOPreprints.7622

Português: DOI 10.1590/SciELOPreprints.7623

 

Contact:

Dr Jose W. Valdez (speaks English and Spanish)
Postdoctoral Researcher
Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9739168
Email: jose.valdez@idiv.de
Web: https://www.idiv.de/en/profile/1290.html

 

Dr Gabriella Damasceno
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Email: gabriella.damasceno@idiv.de

 

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iDiv Media Release TOP NEWS Wed, 07 Aug 2024 00:00:00 +0200
Why making science accessible to kids around the globe rocks! https://idiv-biodiversity.de//en/news/news_single_view/5365.html Communicating science to a broad audience has various benefits for all stakeholders Report by Elisabeth Bönisch, Romy Zeiss (iDiv and Leipzig University) and Professor Dr. Malte Jochum (University of Würzburg and iDiv alumnus)

Leipzig / Würzburg. Making science accessible to everyone is worth it! Communicating to kids forced us to look at our research from a much broader perspective - thereby helping us to improve our own writing skills. Moreover, we vastly expanded our network of research and non-research contacts globally. In an article just out in Soil Organisms, we summarized the various benefits for people involved in our science communication project “Translating Soil Biodiversity”. Our article highlights one way of making science available and accessible, especially to kids around the world, while at the same time benefiting also the communicators and everyone involved.

We all know full work schedules. And science communication is often one of many extra tasks on the researcher’s agenda that doesn’t make it in the end. But it’s worth it! We, Rémy Beugnon, Helen Phillips, Malte Jochum, Romy Zeiss and Elisabeth Bönisch, are the core team coordinating the project “Translating Soil Biodiversity”. But there are far more people involved, among them > 100 volunteers that helped writing and translating 33 articles for kids into already more than 20 languages.

How are we benefiting?

  • By communicating our research to the public in plain language, we all enhanced both our writing skills and our ability to frame the context and relevance of our work. 
  • Collaborating globally also increased our social networks within and across disciplines, for example to responsibles for media and communication, teachers, or subject-specific didactics and pedagogy. 
  • As the main output, our project creates a resource that can be used for teaching in schools, at universities and in adult education. 

"We aim to inspire curiosity, foster understanding, and cultivate a sense of stewardship towards the environment from an early age.”
(from the article)

Our article illustrates both our journey with this science-communication project and the many ways everyone involved has profited from this work. With our article, we hope to motivate fellow scientists to think of creative ways of how to reach broader and particularly non-scientific audiences. Our experience shows that the time and resources put into this line of work pay back in multiple ways and that science communication has the potential to give an additional kind of value and reward to our careers that we do not want to miss.

About the project Translating Soil Biodiversity:

In 2019, our team started editing a series of scientific articles covering various aspects of soil biodiversity tailored towards kids aged 8–15. These articles were written by scientists, reviewed by kids, and finally published in English in the journal Frontiers for Young Minds. To bridge the language barrier and make scientific knowledge accessible and engaging for kids around the world, beyond the English-speaking community, our project Translating Soil Biodiversity aims to provide translations of the articles into as many languages as possible.

Check out the article and visit our project website to find out about the dedicated volunteers whose efforts have made this project possible.

 

Original publication
(Researchers with iDiv affiliation and alumni are bolded)

Beugnon, R. & Zeiss, R., Bönisch, E., Phillips, H. R. P. & Jochum, M. (2024). Communicating soil biodiversity research to kids around the world. Soil Organisms 96(2), 61–68. https://doi.org/10.25674/413

 

Contact person

Elisabeth Bönisch
Research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone +49 341 9733185
E-mail elisabeth.boenisch@idiv.de

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Media Release Experimental Interaction Ecology TOP NEWS Thu, 01 Aug 2024 15:40:45 +0200
Why is fallow land so important? https://idiv-biodiversity.de//en/news/news_single_view/5362.html New video with Dr Guy Peer from iDiv and UFZ shows the importance of fallow land New video with Dr Guy Peer from iDiv and UFZ shows the importance of fallow land
 

Fallow land sometimes has a bad reputation as ‘non-productive’ land. However, they are of great benefit to biodiversity, emphasises Dr Guy Pe'er, scientist at the German Centre for Biodiversity Research (iDiv) and the Helmholtz Centre for Environmental Research (UFZ). In the CAP4GI - GAP for diverse landscapes project, he is working with other scientists from various research institutions and nature conservation organisations to develop and evaluate innovative models for implementing measures that can achieve benefits for both biodiversity and farms.

Ecologist Guy Pe'er and two farmers explain the benefits of fallow land for agriculture, society and biodiversity in a 4-minute video (in German): Link to video

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Media Release TOP NEWS Wed, 31 Jul 2024 14:16:32 +0200
Less productive yet more stable https://idiv-biodiversity.de//en/news/news_single_view/5361.html Low-intensity grassland is better able to withstand the consequences of climate change Low-intensity grassland is better able to withstand the consequences of climate change

Based on a media release of the Helmholtz Centre for Environmental Research (UFZ)

Climate change will have a considerable influence on the biodiversity and productivity of meadows and pastures. However, according to the results of the large-scale climate and land use experiment, the extent of these changes depends on the land use. A team of researchers from UFZ and iDiv found that grassland optimised for high yield responds much more sensitively to periods of drought than less intensively used meadows and pastures. According to an article recently published in Global Change Biology, this can certainly have economic consequences for the farmers affected.

Grassland is one of the most important and most widespread ecosystems on earth. Such open landscapes with grasses and herbs not only cover more than one quarter of the entire land surface but also store at least one third of the terrestrial carbon, are crucial for food production, and can be extremely species-rich in a relatively small area. But what is the future of these habitats? The study provides new insights into this question.

It has long been clear that two environmental changes are threatening the world’s grasslands. Particularly in Europe, grasslands are now fertilised much more heavily, mowed more frequently, and grazed more intensively. In addition, farmers often sow only a handful of grass varieties that promise a particularly high yield. This intensification of land use is fundamentally changing the species composition and functionality of meadows and pastures. The same applies to climate change. For Germany, climate change will result in a shift in the seasonal distribution of precipitation as well as an increase in hydrological extremes (e.g. heavy rainfall and droughts), among other things. It is considered the second largest threat for these ecosystems. 

When both changes come together, they can reinforce each other. However, nobody yet knows exactly what will happen. Most experiments on this topic have so far focussed on either the climate or land use. “What makes our study unique is that we investigated the interaction of both factors”, explains first author Dr Lotte Korell, biologist at iDiv and UFZ. 

This was made possible by the large-scale and long-term experiment of the UFZ in Bad Lauchstädt near Halle, the Global Change Experimental Facility (GCEF). It consists of 50 plots, each measuring 16 × 24 m; these are used with varying degrees of land use intensity. Temperatures and precipitation levels can also be manipulated with the help of mobile roof systems. For example, some plots receive 10% more precipitation in spring and autumn and 20% less in summer than the untreated control plots. This roughly corresponds to the conditions that climate models project for central Germany.

An eight-year data series from this experiment has now been compiled for the new study. The researchers analysed the biodiversity and productivity of the plants on the differently used plots between 2015 and 2022. “This period includes three of the driest years this region has experienced since beginning of records”, recalls Korell. These droughts apparently had a much stronger effect on the plants than the experimentally simulated climate change. 

However, in both cases, the trend pointed in the same direction: species-rich grassland that is only rarely mown or sparsely grazed withstood the heat and drought much better than the intensively used high-performance meadows. “Among other factors, this is probably related to the diversity of species”, says Korell. This varied greatly depending on the land use of the grasslands. 

A diverse mixture of more than 50 native grasses and herbs grew on the less intensively used meadows and pastures of the GCEF. However, on the intensively used grassland, the researchers had sown only the five grass varieties recommended to farmers by the Saxony-Anhalt State Institute for Agriculture and Horticulture for drier sites at the start of the experiment. These included varieties of meadow grass (Dactylis glomerata) and perennial ryegrass (Lolium perenne). 

Because such grasses are bred for maximum yield and were also heavily fertilised – as is common in agricultural practice – the intensive meadows were initially much more productive than the more diverse grasslands. However, they were able to make use of this advantage only in favourable climatic conditions and were not able to withstand the drought as well as the plants in the low-intensity meadows and pastures. In times of drought, the grasses in the intensively used meadows increasingly died back and were replaced by other species such as chickweed (Stellaria media), shepherd’s purse (Capsella bursa-pastoris), dandelion (Taraxacum officinale), and small-flowered cranesbill (Geranium pusillum). “These are mostly short-lived species that survive as seeds”, explains senior author Dr Harald Auge, also a biologist at the UFZ and iDiv Member. When the more competitive plants succumb to drought, these species take the opportunity to invade their habitats: they either migrate from the low-intensity grassland or germinate from the seed stock in the soil. 

This shift in species composition is not particularly welcomed by farmers, especially because most of the new arrivals have a lower fodder quality than the grasses originally sown. The common ragwort (Senecio vulgaris), which was frequently represented among the immigrating species in the experiment, is in fact poisonous. All of this reduces the productivity of the land. 

Farmers have long been aware of this kind of degradation of high-performance grassland by immigrating species. They therefore expect to have to plough up and reseed their land every few years. “However, climate change may accelerate this need and lead to additional costs”, says Korell. Perhaps everything will go well for a few years and it will rain enough. However, it is also possible that several dry summers will follow one another. Climate change is making conditions even more unpredictable. 

Farmers who have only intensive grassland are therefore less able to plan in such times and thus bear a greater economic risk. On the other hand, low-intensity meadows and pastures not only make an important contribution to preserving biodiversity but also help to stabilise the productivity of grassland in times of climate change. 

 

Original publication
(Researchers with iDiv affiliation and alumni bolded)

Lotte Korell, Martin Andrzejak, Sigrid Berger, Walter Durka, Sylvia Haider, Isabell Hensen, Yva Herion, Johannes Höfner, Liana Kindermann, Stefan Klotz, Tiffany M. Knight, Anja Linstädter, Anna-Maria Madaj, Ines Merbach, Stefan Michalski, Carolin Plos, Christiane Roscher, Martin Schädler, Erik Welk, Harald Auge: Land use modulates resistance of grasslands against future climate and inter-annual climate variability in a large field experiment, Global Change Biology, 2024. DOI: 10.1111/gcb.17418

 

Contact:

Dr Lotte Korell
Helmholtz Centre for Environmental Research (UFZ)
German Centre for Integrative Biodiversity Research (iDiv) Halle - Jena - Leipzig
Phone: +49 341 9733246
Email: lotte.korell@ufz.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/717.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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UFZ News Media Release TOP NEWS Mon, 22 Jul 2024 00:00:00 +0200
Considering the mental health implications of nature conservation https://idiv-biodiversity.de//en/news/news_single_view/5356.html Nature supports the economic and social aspects that underly mental health Nature supports the economic and social aspects that underly mental health


Based on a joint text by Imperial College London and the University of Oxford

We gain a variety of health and wellbeing benefits from interacting with nature – everything from physical benefits, like better cardiovascular health, to psychological benefits, like improvements to mood and lower fatigue. But nature also sustains the economic and material dimensions of people’s lives that support their mental health. These links are particularly important in the rural Global South, where millions rely on nature to meet their basic needs.
 
Researchers from the German Centre for Integrative Biodiversity Research (iDiv), the Helmholtz Centre for Environmental Research (UFZ), Imperial College London, and the University of Kent, have published a new framework in One Earth for conservationists and public health professionals to understand the connections between nature, its loss and conservation, and mental health. This framework captures the diverse direct and indirect relationships between mental health and nature, exploring the potential but as yet unknown mental health impacts of the global nature crises. Lead author Dr Thomas Pienkowski, who completed this work as part of his DPhil in Biology and is now at Imperial College London, said:

“We don’t know much about how the global nature crisis will affect mental health. Most research in this area has overlooked how nature supports the socioeconomic fabric of people’s lives that underpin their mental health.”

The framework explains how nature’s material contributions, like wild-harvested foods, products, and building materials, affect the ‘social determinants’ of mental health – and how losing these contributions, like the collapse of fisheries, can worsen stressors like poverty. The researchers also wanted to explore how conserving biodiversity might impact mental health by changing how nature’s benefits are distributed and accessed or creating direct effects through conservation projects.
 
The research has a particular focus on the Global South, where many people rely on natural resources to meet their basic needs. 
 
“The current body of knowledge predominantly represents high-income, English-speaking, and urban populations. This skewed focus motivated our paper to highlight the urgent need to include people who rely directly on nature for their survival,” explains co-author Dr Rachel Oh, Postdoctoral Research Associate at UFZ and iDiv. “For them, restoring, maintaining and/or improving ecosystem functions is crucial, as it ensures the continued supply and, therefore, access to vital natural resources necessary for their survival, health, and wellbeing.”
 
The team hope that the framework helps conservationists to consider the mental health implications of the different strategies that they take. Dr Pienkowski adds an example:

“Governments around the world have committed to expanding area-based conservation to 30% of the world’s surface by 2030, which will affect the lives of hundreds of millions of people. That expansion could take the form of relatively strict protected areas that exclude people. Our framework suggests that such an approach might undermine progress towards global mental health goals. 

Alternatively, other approaches could support local communities and Indigenous groups in managing landscapes in ways that benefit nature while also supporting local livelihoods and cultures. These approaches may help support residents’ mental health by recognising their rights to natural resources, land, culture, and self-determined governance systems.”

 
Original publication
(Researchers with iDiv affiliation are bolded)
 Pienkowski, T., Keane, A., Booth, H., Kinyanda, E., Fisher, J.C., Lawrance, E., Oh, R. R. Y., and Milner-Gulland, E.J. (2024). Nature’s contributions to social determinants of mental health and the role of conservation. One Earth, DOI: https://doi.org/10.1016/j.oneear.2024.05.004

 

Contact:

Dr Ruy Ying Rachel Oh (speaks English and Chinese)
Postdoctoral Researcher in the Ecosystem Services research group
Helmholtz Centre for Environmental Research (UFZ), Germany
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig, Germany
Phone: +49 341 9733121
Email: rachel.oh@idiv.de
Web: https://www.idiv.de/en/profile/1414.html

 

Christine Coester
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: christine.coester@idiv.de

 

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Research TOP NEWS Biodiversity and People Fri, 19 Jul 2024 00:00:00 +0200
How a plant app helps identify the consequences of climate change https://idiv-biodiversity.de//en/news/news_single_view/5352.html By leveraging millions of time-stamped observations, researchers can identify plant rhythms and... By leveraging millions of time-stamped observations, researchers can identify plant rhythms and ecological patterns year-round

Leipzig. A research team led by the German Centre for Integrative Biodiversity Research (iDiv) and Leipzig University has developed an algorithm that analyses observational data from the Flora Incognita app. The novel approach described in Methods in Ecology and Evolution can be used to derive ecological patterns that could provide valuable information about the effects of climate change on plants.

Plants are known to respond to seasonal changes by budding, leafing, and flowering. As climate change stands to shift these so-called phenological stages in the life cycle of plants, access to data about phenological changes – from many different locations and in different plants – can be used to draw conclusions about the actual effects of climate change. However, conducting such analyses require a large amount of data and data collection of this scale would be unthinkable without the help of citizen scientists. “The problem is that the quality of the data suffers when fewer people engage as citizen scientists and stop collecting data,” says first author Karin Mora, research fellow at Leipzig University and iDiv.

Mobile apps like Flora Incognita could help solve this issue. The app allows users to identify unknown wild plants within a matter of seconds. “When I take a picture of a plant with the app, the observation is recorded with the (exact) location as well as a time stamp,” explains co-author Jana Wäldchen from the Max Planck Institute for Biogeochemistry (MPI-BGC), who developed the app with colleagues from TU Ilmenau. “Millions of time-stamped plant observations from different regions have been collected by now.” Although satellite data also records the phenology of entire ecosystems from above, they do not provide information about the processes taking place on the ground.

Plants show synchronised response

The researchers developed an algorithm that draws on almost 10 million observations of nearly 3,000 plants species identified between 2018 and 2021 in Germany by users of Flora Incognita. The data show that each individual plant has its own cycle as to when it begins a flowering or growth phase. Furthermore, the scientists were able to show that group behaviour arises from the behaviour of individuals. From this, they were able to derive ecological patterns and investigate how these change with the seasons. For example, ecosystems by rivers differ from those in the mountains, where phenological events start later.

The algorithm also accounts for the observational tendencies of Flora Incognita users, whose data collection is far from systematic. For example, users record more observations on the weekend and in densely populated areas. “Our method can automatically isolate these effects from the ecological patterns,” Karin Mora explains. “Fewer observations don’t necessarily mean that we can’t record the synchronisation. Of course, there are very few observations in the middle of winter, but there are also very few plants that can be observed during that time.”

It is known that climate change is causing seasonal shifts – for example, spring is arriving earlier and earlier. How this affects the relationship between plants and pollinating insects and therefore potentially also food security is still being subject to further research. The new algorithm can now be used to better analyse the effects of these changes on the plant world.

 

This study was funded by the Deutsche Forschungsgemeinschaft (DFG; FZT-118) and the iDiv Flexpool. Furthermore, the work of the research team was supported by special funds provided by the Saxon State Ministry for Science, Culture and Tourism (SMWK) for the "Breathing Nature" Cluster of Excellence Initiative.

 

Kati Kietzmann

 

Original publication
(Researchers with iDiv affiliation and alumni bolded)

Karin Mora, Michael Rzanny, Jana Wäldchen, Hannes Feilhauer, Teja Kattenborn, Guido Kraemer, Patrick Mäder, Daria Svidzinska, Sophie Wolf, Miguel D. Mahecha (2024): Macrophenological dynamics from citizen science plant occurrence data. Methods in Ecology and Evolution, DOI: 10.1111/2041-210X.14365

 

Related links

Flora incognita

Press release: How smartphones can help detect ecological change

 

Contact:

Dr Karin Mora
Institute for Earth System Science and Remote Sensing
Remote Sensing Centre for Earth System Research
Leipzig University
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: karin.mora@uni-leipzig.de

 

Prof. Dr Miguel Mahecha
Remote Sensing Centre for Earth System Research
Leipzig University
Helmholtz Centre for Environmental Research - UFZ
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: miguel.mahecha@uni-leipzig.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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TOP NEWS Research iDiv Members Media Release Tue, 09 Jul 2024 00:00:00 +0200
What do we need for better biodiversity monitoring in Europe? https://idiv-biodiversity.de//en/news/news_single_view/5354.html Study identifies policy needs, challenges, and future pathways. Study identifies policy needs, challenges, and future pathways.

Based on a media release of IIASA

A new publication in Conservation Letters authored by scientists from the German Centre for Integrative Biodiversity Research (iDiv) and the International Institute for Applied Systems Analysis (IIASA) with a large European consortium provides vital insights into the current status of biodiversity monitoring in Europe, identifying policy needs, challenges, and future pathways.

According to the European Environment Agency, Europe’s biodiversity continues to decline at an alarming rate due to anthropogenic pressures. Improving biodiversity monitoring data is crucial to ensure effective implementation of the EU Biodiversity Strategy goals, successful conservation policies, and restoration management under the EU Nature Restoration Law. Knowing about data needs from users and policy makers is the first step toward achieving this.

“Current monitoring efforts in Europe suffer from a variety of limitations, hindering their effectiveness. They are often fragmented across ecosystems and habitats with little continuity. For example, the environmental status of 20-70% of all EU marine regions is unknown,” says study lead author Hannah Moersberger from the Helmholtz Centre for Environmental Research (UFZ) and iDiv. “In addition, there is a lack of studies engaging directly with data users and policymakers to map their needs.” 

Key findings 

To address these issues, the scientists used a four-step user-centered stakeholder engagement process, which consisted of an international public stakeholder workshop, an online survey, semi-structured interviews, and an expert meeting with representatives of EU member states. The survey conducted across Europe identified 274 biodiversity monitoring programs that are currently in place across European countries and agencies. The data reflected a bias in the attention paid to different biomes and species. Birds were, for instance, the most frequently monitored group, accounting for 28% of all monitoring efforts.

“In our study, we systematically assessed the user and policy needs as well as regular uptake of monitoring data from structured monitoring and citizen science programs in national policy workflows,” says senior author Professor Aletta Bonn, head of the Biodiversity and People research group at UFZ, iDiv, and Friedrich Schiller University Jena.

“Our research identified and highlighted the many uses such data can have across a variety of sectors, whether for drawing up agricultural strategies, conservation and restoration plans, or managing hunting permits within a country,” explains study co-author Jose Valdez from iDiv and Martin Luther University Halle-Wittenberg (MLU).

The study identified four main clusters of key policy areas related to biodiversity monitoring within the next decade: assessing biodiversity and species trends; assessing biodiversity policy impact and effectiveness; integrating biodiversity in other policy sectors; and operationalization of monitoring. 

Challenges and solutions 

The study also identified the top ten challenges to current biodiversity monitoring activities in Europe. These were primarily associated with four major types of obstacles: lack of integrated data, insufficient data, insufficient resources, and biased data. The stakeholders involved in the study identified five ways to improve biodiversity monitoring and policy impacts in Europe:

  • enhanced coordination and cooperation
  • standardization for enhanced data gathering and dissemination
  • use of advanced models and new technologies
  • better coordination of financial resources and capacity building
  • stakeholder engagement

Building on this study, a proposal for the European Biodiversity Observation Coordination Centre was presented by the EuropaBON consortium to the European Commission and the European Environment Agency in Brussels earlier this year.

“This is a major milestone for safeguarding biodiversity in Europe and facilitating modern, evidence-based policy and decision making for conservation and restoration management,” concludes Professor Henrique Pereira, another author of the study, chair of the EuropaBON consortium, and head of the Biodiversity Conservation research group at iDiv and MLU.

 

Original publication
(Researchers with iDiv affiliation and alumni bolded)

Hannah Moersberger, Jose Valdez, Juliette G. C. Martin, Jessica Junker, Ivelina Georgieva, Silke Bauer, Pedro Beja, Tom D. Breeze, Miguel Fernandez, Néstor Fernández, Lluís Brotons, Ute Jandt, Helge Bruelheide, W. Daniel Kissling, Christian Langer, Camino Liquete, Maria Lumbierres, Anne Lyche Solheim, Joachim Maes, Alejandra Morán-Ordóñez, Francisco Moreira, Guy Pe'er, Joana Santana, Judy Shamoun-Baranes, Bruno Smets, César Capinha, Ian McCallum, Henrique M. Pereira, Aletta Bonn (2024). Biodiversity monitoring in Europe: user and policy needs. Conservation Letters. DOI: 10.1111/conl.13038     

 

Contact:

Prof Dr Aletta Bonn
Head of Department Biodiversity and People
Helmholtz Centre for Environmental Research (UFZ)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Friedrich Schiller University Jena
Phone: +49 341 9733153
Email: aletta.bonn@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/137.html

 

Prof Dr Henrique Miguel Pereira (speaks English and Portuguese)
Head of Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Email: henrique.pereira@idiv.de
Web: https://www.idiv.de/en/profile/132.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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Biodiversity Conservation iDiv Biodiversity and People Media Release TOP NEWS Tue, 02 Jul 2024 00:00:00 +0200
New study helps unravel the paradox of habitat fragmentation on biodiversity https://idiv-biodiversity.de//en/news/news_single_view/5351.html New insights could impact future conservation strategies. New insights could impact future conservation strategies.

Based on a media release by Professor Dr Jinbao Liao, Yunnan University

Habitat fragmentation, a process where a large, continuous habitat is divided into smaller, isolated areas, can both help and harm biodiversity, depending on the total amount of habitat remaining in the landscape, according to a new study published in Nature Ecology & Evolution.

The research by Professor Jonathan Chase of the German Centre for Integrative Biodiversity Research (iDiv) and the Martin Luther University Halle-Wittenberg (MLU) and his collaborators shows that the total amount of habitat remaining in a landscape can moderate whether more or less fragmentation in the remaining habitats can increase or decrease diversity.
 
Many studies show that habitat destruction, often due to human activities, is the predominant cause of biodiversity loss and change. However, there has been a lot of discussion about the role of habitat fragmentation, which can be caused by the construction of roads and urban development, for example.
 
“There has been a lot of contention about just how ‘bad’ fragmentation really is for biodiversity,” Chase explains. “While it is clearly bad for some species, other species are quite happy.”
 
Among ecologists and conservationists, this debate is known as the SLOSS (Single-Large-Or-Several-Small) debate and centres around the question of whether one large reserve can maintain more species than several small reserves.

Better a dandelion in the wind? 

The results show that when habitats are largely intact, small amounts of fragmentation can favour species that take advantage of habitat isolation. These species are good colonisers, like the common Dandelion (Taraxacum officinale), whose seeds fly on the wind and find any open space to grow. This allows them to coexist among more competitively dominant species, leading to overall higher diversity and positive fragmentation effects. 
 
However, when large amounts of habitat have been destroyed, fragmentation can lead to negative effects on biodiversity by causing the most competitive species to go extinct. These species are the poorest colonisers, like bunchgrasses, which grow in clumps and are long-lived with strong root systems.
 
Although the model used by the researchers is simplified, its general characteristics are likely applicable in many natural metacommunities. To illustrate this, the researchers show that the general predictions of this framework — shifts from positive to negative fragmentation effects with increasing habitat loss — are consistent with data from a compilation of fragmented metacommunities across the globe. 
 
“Our study provides theoretical grounds to reconcile this binary perspective and also points a way towards designing landscapes that minimise biodiversity losses,” Chase adds.

 

Original publication
(Researchers with iDiv affiliation are bolded)

Zhang, H., Chase, J.M. & Liao, J. (2024). Habitat amount modulates biodiversity responses to fragmentation. Nature Ecology & Evolution, DOI: 10.1038/s41559-024-02445-1

 

Contact:

Prof Dr Jonathan Chase
Head of the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733120

Email: jonathan.chase@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/synthesis.html

 

Christine Coester
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: christine.coester@idiv.de

 

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Research TOP NEWS Biodiversity Synthesis Fri, 28 Jun 2024 00:00:00 +0200
Closing the Biodiversity Knowledge Gap: Unlocking Biodiversity Insights from the Tropical Andes https://idiv-biodiversity.de//en/news/news_single_view/5342.html Report by Jose Valdez, postdoctoral researcher of Biodiversity Conservation at iDiv and Martin...

Report by Jose Valdez, postdoctoral researcher of Biodiversity Conservation at iDiv and Martin Luther University Halle-Wittenberg (MLU)

Despite hosting some of the world's most biodiverse ecosystems and the urgency of the region's conservation challenges, researchers in Bolivia, Ecuador, and Peru often struggle to share their unique insights into these complex ecosystems with the global scientific community. This results in a "publication gap" where crucial biodiversity knowledge from the region remains underrepresented in global conversations.

Untapped Knowledge, Global Impact

“The Tropical Andes hold a wealth of local biodiversity knowledge, yet our work remains largely unseen.” highlights co-author Lucía Castro Vergara of the Asociación para la Conservación de la Cuenca Amazónica (ACCA). "While neighbouring countries like Brazil, Mexico, and Colombia are prolific publishers, the Tropical Andes trails behind leaving an untapped reservoir of biodiversity knowledge inaccessible to the global scientific community."

To address this disparity, we conducted a comprehensive study, which combined in-depth surveys of over 500 scientists across the region with targeted workshops designed to help researchers overcome obstacles to publication.

The Roadblocks to Knowledge-Sharing

The survey results highlighted several interconnected challenges that contribute to the lower publication rates of researchers in the Tropical Andes, including:

  1. Lack of sufficient training and institutional support structures for navigating the publishing process, leaving researchers feeling overwhelmed and ill-equipped
  2. Severe limitations in funding and resources available for scientific research, constraining access to high-impact journals and essential materials
  3. Language barriers in publishing in English-language journals, a significant hurdle given the relatively lower English proficiency in the region
  4. Weaker incentives and limited institutional pressure to publish, as career advancement may not prioritize academic journal publications
  5. Personal challenges such as inadequate understanding and experience in the publication process, resulting in self-doubt, fear of rejections, time constraints, and difficulties in manuscript preparation

Surprisingly, the overwhelming majority of participants were experienced professionals with advanced degrees, with around two-thirds stating they had research ready for publication. This highlights a wealth of untapped scientific contributions and underscores the personal and systematic barriers to publishing their work.

Strategies for Change

To overcome these challenges, survey respondents proposed strategies focused on:

  1. Expanding training initiatives on the publication process, starting at the undergraduate level, and organizing specialized workshops on academic writing and communication.
  2. Facilitating collaborative research networks, interdisciplinary cooperation, and institutional support systems to foster knowledge exchange and a sense of community.
  3. Providing wider access to essential resources like literature, data, and writing tools, and leveraging free and cost-effective platforms to optimize workflow.
  4. Implementing recognition, awards, and career advancement incentives that value meaningful, high-impact publications with societal relevance.
  5. Cultivating a research culture that emphasizes the importance of openly sharing data and findings for the advancement of science and society.

Empowering the Voices of Andean Biodiversity

With biodiversity loss accelerating due to human activities and climate change, closing this publication gap is vital for evidence-based conservation policies and sustainable development in the Tropical Andes. Our study offers a tangible roadmap for nurturing local scientific knowledge to enrich the global knowledge ecosystem. By empowering the voices of local researchers, we can unlock the full potential of this irreplaceable region to inform evidence-based conservation efforts and sustainable development.

“Given the urgency of our region's environmental issues, we need to offer practical solutions that accelerate the transfer of knowledge into decision-making and elevate local research to ensure their insights are part of the global scientific discourse," said co-author Dr. Miguel Fernandez (iDiv, MLU). 

 

Original publication
(Researchers with iDiv affiliation and alumni bolded)

Valdez, J.W., Castro Vergara, L., Orihuela, and Fernandez, M. (2024). Overcoming the Tropical Andes publication divide: insights from local researchers on challenges and solutions. PLOS ONE, DOI: 10.1371/journal.pone.0306189

 

Contact:

Dr Jose W. Valdez (speaks English and Spanish)
Postdoctoral Researcher
Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9739168
Email: jose.valdez@idiv.de
Web: https://www.idiv.de/en/profile/1290.html

 

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Media Release Biodiversity Conservation TOP NEWS Wed, 26 Jun 2024 00:00:00 +0200
Germany's leading role in biodiversity research and policy https://idiv-biodiversity.de//en/news/news_single_view/5341.html iDiv met with members of the Bundestag to discuss expanding Germany's role iDiv met with members of the Bundestag to discuss expanding Germany's role

 

The full text is only available in German.

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iDiv TOP NEWS Media Release Tue, 25 Jun 2024 00:00:00 +0200
Soil fauna has the potential to fundamentally alter carbon storage in soil https://idiv-biodiversity.de//en/news/news_single_view/5337.html Life strategies of a multitude of soil faunal taxa can affect the formation of organic matter in... Life strategies of a multitude of soil faunal taxa can affect the formation of organic matter in soil.

Based on a media release of the Czech Academy of Sciences

The life strategies of a multitude of soil faunal taxa can strongly affect the formation of labile and stabilized organic matter in soil, with potential consequences for how soils are managed as carbon sinks, nutrient stores, or providers of food. This is the main conclusion of a review led by a team of researchers from the Czech Academy of Sciences, the German Centre for Integrative Biodiversity Research (iDiv), Leipzig University (UL), and the Senckenberg Society for Nature Research. Based on a review of more than 180 scientific articles, the authors highlight major pathways by which soil fauna can influence soil organic matter stability, identify knowledge gaps, and suggest future research directions. The study has recently been published in Nature Communications.

The relevance of soil fauna to soil biogeochemical cycles has well been recognized. However, knowledge on how soil fauna influences the formation of particulate (labile) and mineral-associated organic matter (stabilized for centuries to millennia) and the carbon within is widely lacking. “We were surprised by the scarcity of studies on how, both mechanistically and quantitatively, soil fauna affects particulate and mineral-associated organic matter, which certainly hampers the development of more effective carbon-focused soil management strategies,” says Dr Gerrit Angst, lead author of the study from the Czech Academy of Sciences and iDiv. The international team of authors, comprised of researchers from the Czech Republic, Germany, and France, thus reviewed the literature and conceptualized how multiple soil faunal taxa can alter soil organic matter stability.

The authors highlight the relevance of three major processes – transformation, translocation, and grazing on microorganisms – by which soil fauna alters factors deemed essential in the formation of labile and stabilized soil organic matter. This includes ingestion of plant residues and chemical and physical alteration of this material before egestion as feces, vertical and horizontal transport of plant residues and organic matter in soil profiles, and changes in microbial community composition and abundance via faunal grazing on microorganisms. “We strongly emphasize that the processes identified in our review can fundamentally affect the dynamics of particulate and mineral-associated organic matter in soil, while quantitative data, except for earthworms, are virtually absent,” explains Angst.

The authors call for coordinated and cross-disciplinary studies on multiple scales and faunal taxa that combine isotopic, microbial, and molecular methods to help close the major identified research gaps. “Only if we include soil fauna in our concepts and models will we be able to effectively manage soils as carbon sinks, nutrient stores, and providers of food in a rapidly changing environment,” concludes Prof Nico Eisenhauer from iDiv and UL, senior author of the study.

 

Original publication
(Researchers with iDiv affiliation and alumni in bold)

Angst, G., Potapov, A., Joly, FX, Angst, S., Frouz, J., Ganault, P. & Eisenhauer, N. (2024). Conceptualizing soil fauna effects on labile and stabilized soil organic matter. Nature Communications, DOI: https://doi.org/10.1038/s41467-024-49240-x

 

Contact:

Dr Gerrit Angst
Institute of Soil Biology and Biogeochemistry
Biology Centre of the Czech Academy of Sciences
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: gerrit.angst@bc.cas.cz

 

Prof Dr Nico Eisenhauer
Head of the research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 97 33167
Email: nico.eisenhauer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/eisenhauer_nico.html

 

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Experimental Interaction Ecology Media Release TOP NEWS Mon, 17 Jun 2024 00:00:00 +0200
Land management and climate change affect ecosystems’ ability to provide multiple services simultaneously https://idiv-biodiversity.de//en/news/news_single_view/5335.html New study in Nature Communications Integrative study blends impacts on food production, soil health, biodiversity and other ecosystem services

A novel study published in Nature Communications found that agroecosystems in Central Germany, specifically grasslands and croplands, may have an enhanced capacity to provide multiple goods and services simultaneously when land management reduces the use of pesticides and mineral nitrogen fertiliser. 

This finding holds true under potential future climate conditions, with soil biodiversity expected to be a significant element of so-called multifunctionality, according to researchers at the German Centre for Integrative Biodiversity Research (iDiv), the Helmholtz Centre for Environmental Research (UFZ), Leipzig University (UL), and the Martin Luther University Halle-Wittenberg (MLU).

The study is also the first to employ mixed ecological-economic multifunctionality measures that take into account the preferences of stakeholders for different ecosystem services. For instance, farmers put a higher value on food productivity than other stakeholders. In addition, society as a whole benefits from regulating services like carbon sequestration, and the preservation of water quality.

To date, considerable debate exists about the ideal farming method that aligns with society’s varied values. Intensive farming uses mineral fertilisers and synthetic pesticides to increase yields, while extensive farming avoids agrochemicals. Each comes with trade-offs: Intensive farming can increase yields but may pollute, whereas extensive farming might require more land due to lower yields per unit area.

“The unique study design enabled us to assess the effects of major global change drivers, such as climate and land-use change, on ecosystem service provision”, says first author Friedrich Scherzinger, alumnus of iDiv and UL. Scherzinger led the study for his master's thesis at UL and the University of Graz. “These ecosystem services are essential for human well-being. Combining both economic and ecological research provides a more holistic view of interconnected parts of the ecosystem.“

Integrating ecology and economics from the start

The researchers used a large-scale field experiment with five land-use types under two different climate scenarios (current and potential future climate): the Global Change Experimental Facility (GCEF), operated by the UFZ. The ecological multifunctionality portion of the assessment explored 14 ecosystem functions, such as nitrogen leaching and aboveground biomass production; whereas the economic multifunctionality assessment incorporated the total financial value of the resulting six ecosystem services: food production, climate regulation, water quality, soil health, biodiversity conservation, and landscape aesthetics.

“The Global Change Experimental Facility is a unique experiment“, says co-author and GCEF coordinator Dr Martin Schädler, ecologist at UFZ and iDiv. “It allows us to directly compare the responses of different land-use types to climate change under standardised conditions without confounding effects of differing site conditions. This is especially important for contrasting intensive with extensive production systems which, in the real world, are often established under very different settings.”

By integrating the preferences of farmers, local residents, environmental conservation agencies, and tourism agencies for different ecosystem services from the outset, the researchers offer a more comprehensive assessment of ecosystem services that overcomes the shortcomings of a purely economic valuation. 

“Higher biodiversity levels stabilise biomass yields and make them more resilient to disturbances, similar to a diversified stock portfolio”, says Prof Martin Quaas, economist at iDiv and UL, and senior author of the study. “Based on this effect, we could calculate a natural insurance value of biodiversity.”

The findings suggest that future climate and intensive management reduce ecological multifunctionality for both grasslands and croplands. Overall, the economic multifunctionality measure is approximately 1.7 to 1.9 times higher for extensive management compared to intensive management, and this applies to both grasslands and croplands. However, when considering only farmers’ preferences, intensively managed grasslands exhibit higher multifunctionality than those without. The study’s results are based on measurements per unit area, but they were not evaluated based on the amount of yield produced.

Linking soil biodiversity to ecosystem services

The study also explored the relationship between soil biodiversity (the variety of life in the soil) and ecological multifunctionality across land-use types and under current and potential future climate conditions.

The findings suggest that soil biodiversity might be an important part of the ecosystem’s ability to perform multiple functions simultaneously, and that ecosystems with low soil biodiversity might be particularly vulnerable to future climate conditions.

“Roughly 60% of all species on Earth live in the soil. These soil creatures are not only incredibly diverse but are the functional backbone of our ecosystems”, explains Prof Nico Eisenhauer, soil ecologist at iDiv and UL, and senior author of the study. “The study indicates that we can maintain soil biodiversity through targeted management strategies to sustain the multiple services that nature provides to us.”

The study is an essential step towards a holistic and comprehensive approach, with the authors cautioning against a significant decrease in the benefits society derives from land due to climate change, biodiversity loss, and heavy use of agrochemicals. 

“Our study reveals that farmers maximise their income through intensive management, while ecosystem service provision is highest under extensive management”, says Scherzinger. “Since farmers are traditionally the ones managing the land, societal benefit cannot be optimal without a system that incentivises farmers in a way that their income gap between intensive and extensive management is bridged.”

However, relevant aspects, such as landscape diversity and land footprint (the area needed per unit yield), were not considered in this study, making it difficult to draw conclusions as to what type of agriculture is ultimately the best fit for purpose.

“Future research should focus on landscape-level ecosystem service provision and the role of landscape heterogeneity for optimal societal outcome”, Scherzinger concludes. 

 

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

 

Original Publication
(Researchers with iDiv affiliation and alumni bolded)

Scherzinger, F., Schädler, M., Reitz, T., Yin, R., Auge, H., Merbach, I., Roscher, C., Harpole, S., Marder, F., Blagodatskaya, E., Siebert, J., Ciobanu, M., Eisenhauer, N., Quaas, M. (2024). Sustainable land management enhances ecological and economic multifunctionality under ambient and future climate, Nature Communications, DOI: 10.1038/s41467-024-48830-z

 

Contact:

Friedrich Scherzinger
Alumnus of the
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and
Leipzig University
Email: f.a.scherzinger@gmail.com

 

Prof Dr Nico Eisenhauer
Head of the research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 97 33167
Email: nico.eisenhauer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/eisenhauer_nico.html

 

Prof Dr Martin Quaas
Head of the research group Biodiversity Economics
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Email: martin.quaas@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/biodiversity-economics.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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TOP NEWS Physiological Diversity Media Release Experimental Interaction Ecology iDiv Members Biodiversity Economics Thu, 13 Jun 2024 00:00:00 +0200
Low-intensity grazing is locally better for biodiversity but challenging for land users, a new study shows https://idiv-biodiversity.de//en/news/news_single_view/5311.html Land users struggle with inflexible regulations and a lack of workforce Land users struggle with inflexible regulations and a lack of workforce

A team of researchers led by the German Centre for Integrative Biodiversity Research (iDiv), Leipzig University (UL), and the Helmholtz Centre for Environmental Research (UFZ) has investigated the motivation and potential incentives for and challenges of low-intensity grazing among farmers and land users in Europe. The interview results have been published in Land Use Policy.

The grazing of both domestic and wild animals is shaping landscapes across Europe. It can also contribute to multiple ecosystem services, such as providing habitat for biodiversity. Grazing systems with lower densities of animals and with minimal and only targeted applications of deworming and other medicinal treatments offer benefits for local biodiversity protection and various ecosystem services. However, this type of land management also poses a range of challenges, leading to a constant decline in the number of land users engaged in low-intensity grazing. A team of researchers led by iDiv, UL, and UFZ set out to investigate these challenges and potential interventions in eight European case studies. Between 2019 and 2021, they conducted 74 face-to-face interviews with farmers, landowners, livestock owners, and managers of a rewilding area with semi-wild herbivores, like wild ponies or semi-wild cattle.

Land users rely on subsidies, but money is not everything 

The researchers focused on the motivation and challenges driving decision-making among all land users engaged in low-intensity grazing practices. This was despite economic considerations becoming increasingly important as land users’ revenue-generating activities are no longer sufficient to cover the rising cost of equipment, rent, and taxes. 

“Money is not everything. Many of the land users we interviewed practice this type of grazing management because they think it is good, not out of economic motivation”, says first author Dr Julia Rouet-Leduc. Rouet-Leduc led the project as a former doctoral researcher at iDiv and UL and is now a postdoctoral researcher at the Stockholm Resilience Centre. Caring for nature and, in some cases, also the desire to maintain traditional agricultural practices were important aspects of the land users’ motivation. For example, a land user working with wild ponies in Galicia (Spain) shared: “The main reason for the maintenance of this system is that people … love the ponies; they ‘have a fever’, and this tradition runs very deeply in their hearts.” 

The researchers found that many land users struggle with rules and regulations that are incompatible with low-intensity grazing management. For example, rules to mark or tag livestock – an extremely challenging task when animals are allowed to graze freely in large areas – were perceived as limiting. Land users also felt that the policies in place, especially the Common Agricultural Policy of the European Commission (CAP), were holding back nature-friendly and sustainable practices. For example, a land user in Romania noted that farmers were required to remove scrubs from their pastures or they would otherwise not be eligible for subsidies or even have to pay penalties. However, scrubs have important ecosystem functions, such as providing shade in the summer and as an additional food resource in the winter. In general, the CAP was perceived as too restrictive, and many land users chose not to apply for subsidies at all. “By not applying for CAP support, we have the freedom to really see what suits the local ecosystem”, a Belgian land user stated.

Rural exodus is putting traditional labour at risk

The interviews also showed that many land users struggle with socio-economic changes in the countryside. The so-called ‘Rural Exodus’ is leading to a lack of workforce, while physical work is still very much needed, especially for work with cattle or horses. “The next generation does not want to farm because it is too hard, too much work”, a land user from Lithuania said. “They usually move abroad and choose easier career options'.'

“The CAP could support farmers in High Nature Value farming regions and put incentives in place to preserve or restore extensive grazing systems,” senior author Dr Guy Pe’er, a senior researcher at UFZ and iDiv, suggests. “It’s not a lack of budgets but rather the lack of ambition to support sustainable farming.”

More flexibility and improved market access needed

The researchers used the interviews to derive and suggest interventions to encourage better grazing practices. “What is needed is more flexibility for land users”, Rouet-Leduc says. “Current policies are, for the most part, not encouraging such practices, and particularly not offering a level playing field for land users.” While the EU’s CAP offers important economic support, it also drives counter-productive management due to problematic requirements, she adds. Additional financial incentives could improve the support for more sustainable grazing management, according to the study’s authors. Especially in areas where land has been abandoned, there can be opportunities for rewilding large herbivores, which ultimately provide multiple ecosystem services. However, such systems require flexibility since they differ from management approaches with domestic animals. 

The researchers also call for better labelling and certification for environmentally friendly grazing practices to increase public support and to help develop markets for such products. Some of the interviewed land users felt that market access could be improved by supporting direct marketing, for example, via farm shops.

“There are clearly real challenges for farmers, and they are not easy to overcome”, Pe’er explains in light of ongoing farmers’ demonstrations in countries like Germany, Poland, and Italy. “But removing environmental standards will not help land users. They need a package that includes an ambitious CAP reform, providing real support for farmers who need it to be more sustainable; the Nature Restoration Law to improve the standards of good management; and a framework for sustainable food systems to improve the market options for sustainable farming.” 


This study was, among others, funded by the German Research Foundation (DFG; FZT-118) and as part of GRAZELIFE, a LIFE Preparatory Project on request of the European Commission to assess the impact of different grazing systems on ecosystem service provision (LIFE18PRE/NL002).

Kati Kietzmann

 

Original publication

Julia Rouet-Leduc, Fons van der Plas, Aletta Bonn, Wouter Helmer, Melissa R. Marselle, Erica von Essen, Guy Pe’er (2024.) Exploring the motivation and challenges for land-users engaged in sustainable grazing in Europe. Land Use Policy, DOI: 10.1016/j.landusepol.2024.107146 

 

Contact:

Dr Julia Rouet-Leduc
Alumna of the German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and Leipzig University
Stockholm Resilience Centre
Email: julia.rouet.leduc@su.se

 

Dr Guy Pe’er
Biodiversity and People
Helmholtz Centre for Environmental Research (UFZ)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33182
Email: guy.peer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/643.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Media Release iDiv TOP NEWS Tue, 30 Apr 2024 00:00:00 +0200
Climate change could become the main driver of biodiversity decline by mid-century https://idiv-biodiversity.de//en/news/news_single_view/5306.html Largest modelling study of its kind, published in Science Largest modelling study of its kind, published in Science


Global biodiversity has declined between 2% and 11% during the 20th century due to land-use change alone, according to a large multi-model study published in Science. Projections show climate change could become the main driver of biodiversity decline by the mid-21st century. 

The analysis was led by the German Centre for Integrative Biodiversity Research (iDiv) and the Martin Luther University Halle-Wittenberg (MLU) and is the largest modelling study of its kind to date. The researchers compared thirteen models for assessing the impact of land-use change and climate change on four distinct biodiversity metrics, as well as on nine ecosystem services.

GLOBAL BIODIVERSITY MAY HAVE DECLINED BY 2% TO 11% DUE TO LAND-USE CHANGE ALONE

Land-use change is considered the largest driver of biodiversity change, according to the Intergovernmental Platform on Biodiversity and Ecosystem Services (IPBES). However, scientists are divided over how much biodiversity has changed in past decades. To better answer this question, the researchers modelled the impacts of land-use change on biodiversity over the 20th century. They found global biodiversity may have declined by 2% to 11% due to land-use change alone. This span covers a range of four biodiversity metrics1 calculated by seven different models.

“By including all world regions in our model, we were able to fill many blind spots and address criticism of other approaches working with fragmented and potentially biased data,” says first author Prof Henrique Pereira, research group head at iDiv and MLU. “Every approach has its ups and downsides. We believe our modelling approach provides the most comprehensive estimate of biodiversity trends worldwide.”

MIXED TRENDS FOR ECOSYSTEM SERVICES

Using another set of five models, the researchers also calculated the simultaneous impact of land-use change on so-called ecosystem services, i.e., the benefits nature provides to humans. In the past century, they found a massive increase in provisioning ecosystem services, like food and timber production. By contrast, regulating ecosystem services, like pollination, nitrogen retention, or carbon sequestration, moderately declined.

CLIMATE AND LAND-USE CHANGE COMBINED MIGHT LEAD TO BIODIVERSITY LOSS IN ALL WORLD REGIONS

The researchers also examined how biodiversity and ecosystem services might evolve in the future. For these projections, they added climate change as a growing driver of biodiversity change to their calculations.

Climate change stands to put additional strain on biodiversity and ecosystem services, according to the findings. While land-use change remains relevant, climate change could become the most important driver of biodiversity loss by mid-century. The researchers assessed three widely-used scenarios – from a sustainable development to a high emissions scenario. For all scenarios, the impacts of land-use change and climate change combined result in biodiversity loss in all world regions. While the overall downward trend is consistent, there are considerable variations across world regions, models, and scenarios.

PROJECTIONS ARE NOT PREDICTIONS

“The purpose of long-term scenarios is not to predict what will happen,” says co-author Dr Inês Martins from the University of York. “Rather, it is to understand alternatives, and therefore avoid these trajectories, which might be least desirable, and select those that have positive outcomes. Trajectories depend on the policies we choose, and these decisions are made day by day.” Martins co-led the model analyses and is an alumna of iDiv and MLU.

The authors also note that even the most sustainable scenario assessed does not deploy all the policies that could be put in place to protect biodiversity in the coming decades. For instance, bioenergy deployment, one key component of the sustainability scenario, can contribute to mitigating climate change but can simultaneously reduce species habitats. In contrast, measures to increase the effectiveness and coverage of protected areas or large-scale rewilding were not explored in any of the scenarios

MODELS HELP IDENTIFY EFFECTIVE POLICIES

Assessing the impacts of concrete policies on biodiversity helps identify those policies most effective for safeguarding and promoting biodiversity and ecosystem services, according to the researchers. “There are modelling uncertainties, for sure,” Pereira adds. “Still, our findings clearly show that current policies are insufficient to meet international biodiversity goals. We need renewed efforts to make progress against one of the world’s largest problems, which is human-caused biodiversity change.”

1global species richness, local species richness, mean species habitat extent, biodiversity intactness

Volker Hahn


This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

 

Original paper
(Researchers with iDiv affiliation and alumni bolded)
Henrique M. Pereira, Inês S. Martins, Isabel M.D. Rosa, HyeJin Kim, Paul Leadley, Alexander Popp, Detlef P. van Vuuren, George Hurtt, Luise Quoss, Almut Arneth, Daniele Baisero, Michel Bakkenes, Rebecca Chaplin-Kramer, Louise Chini, Moreno Di Marco, Simon Ferrier, Shinichiro Fujimori, Carlos A. Guerra, Michael Harfoot, Thomas D. Harwood, Tomoko Hasegawa, Vanessa Haverd, Petr Havlík, Stefanie Hellweg, Jelle P. Hilbers, Samantha L. L. Hill, Akiko Hirata, Andrew J. Hoskins, Florian Humpenöder, Jan H. Janse, Walter Jetz, Justin A. Johnson, Andreas Krause, David Leclère, Tetsuya Matsui, Johan R. Meijer, Cory Merow, Michael Obersteiner, Haruka Ohashi, Adriana De Palma, Benjamin Poulter, Andy Purvis, Benjamin Quesada, Carlo Rondinini, Aafke M. Schipper, Josef Settele, Richard Sharp, Elke Stehfest, Bernardo B. N. Strassburg, Kiyoshi Takahashi, Matthew V. Talluto, Wilfried Thuiller, Nicolas Titeux, Piero Visconti, Christopher Ware, Florian Wolf, Rob Alkemade (2024). Global trends and scenarios for terrestrial biodiversity and ecosystem services from 1900 to 2050. Science 384, 458-465. DOI: 10.1126/science.adn3441

 

 

Contact:

Prof Dr Henrique Miguel Pereira (speaks English and Portuguese)
Head of Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Email: henrique.pereira@idiv.de
Web: https://www.idiv.de/en/profile/132.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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iDiv Members Biodiversity Conservation TOP NEWS Media Release Fri, 26 Apr 2024 00:00:00 +0200
Study shows how plants regulate the climate in Europe https://idiv-biodiversity.de//en/news/news_single_view/5310.html Local differences in plant traits partially explain variation in climate-regulation processes Local differences in plant traits partially explain variation in climate-regulation processes

Based on a media release of Martin Luther University Halle-Wittenberg

The climate regulates plant growth, but the climate is also regulated by plants. Depending on the vegetation composition, ecosystems even have a strong influence on the climate in Europe, a study by Martin Luther University Halle-Wittenberg (MLU) and the German Centre for Integrative Biodiversity Research (iDiv) in the journal Global Change Biology shows. The researchers linked satellite data with around 50,000 vegetation records from across Europe. A good five per cent of regional climate regulation can be explained by local plant diversity. The analysis also shows that the effects depend on many other factors. Plants regulate the climate by reflecting sunlight or cooling their surroundings through evaporation.

"Plants and climate have an extremely complex relationship: on the one hand, the climate has a considerable influence on plant growth and also on plant characteristics, such as growth height, leaf thickness or root depth. On the other hand, plants regulate climatic conditions in many different ways," says Dr Stephan Kambach from MLU. For example, if plants reflect a lot of sunlight, less heat accumulates on site. Plants can also cool their surroundings by evaporating water and capture large quantities of carbon dioxide.

However, according to Kambach, little was previously known about the extent to which the various functional plant characteristics, such as the unique characteristics of leaves and roots, affect the climate. In order to close this knowledge gap, the team combined regional data from satellite observations with local surveys of plants and plant traits at almost 50,000 locations in Europe. "It was important for us to combine areas from very different habitats. Our data therefore includes information from coniferous, deciduous and evergreen broadleaf forests as well as various shrub and open land formations," explains Professor Dr Helge Bruelheide, senior author of the study. Bruelheide is a member of iDiv and head of the Geobotany working group at MLU.

"We show that a significant proportion of the observed climate-regulating processes can be explained by differences in the functional traits of the local plants. It therefore depends very much on which plants grow in which quantities in an ecosystem," continues Kambach. However, the effects differed greatly between individual ecosystems, for example between evergreen coniferous and deciduous forests. "Overall, we were nevertheless able to prove that a taller plant communities generally reflect less sunlight and that larger leaves are associated with higher evaporation and more sequestered carbon," Kambach says.

The study is a key outcome of the European research project FeedBaCks, which is investigating the feedback mechanisms between biodiversity and climate and their consequences for humans. It is coordinated by the University of Zurich. In addition to MLU, partners include the universities of Brno (Czech Republic), Frankfurt/Main and Grenoble (France) as well as the Swiss Federal Research Institute (WSL, Switzerland), the Senckenberg Society for Nature Research and the Stockholm Resilience Centre (Sweden).

"Our study also provides important indicators for nature conservation and politics. When planning measures to mitigate climate change, the potential impacts and feedbacks of biodiversity should be taken into account," Helge Bruelheide concludes.  

 

Original publication

Stephan Kambach, Fabio Attorre, Irena Axmanová, Ariel Bergamini, Idoia Biurrun, Gianmaria Bonari, Maria Laura Carranza, Alessandro Chiarucci, Milan Chytrý, Jürgen Dengler, Emmanuel Garbolino, Valentin Golub, Thomas Hickler, Ute Jandt, Jan Jansen, Borja Jiménez-Alfaro, Dirk Nikolaus Karger, Zdeňka Lososová, Valerijus Rašomavičius, Solvita Rūsiņa, Petra Sieber, Angela Stanisci, Wilfried Thuiller, Erik Welk, Niklaus E. Zimmermann, Helge Bruelheide. Climate regulation processes are linked to the functional composition of plant communities in European forests, shrublands, and grasslands. Global Change Biology (2024). doi: 10.1111/gcb.17189


Further informationen

www.biodiv-feedbacks.org

 

Contact:

Dr Stephan Kambach
Martin Luther University Halle-Wittenberg
German Center for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: stephan.kambach@botanik.uni-halle.de

 

Prof Helge Bruelheide
Professor for Geobotany
Martin Luther University Halle-Wittenberg
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49-345 5526222
Email: helge.bruelheide@botanik.uni-halle.de
Web: http://www.botanik.uni-halle.de/geobotanik/helge_bruelheide/

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Research iDiv Members TOP NEWS Media Release Tue, 23 Apr 2024 00:00:00 +0200
iDiv's Nico Eisenhauer becomes member of the Leopoldina Academy https://idiv-biodiversity.de//en/news/news_single_view/5308.html Nico Eisenhauer was admitted to the German National Academy of Sciences Leopoldina. Nico Eisenhauer was admitted to the German National Academy of Sciences Leopoldina.

 

The full text is only available in German.

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Experimental Interaction Ecology iDiv TOP NEWS Thu, 18 Apr 2024 00:00:00 +0200
Rewilding amphibians: Protecting endangered species to restore ecosystems https://idiv-biodiversity.de//en/news/news_single_view/5301.html Researchers at iDiv propose a new strategy for rewilding amphibians in a recent study. Researchers at iDiv propose a new strategy for rewilding amphibians in a recent study.

By Dr Gavin S. Stark, a postdoctoral researcher in the Biodiversity Conservation group at iDiv and lead author of the study.

In a recent paper published in Conservation Biology, iDiv researchers suggest that given amphibians' ability to act as 'canaries in the coal mine' for aquatic environments, they should be reintroduced or rewilded. Rewilding would not only help protect these endangered species but simultaneously promote ecological stability.
 
Amphibians, such as salamanders, frogs, and newts, are the most threatened of all vertebrates, with over 40% of all species worldwide at risk of extinction. They are also unique in providing early information about aquatic ecosystems' ecological state due to their extremely sensitive and permeable skins.

According to the researchers, the presence and overall health of amphibians as so-called bioindicators is important for setting more ambitious conservation objectives in the future, such as reintroducing mammals.
 
The researchers also present a reintroduction scheme outlining steps to establish a stable ecosystem using more robust species, like amphibians, with the goal of restoring ecological interactions. Restoring ecological interactions can help conservationists reintroduce other, more specialised species as aquatic ecosystems recover. 
 
The state of the world's amphibians
Amphibian declines and extinctions are attributed to multiple, complex factors, including habitat degradation, climate change, and, most critically, infectious diseases such as Batrachochytrium dendrobatidis. 
 
Addressing these extinction drivers makes it possible to improve the effectiveness of conservation efforts to protect amphibians. However, to date, most conservation programs have yet to effectively take action to support this vanishing group of species. Alternative conservation strategies are needed to protect and promote amphibians in different regions. 
 
Rewilding is an increasingly popular conservation strategy that reintroduces a native species into an environment where it was once found but is no longer present. Beavers, moose, and wolves are some species that have been effectively reintroduced in Europe in recent years. 
 
The researchers argue that incorporating amphibians in rewilding projects can help conserve endangered species, such as tropical frogs, and restore ecosystem functionality for other organisms.
 
Amphibians for Rewilding
With their paper, the researchers seek to raise awareness of the benefits of amphibians in rewilding projects. They highlight that amphibians can serve a dual purpose as bioindicators for ecosystem health and as key species in an ecosystem's food webs.
 
The researcher's well-planned reintroduction scheme for amphibians outlines steps to establish a stable ecosystem using more robust species to restore ecological interactions, which can also be applied to other groups in various regions and help promote rewilding as a leading conservation strategy worldwide. 
 
In general, the steps are divided into three stages: (1) assessing the state of the ecosystem, (2) choosing the most ideal candidate for reintroduction, and (3) reintroducing more sensitive amphibians if the ecosystem is recovering.

The European green toad (Bufotes viridis) would be a strong candidate for reintroduction in degraded aquatic areas in Eastern Germany (Step 2), and the European tree frog (Hyla arborea) is an example of a more sensitive amphibian that could be considered if an ecosystem is recovering (Step 3).
 
These three steps are imperative for an effective restoration action that will improve the status of aquatic ecosystems while boosting their amphibian residents.

Stark, G., & Schwarz, R. (2024). Rewilding a vanishing taxon–Restoring aquatic ecosystems using amphibians. Biological Conservation, 292, 110559. DOI: 10.1016/j.biocon.2024.110559.

 

The full text is only available in German.

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Biodiversity Conservation TOP NEWS Media Release Wed, 17 Apr 2024 00:00:00 +0200
iDiv's founding director Christian Wirth Member of the Saxon Academy https://idiv-biodiversity.de//en/news/news_single_view/5300.html High scientific honour  

The full text is only available in German.

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TOP NEWS iDiv Members Fri, 12 Apr 2024 00:00:00 +0200
Demand for critical minerals puts African great apes at risk https://idiv-biodiversity.de//en/news/news_single_view/5293.html One-third of Africa’s great ape population faces risks related to mining One-third of Africa’s great ape population faces risks related to mining

A recent study led by researchers from the German Centre for Integrative Biodiversity Research (iDiv), the Martin Luther University Halle-Wittenberg (MLU) and the non-profit conservation organization Re:wild shows that the threat of mining to the great ape population in Africa has been greatly underestimated. Their results have been published in Science Advances.

The rising demand for critical minerals, such as copper, lithium, nickel, cobalt, and other rare earth elements required for the large-scale transition to cleaner energy is causing a surge of mining in Africa, where a large share of those mineral resources is still unexploited. This is driving deforestation of tropical rainforests, which are home to many species, including humans’ closest living relatives, the great apes. According to the study, the threat of mining to great apes in Africa has been greatly underestimated:  up to one-third of the entire population - nearly 180,000 gorillas, bonobos and chimpanzees - could be at risk. The researchers also highlight that because mining companies are not required to make biodiversity data publicly available, the true impact of mining on biodiversity and great apes, in particular, may be even higher. 

In their study, the team used data on operational and preoperational mining sites in 17 African nations and defined 10 km buffer zones to account for direct impacts, such as habitat destruction and light and noise pollution. They also defined 50 km buffer zones for indirect impacts linked to increased human activity near mining sites: New roads and infrastructure are built to access these once-remote areas, and many people migrate to these areas looking for employment. This in turn, increases pressures on great apes and their habitat through increased hunting, habitat loss, and higher risk of disease transmission. By integrating data on the density distribution of great apes, the researchers investigated how many African apes could potentially be negatively impacted by mining and mapped areas where frequent mining and high ape densities overlapped.

Great apes in West Africa are most severely affected

In the West African countries of Liberia, Sierra Leone, Mali, and Guinea, overlaps of high ape density and mining areas – including the 10 km and 50 km buffer zones – were the largest. The most significant overlap of mining and chimpanzee density - both in terms of proportion of population and overall numbers - was found in Guinea. Here, more than 23,000 chimpanzees, or up to 83% of Guinea’s ape population, could be directly or indirectly impacted by mining activities. In general, the most sensitive areas - those with relatively high ape and mining densities - are not protected.

“Currently, studies on other species suggest that mining harms apes through pollution, habitat loss, increased hunting pressure, and disease, but this is an incomplete picture,” says first author Dr Jessica Junker. Junker works for Re:wild and led the study as a postdoctoral researcher at iDiv and MLU. “The lack of data sharing by mining projects hampers our scientific understanding of its true impact on great apes and their habitat.” 

The researchers also explored how mining areas intersect with what is considered 'Critical Habitat'—regions crucial for their unique biodiversity, unrelated to apes. They found a noteworthy 20% overlap between the two. Critical Habitat designation entails strict environmental regulations, especially for mining projects seeking funding from entities like the International Finance Corporation (IFC) – a branch of the World Bank which lends funds to the private sector – or other lenders adhering to similar standards, and aiming to operate within these zones. Previous efforts to map ‘Critical Habitat’ in Africa have overlooked significant portions of ape habitats that would qualify under international benchmarks such as the IFC Performance Standard 6. “Companies operating in these areas should have adequate mitigation and compensation schemes in place to minimize their impact, which seems unlikely, given that most companies lack robust species baseline data that are required to inform these actions,” says Dr Tenekwetche Sop, manager of the IUCN SSC A.P.E.S. Database at the Senckenberg Museum of Natural History, a repository of all great ape population data. “Encouraging these companies to share their invaluable ape survey data with our database serves as a pivotal step towards transparency in their operations. Only through such collaborative efforts can we comprehensively gauge the true extent of mining activities' effects on great apes and their habitats.”

Short-term offset plans fail to compensate for the long-term impacts of mining

Even though the indirect and long-term impacts of mining are difficult to quantify, they often extend well beyond the boundaries of the actual mining project. Currently, these risks are rarely considered and mitigated by mining companies. Compensation or offset is then based on an approximation of impacts, which the researchers suggest is often inaccurate, and underestimated. Furthermore, current offset schemes are developed to last as long as mining projects are active (usually c.20 years), whereas most mining impacts on great apes are permanent.

”Mining companies need to focus on avoiding their impacts on great apes as much as possible and use offsetting as a last resort as there is currently no example of a great ape offset that has been successful”, explains Dr Genevieve Campbell, lead of the IUCN SSC PSG SGA/SSA ARRC Task Force and senior researcher at Re:wild. ‘’Avoidance needs to take place already during the exploration phase, but unfortunately, this phase is poorly regulated and ‘baseline data’ are collected by companies after many years of exploration and habitat destruction have taken place. These data then do not accurately reflect the original state of the great ape populations in the area before mining impacts.’’

“A shift away from fossil fuels is good for the climate but must be done in a way that does not jeopardize biodiversity. In its current iteration it may even be going against the very environmental goals we’re aiming for”, says Jessica Junker. “Companies, lenders and nations need to recognize that it may sometimes be of greater value to leave some regions untouched to mitigate climate change and help prevent future epidemics.”

 

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

Kati Kietzmann

 

Original publication
(Researchers with iDiv affiliation and alumni are in bold)

Jessica Junker, Luise Quoss, Jose Valdez, Mimi Arandjelovic, Abdulai Barrie, Genevieve Campbell, Stefanie Heinicke, Tatyana Humle, Célestin Yao Kouakou, Hjalmar S. Kühl, Isabel Ordaz-Nemeth, Henrique M. Pereira, Helga Rainer, Johannes Refisch, Laura Sonter, Tenekwetche Sop (2024). Threat of mining to African great apes. Science Advances, DOI: 10.1126/sciadv.adl0335

 

Contact:

Dr Jessica Junker
Re:wild
Alumna of German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and of Martin Luther University Halle-Wittenberg
Email: jjunker@rewild.org

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Research Biodiversity Conservation TOP NEWS iDiv Media Release Wed, 03 Apr 2024 00:00:00 +0200
iDiv is mourning the loss of Diana Wall https://idiv-biodiversity.de//en/news/news_single_view/5296.html Diana Wall passed away on the 25th of March 2024. Diana Wall, a leading environmental scientist and...

Diana Wall passed away on the 25th of March 2024. Diana Wall, a leading environmental scientist and soil ecologist, has been a longstanding member of iDiv's Scientific Advisory Board (SAB) and part of several research endeavours at iDiv.

It is with great sadness that we received the news that Diana Harrison Wall passed away. Diana Wall, a professor of biology and a Distinguished Professor at Colorado State University, was a soil ecologist whose interdisciplinary research uncovered dramatic impacts to invertebrate communities in response to climate change, the key role nematode species play in soil carbon turnover, and how they survive such extreme environments like the dry valleys of the Antarctic.

Diana Wall has been a long-standing member of iDiv's Scientific Advisory Board and part of the sDiv groups sOILDIV and sWORM as well as several research endeavours at iDiv.

 

„Diana was a truly inspiring scientist, a global leader in soil ecology, and the most friendly and supportive colleague you can imagine. Her loss is a huge shock to the community, but we will keep her important work alive with continuing projects like Soil BON and the Global Soil Biodiversity Initiative.”

Professor Dr Nico Eisenhauer, head of Experimental Interaction Ecology (EIE) at iDiv and Leipzig University

 

"As a leading scientist in ecology, Diana Wall has been a great inspiration to me and many other female scientists alike. When she was visiting iDiv for a workshop, she made time to join one of our female scientist career lunches to informally share her experiences with all female scientists over a pizza and some sodas. Thanks, Diana, for inspiring us to never give up!"

Professor Dr Nicole van Dam, iDiv Member and Scientific Director of the Leibniz Institute for Vegetable and Ornamental Crops (IGZ)

 

Contact:

Prof Dr Nico Eisenhauer
Head of the research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 97 33167
Email: nico.eisenhauer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/eisenhauer_nico.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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TOP NEWS Media Release Tue, 02 Apr 2024 00:00:00 +0200
Genetic traces of hierarchy: How social standing shapes the epigenome of Tanzania’s Spotted Hyenas https://idiv-biodiversity.de//en/news/news_single_view/5292.html New study reveals how social status and behaviour are reflected in the genetic makeup New study reveals how social status and behaviour are reflected in the genetic makeup

Based on a media release from the Leibniz Institute for Zoo and Wildlife Research (Leibniz-IZW)

A research consortium led by scientists from the German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and the Leibniz Institute for Zoo and Wildlife Research (Leibniz-IZW) provide evidence that social behaviour and social status are reflected at the molecular level of gene activation (epigenome) in juvenile and adult free-ranging spotted hyenas. The results, published in the scientific journal Communications Biology, contribute to a better understanding of the role of epigenetic mechanisms in the interplay of social, environmental and physiological factors in the life of a highly social mammal.

In mammals, social behaviour and social status can substantially influence the survival, reproductive performance and health of individuals. However, it is not yet fully understood how the translation of social and environmental factors into the physiology of an organism is reflected in molecular processes. Now, scientists have found that social status influences epigenetic patterns, more specifically, the methylation of DNA in both young and adult female spotted hyenas (Crocuta crocuta), which determines the activation of genes. They analysed DNA from gut epithelium cells from 18 adult female hyenas and 24 cubs with known social status from three clans in the Serengeti National Park, Tanzania. The scientists identified and validated 149 genome regions where high-ranking and low-ranking individuals differed in the methylation of DNA (differentially methylated regions, DMRs). “We could, for the first time, provide evidence for epigenetic signatures of social inequalities in both young and adult spotted hyenas”, says senior author Dr Alexandra Weyrich, sDiv scientist at iDiv and head of the working group “Wildlife Epigenetics” at the Leibniz-IZW. “We hope that in the future epigenetic biomarkers can be incorporated in biodiversity research to understand species‘ responses to environmental differences better”.

The findings show that these epigenetic signatures are stable across life stages – and that they are linked to important physiological processes: Many of the identified DMRs were involved in the regulation of energy conversion, immune response, glutamate receptor signalling and ion transportation. “Especially the large number of DMRs in genes involved in energy conversion caught our eye”, says first author Colin Vullioud, data scientist in Weyrich’s working group. Co-author Dr Sarah Benhaiem, co-head of the Serengeti Hyena Project, explains: “We suspect that this may be driven by differences in behaviour and specifically the greater use of long-distance foraging trips by low-ranking than high-ranking females – the latter monopolising resources in their clan territory.” Interestingly, these genes were more methylated (or hypermethylated) in low-ranking adult females but not in cubs. This could indicate an adjustment of low-ranking adult females to higher energetic costs of frequent long-distance commuting, a behaviour not displayed by cubs. “Although the exact physiological consequences of the observed hypermethylation remain to be investigated, these findings are consistent with our observations and hint at the sought-after missing link between social and physiological factors”, according to Weyrich and Benhaiem.

The analyses build on long-term research on spotted hyenas in the Serengeti, which started in 1987. The females in this investigation are individually known, and their social status has been tracked for generations. This provided ideal conditions to study the links between behaviour, physiological factors, epigenetic modifications and fitness in terms of survival and reproduction in a wild population. The use of faecal samples collected in a non-invasive manner is one of the strengths of the investigation, the authors surmise. “The capture methylation method we used enriches methylated DNA as well as mammalian DNA, which improved the amount of hyena DNA over bacterial DNA and the quality of the sequencing data”, Weyrich explains.

DNA methylation is a chemical modification of the basic building blocks of a cell's genetic material. This modification is enabled by the transfer of methyl groups to nucleobases at certain positions in the DNA. As the basic structure of the respective nucleobase is unaltered, DNA methylation is not a genetic mutation but a modification which determines whether this part of the DNA is ‘being used’ (activated) or switched off. DNA methylation is the most important epigenetic modification and, thus, a pivotal part of making genetic information available to the physiological processes within a cell.

Spotted hyenas are highly social animals and an excellent example of how differences in physiological processes and health can accompany status-related differences. In hyena clans, females and their offspring socially dominate all immigrant males, and social status is behaviourally “inherited” by cubs from mothers who gain privileges associated with maternal social status. Therefore, social status is stable and predictable because it is determined by family relationships and behavioural conventions. 

“Additionally, the effects of social status on life history trajectories and health are typically passed across generations”, adds Heribert Hofer, Director of Leibniz-IZW. For example, high-ranking females have priority access to resources in the clan territory and do not need to commute as much as low-ranking females to find food. They are, therefore, much more often present at the communal den and nurse their young more frequently. The milk-dependent cubs disproportionally benefit at this early stage in their life – by growing faster, having a higher chance of surviving to adulthood and starting reproduction at an earlier age than the offspring of low-ranking females.
 
Original Publication
Vullioud C, Benhaiem S, Meneghini D, Szyf M, Shao Y, Hofer H, East ML, Fickel J, Weyrich A (2024): Epigenetic signatures of social status in female free-ranging spotted hyenas (Crocuta Crocuta). Communications Biology.DOI: 10.1038/s42003-024-05926-y

 

Contact:

Dr Alexandra Weyrich (English, German)
Postdoctoral Researcher
sDiv - Synthesis Centre
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9733224
Email: alexandra.weyrich@idiv.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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TOP NEWS Media Release Thu, 28 Mar 2024 00:00:00 +0100
What do birds and rivers have to do with euro notes? https://idiv-biodiversity.de//en/news/news_single_view/5277.html Ecologist Prof Henrique Pereira is part of the ECB's Motifs Advisory Group, which proposes motifs...  

The full text is only available in German.

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Media Release TOP NEWS MLU News Biodiversity Conservation Tue, 26 Mar 2024 00:00:00 +0100
Citizen Science Project FLOW shows that most small streams in Germany are in a moderate ecological state https://idiv-biodiversity.de//en/news/news_single_view/5270.html New study published in Science of the Total Environment This text is only available in German.

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Media Release Research TOP NEWS Thu, 14 Mar 2024 09:39:58 +0100
Extinctions could result as fish change foraging behaviour in response to rising temperatures https://idiv-biodiversity.de//en/news/news_single_view/5274.html Fish species respond to temperature increases by going after more readily available prey. Models... Fish species respond to temperature increases by going after more readily available prey. Models suggest this behaviour could lead to more extinctions.

Fish are changing how they search for and consume prey in warmer waters, with models suggesting extinctions become more likely due to this behaviour change, according to a new study published in Nature Climate Change.
 
Led by researchers at the German Centre for Integrative Biodiversity Research (iDiv) and the Friedrich Schiller University Jena, the researchers found that fish in the Baltic Sea respond to temperature increases by consuming the first prey they encounter. This change in foraging behaviour led to the fish selecting prey that tends to be more abundant and smaller. Small prey present in their environment at all temperatures included brittle stars, small crustaceans, worms, and molluscs.
 
Fish, like many other consumer species, need more food when temperatures increase because their metabolism also increases. Although more abundant prey provides an immediate energy source, this so-called flexible foraging behaviour means fish are missing out on opportunities to satisfy their long-term energy needs by consuming larger prey that provide more calories. 
 
Model food web calculations show that this mismatch between a fish’s energetic requirements and their actual food intake could lead to more extinctions under warmer conditions, with fish ultimately starving because they are not eating enough to meet their energetic needs. The model, which can also be applied to other consumer species, suggests this is especially true for species higher up in food chains. The authors suggest that overall, this flexible foraging behaviour may make communities more vulnerable to climate change.
 
“It is usually assumed that species will adapt their foraging to maximise the amount of energy they consume”, explains first author Benoit Gauzens of iDiv and the University of Jena. “But these findings suggest fish – and other animals, too – may respond to the stress of climate change in unexpected and inefficient ways.”

Data from fish stomachs

The researchers analysed ten years of data about the stomach contents of six commercially important fish species with different feeding strategies in the Bay of Kiel. For example, flatfish, like the European flounder (Platichthys flesus), tend to be sit-and-wait predators, whereas Atlantic Cod (Gadus morhua) are more actively foraging feeders. 
 
Collected year-round from 1968 to 1978, this data provided insight into the fish’s diets – what was in their stomachs – and which prey was present in their environment at different temperatures. The stomach contents indicated that fish gradually shifted their focus from less abundant prey to more abundant prey as waters became warmer.
 
"Fish species in the Baltic Sea and elsewhere are facing a multitude of man-made pressures, like overfishing or pollution”, adds co-author Gregor Kalinkat of the Leibniz Institute of Freshwater Ecology and Inland Fisheries (IGB). “The effect of more inefficient prey searching behaviour under warming might be another, so far overlooked factor leading to fish stocks that cannot recover even when fisheries pressure is significantly reduced."
 
Using these insights, the researchers then calculated how this change in foraging behaviour at different temperatures impacts other species and the ecosystem overall using mathematical food web models based on theoretical communities. The results suggest that this change in foraging behaviour when temperature increases leads to more extinctions for consumer species, like fish. These extinctions, in turn, come with knock-on effects for other species in the community.
 
“Adaptation of foraging behaviour to local environmental conditions is usually a key to maintaining high levels of biodiversity in ecosystems”, Gauzens adds. “It is therefore puzzling to see that this might not be entirely true in the context of temperature increase.”
 
Though striking, the implications of the findings are estimated as they are currently based on theoretical models. In future, the researchers hope to test the mechanism in a natural environment and study different organisms to see whether they exhibit similar or different changes in their foraging behaviour.
 
Original publication
(Researchers with iDiv affiliation and alumni bolded)
Benoit Gauzens, Benjamin Rosenbaum, Gregor Kalinkat, Thomas Boy, Malte Jochum, Susanne Kortsch, Eoin J. O’Gorman, Ulrich Brose (2024). Flexible foraging behaviour increases predator vulnerability to climate change, DOI:10.1038/s41558-024-01946-y

 

Contact:

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TOP NEWS Theory in Biodiversity Science Media Release Tue, 27 Feb 2024 00:00:00 +0100
Disentangling Nature’s Contributions to International Trade https://idiv-biodiversity.de//en/news/news_single_view/5260.html A new approach to quantify the dependency of international trade and so-called Nature’s... A new approach to quantify the dependency of international trade and so-called Nature’s contributions to people

Researchers have developed a multi-step process to quantify the dependency of international trade and so-called Nature’s contributions to people. With their new approach, which has been published in People and Nature, the researchers hope to improve knowledge about the complex relationship between nature and international trade.

Humans are dependent on nature: It provides essential ecosystem services, such as clean water, food, and a variety of raw materials; it regulates the climate, and it offers space for a wide range of recreational activities. All of these benefits are Nature's contributions to people (NCPs). In a globalised world, consumers are increasingly disconnected from NCPs, as many everyday products are produced in distant parts of the world. Agricultural products, in particular, are heavily dependent on NCPs, and NCPs are, in turn, affected by human activities and decisions, such as how land is used and managed.

But how exactly is international trade linked to NCPs, and how can this link be made more tangible and comparable? With the help of an international team led by the synthesis centre sDiv at the German Centre for Integrative Biodiversity Research (iDiv), the researchers developed a multi-step process to help quantify the dependency of international trade on NCPs. To this end, the scientists analysed different studies about internationally traded products and nature’s contribution to these products. “This paper is one of the first to explicitly examine the relationship between NCPs and international agricultural trade", says first author Alexandra Marques, senior researcher at PBL Netherlands Environmental Assessment Agency. "This aspect isn't frequently studied nor quantified".

Everyday products depend on services provided by nature

Foods such as coffee and cocoa would not exist without the help of pollinators, and many other staple products also depend on the various services nature provides. However, there is currently limited data available to trace a bar of chocolate, for example, back to the fields where the cocoa beans were grown. “And it is even more complicated to disentangle which proportion of that bar of chocolate is in the end created by pollinators, let alone how big the contribution of the pollinator habitat is”, says senior author Nynke Schulp, Associate Professor at Vrije Universiteit Amsterdam.

NCPs can also include cultural or value-based contributions. “While there is knowledge on how agricultural products depend on some types of NCPs, this is much less so for other types of NCPs, such as non-material NCPs”, says Alexandra Marques. Cultural or non-material NCPs include local knowledge and values linked to an ecosystem that has an impact on the products produced locally. Approaches that account for non-material NCPs include the concept of terroir in viticulture, i.e. the interplay of soil, climate, topography and many other factors. A seal of origin that is based on terroir - for example, in France through the Appellation d'Origine Contrôlée (AOC) - creates awareness among consumers of the respective region and the distance that the product has travelled. The concept is also increasingly recognised for cheeses such as Comté, whisky or, more recently, bat-friendly tequila.

Many pieces of the puzzle still don't provide a complete picture

By analysing the individual studies as pieces of a larger puzzle, the researchers arrived at a three-stage process that can, in principle, be applied to all agricultural and internationally traded products: 1) spatial mapping of NCP's supply and demand; 2) linking spatial mapping with agricultural products; and 3) tracing international trade flows. This approach can already be applied to certain products. For example, the team is currently working on quantifying some of the dependencies related to the trade of coffee and soy from Brazil.

However, in order to link NCPs with even more agricultural products, researchers need transparent data on the respective trade flows and the regions where these goods are produced and consumed. "In principle, the current state of technology can solve this bottleneck, for example, through satellite images, artificial intelligence, and high computing power", Nynke Schulp says. "The challenge now lies in data proprietary rights and privacy. Appropriate legal frameworks are needed here".

With their new approach, the researchers hope to improve knowledge about the complex relationship between nature and international trade, adding to biodiversity assessments and to the work of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services (IPBES) and other bodies. A better understanding of NCP dependencies in different production processes will also support implementing Target 15 of the Kunming Montreal Global Biodiversity Framework, which requires businesses to disclose and assess their dependencies on nature. “We are very happy that we can foster global collaboration among leading scientists at our international iDiv synthesis centre, and assess how agricultural trade affects biodiversity in distant countries”, says Professor Dr Aletta Bonn, head of Biodiversity and People at iDiv, the Helmholtz Centre for Environmental Research (UFZ) and Friedrich Schiller University Jena.

 

The study was funded by the German Research Foundation (DFG; FZT-118), among others. It is a product of the sDiv synthesis working group sTradES. iDiv's synthesis centre sDiv supports working group meetings where international researchers work together on scientific questions.

Kati Kietzmann

 

Original publication
(Researchers with iDiv affiliation and alumni in bold)

Marques, A., Bonn, A., Castro, A. J., Chaudhary, A., Felipe-Lucia, M. R., Kastner, T., Koellner, T., Lancker, K., Lopez Hoffman, L., Meyer, C., Pfister, S., Rabeschini, G., Willemen, L., & Schulp, C. J. E. (2024). The role of nature's contributions to people in sustaining international trade of agricultural products. People and Nature. DOI: 10.1002/pan3.10607 

 

Contact:

Dr Alexandra Marques
PBL Netherlands Environmental Assessment Agency
The Hague, The Netherlands
Email: alexandra.marques@pbl.nl

 

Prof Dr Aletta Bonn
Head of Department Biodiversity and People
Helmholtz Centre for Environmental Research (UFZ)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Friedrich Schiller University Jena
Phone: +49 341 9733153
Email: aletta.bonn@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/137.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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sDiv TOP NEWS Media Release Fri, 23 Feb 2024 00:00:00 +0100
Increasingly similar or different? Centuries-long analysis suggests biodiversity is differentiating and homogenising to a comparable extent https://idiv-biodiversity.de//en/news/news_single_view/5256.html A new analysis shows that while many biotic communities are becoming more similar through time, an... Findings counter a pervasive expectation in the scientific community

The tendency of communities and the species within them to become more similar or more distinct across landscapes – biotic homogenisation and differentiation – are approximately balanced, according to a new study published in Science Advances. 

Led by researchers at the German Centre for Integrative Biodiversity Research (iDiv) and the Martin Luther University Halle-Wittenberg (MLU), the researchers analysed 527 datasets collected from ecosystems like grasslands, shrublands, and coral reefs as far back as 500 years ago. The analysis is the first of its kind to provide a comprehensive assessment of how local and regional biodiversity changes combine across landscapes over centuries.

“We wanted to examine the idea that homogenisation is a defining characteristic of the biodiversity crisis”, first author Dr Shane Blowes of iDiv and MLU says. “By combining a classic measure of scale-dependent biodiversity change with an unprecedented collation of data, we found that it is equally likely for communities to become more different through time in response to ongoing human impacts on the environment”. 

No change means more than you think

The analysis integrated measures of change in the number of different species (species richness) present in a single site with changes occurring across multiple sites combined within a landscape or geographical region. This allowed the researchers to determine whether species composition was becoming more similar or different across sites. 

They found no change in the spatial variation of species composition was the most common outcome. This was despite many instances of homogenisation and differentiation among communities over time. In fact, net trends in biodiversity change across scales were so weak that they were often indistinguishable from zero. 

The data also showed a weak homogenising trend across larger regions over many hundreds of years due to increased numbers of widespread species in communities; however, this trend was balanced by the differentiation of communities at smaller scales. These findings were consistent across many life forms, from fish to birds to plants and mammals.

Studies on biodiversity change paint a complex picture, and researchers are often of two minds about how species’ responses to human-driven changes should be characterised. However, the concept of homogenisation remains a pervasive expectation in the scientific community and the wider public.

“Our analysis exposes the complexity of the issue”, Professor Jonathan Chase, senior author of the study and professor at iDiv and MLU, explains. “It doesn’t mean severe changes aren’t happening in the world; it means we need to move beyond a belief that homogenisation is the main way biodiversity is changing”. 

Patterns for multiscale conservation

The researchers also present scenarios in their study that characterise changes in species occupancy: homogenisation is largely driven by increases in the average occupancy, whereas differentiation is driven by decreases in the average occupancy.

The scenarios make clear that even small changes in occupancy – due to landscape fragmentation via manmade roads or fences, the introduction of plants and animals to areas beyond their historic boundaries, and climate change, which can drive species to shift their range –  can tip a community toward either homogenisation or differentiation. 

The bright red Louisiana crawfish (Procambarus clarkii), which is native to northern Mexico and the southeastern United States, is an example of an introduced species that is flourishing in Germany’s freshwaters, driving homogenisation.

“We are seeing more and more that many threatened species require protection across multiple sites or at landscape scales to be effective”, Blowes adds. “A simple framework can help biodiversity management and conservation move to the multiscale approach needed to understand biodiversity change fully”. 

Original publication

(Researchers with iDiv affiliation and alumni in bold)

Shane A. Blowes, Brian McGill, Viviana Brambilla, Cher F. Y. Chow, Thore Engel, Ada Fontrodona-Eslava, Inês S. Martins, Daniel McGlinn, Faye Moyes, Alban Sagouis, Hideyasu Shimadzu, Roel van Klink, Wu-Bing Xu, Nicholas J. Gotelli, Anne Magurran, Maria Dornelas, Jonathan M. Chase (2024). Synthesis reveals approximately balanced biotic differentiation and homogenization, Science Advances, DOI:10.1126/sciadv.adj9395

 

Contact:

Dr Shane Blowes
Biodiversity Synthesis
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733254
Email: shane.blowes@idiv.de

 

Prof Dr Jonathan Chase
Head of the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733120

Email: jonathan.chase@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/synthesis.html

 

Christine Coester
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: christine.coester@idiv.de

 

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Research Biodiversity Synthesis TOP NEWS Wed, 21 Feb 2024 00:00:00 +0100
Converting rainforest to plantation impacts food webs and biodiversity https://idiv-biodiversity.de//en/news/news_single_view/5258.html Nature study on the effects of land use change in tropical ecosystems Nature study on the effects of land use change in tropical ecosystems

Based on a media release of the University of Goettingen

The conversion of rainforest into plantations erodes and restructures food webs and fundamentally changes the way these ecosystems function, according to a new study published in Nature. The findings provide the first insights into the processing of energy across soil and canopy animal communities in mega-biodiverse tropical ecosystems.

Every day, new areas of rainforests are converted into plantations, drastically changing tropical biodiversity and the way the ecosystem functions. Yet, the current understanding of the consequences is fragmentary: previous studies tended to examine either biodiversity or the ecosystem. An international research team led by the universities of Göttingen in Germany and Bogor in Indonesia in collaboration with the German Centre for Integrative Biodiversity Research (iDiv) and Leipzig University (UL) brings these threads together in this study. They analysed organisms ranging from microscopic mites and earthworms in the soil, to beetles and birds in tree canopies, comparing tropical rainforest with rubber and oil palm plantations in Sumatra, Indonesia.

The researchers set out to study both biodiversity – plants, insects, vertebrates – and changes in how food webs function – biomass, trophic structure, energy fluxes. To do this, they estimated the abundance and biomass of the following: arthropods (such as spiders, insects, mites and centipedes) in the tree canopies using a technique known as “fogging”; birds using audio recorders and observation at specific points; and soil arthropods and earthworms from soil cores. This information was collected across 32 sites representing rainforest or plantations. They analysed their findings using existing models on traits and feeding preferences to reconstruct food webs at each site and across all animal groups. The results were used as measures of the distribution of energy and consumption of different resources (living plants, litter, bacteria, fungi, soil organic matter, other animals) in food webs above and below the ground. This method takes into account decomposition and quantifies the actions of predators (such as certain spiders or birds) in food webs.

The scientists identified that most energy in rainforest animal communities flows to arthropods in soil food webs. Plantations, by contrast, had a very different energy distribution: food webs in canopies were less rich and less complex, and food webs in the soil were also changed. Instead of diverse arthropod communities, virtually all energy was allocated to invasive species of earthworms. Because of these changes, there was generally little predation and relatively high numbers of plant feeding insects (such as caterpillars and beetles) in plantations.

“It is fascinating to see how all these different organisms are connected, from minute arthropods to birds, from soils to canopies. Scientists clearly need to investigate such connections in different parts of the ecosystem, particularly endangered areas of biodiversity – such as the one beneath our feet!” said Anton Potapov, first author of the study, who was at the University of Göttingen during the data collection and later headed the junior research group Biodiversity and Soil Functions at iDiv and UL.

“The ongoing conversion of rainforest into plantations is not just causing a massive decline in biodiversity, but it is also changing the way these ecosystems function,” explains Professor Stefan Scheu, senior author and head of Animal Ecology, University of Göttingen. “For sustainable management of converted ecosystems, we need to understand how all these linked elements and connections are impacted. A more holistic approach can then be developed to promote the functioning of ecosystems both above and below ground.”

 

Original publication
(Researchers with iDiv affiliation in bold)

Anton M. Potapov, Jochen Drescher, Kevin Darras, Arne Wenzel, Noah Janotta, Rizky Nazarreta, Kasmiatun, Valentine Laurent, Amanda Mawan, Endah H. Utari, Melanie M. Pollierer, Katja Rembold, Rahayu Widyastuti, Damayanti Buchori, Purnama Hidayat, Edgar Turner, Ingo Grass, Catrin Westphal, Teja Tscharntke, Stefan Scheu (2024). Rainforest transformation reallocates energy from green to brown food webs. Nature. DOI: 10.1038/s41586-024-07083-y

 

Contact:

Dr Anton Potapov
Head of Soil Zoology Department
Senckenberg Museum für Naturkunde Görlitz
Phone: +49 3581 4760-5545
Email: anton.potapov@senckenberg.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Media Release iDiv TOP NEWS Tue, 20 Feb 2024 00:00:00 +0100
Critical Habitats at Risk: Three-quarters of vegetation types in the Americas are under-protected https://idiv-biodiversity.de//en/news/news_single_view/5252.html Study identifies vegetation types most in need of conservation efforts to protect threatened... Study identifies vegetation types most in need of conservation efforts to protect threatened species.

The study published in Global Ecology and Conservation found that three-quarters of these distinct habitats in North, Central, and South America fall below the Global Biodiversity Convention’s target of 30% protection. The research led by the German Centre for Integrative Biodiversity Research (iDiv) and Martin Luther University Halle-Wittenberg (MLU) also highlights that over 40% of threatened bird and mammal species are mostly found in a single vegetation type, putting them at risk for extinction if these critical habitats remain unprotected.

The Americas are home to some of the world's most biologically diverse regions, yet they are confronted with significant challenges due to habitat loss and degradation. While substantial protected areas exist, many smaller, yet crucial habitats within these landscapes remain unprotected. Despite the protection of large habitats, the specific needs of many species, especially those that are rare, specialised, and threatened, are often overlooked by broader habitat categorisations, leaving them vulnerable to habitat loss and degradation. Detailed fine-scaled habitat assessments at localised scales are essential to identify and protect critical habitats for species in the region.

To address this gap, a team of researchers led by iDiv and MLU conducted a comprehensive continent-wide analysis. Their study integrated fine-scale habitat maps, utilising the International Vegetation Classification (IVC) system, which encompasses over 300 vegetation types classified by unique plant communities and local environmental conditions. The research team also utilised the highest-resolution species distribution maps available for over 6,000 bird and mammal species. They then identified critical vegetation types by developing a conservation value index that incorporated the distribution of threatened species, habitat-associated species, current protection levels, and projected future threats across the Americas.

"Fine-scale vegetation mapping allowed us to pinpoint the localised vegetation types that harbour disproportionately high numbers of specialised species," said first author Lea Schulte (Leibniz University Hannover). "This level of precision is critical for effective conservation planning."

The study found significant differences in the level of protection between vegetation types, with nearly three-quarters of assessed vegetation types currently below the Global Biodiversity Convention’s 30% protection target. Additionally, 20% of assessed bird and mammal species had at least half of their habitat range within a single vegetation type. Alarmingly, this included over 40% of all threatened species, emphasising the importance of targeted efforts to conserve these vegetation types.

"Our study demonstrates the value of finer-scale, localised habitat assessments, which reveal vulnerabilities often overlooked in broader classifications," stated senior author Dr Jose Valdez (iDiv, MLU). "By identifying key vegetation types vital for threatened and specialised species, we can implement tailored conservation strategies to protect biodiversity."

Priority areas identified included the species-rich Northern Andean montane forests and Central American highlands, Brazil's Cerrado savanna and Atlantic Forest, and the Caribbean islands. However, the study found these critical areas remain dangerously under-protected and highly threatened by human activities.

The researchers emphasize that reaching global 30% protection targets requires comprehensive approaches encompassing habitat diversity, not just area-based goals. They advocate for expanded efforts to map critical vegetation types and species distributions, which can inform precise conservation planning when combined with emerging land use threats.

"This study not only emphasises the urgent need for conservation action in the Americas but also provides a comprehensive blueprint for identifying at-risk habitats globally," said Lea Schulte. "By utilising a flexible framework, we can effectively identify critical vegetation types that support threatened biodiversity and vegetation-associated species. This enables us to efficiently mobilise resources and prioritise the protection of areas where they are most critically needed."

 

Original publication
(Researchers with iDiv affiliation are in bold)

Schulte, L., Quoss, L., Comer, P., Lumbierres, M., Oceguera , E., Pereira, H. M., & Valdez, J. (2024). Identifying Critical Vegetation Types for Biodiversity Conservation in the Americas. Global Ecology and Conservation. DOI: 10.1016/j.gecco.2024.e02831

 

Contact:

Dr Jose W. Valdez (speaks English and Spanish)
Postdoctoral Researcher
Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9739168
Email: jose.valdez@idiv.de
Web: https://www.idiv.de/en/profile/1290.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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TOP NEWS Research Media Release iDiv Wed, 14 Feb 2024 00:00:00 +0100
Fish in the upper Danube could be just as endangered in the future as they were in the past, but for different reasons https://idiv-biodiversity.de//en/news/news_single_view/5254.html Higher temperatures could pose the greatest threat

Based on a media release from the Leibniz Institute of Freshwater Ecology and Inland Fisheries (IGB)

Rivers belong to the most threatened ecosystems on Earth. While many studies have projected climate change effects on species, little is known about the severity of these changes compared to historical alterations. Researchers led by the Leibniz Institute of Freshwater Ecology and Inland Fisheries (IGB) and the German Centre for Integrative Biodiversity Research (iDiv) explored the vulnerability of 48 native fish species in the upper Danube River Basin to past and potential future environmental changes. They show that fish have been particularly sensitive to changes in flow regimes in the past, while higher temperatures will pose the greatest threat in the future. The threat assessment will remain at least as high in the future. However, it could probably be mitigated by reconnecting former floodplains and improving river connectivity. 

With almost a third of all freshwater species threatened with extinction – and a quarter of all known freshwater fish species – freshwaters belong to the most vulnerable ecosystems on earth. Fish species in river ecosystems are sensitive to alterations in discharge and temperature. Human interventions such as straightening and damming have historically altered river flows around the world, negatively affecting fish abundance, demography and diversity. When assessing the conservation needs of freshwater biodiversity under future climate change scenarios, it is important to understand the often dramatic historical environmental changes and their effects on species or populations.

“Fish communities in the upper Danube River Basin have already come under severe pressure over the last 200 years due to massive changes in the water regime. Our results show that the vulnerability of species in the past was mainly due to anthropogenic interventions such as river straightening. This has severely impacted the river. Future potential vulnerability is mainly due to temperature,” said Dr Martin Friedrichs-Manthey, lead author of the study. He is a scientist at the Friedrich Schiller University Jena, a guest scientist at the Helmholtz Centre for Environmental Research (UFZ) and works at the German Centre for Integrative Biodiversity Research (iDiv).

Future changes for Danube fish: at least the same overall vulnerability as in the past 

The research team investigated the vulnerability of the fish species to future climate scenarios. In the most likely scenario, they found an increase in fish vulnerability. This is mainly due to a 2°C increase in the average annual temperature. Moreover, the study shows that future environmental conditions for riverine fish species driven by temperature would change at least at a similar magnitude as past hydrological changes driven by anthropogenic river regulations. “This result surprised us, as we had assumed that future climate change would not lead to such a high threat assessment as the massive regulation of the Danube in the past,” said IGB scientist Dr Sami Domisch, who led the study.

Sins of the past concerning the upper Danube River: 15 per cent of its length lost, 90 per cent of its banks embanked

The regulation of the Danube for flood protection and shipping began at the end of the 16th century. By the end of the 19th century, the German and Austrian main stem had lost 15 per cent of its length due to channelisation, and today, more than 90 per cent of the shoreline of the upper Danube mainstream is embanked. And more than 70 hydroelectric power stations in the main river alone fragment the upper Danube. This has led to the loss of almost all free-flowing river stretches. These structural changes have decimated the number and diversity of native fish species. Take the sturgeon, for example: six different species used to live in the Danube. Today, five are classified as critically endangered, and one is already extinct.

Vulnerability of fish communities could be buffered by floodplain connectivity and improved river continuity

However, in their study, the researchers also point to possible solutions: “Other studies on invertebrates or marine fish have already shown that a reduction in environmental pollution - for example by improving water quality - can promote resilience to the expected climatic stresses. According to our assessment, this would also be possible in the Danube,” said Dr Sami Domisch.

The authors identified the restoration of floodplains as an effective measure for the conservation of fish communities. Other studies have shown that in the upper Danube catchment area, around a quarter of the historically available and currently cut-off floodplain area has good potential for restoration measures. In view of rising temperatures, the upper Danube catchment, with its many headwaters, could also offer temperature refuges for sensitive cold-water fish. To achieve this, however, river continuity must be improved so that species can also reach these areas.

Scientific approach

The researchers used a 300-year time series of hydrological and climatic data to investigate the vulnerability of 48 native fish species in the upper Danube catchment to past and potential future environmental changes. The research area stretched from the source of the Danube to Vienna and covered an area of over 100,000 square kilometres and around 1000 kilometres of the main Danube river. Based on modelled and observed hydrological and climatic data, they calculated estimates of species-specific vulnerability for the period from 1800 to 2100. They compared the estimated vulnerability of species between two historical time intervals (1800-1830 and 1900-1930) and a future time interval (2070-2100) for two different climate scenarios. In addition, they determined the most important environmental factors for the vulnerability of species and their changes over the last 200 years and the projected 100 years in the future. The current environmental conditions and, thus, the modelled habitat suitability of the fish species were used as a baseline.

 

Original publication:
(iDiv authors bolded)
Friedrichs-Manthey, M., Langhans, S. D., Borgwardt, F., Hein, T., Kling, H., Stanzel, P., Jähnig, S. C., & Domisch, S. (2024). Three hundred years of past and future changes for native fish species in the upper Danube River Basin—Historical flow alterations versus future climate change. Diversity and Distributions, 00, 1–14. https://doi.org/10.1111/ddi.13808

 

Contact:

Dr Martin Friedrichs-Manthey
Postdoctoral researcher
of the Biodiversity and People research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Helmholtz Centre for Environmental Research (UFZ)
Friedrich Schiller University Jena
Email: martin.friedrichs-manthey@idiv.de
Web: https://www.idiv.de/de/profile/1376.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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Media Release TOP NEWS Biodiversity and People Wed, 14 Feb 2024 00:00:00 +0100
Ecologist Brian McGill receives Humboldt Research Award https://idiv-biodiversity.de//en/news/news_single_view/5250.html The US researcher will use the prize money for several stays at iDiv The US researcher will use the prize money for several stays at iDiv

Based on a media release of Martin Luther University Halle-Wittenberg

The Alexander von Humboldt Foundation has honoured US scientist Professor Dr Brian McGill from the University of Maine with the prestigious Humboldt Research Award. The biodiversity researcher was nominated by Professor Dr Jonathan Chase, head of Biodiversity Synthesis at the German Centre for Integrative Biodiversity Research (iDiv) and Martin Luther University Halle-Wittenberg (MLU). The award is endowed with 60,000 euros. McGill will use the money for several research stays at iDiv.

Brian McGill is an internationally renowned macroecologist. His research focuses on the consequences of anthropogenic changes on species communities and biological diversity. In particular, he is investigating the impacts of global warming or land-use change, for example through urbanization. McGill studied at Harvard University and received this doctorate from the University of Arizona. He has been a professor at the University of Maine since 2015. He has authored and co-authored more than 200 publications, including high-impact studies in Nature, Science and Trends in Ecology & Evolution.

In 2017, McGill had visited iDiv for several weeks. Together with Jon Chase, he developed a critical set of methodologies that helps dissect the influence of different factors (abundances, spatial distributions) on biodiversity change. McGill plans to contribute to further developing this approach during his stays in Germany. “I am looking forward to continuing this project and using the extended stay to brainstorm some fundamental new directions to explore. iDiv is a wonderfully intellectually stimulating environment for an ecologist,” McGill says. He also plans to use his time in Germany to finalise a book on ecology and global change.

The Alexander von Humboldt Foundation awards the Humboldt Research Award to scientists who have had a fundamental impact on their field of expertise, and from whom further outstanding achievements are expected. The awardees may conduct research projects of their own choice in Germany in collaboration with colleagues from the field.

 

 

Contact:

Prof Dr Jonathan Chase
Head of the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733120

Email: jonathan.chase@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/synthesis.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Media Release MLU News TOP NEWS Fri, 09 Feb 2024 00:00:00 +0100
Wolves and elk are (mostly) welcome back in Poland and Germany’s Oder Delta region, survey shows https://idiv-biodiversity.de//en/news/news_single_view/5241.html Survey shows positive attitudes towards rewilding in the Oder Delta region, but finds locals’... Survey shows positive attitudes towards rewilding in the Oder Delta region, but finds locals’ feelings are mixed.

An online survey conducted in Germany and Poland shows that large parts of the participants support the return of large carnivores and herbivores, such as wolves and elk, to the Oder Delta region, according to a study published in People and Nature. Presented with different rewilding scenarios, the majority of survey participants showed a preference for land management that leads to the comeback of nature to the most natural state possible. Locals, on the other hand, showed some reservations.

In recent years, the concept of rewilding has captured the attention of conservationists, who see it as a promising and cost-effective tool to combat biodiversity loss and restore ecosystems. The Oder Delta area, which spans the northern border between Germany and Poland, is particularly suitable for the natural comeback of wildlife. It comprises diverse natural habitats, like riparian forests, standing- and flowing waters, open and semi-open inland dunes, and heathlands, and is surrounded by diverse landscapes of forests, rivers, and wetlands. 

To measure public sentiment towards rewilding in the Oder Delta, a team of researchers led by the German Centre for Integrative Biodiversity Research (iDiv) and the Martin Luther University Halle-Wittenberg (MLU) carried out an online, choice experiment survey. Given the geographic position of the area across both Germany and Poland, the survey offered a unique opportunity to investigate differences in attitudes between the two countries. Approximately 1,000 respondents from each country were presented with different scenarios describing the ecological status of the Oder Delta in 2050 as a result of various management interventions. The scenarios included, for example, the conditions of rivers and forests and the presence of large animals such as elk, lynx, or wolves. Beyond the “status quo” option, an intensification of land use in the region, respondents were presented with two alternative scenarios with varying biodiversity benefits.

Importantly, only the status quo option came at no additional cost. The two alternative options were associated with tax payments to fund the necessary interventions, meaning that respondents were faced with a trade-off: an increase in nature benefits went hand in hand with an increase in taxes. “This allowed us to calculate the respondents’ willingness to pay for different management interventions in the Oder Delta region”, says lead author Rowan Dunn-Capper from iDiv and MLU. “This helps us understand broader preferences for rewilding”. 

Strong preferences for rewilding

The study revealed a significant appetite for rewilding initiatives at the national scale, particularly for the presence of large animals, such as wolves, lynx, elk, and bison in the Oder Delta. Willingness to pay for scenarios in which large animal species were present was almost three times larger than for restoring the most natural landscape elements. “To find such preference was surprising given the often-negative portrayal of large animal species, notably the wolf, in the popular media”, says Dunn-Capper. “It suggests the public may be more welcoming of wildlife return than first thought”. This preference was also true for forests and agriculture: respondents in Germany as well as in Poland had a strong preference for the most natural rewilding levels with minimum human intervention on the ecosystem. Additionally, the fact that results for Germany and Poland were broadly comparable indicates that preferences for rewilding hold across political and cultural contexts.

Locals are less enthusiastic about rewilding

Survey participants living near the Oder Delta (within 100km) did not show the same appetite for rewilding initiatives. Local respondents showed a preference for large herbivores, such as elk and bison, but were less enthusiastic about the presence of large carnivores, like wolves. Similarly, local respondents showed contrasting preferences for certain rewilding interventions in rivers and agricultural landscapes compared to the national sample. For example, a significant share of local respondents were not willing to pay for scenarios in which flooding regimes were fully restored in the Oder Delta. “This underscores the intricacies of conservation planning and highlights the importance of local input to foster biodiversity democracy, this is the management of natural resources as a democratic process”, says senior author Professor Henrique Pereira, head of Biodiversity Conservation at MLU and iDiv. “Generally, our findings support rewilding as a novel ecosystem restoration approach that has public acceptance to become mainstream across Europe.”

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

Kati Kietzmann

 

Original publication
(Researchers with iDiv affiliation in bold)

Rowan Dunn-Capper, Marek Giergiczny, Néstor Fernández, Fabian Marder, Henrique M. Pereira (2024). Public preference for the rewilding framework: a choice experiment in the Oder Delta. People and Nature, DOI: 10.1002/pan3.10582

 

Contact:

Rowan Dunn-Capper
Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Email: rowan.dunn-capper@idiv.de

 

Prof Dr Henrique Miguel Pereira (speaks English and Portuguese)
Head of Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Email: henrique.pereira@idiv.de
Web: https://www.idiv.de/en/profile/132.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Biodiversity Conservation iDiv TOP NEWS Research Media Release Mon, 22 Jan 2024 00:00:00 +0100
Bloom or bust https://idiv-biodiversity.de//en/news/news_single_view/5243.html Whitepaper examines the role of technology and finance to address biodiversity challenges Whitepaper examines the role of technology and finance to address biodiversity challenges

A new white paper ‘Bloom or bust’, that has been produced by USB together with experts including Dr Miguel Fernandez from the German Centre for Integrative Biodiversity Research (iDiv) and Martin Luther University Halle-Wittenberg, takes stock of where the world stands on biodiversity loss, existing solutions, and the role that finance, government action, and collaboration can play.

“Given the strong dependencies between the global economy and nature, the urgency of tackling biodiversity loss is not only an environmental imperative, but also a crucial economic imperative”, says Dr Miguel Fernandez. “Governments, the private sector, and academia should feel that participating in success stories where we collaboratively mobilize technological and financial solutions is not a sacrifice, but an opportunity to catalyze innovation and to strength our adaptive capacity to deal with an uncertain future while we work together to foster a sustainable, nature-positive economy.”

 

White paper “Bloom or bust. Aligning technology and finance to address biodiversity challenges” [Download PDF]

 

Contact:

Dr Miguel Alejandro Fernandez Trigoso (speaks Englisch and Spanish)
Lead Scientific Officer
Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Phone: +49 341 9733192
Email: miguel.fernandez@idiv.de

 

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Media Release Mon, 22 Jan 2024 00:00:00 +0100
Honoured: Christian Wirth appointed External Member of the Max Planck Institute for Biogeochemistry https://idiv-biodiversity.de//en/news/news_single_view/5239.html Wirth’s work complements research focus of the Max Planck Institute

Based on a media relase by the Max Planck Institute for Biogeochemistry

The Max Planck Institute for Biogeochemistry (MPI BGC) has gained a new external member: Prof Dr Christian Wirth has been appointed by the Senate of the Max Planck Society as External Scientific Member at the request of the MPI BGC. Wirth is the founding director and spokesperson of the German Centre for Integrative Biodiversity Research (iDiv), professor at Leipzig University and director of the Leipzig Botanical Garden. The plant ecologist investigates the effects of natural and man-made changes in plant biodiversity on ecosystem processes, such as carbon storage, water consumption and energy balance. As a former group leader and later fellow at the MPI BGC, Wirth initiated and supported the development of the TRY database, the world's largest collection on plant traits. His research on the influence of climate change on biodiversity and ecosystem services of forests ideally complements the research focus of the Max Planck Institute in Jena. 

Biologist Prof Dr Christian Wirth from Leipzig University, Speaker of the German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig, has been appointed  External Member of the Max Planck Society by its Senate, at the request of the Max Planck Institute for Biogeochemistry (MPI BGC) in Jena. The awarding of this honorary title is intended to further strengthen research cooperation in the field of biodiversity, biogeochemistry and global change between the MPI BGC, Leipzig University and, in particular, the iDiv Center. In addition to Prof Christian Wirth, Prof Anna Michalak, Director of the Department of Global Ecology at the Carnegie Institution for Science and Professor of Earth System Science and Biology at Stanford University, was also appointed as an external member with MPI BGC in 2023.

“I am delighted to be breaking new ground with my excellent colleagues at the MPI for Biogeochemistry. Species extinction and climate change are phenomena of one and the same problem. The consequences of biodiversity loss cannot be understood without biogeochemistry and the relationship to the Earth system,” says Wirth.

Wirth has a long and fruitful relationship with the MPI BGC in Jena. From 2005 to 2009, he was head of the independent Max Planck Research Group “Organismic Biogeochemistry”, where he conducted research at national and international locations, but also in Central Germany, for example in the DFG-funded “Jena Experiment” and the “Biodiversity Exploratories”. He then accepted a position at Leipzig University. There, together with many colleagues from Central Germany, he was instrumental in founding the German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig and acted as its director and speaker. 

From 2013 to 2022, Prof. Wirth, together with Dr Jens Kattge and Dr Gerhard Bönisch from the MPI BGC, was able to continue the successful work on the TRY database, which he had already started as group leader, as a part-time Max Planck Fellow. The TRY database, now the world's largest database on plant traits, is requested by scientists worldwide approximately every two hours. From the publicly accessible TRY database, records on the locations, properties and functions of plants and their changes are then provided.

Prof. Wirth is highly successful in communicating the increasing importance of biodiversity, particularly in the context of climate change, to a wide audience. As director of the botanical garden, head of the forest crane in the Auwald and of the research arboretum in Leipzig, and in many eloquent lectures, he has already been able to inspire the interested public about biodiversity. Due to his outstanding achievements in biodiversity research, he was honoured with the Leipzig Science Award in 2022.

In special recognition of his scientific achievements, Wirth was recently appointed to the newly founded “Forum Zukunftsstrategie” by Federal Education Minister Bettina Stark-Watzinger. Wirth is currently also leading the national biodiversity assessment “Fact Check for the Conservation of Biodiversity” of the Federal Ministry of Science and Research (BMBF). 

“We are very happy to have gained Christian Wirth as an external member, who with his understanding of global biodiversity optimally complements our research on global element cycles,” says Prof Sönke Zaehle, Managing Director at the MPI BGC, and continues: “We look forward to further constructive cooperation and new impulses to better understand the importance of biodiversity for global element cycles and, above all, their stability against the background of current climate and land use changes.”

 

Contact:

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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TOP NEWS Media Release iDiv Members Wed, 17 Jan 2024 00:00:00 +0100
Global study of extreme drought impacts on grasslands and shrublands https://idiv-biodiversity.de//en/news/news_single_view/5237.html Effects of extreme drought have been greatly underestimated Effects of extreme drought have been greatly underestimated

Based on a media release of Colorado State University

A global study organized and led by Colorado State University scientists and with participation of several researchers from the German Center for Integraitive Biodiversity Research (iDiv) shows that the effects of extreme drought – which is expected to increase in frequency with climate change – have been greatly underestimated for grasslands and shrublands. 

The findings – published in Proceedings of the National Academy of Sciences – quantify the impact of extreme short-term drought on grassland and shrubland ecosystems across six continents with a level of detail that was not previously possible. It is the first time an experiment this extensive has been undertaken to generate a baseline understanding of the potential losses of plant productivity in these vital ecosystems. 

Melinda Smith, a professor in the Department of Biology at CSU, led the study and was the first co-author along with Kate Wilkins, the Regional Conservation Director for Colorado at the Denver Zoo. Dr. Smith said the observed reduction in a key carbon cycle process after a single 1-in-100-year drought event greatly exceeds previously reported losses for grasslands and shrublands.

“We were able to determine that the loss of aboveground plant growth – a key measure of ecosystem function – was 60% greater when short-term drought was extreme compared to the less severe droughts that have been more commonly experienced historically,” she said. “Past studies suffered from methodological differences when estimating the impacts of extreme drought in natural ecosystems, but our standardized, distributed approach here addressed that problem.” 

The project also showcases the variability in drought response across grassland and shrubland ecosystems – offering both a review of the global impacts of climate change as well as a glimpse into which areas will be most stressed or most resilient in the coming years.

Gathering global drought data on grassland and shrubland ecosystems  

Known as the International Drought Experiment, the newly published research originally dates back to 2013 as part of the National Science Foundation’s Drought-Net Research Coordination Network. Altogether, there are more than 170 authors representing institutions from around the world cited in the new PNAS study, which was completed over the last four years. 

To gather their data, researchers built rainfall manipulation structures to experimentally reduce the amount of naturally occurring precipitation available to ecosystems for at least a full growing season. About half of the participating sites imposed extreme drought conditions with these structures, while the rest imposed less severe drought for comparison.

As Earth’s climate continues to change, short-term droughts that are statistically extreme in intensity will become more common, with what were once considered 1-in-100-year droughts now potentially happening every two to five years. But because of the historic rarity of extreme droughts researchers had been unable to estimate the actual magnitude of their ecological consequences. 

Smith said grasslands and shrublands were perfect test areas to fill that research gap because they are easier to manipulate for study than other systems, such as forests. They also store more than 30% of the global stock of carbon and support key industries such as livestock production.

“They are key ecosystems that are scalable to the globe, which makes them highly relevant for this kind of work,” said Smith. “Grasslands and shrublands cover between 30% and 40% of the globe and frequently see deficits in precipitation. That means they are more vulnerable to climate change.” 

Findings from the sites, including the Bad Lauchstädt Experimental Research Station of the Helmholtz Centre for Environmental Research (UFZ), also provide insight into how specific climates, soil and vegetation types broadly influence drought response. While the work shows that drier and less diverse sites are likely to be the most vulnerable to extremes, the severity of the drought was the most consistent and important factor in determining an ecosystem’s response.

“Our data suggests greater losses in drier sites, but if you are getting to the extremes – which is what is being forecasted – we can generally expect substantial losses no matter where you are in the world,” she said. “We also found that even moderate losses from less severe droughts would still likely result in large impacts to the populations that rely on these systems. And then there is a combined loss of function across the globe to consider as well.”

The team is currently examining data collected from the full four years of the project to now assess multiyear drought impacts globally.

 

Original publication
(Researchers with iDiv affiliation in bold)

Melinda D. Smith, Kate D. Wilkins, […] Harald Auge, […], Anne Ebeling, Nico Eisenhauer, […], Daniela Hoss, […], Christiane Roscher, […], Marie Sünnemann et al. (2024). Extreme drought impacts have been underestimated in grasslands and shrublands globally. PNAS, DOI: 10.1073/pnas.2309881120

 

Contact:

Prof Dr Nico Eisenhauer
Head of the research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 97 33167
Email: nico.eisenhauer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/eisenhauer_nico.html

 

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TOP NEWS Media Release Tue, 09 Jan 2024 00:00:00 +0100
Use of habitat for agricultural purposes puts primate infants at risk https://idiv-biodiversity.de//en/news/news_single_view/5235.html Study reveals link between frequent plantation visits and infant mortality in wild southern... Study reveals link between frequent plantation visits and infant mortality in wild southern pig-tailed macaques in Peninsular Malaysia

Frequent visits to oil palm plantations are leading to a sharp increase in mortality rates among infant southern pig-tailed macaques (Macaca nemestrina) in the wild, according to a new study published in Current Biology. In addition to increased risk from predators and human encounters, exposure to harmful agricultural chemicals in this environment may negatively affect infant development.

In wild populations, infant survival is crucial for determining individual fitness and for maintaining viable populations in changing environments. For primates, agricultural areas adjacent to tropical forest habitat can be a mixed blessing: While crop plantations can provide easy access to food, they also come with increased exposure to various hazards, which is likely contributing to reduced infant survival in several wild primate species. 

Exposure to palm plantations increases infant mortality

In a long-term collaboration between Universiti Sains Malaysia (USM), the German Centre for Integrative Biodiversity Research (iDiv), Leipzig University (UL), and the Max Planck Institute for Evolutionary Anthropology (MPI EVA), researchers set out to investigate potential links between frequent visits to oil palm plantations and the particularly high infant mortality they observed among wild southern pig-tailed macaques in Peninsular Malaysia. In a habituated study population in this region, 57% of all infants born between 2014 and 2023 died before the age of one – a rate that far exceeds mortality rates reported in other wild primate populations.

For almost ten years, the researchers followed two groups of macaques living in a mosaic of rainforest and oil palm plantations. They found that prolonged exposure to oil palm plantations during infancy tripled the likelihood of infant mortality. This key finding could be explained by increased encounters with predators and humans, and potential exposure to harmful chemicals such as pesticides in this environment.

“Some of these risks are relatively clear: infant macaques are more likely to fall prey to feral dogs that roam in the plantations in packs or to be captured by humans and sold illegally as pets,” explains Dr Nadine Ruppert from USM, who established and leads the field site. “But the potential long-term effects of the pesticides used to manage the monocultures on mammalian wildlife are much less obvious and very poorly understood.” 

Pesticides may affect foetal development

The study also found increased infant mortality rates when mothers gave birth for the first time or when there was a long interval between two consecutives births, which contradicts studies that report increased mortality when the interbirth interval is shorter. The accumulation or uptake of pesticides in the mother’s body may play a key role: “The literature suggests that certain harmful substances used in agriculture can cross the placental barrier and be passed on to the unborn offspring. We also know that certain fat-soluble molecules can be passed on through breastmilk,” says lead author Dr Anna Holzner (iDiv, MPI EVA, UL and USM). “Accordingly, the longer the chemicals accumulate in the mother’s body, the more they could influence foetal development during pregnancy and also during lactation.”

The study highlights the urgent need to address anthropogenic threats to animals in agricultural landscapes. “We know that the use of pesticides in agriculture has led to drastic declines in insect populations, so chemical analysis is essential to understand the effects of pesticides on mammalian wildlife,” says Professor Dr Anja Widdig (UL, MPI EVA and iDiv), senior author and leading PI in this iDiv Flexpool project. “Our findings underscore the critical need to implement environmentally friendly cultivation practices that minimise the risks to wildlife populations and also to people living near plantations.”

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

Kati Kietzmann

 

Original publication
(Researchers with iDiv affiliation are in bold)

Anna Holzner, Nurul Iza Adrina Mohd Rameli, Nadine Ruppert, Anja Widdig (2024): Agricultural habitat use affects infant survivorship in an endangered macaque species. Current Biology, DOI: 10.1016/j.cub.2023.12.002

 

Related links

Nature Research Highlight "Life is short for baby monkeys amit the oil palms"

 

Contact:

Dr Anna Holzner
German Centre for Integrative Biodiversity Research (iDiv)
Behavioural Ecology Research Group, Institute of Biology, Faculty of Life Sciences,
Leipzig University
Max Planck Institute for Evolutionary Anthropology
Email: anna.holzner@uni-leipzig.de

 

Prof Anja Widdig
Leipzig University
Max Planck Institute for Evolutionary Anthropology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9736-707
Email: anja.widdig@eva.mpg.de

 

Dr Nadine Ruppert
School of Biological Sciences
Universiti Sains Malaysia
Email: n.ruppert@usm.my

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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iDiv Members Research TOP NEWS Media Release Mon, 08 Jan 2024 00:00:00 +0100
Environmental economist: "There is no justification for subsidising agricultural diesel" https://idiv-biodiversity.de//en/news/news_single_view/5234.html Interview with Martin Quaas, head of Biodiversity Economics research group Interview with Martin Quaas, head of Biodiversity Economics research group

 

The full text is only available in German.

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TOP NEWS Media Release Biodiversity Economics Fri, 05 Jan 2024 00:00:00 +0100
How can Europe restore its nature? https://idiv-biodiversity.de//en/news/news_single_view/5229.html Final vote of the EU Parliament in 2024 Final vote of the EU Parliament in 2024

Based on a media release of the University of Duisburg-Essen

Early 2024, the European Parliament will take a final vote on the ‘Nature Restoration Law’ (NRL), a globally unique but hotly debated regulation that aims to halt and reverse biodiversity loss in Europe. An international team of scientists led by the University of Duisburg-Essen und with contribution from reseachers from the German Center for Integrative Biodiversity Research (iDiv) as well as the Helmholtz Centre for Environmental Research (UFZ) investigated the prospects of the new regulation. The article has been published in the Science Magazine.

The ‘Nature Restoration Law’ (NRL) requires member states of the EU to implement restoration measures on at least 20 per cent of land and marine areas by 2030, and in all ecosystems in need of restoration by 2050. This includes specific targets to rewet peatlands and to increase pollinator populations. The NRL has already overcome various hurdles: most recently, it was approved by the EU Parliament’s Environment Committee, after delegations of the Parliament and the Council negotiated the final text.

But will the regulation really achieve its aims? The authors, including scientists leading large European projects on nature restoration and biodiversity, analysed experiences with other European environmental directives and policies, and evaluated the prospects of the NRL to be successful. 

“The NRL avoids several pitfalls that often obstruct the implementation of European policies and regulations, showing that the Commission learned from past experiences” says Prof. Dr Daniel Hering from the University of Duisburg-Essen, first author of the study. “The regulation sets ambitious targets and timelines, and implementation steps are clearly laid out. It also saves time as it does not need to be transposed into national law.” At the same time, national implementation will be crucial for the NRL’s success. “While targets are precisely defined and binding, the steps to achieve them need to be decided by individual European countries and most of them are voluntary” says Prof. Dr Josef Settele from Helmholtz Centre for Environmental Research (UFZ) in Halle, one of the study’s authors.

Key to the implementation will be the cooperation of nature restoration with land users, in particular with agriculture. “Intensive agriculture is still a key driver for biodiversity loss in Europe”, says senior author Dr Guy Pe’er from iDiv and UFZ. “But targets for agriculture and nature restoration could be coordinated, with opportunities for both”. Agriculture directly benefits from healthy soils and pollinator populations and from increased water storage capacity in the landscape that are all targets of the NRL. 

The authors conclude that funds provided by the EU’s Common Agricultural Policy need to be used for achieving the NRL’s aims: a statement to be intensively debated in science and application.

Overall, the authors provide a positive outlook for the NRL, but warn that ambitious national implementation and cooperation with economic sectors, such as agriculture, will eventually determine the success of nature restoration in Europe.

 

Original publication
(Researchers with iDiv affiliation in bold)

Daniel Hering, Christian Schürings, Franziska Wenskus, Kirsty Blackstock, Angel Borja, Sebastian Birk, Craig Bullock, Laurence Carvalho, Magda Bou Dagher-Kharrat, Sebastian Lakner, Nataša Lovrić, Shane McGuinness, Gert-Jan Nabuurs, Agustín Sánchez-Arcilla, Josef Settele, Guy Pe’er: Securing success for the EU Nature Restoration Law. Science. DOI: 10.1126/science.adk1658

 

Contact:

Prof Dr Daniel Hering
Department of Aquatic Ecology
University of Duisburg-Essen
Email: daniel.hering@uni-due.de

 

Dr Guy Pe’er
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
“Agriculture and Ecosystem Services'' group,
Dept. Ecosystem Services,
Helmholtz Centre for Environmental Research (UFZ)
Phone: +49 341 97 33182
Email: guy.peer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/643.html

 

Prof. Dr. Josef Settele
Head of the Department of Conservation Biology & Social-Ecological Systems
Helmholtz Centre for Environmental Research (UFZ)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: josef.settele@ufz.de
Web: http://www.ufz.de/index.php?de=38572

 

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TOP NEWS Media Release Fri, 15 Dec 2023 00:00:00 +0100
Common insect species are suffering the biggest losses https://idiv-biodiversity.de//en/news/news_single_view/5231.html Declines in insect numbers are largely driven by losses of more abundant species Declines in insect numbers are largely driven by losses of more abundant species

Leipzig. Insect decline is being driven by losses among the locally more common species, according to a new study published in Nature. Led by researchers at the German Centre for Integrative Biodiversity Research (iDiv) and the Martin Luther University Halle-Wittenberg (MLU), the meta-analysis of 923 locations around the world notes two significant trends: 1) the species with the most individuals (the highest abundance) are disproportionately decreasing in number, and 2) no other species have increased to the high numbers previously seen. This likely explains the frequent observation that there are fewer insects around now than ten, twenty, or thirty years ago.

Researchers at iDiv looked at long-term trends of land-based insects, such as beetles, moths, and grasshoppers, and found that decreases in the number of the formerly most common species have contributed most to local insect declines. Common or abundant insect species are those species that are locally found in the highest numbers, but which species these are differ among locations. The study’s findings challenge the idea that changes in insect biodiversity result from rarer species disappearing.

The study follows the recent sounding of alarm bells about insect loss, as researchers note dramatic declines in the total number of insects in many parts of the world. However, little is known about the general trends among locally rare and abundant species over long periods. “It was obvious this needed exploring,” says Dr Roel van Klink, lead author of the study and senior scientist at iDiv and MLU. “We had to know whether observations about declines in total abundances of insects differed among common and rare species, and how this translated into changes in the overall insect diversity.”

More common species are losing out

Van Klink and colleagues set out to better understand trends in insect numbers by diving into past studies. They compiled a database on insect communities using data collected over periods between 9 and 64 years from 106 studies. For example, one Dutch study on ground beetles was started in 1959 and continues today. 

With this updated database, the researchers confirmed that despite variation among the data, on the whole, land-based insects from these long-term surveys are declining by 1.5% each year. To better understand this pattern, they compared the trends of species in different abundance categories and found that species that were the most abundant at the start of the time series showed the strongest average decline – around 8% annually – while rarer species declined less.

Importantly, the losses of previously dominant species were not compensated for by rises in other species, which has far-reaching implications: Abundant species are a staple food for birds and other insect-eating animals, making them essential for ecosystems. “Food webs must already be rewiring substantially in response to the decline of the most common species”, explains van Klink. “These species are super important for all kinds of other organisms and for the overall functioning of the ecosystem”.

Winners and Losers

The analysis clearly shows that the formerly abundant species are consistently losing the most individuals compared to the less abundant insect species. However, less abundant and rare species are also taking losses, driving declines in local species numbers. The study found a modest decrease in the overall number of species of just under 0.3% annually. This decline indicates that in addition to significant losses of common species, some rare species are going locally extinct.

Coming out on top are new arrivals who managed to successfully establish themselves. Most of these new arrivals stay locally rare and replace other formerly rare insects, but occasionally they become very abundant. The invasive Asian Ladybeetle (Harmonia axyridis), which is now common throughout Europe, the Americas and South Africa, is one such example.

According to the paper’s authors, further research is necessary to determine the underlying causes of these trends. Although this study did not explicitly investigate possible causes, the declines are likely linked to recent human-related impacts, such as climate change and urbanisation, which are considered major drivers of biodiversity loss. “Insects seem to be taking a heavier hit than many other species as humans continue to dominate the planet,” explains Prof Jonathan Chase, senior author of the study and research group head at iDiv and MLU. “Other studies, including those our team has worked on, have not found such diversity declines at local scales from many other groups of animals and plants”.

While the study’s results are striking, these trends are strongly biased to data on insect communities in Europe and North America. As such, they should not be interpreted as a global phenomenon. Chase adds: “The patterns we observed might be a best-case scenario for quantifying the real impact of people on insects,” referring to what scientists have called the lifeboat effect. “These declines were observed in long-term data from areas that have remained largely intact, sort of like a lifeboat, rather than in areas where massive conversion of natural areas into human-dominated landscapes has occurred, such as malls and parking lots”. 

 

Original publication:
(Researchers with iDiv affiliation and alumni bold)

Roel van Klink, Diana E. Bowler, Konstantin B. Gongalsky, Minghua Shen, Scott R. Swengel, Jonathan M. Chase (2023). Disproportionate declines of formerly abundant species underlie insect loss. Nature, DOI: https://doi.org/10.1038/s41586-023-06861-4

 

Contact:

Dr Roel van Klink
(speaks English, German and Dutch)
Senior Scientist in the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 1520 3117216
Email: roel.klink@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/788.html

 

Prof Dr Jonathan Chase
Head of the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733120

Email: jonathan.chase@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/synthesis.html

 

Christine Coester
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9733197
Email: christine.coester@idiv.de

 

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Biodiversity and People Media Release Biodiversity Synthesis TOP NEWS Fri, 15 Dec 2023 00:00:00 +0100
How forests smell - a risk for the climate? https://idiv-biodiversity.de//en/news/news_single_view/5227.html New study on the link between biodiversity and climate New study on the link between biodiversity and climate

Based on a media release of Leipzig University

Plants emit odours for a variety of reasons, such as to communicate with each other, to deter herbivores or to respond to changing environmental conditions. An interdisciplinary team of researchers from Leipzig University, the Leibniz Institute for Tropospheric Research (TROPOS) and the German Centre for Integrative Biodiversity Research (iDiv) carried out a study to investigate how biodiversity influences the emission of these substances. For the first time, they were able to show that species-rich forests emit less of these gases into the atmosphere than monocultures. In the past, it was assumed that forests with more species would release more emissions. Experiments by the Leipzig team have now disproved this assumption. Their study has been published in the journal Communications Earth & Environment.

Plant odours penetrate the atmosphere

Plants produce a variety of organic compounds to communicate with each other and with their environment. These are known as biogenic volatile organic compounds (BVOCs), such as terpenes, which give plants their characteristic scent and help to repel pests. As well as acting as chemical signals, these substances play a role in regulating climate, air quality and atmospheric chemistry. This is because these BVOCs emitted by plants form biogenic secondary organic aerosols (BSOAs) in the air, i.e. particles in the atmosphere. These aerosols in turn affect air quality, cloud formation and the climate.

MyDiv Experiment: Measurements in plots with different tree species

But how do emissions and concentrations of aerosols in the air change as biodiversity declines or plants are stressed by drought? The interdisciplinary team led by scientists Dr Anvar Sanaei and Professor Alexandra Weigelt from Leipzig University and other researchers from TROPOS and iDiv investigated this question. The scientists collected the data at the MyDiv tree diversity experimental site. The iDiv platform, near Bad Lauchstädt in Saxony-Anhalt, covers around two hectares and has 80 plots with ten tree species growing together in monocultures or mixtures of different species. For the study, the team spent almost two weeks collecting air samples from ten of the 11x11 metre plots, which grow four tree species – rowan, wild cherry, common ash and sycamore – in different combinations.

Fewer plant odours, fewer risks 

“In the field, we measured BVOCs and BSOA compounds in ten plots of varying tree diversity. Our results show that the amount of BVOCs decreases with increasing biodiversity in most cases,” says Dr Anvar Sanaei, first author of the study and postdoctoral researcher at the Institute of Biology at Leipzig University. It is estimated that global BVOC emissions from vegetation will increase by around a third as a result of climate change. “There are considerable uncertainties here: these precursor gases can form particles, which in turn can become cloud droplets. Whether BVOCs ultimately cool or warm the atmosphere depends on many factors and is difficult to predict. However, more biodiversity and fewer BVOCs would reduce the changes in the atmosphere and thus also the risks of climate change – including changes in precipitation,” adds Professor Hartmut Herrmann from TROPOS. The second part of the study shows how difficult it is to investigate these complex processes in the field: the team was unable to establish any clear correlations for BSOAs, which could be partly due to environmental influences, as the conversion of BVOC gases into BSOA particles takes a certain amount of time. At just under two weeks, the measurement campaign was also comparatively short. That is why the team wants to continue the research – not least because many questions remain unanswered.

More stress, more plant odours?

Previously, it was thought that species-rich forests and grasslands released more gases into the atmosphere than species-poor ones. The reason for this was thought to be that species-rich systems produce more biomass because they can utilise resources such as light, water and nutrients more efficiently. More biomass then also means more leaf surface area from which the gases can be emitted. “Our new results, however, suggest that the situation may be due to the fact that plants in species-rich forests and grasslands are under less stress. Compared to monocultures, they face fewer herbivores and less heat and drought. But this is just a hypothesis for now. Much more research is needed to better understand how biodiversity affects the atmosphere, where we need to look more closely at the microclimate, above- and below-ground stress on plants, and many other factors in long-term experiments,” says Professor Nico Eisenhauer from iDiv.

Biology + climate research + chemistry = A team fit for the future

What made this study so special was that different disciplines worked together, combining atmospheric and biological measurements. “Only with knowledge from biology, climate research and atmospheric chemistry can we decipher how plant emissions are linked to biodiversity and the atmosphere. Our study highlights the need for experiments at the local and regional scales and the development of models to improve our understanding of biosphere-atmosphere interactions,” says senior author and iDiv member Professor Alexandra Weigelt from the Institute of Biology. 

Katarina Werneburg and Tilo Arnhold

 

Original publication
(Researchers with iDiv affiliation are in bold)

Anvar Sanaei, Hartmut Herrmann, Loreen Alshaabi, Jan Beck, Olga Ferlian, Khanneh Wadinga Fomba, Sylvia Haferkorn, Manuela van Pinxteren, Johannes Quaas, Julius Quosh, René Rabe, Christian Wirth, Nico Eisenhauer & Alexandra Weigelt (2023). Changes in biodiversity impact atmospheric chemistry and climate through plant volatiles and particles. Commun Earth Environ, DOI: 10.1038/s43247-023-01113-9 

 

The study was funded by the Saxon State Ministry of Science, Culture and Tourism (SMWK; 3-7304/35/6-2021/48880), the European Union (ACTRIS-IMP (871115), ATMO-ACCESS (101008004) and ACTRIS-D (01LK2001A)), the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation funding programme (Grant Agreement No. 677232) and the German Research Foundation (DFG; via Gottfried Wilhelm Leibniz Prize (Ei 862/29-1) and the German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig (FZT 118, 202548816)).

 

Contact:

Prof Dr Alexandra Weigelt
Systematic Botany and Functional Biodiversity
University of Leipzig
German Centre for Integrative Biodiversity Research (iDiv)
Halle-Jena-Leipzig
Phone: +49-341-97-38594
Email: alexandra.weigelt@uni-leipzig.de

 

Prof Dr Nico Eisenhauer
Head of the research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 97 33167
Email: nico.eisenhauer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/eisenhauer_nico.html

 

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Experimental Interaction Ecology Media Release TOP NEWS iDiv Members Wed, 13 Dec 2023 00:00:00 +0100
Recommendations for a research agenda on biodiversity and pandemics https://idiv-biodiversity.de//en/news/news_single_view/5225.html Report of an Expert Working Group outlines policy recommendations to develop broader transformative... Report of an Expert Working Group outlines policy recommendations to develop broader transformative policies for human, animal, and ecosystem health

Leipzig. An Expert Working Group with involvement of the German Centre for Integrative Biodiversity Research (iDiv) has published science-policy recommendations for future research to support transformative pandemic-prevention and preparedness policies. The report was published by Eklipse, a spinoff of a UFZ-led EU project.

The final knowledge synthesis report from the Eklipse Expert Working Group working on biodiversity and pandemics has now been released. This report outlines science policy recommendations regarding biodiversity and pandemics that need to be implemented in order to develop broader transformative policies for human, animal, and ecosystem health. A particular focus lies on policies to support and promote research needed to prevent and manage spillover events in which pathogens originating in wildlife cause disease outbreaks or even pandemics in humans or large-scale disease events in domesticated animals (panzootics).

“This report emphasizes the urgent need for an integrated approach in science policy to address the interplay between biodiversity and human health. I am delighted to have contributed to identifying crucial gaps in our understanding of the interactions between pandemics and biodiversity”, says Dr Miguel Fernandez, researcher at iDiv and Martin Luther University Halle-Wittenberg. “As a key message, our report advocates for interdisciplinary research strategies to address pandemics and broader environmental crises, highlighting the crucial role of science in achieving a more sustainable future.”

The report, which was requested by the European Commission services, was prepared by an Eklipse Expert Working Group active from 2022 to 2023. The group undertook a scoping review of scientific literature and collected input from a large body of external experts through an online survey and focus group discussions. Using these results, the group formulated recommendations for shaping a strategic research agenda on biodiversity and pandemics.

 

Original publication
(Researchers with iDiv affiliation are in bold)

Soushieta Jagadesh, Alexandre Caron, Claire Lajaunie, Hatice Mahur Turan, Nils Bunnefeld, Andrew Cunningham, Miguel Fernandez, Alister Scott, Norbert Tchouaffe Tchiadje, Adam Izdebski, Julie Teresa Shapiro (2023). Biodiversity and pandemics: Interdisciplinary research and action priorities. Eklipse Evidence Report 02/2023

 

Link to report

View PDF

 

Contact:

Dr Miguel Alejandro Fernandez Trigoso (speaks Englisch and Spanish)
Lead Scientific Officer
Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Phone: +49 341 9733192
Email: miguel.fernandez@idiv.de

 

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TOP NEWS iDiv Media Release Thu, 07 Dec 2023 00:00:00 +0100
Deciphering nature's climate shield: Plant diversity stabilises soil temperature https://idiv-biodiversity.de//en/news/news_single_view/5223.html Study reveals natural solution to mitigate effects of climate change Study reveals natural solution to mitigate effects of climate change

Based on a media release of Leipzig University

A new study has revealed a natural solution to mitigate the effects of climate change, such as extreme weather events. Researchers from Leipzig University, the Friedrich Schiller University Jena, the German Centre for Integrative Biodiversity Research Halle-Jena-Leipzig (iDiv) and other research institutions have discovered that high plant diversity acts as a buffer against fluctuations in soil temperature. This buffer can then be of vital importance to ecosystem processes. They have just published their new findings in the journal Nature Geoscience.

“Soil temperature plays a central role in controlling important ecosystem processes related to water, carbon and nutrient dynamics, microbial activity and agricultural productivity,” explains the lead author of the study, Dr Yuanyuan Huang. Despite its importance, no study has yet investigated whether plant diversity in particular acts as a buffer against fluctuations in soil temperature during long-term plant community development.

In their study, Huang and her colleagues present the results of a comprehensive data set collected from 2004 to 2021 in a large-scale grassland biodiversity experiment – the Jena Experiment. The experimental site consists of 80 plots with a variety of plants ranging from one to 60 species. In addition, four plots of unplanted soil and two plots of uncontrolled vegetation provided important reference points. Soil temperature was automatically recorded at depths of five and 15 centimetres at one-minute intervals over a period of 18 years, which spanned considerable climate variability. Dr Anne Ebeling, scientific coordinator of the experiment, says: “We have just celebrated the 20th anniversary of the Jena Experiment. Over these two decades, we have experienced a number of extreme weather events, including prolonged droughts, a major flood in 2013 and exceptionally cold springs.” Gideon Stein, the second author of the study and responsible for the data preparation, adds: “It is really interesting to see how many historical events can be found in the temperature data of the Jena Experiment.”

“This unprecedented analysis of long-term, high-resolution data provides compelling evidence that plant diversity acts as a natural buffer and provides stability in the face of climate extremes,” emphasises Huang. Throughout the 18-year period, plant diversity showed a remarkable ability to protect the soil from overheating in scorching heat and to help retain heat in colder periods.

In summer, on days with particularly high air temperatures, the soil temperature in plant communities with 60 species was 5.04 degrees Celsius lower than in plots with no plants. For comparison, this difference is more than double the difference between monocultures and bare soil at the same time. However, on days with particularly low air temperatures, the soil temperature in the 60-species plant community was 1.48 degrees Celsius warmer than in the plots with no plants, which in this case is almost five times the difference between monocultures and the bare soil.

The researchers concluded that plant diversity can stabilise soil temperature throughout the year. The effects intensified as the experimental communities became older, and are even more pronounced under the harshest climate conditions, such as scorching hot days and dry years.

In a second step, Huang and her colleagues set out to investigate the causes of the stabilising effect of plant diversity. Plant diversity not only increased the total leaf area of the plants, leading to greater shading, but also increased the organic carbon content of the soil. The stabilising effect of plant diversity was demonstrated by a reduction in heat conduction in the top 60 centimetres of soil. As a result, soil temperature remained more stable throughout the year and throughout the topsoil in communities with higher plant diversity.

These findings have far-reaching implications. In temperate grasslands and beyond, the stabilisation of soil temperature provided by plant diversity could be crucial in mitigating the negative effects of extreme climate events. This includes the decomposition of carbon in the soil and its release into the atmosphere. According to the researchers, this natural mechanism thus also has the potential to slow down the process of global warming.

“Our research shows the remarkable ability of plant diversity to act as a protective shield against the impacts of climate change. It is a stark reminder of the importance of conserving and promoting biodiversity in our ecosystems to protect the environment and ensure a sustainable future,” says Professor Nico Eisenhauer, head of the study and spokesperson for the Jena experiment. He adds that the study not only adds to our understanding of the vital role of biodiversity, but also offers a glimmer of hope in the ongoing fight against climate change.

Susann Sika

 

Original publication
(Researchers with iDiv affiliation in bold)

Yuanyuan Huang, Gideon Stein, Olaf Kolle, Karl Kübler, Ernst-Detlef Schulze, Hui Dong, David Eichenberg, Gerd Gleixner, Anke Hildebrandt, Markus Lange, Christiane Roscher, Holger Schielzeth, Bernhard Schmid, Alexandra Weigelt, Wolfgang W. Weisser, Maha Shadaydeh, Joachim Denzler, Anne Ebeling, Nico Eisenhauer (2023). Enhanced stability of grassland soil temperature by plant diversity, Nature Geoscience, doi: 10.1038/s41561-023-01338-5

 

Contact:

Dr Yuanyuan Huang
Experimental Interation Ecology
German Centre for Integrative Biodiversity Research (iDiv)
Leipzig University
Phone: +49 341 9739159
Email: yuanyuan.huang@idiv.de

 

Prof Dr Nico Eisenhauer
Head of the research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 97 33167
Email: nico.eisenhauer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/eisenhauer_nico.html

 

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iDiv Media Release Experimental Interaction Ecology Research TOP NEWS Wed, 06 Dec 2023 00:00:00 +0100
Ecology: “iDiv Universities” climb to the top of the international Shanghai Ranking 2023 https://idiv-biodiversity.de//en/news/news_single_view/5221.html Halle, Jena and Leipzig are three of the top six German universities in the field of ecology

Halle, Jena, Leipzig. The three universities that comprise the German Centre for Integrative Biodiversity Research’s (iDiv) consortium rose to the top of this year’s international Shanghai Ranking in the field of ecology. Of the 5,000 universities evaluated, the universities of Halle, Jena, and Leipzig placed 27th, 51st*, and 35th, respectively. This recognition means Central Germany is home to three of the country’s six highest-ranked universities in the field.

The Global Ranking of Academic Subjects (GRAS) evaluates field-specific indicators in five categories: research performance, research influence, international cooperation, research quality, and international academic awards.

Led by the ShanghaiRanking Consultancy, the GRAS was first published in 2017. At that time, the three universities that make up the iDiv consortium were ranked between 151 to 200 in the field of ecology. In the new 2023 ranking, the Central German universities jumped to the top of the list based on evaluations made between 2018 and 2022.

These strides are also seen when looking at the number of peer-reviewed publications that came out of iDiv over the same time span. Founded in 2012, iDiv helps link the biodiversity research taking place in Central Germany. From 2013 to 2017, iDiv researchers published 1,301 publications, and from 2018 to 2022, iDiv researchers produced 2,266 publications – a 74% increase in scientific output.

“When iDiv was founded eleven years ago, our three universities laid the foundations for a wonderful success story,” says iDiv speaker Prof Henrique Pereira, research group head at iDiv and Martin Luther University Halle-Wittenberg. "iDiv was the necessary catalyst that helped us win international recognition for German research in the field of ecology. Today we are playing in the ecological Champions League, alongside universities such as Stanford, Oxford, and Zurich.”

According to Pereira, the Shanghai Ranking’s findings validate the work and effort put forward in recent years: “Investing in research pays off. We have to continue advancing this great trend in the international recognition of our universities.”
Volker Hahn

* together with 24 other universities (places 51-75)

 

International GRAS ranking in the field of ecology:
https://www.shanghairanking.com/rankings/gras/2023/RS0106

Methodology:
https://www.shanghairanking.com/methodology/gras/2023

 

Contact:

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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iDiv TOP NEWS Media Release Mon, 04 Dec 2023 00:00:00 +0100
Highly Cited Researchers 2023 https://idiv-biodiversity.de//en/news/news_single_view/5214.html Eight iDiv members named Highly Cited Researchers

Clarivate Analytics lists eight iDiv members in its 2023 selection of “Highly Cited Researchers”. According to Clarivate Analytics, these scientists have demonstrated significant influence through the publication of multiple papers, highly cited by their peers, during the last decade.

The following iDiv researchers can be found on the list (in alphabetical order):

• Prof Bruno Glaser (Martin Luther University Halle-Wittenberg, iDiv)

• Dr Jens Kattge (Max Planck Institute for Biogeochemistry, iDiv)

• Dr Martin Mascher (Leibniz Institute of Plant Genetics and Crop Plant Research, iDiv)

• Prof Henrique Pereira (iDiv, Martin Luther University Halle-Wittenberg)

• Prof Markus Reichstein (Max Planck Institute for Biogeochemistry, iDiv)

• Prof Josef Settele (Helmholtz Centre for Environmental Research – UFZ, iDiv, Martin Luther University Halle-Wittenberg)

• Dr Marten Winter (iDiv, Leipzig University)

• Prof Sönke Zaehle (Max Planck Institute for Biogeochemistry, iDiv)

 

In total, approximately 6,900 researchers have been selected.

See full list: https://clarivate.com/highly-cited-researchers/

 

Contact:

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TOP NEWS Wed, 15 Nov 2023 00:00:00 +0100
DFG gives green light for new Research Training Group https://idiv-biodiversity.de//en/news/news_single_view/5209.html Doctoral researchers will investigate sustainable concepts for the use of natural common goods Doctoral researchers will investigate sustainable concepts for the use of natural common goods

Based on a media release of Leipzig University

Another great success for Leipzig in supporting early career researchers: the German Research Foundation (DFG) announced that it will provide around 7 million euros in funding for a new Research Training Group from April 2024. Under the leadership of Professor Martin Quaas, head of Biodiversity Economics at the German Centre for Integrative Biodiversity Research (iDiv) and  Leipzig University, more than 40 doctoral researchers in the fields of economics and management science, the natural and life sciences will investigate sustainable concepts for the use of natural common goods.

Air pollution, species loss, overfishing – the list of challenges to sustainable development is long. In most cases, it is people who have overexploited natural resources for economic gain: they have overfished the oceans, crowded out insects through unbalanced agricultural practices and polluted the air with industrial emissions. Some of these undesirable developments have already been partially reversed, but in some cases new problems have arisen. The new Research Training Group, Economics of Connected Natural Commons (ECO-N), will explore these complex interactions between economic demands, human behaviour and natural resources.

From 1 April 2024 until 2029, 42 doctoral researchers will develop an integrative perspective on the sustainable use of natural commons in the areas of atmosphere and biodiversity. In interdisciplinary collaborative projects, they will develop a shared, overarching understanding of the interaction between economic activity and natural dynamics. “On this basis, and by synthesising many forms of management of natural commons, we aim to propose instruments and mechanisms for the sustainable use of natural commons,” says Professor Martin Quaas, spokesperson of the Research Training Group (RTG). “This new RTG is also an important milestone for us on the way to a potential Cluster of Excellence, called Breathing Nature, for which we submitted a draft proposal at the end of May as part of the Excellence Strategy of the German federal and state governments,” adds Professor Johannes Quaas, a meteorologist at Leipzig University and designated spokesperson for the proposed Cluster of Excellence.

ECO-N is a response to the growing demand in research, government and practice for academically qualified specialists who are capable of analysing difficult sustainability problems across sectors and disciplines. The new Research Training Group combines the expertise of the Faculty of Economics and Management Science, the Faculty of Physics and Earth System Sciences and the Faculty of Life Sciences at Leipzig University. Also involved are iDiv and the non-university research institutions Helmholtz Centre for Environmental Research (UFZ), Leibniz Institute for Tropospheric Research (TROPOS) and the German Biomass Research Centre (DBFZ).

Dr. Katarina Werneburg

 

Contact:

Prof Dr Martin Quaas
Head of research group Biodiversity Economics
German Centre for Integrative Biodiversity Research (iDiv)
Leipzig University
Phone: Please contact the iDiv Media and Communications department
Email: martin.quaas@idiv.de

 

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iDiv Biodiversity Economics Media Release TOP NEWS Mon, 13 Nov 2023 00:00:00 +0100
When writers write about biodiversity https://idiv-biodiversity.de//en/news/news_single_view/5211.html How authors’ personal circumstances influence the depiction of nature in their works How authors’ personal circumstances influence the depiction of nature in their works

Based on a media release of Leipzig University

Novels and poems often contain descriptions of plants or animals – sometimes more, sometimes less detailed. The extent to which flora and fauna feature in a literary work also depends on who wrote it and under what circumstances. For example, female authors tend to use more species names when they write. This is the conclusion of a research team from Leipzig University, the German Centre for Integrative Biodiversity Research (iDiv) and Goethe University Frankfurt, who examined around 13,500 literary works by approximately 2,900 authors. The study published in People and Nature is an example of how methods from the natural sciences and the humanities can be combined using digital techniques.

In a study around two years ago, the research team already demonstrated that biodiversity in western literature has been steadily declining since the 1830s. The researchers have now published a follow-up study. They explain how factors such as the author’s gender, place of residence or age influence the importance given to nature in their works. According to their findings, it makes a difference whether a literary work was written, for example, by a young woman from a US village or by a middle-aged man from a European city.

The study involved researchers from the digital humanities, biology and literary studies. The researchers again used the Project Gutenberg library for their analysis. They linked the works contained therein – mostly western literature from Europe and North America – to biographical information about the authors, which they gathered from online sources such as Wikidata, LibraryThing.de and WorldCat.org, and then manually categorised. In the end, 13,493 works from 1705 to 1969 by 2847 authors were analysed using machine learning methods.

In the 2021 study, the researchers already developed metrics that make it possible to measure biodiversity in literary works. For example, they counted the number of terms used to describe animals or plants in each work, or calculated the variety of vocabulary used to describe living things. Now they have used an algorithm to relate those values to the biographical information about the authors. 

They found that, on average, works written by women contained more biodiversity than those written by men across all the periods analysed. 
Where the authors came from and where they lived also played a role: the researchers found more occurrences of nature in the works of North American authors than in European works. In addition, writers from smaller towns tended to describe more biodiversity in their work than those living in larger cities. 
In terms of age, the picture was mixed: on average, young authors under 25 and older authors over 70 wrote about plants and animals more often than middle-aged authors. According to the analysis, however, whether the writer had children had no influence on the occurrences of biodiversity in their works. 
In addition to these five core variables, the researchers included many other aspects in the analysis, such as the authors’ level of education, the literary genre and the intention of the works.

“The results are statistically highly significant,” says Lars Langer, a doctoral researcher at the Institute of Computer Science at Leipzig University and lead author of the study. “However, it is important to stress that these are statistical statements, which means that in individual cases the situation can be completely different or even the opposite.” 

The study does not provide any direct answers to the question of why the authors’ personal circumstances affect the occurrences of biodiversity in their works. But Langer makes an assumption: “Almost all the correlations we can find can be traced back indirectly to the corresponding education and socialisation. High standards of general education promote an appreciation of nature.” The findings therefore also have implications when it comes to educating specific target groups within society and raising their awareness of biodiversity issues. 

Almost as a by-product of the study, a new resource was created for future use by the scientific community. According to the research team, the text corpus, enriched with biographical information, is a valuable new source for further research projects at the intersection of literary studies and the digital humanities.

Nina Vogt

 

Original publication
Lars Langer, Manuel Burghardt, Roland Borgards, Ronny Richter, Christian Wirth (2023). The relation between biodiversity in literature and social and spatial situation of authors: Reflections on the nature–culture entanglement", People and Nature, DOI: doi.org/10.1002/pan3.10551 

 

Contact:

Lars Langer
Computational Humanities
Leipzig University
Email: lars.langer@uni-leipzig.de

 

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iDiv TOP NEWS Media Release Mon, 13 Nov 2023 00:00:00 +0100
Tailoring Biodiversity Information to Local Needs in the Threatened Tropical Andes https://idiv-biodiversity.de//en/news/news_single_view/5192.html A new approach to co-designing biodiversity indicators A new approach to co-designing biodiversity indicators relevant for conservation

Lima, Halle, Leipzig. Sustainable biodiversity conservation requires cooperation among scientific, societal, economic, and political institutions. In the journal Conservation Science and Practice, researchers have published a new approach to co-designing biodiversity indicators relevant for conservation. They brought together multiple stakeholders in a consultative process, tailoring user-relevant biodiversity information to local needs. The project was led by researchers of the German Centre for Integrative Biodiversity Research (iDiv) and the Martin Luther University Halle-Wittenberg, together with multiple partners in the Tropical Andes. The collaborative approach can serve as a blueprint for making biodiversity information more inclusive, considering the diverse worldviews, values, and knowledge systems between science, policy, and practice.

The study demonstrates the power of engaging local stakeholders in biodiversity decision-making. Over 400 people participated in localised surveys and workshops across Bolivia, Peru and Ecuador. They included local communities, businesses, and civil society organisations in each country.

"This process amplified underrepresented voices frequently excluded from policymaking," said Gabriela Orihuela, President of the Association in support of the National Botanical Garden of Lima. "It enabled the development of scalable conservation solutions aligned to local needs and priorities."

The researchers used tailored storylines and ecological narratives during the surveys and workshops to effectively communicate biodiversity challenges and potential solutions among the participants. 

Based on participant feedback, the team then co-designed biodiversity insights that meet user needs. The team collaborated with stakeholders to transform raw biodiversity data into actionable insights and user-friendly products, tailored for policymakers, communities, and key audiences to use in conservation efforts and decision-making in the region.

“Stakeholders expressed the need for biodiversity information in clear formats and languages,” said Natividad Quillahuaman of the Asociación para la Conservación de la Cuenca Amazónica (ACCA) “This process transformed raw biodiversity data into actionable information to support urgent biodiversity needs across sectors.”

The study led to new collaborations among six institutions across Latin America and Europe, pioneering an inclusive biodiversity research model. It also produced scientific publications and news coverage in multiple languages, while building local capacity through training programs to ensure sustained impact. Significantly, most authors were locally based, representing the communities in the regions, underscoring the commitment to amplifying regional voices.

"By engaging local voices tailoring solutions that address local needs and priorities, we created a blueprint for effective biodiversity policies in this globally vital region," stated lead author Dr. Jose Valdez, researcher at the German Centre for Integrative Biodiversity Research (iDiv) and the Martin Luther University Halle-Wittenberg. "This inclusive approach can serve as a model for balancing conservation, development and sustainability not just in the Tropical Andes but other regions as well.”

As biodiversity threats mount globally, this study's inclusive approach demonstrates the power of participatory processes to amplify local voices and strike a critical balance between urgent conservation needs and community priorities in globally vital ecosystems.

 

Original publication:
(Researchers with iDiv affiliation and alumni bold)

Valdez, J.W., Pereira, H.M., Morejón, G.F., Acosta-Muñoz, C., Bonet Garcia, F.J., Castro Vergara, L., Claros R. X., Gill, M.J., Josse, C., Lafuente-Cartagena, I., Langstroth, R., Novoa Sheppard, S., Orihuela, G., Prieto-Albuja, F.J., Quillahuaman, N., Terán, M.F., Zambrana-Torrelio, C.M., Navarro, L.M., Fernandez, M. (2023). Tailoring evidence into action: using a codesign approach for biodiversity information in the Tropical Andes. Conservation Science and Practice, DOI: 10.1111/csp2.13035

 

Contact:

Dr Jose W. Valdez (speaks English and Spanish)
Postdoctoral Researcher
Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9739168
Email: jose.valdez@idiv.de
Web: https://www.idiv.de/en/profile/1290.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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TOP NEWS Biodiversity Conservation Fri, 03 Nov 2023 00:00:00 +0100
Even low levels of artificial light disrupt ecosystems https://idiv-biodiversity.de//en/news/news_single_view/5202.html Surprisingly far-reaching impacts of light pollution Light pollution at night is disturbing above- and belowground ecosystems with implications for ecosystem stability and human well-being

Leipzig, Jena. A new collection of papers on artificial light at night show the impact of light pollution to be surprisingly far-reaching, with even low levels of artificial light disrupting species communities and entire ecosystems. Published in Philosophical Transactions of the Royal Society B, the special theme issue, which includes 16 scientific papers, looks at the effects of light pollution in complex ecological systems, including soil, grassland, and insect communities. Led by researchers at the German Centre for Integrative Biodiversity Research (iDiv) and the Friedrich Schiller University Jena, the collection notes the increasing ubiquity of light pollution, while emphasising the domino effect light pollution has on ecosystem function and stability.

Night skies are becoming brighter as the use of artificial lighting spreads across the globe. With an estimated annual uptick of up to 10%, the prevalence of light pollution is disrupting the natural light cycles that have been largely consistent throughout the Earth’s history. These light cycles are vitally important to organisms who rely on light as a source of energy and information. To date, studies looking at the impact of light pollution have largely focused on human health and individual species’ responses, whereas investigating entire ecosystems, where species are linked through diverse interactions, has remained scarce. “Species do not exist in isolation but rather interact in numerous ways”, explains iDiv and the University of Jena’s Dr Myriam Hirt, who led the compilation and editing of the theme issue together with Dr Remo Ryser. “Our aim was to better understand how the brightening of the night sky affects entire ecosystems and the benefits they provide”.
 
Using the iDiv Ecotron, which consists of multiple controlled experimental-ecosystem chambers (so-called EcoUnits), several researchers simulated and altered light conditions at night. Key findings include the ability of artificial light to:

  • reach belowground soil communities, impacting soil basal respiration and carbon-use efficiency
  • influence invertebrate activity, which was linked to higher predation rates at night
  • reduce plant biomass and diversity, as well as change plant traits, such as leaf hairiness
  • potentially shift – homogenize – the periods when species are active, leading to increased overlap and ultimately threatening species persistence. 

The studies also showed that even low intensities of light pollution – illuminance lower than that of a full moon – have profound effects not only on the behavioural and physiological responses of individual species but at more complex levels, such as communities and ecological networks, like food webs. “Their individual responses to artificial lighting and their relationships with one another determine the outcome for the entire ecological system. For instance, an activity shift of diurnal and crepuscular species into the night increases extinction risks in the entire community”, says Dr Remo Ryser of iDiv and the University of Jena. 
 
Another study in the issue investigated how artificial light produces indirect cascading effects with implications for humans. For example, changes in the abundance and behaviour of mosquitoes – a vector species – in response to artificial light at night. The study shows that exposure leads to changes in the timing of key behaviors, such as host-seeking, mating, and flight activity, which might carry wide-scale consequences on the transmission of vector-borne diseases, like malaria. A further paper looked at how different lighting strategies may mitigate the negative effects of artificial light. However, the special issue points out that flipping the switch on light pollution requires a nuanced approach given that the impact of light pollution varies significantly among species. This suggests that mitigation strategies may not be universally applicable.

As darkness disappears due to the consistent rise in artificial lighting around the world, the collection of studies highlights the cost of this expansion to people’s health and ecosystems. By acknowledging the impact of this human-caused disturbance on species interactions and feedback loops, the special issue hopes to inspire future research and action that not only helps mitigate the harmful effects of light pollution, but fosters a sustainable coexistence between society’s needs and the natural environment. “The benefits of artificial light during the night are undeniable, but its adverse effects should not be ignored”, says Dr Myriam Hirt. 
Christine Coester

 

Original publication
(Researchers with iDiv affiliation bold)
 
Myriam R. Hirt, Darren M. Evans, Colleen R. Miller, Remo Ryser (2023). Light pollution in complex ecological systems. Philosophical Transactions of the Royal Society B, DOI: https://doi.org/10.1098/rstb/378/1892

 

Contact:

Dr Myriam Hirt
Theory in Biodiversity Science research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Friedrich Schiller University Jena
Phone: +49 341 9733206
Email: myriam.hirt@idiv.de
Web: https://www.idiv.de/en/profile/104.html

 

Dr Remo Ryser
Theory in Biodiversity Science research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Friedrich Schiller University Jena
Email: remo.ryser@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/561.html

 

Christine Coester
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: christine.coester@idiv.de

 

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Media Release TOP NEWS Experimental Interaction Ecology Theory in Biodiversity Science Mon, 30 Oct 2023 00:00:00 +0100
How social media can contribute to species conservation https://idiv-biodiversity.de//en/news/news_single_view/5199.html Data published on social media platforms can improve knowledge about species distribution and... Data published on social media platforms can improve knowledge about species distribution and inform conservation planning

Leipzig. Photos of plant and animal species that are posted on social media can help protect biodiversity, especially in tropical regions. This is the conclusion of a team of researchers led by the German Centre for Integrative Biodiversity Research (iDiv), the Helmholtz Centre for Environmental Research (UFZ), the Friedrich Schiller University Jena (FSU), and the University of Queensland (UQ). Recently published in BioScience, One Earth, and Conservation Biology, the three studies investigated the benefits of using Facebook data for conservation assessments in Bangladesh. The researchers point out that social media can support species monitoring and significantly contribute to conservation assessments in tropical countries.

The tropics are biodiversity hotspots but our knowledge about the populations of animal and plant species in these regions is spotty at best. While monitoring programmes and citizen science initiatives are well established in developed countries, they are still rare in developing countries. However, accurate documentation of biodiversity can help identify which species need special protection. With the increasing use of social media and the widespread availability of high-quality digital cameras, new opportunities are arising. Nature photographers worldwide are sharing their biodiversity observations on social media, which has huge potential. A research team has used the South Asian country of Bangladesh as an example to investigate what contribution Facebook data can make to biodiversity monitoring and, ultimately, to assessing potential protected areas.

In their study, the scientists scraped Facebook groups for nature photographs taken in Bangladesh. The information they were able to derive from the species and location information in the photos was entered into a common data pool with data from the Global Biodiversity Information Facility (GBIF). The GBIF is fed by established citizen science platforms, such as eBird and iNaturalist. This is already working well in the global North. For animal and plant species in developing and emerging countries; however, there is significantly less data. By integrating Facebook data, the research team was able to compile more than 44,000 records for nearly 1,000 animal species, 288 of which are considered endangered according to the IUCN. Over 25% of the data came from Facebook groups, and more than half of the data was for butterflies and birds. "If we only used the data from the GBIF, we would have missed out on data on the distribution of hundreds of endangered species", says Dr Shawan Chowdhury, researcher at iDiv, UFZ and Friedrich Schiller University Jena.

Facebook data shows priority conservation areas

Using this new database, the research team created a map of particularly suitable habitats for the different animal species and compared it with existing protected areas. Currently, only 4.6% of Bangladesh's land area is designated as protected areas, much of which is located in the southwest of the country. In particular, areas where already-threatened species are found are not adequately covered by the current protected areas - a typical phenomenon in tropical regions. To ensure that there are enough protected areas for all threatened species in Bangladesh, the proportion of the area under protection would have to be increased to 39% and these areas would need to be better distributed in the country. The data also showed that, for example, 45% of the butterfly species in Bangladesh were found in green areas in the capital Dhaka, almost half of which are considered endangered. This finding suggests that when planning new protected areas, it might be worth looking at unconventional areas, such as in and around urban areas.

Social media data should be handled with care

Despite these results, the use of social media data still poses challenges. As with many citizen science initiatives, the data collected from users is rarely evenly distributed. Instead, they are often concentrated in easily accessible regions, such as in close proximity to cities. Making social media data usable for research is also currently very time-consuming. For their study, the researchers manually searched the Facebook groups for the species on the Red List and verified each individual photo, including species and location information. New technologies, such as artificial intelligence and deep learning, could make this process easier in the future. 

“The integration of biodiversity data from citizen science and published on social media holds great potential, especially for tropical regions where there is a lack of reliable and up-to-date structured monitoring data to inform conservation planning”, says Professor Aletta Bonn, head of research group Ecosystem Services at UFZ, the University of Jena and iDiv. In these regions, observation data published on Facebook or other social media platforms can contribute to a better and systematic assessment of potential protected areas – an important step towards achieving the Kunming-Montreal goals and placing 30 per cent of land and marine areas under protection by 2030.

Kati Kietzmann

 

Original publications
(Researchers with iDiv affiliation and alumni in bold)

Shawan Chowdhury, Upama Aich, Md Rokonuzzaman, Shafiul Alam, Priyanka Das, Asma Siddika, Sultan Ahmed, Mahzabin M. Labi, Moreno Di Marco, Richard A. Fuller, Corey T. Callaghan (2023). Increasing biodiversity knowledge through social media: a case study from tropical Bangladesh. BioScience; DOI: 10.1093/biosci/biad042

Shawan Chowdhury, Richard A. Fuller, Md. Rokonuzzaman, Shofiul Alam, Priyanka Das, Asma Siddika, Sultan Ahmed, Mahzabin Muzahid Labi, Sayam U. Chowdhury, Sharif A. Mukul, Monika Böhm, Jeffrey O. Hanson (2023). Insights from citizen science reveal priority areas for conserving biodiversity in Bangladesh. One Earth; DOI: 10.1016/j.oneear.2023.08.025

Shawan Chowdhury, Richard A. Fuller, Sultan Ahmed, Shofiul Alam, Corey T. Callaghan, Priyanka Das, Ricardo A. Correia, Moreno Di Marco, Enrico Di Minin, Ivan Jarić, Mahzabin Muzahid Labi, Richard J. Ladle, Md. Rokonuzzaman, Uri Roll, Valerio Sbragaglia, Asma Siddika, Aletta Bonn (2023). Using social media records to inform conservation planning. Conservation Biology, DOI: 10.1111/cobi.14161

 

Contact:

Dr Shawan Chowdhury
German Center for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Friedrich Schiller University Jena
Helmholtz Center for Environmental Research (UFZ)
Email: shawan.chowdhury@idiv.de

 

Prof Dr Aletta Bonn
Head of Department Ecosystem Services
Helmholtz Centre for Environmental Research (UFZ)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Friedrich Schiller University Jena
Phone: +49 341 9733153
Email: aletta.bonn@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/137.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Research Media Release Biodiversity and People iDiv TOP NEWS Fri, 27 Oct 2023 00:00:00 +0200
Funding new research in the Jena Experiment – focus on ecosystem stability https://idiv-biodiversity.de//en/news/news_single_view/5191.html DFG to fund Research Unit Deutsche Forschungsgemeinschaft (DFG) to fund Research Unit for another four years

Joint media release from iDiv, Leipzig University and Friedrich Schiller University Jena

Jena/Leipzig. The Deutsche Forschungsgemeinschaft (DFG) is to fund a Research Unit in the Jena Experiment for a further four years with around five million euros. The scientists, led by the German Centre for Integrative Biodiversity Research (iDiv), Leipzig University and the Friedrich Schiller University Jena, will focus in particular on the stabilising effect of biodiversity against extreme climate events such as drought, heat and frost.

Biodiversity affects how ecosystems function and the services they provide to us. Over the past 20 years, these relationships have been studied in Europe’s largest outdoor biodiversity laboratory, the Jena Experiment.

The ten hectares of former farmland on the banks of the river Saale are now home to some 150 experimental plots with different combinations of grassland plants: plots with only one species, with two, four, eight, sixteen or sixty species. This unique, long-term experiment is shedding light on the relationships between biodiversity and ecosystem functioning.

In 2019, the DFG decided to fund a new Research Unit in the Jena Experiment (FOR 5000). After four successful years, this funding is now being extended for a further four years, with a total budget of around 5 million euros. The new focus is on the stabilising effect of biodiversity against extreme climate events such as heat, frost or heavy rainfall. A central hypothesis is that species-rich grasslands are more stable than those with fewer species. In this context, stable means that the properties and functions of an ecosystem (e.g. plant biomass, soil temperature or nutrient levels) change little over time.

In some cases, biodiversity has already been shown to have a stabilising effect. For example, a large meta-study involving the Jena Experiment showed that the growth of species-rich grasslands is less affected by particularly wet or dry weather than that of species-poor grasslands. The researchers will now investigate this stabilising effect for other important ecosystem functions and aim to gain a better understanding of the underlying mechanisms.

The new phase of the Research Unit is working on a total of twelve sub-projects involving twelve German research institutions. In addition to iDiv and the Universities of Leipzig and Jena, these include the Helmholtz Centre for Environmental Research (UFZ) and the Max Planck Institute for Biogeochemistry in Jena. Moreover, there are international partners from Austria, the Netherlands, the US, China and France.

“Two important processes are taking place at the moment: both the climate and biodiversity are changing rapidly. This is why it is very important to investigate whether, and how, biodiversity can help to stabilise ecosystem functions,” says Professor Nico Eisenhauer, spokesperson for the DFG Research Unit and group head at iDiv and Leipzig University. “The Jena Experiment, with its long-term experiment in the Saale floodplain, offers ideal experimental conditions for this research question. We have been measuring ecosystem processes and environmental changes here for more than 20 years and can now study what makes ecosystems stable. Agriculture and nature conservation will also benefit from our findings.”
Volker Hahn, Kati Kietzmann

 

Contact:

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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TOP NEWS Media Release Experimental Interaction Ecology Tue, 10 Oct 2023 00:00:00 +0200
Mixed forests are more productive when they are structurally complex https://idiv-biodiversity.de//en/news/news_single_view/5193.html New study published in Science Advances

Dresden, Halle, Leipzig. Tree species richness increases forest productivity by enhancing aboveground structural complexity. This is the key result of a joint study by TUD Dresden University of Technology, the German Centre for Integrative Biodiversity Research (iDiv), Leuphana University Lüneburg, Martin Luther University Halle-Wittenberg, Leipzig University, and the University of Montpellier. The results have been published in the journal Science Advances.

Based on a media release by TUD

If many different tree species all grow together in a specific area, it has a positive effect on their growth and, as a result, on timber production - this has already been confirmed by a number of other studies. The greater the diversity of tree species in a forest, the more complex the structures. The species do not only grow to different heights in a given period and have very differently developed canopies, they also have individual demands for light, water and nutrients. So far, it has been unclear how structural complexity is related to productivity and which mechanisms are at work in an area of mixed tree species.

Near the town of Bad Lauchstädt in southern Saxony-Anhalt, the MyDiv tree diversity experiment was established in the spring of 2015: A total of 140 saplings were planted in 80 plots of 121 m2 each (11 m x 11 m). There are a total of ten native deciduous tree species in different combinations: as monocultures, or with a mixture of two or even four different tree species. Over the past two years, researchers investigated the importance of the structural complexity of the plots for productivity. In addition to the direct measurement of tree height and trunk diameter to calculate the wood volume of the trees, terrestrial laser scanning was used to calculate an index of the three-dimensional structural complexity for each plot. 

The results show that it is not species diversity alone that makes for better tree growth, but also the associated structural complexity. Structurally complex communities were almost twice as productive as their structurally simple counterparts. A mix of tree species that require a lot of light paired with shade-tolerant species proved to be particularly effective.

A unique feature of the MyDiv experiment is that the two main types of mycorrhiza — arbuscular mycorrhiza and ectomycorrhiza — are each represented by five tree species. Mycorrhiza is the term used to describe the symbiotic relationship between fungi and plants, in which the mycelium of the fungus is connected to a tree root, for example, and nutrients are exchanged for the benefit of both partners. This allowed the scientists to investigate not only the influence of above-ground structures, but also what happens below the soil. It turned out that a mix of trees with different types of mycorrhiza had no effect on tree growth.

The study provides valuable information for reforestation projects and shows that the right composition of tree species can ensure significantly faster tree growth. This is all the more important because trees are effective carbon stores, and reforestation is considered an important tool in the effort to combat climate change. 

 

Original publication
(Authors with iDiv affiliation and alumni bold)

Ray, T., Delory, B.M., Beugnon, R., Bruelheide, H., Cesarz, S., Eisenhauer, N., Ferlian, O., Quosh, J., von Oheimb, G., Fichtner, A. (2023). Tree diversity increases productivity through enhancing structural complexity across mycorrhizal types. Science Advances 9,eadi2362. DOI: 10.1126/sciadv.adi2362

 

Contact:

Dr Olga Ferlian
Postdoctoral researcher
Experimental Interaction Ecology research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Email: olga.ferlian@idiv.de
Web: https://www.idiv.de/en/profile/108.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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TOP NEWS Media Release iDiv Members Experimental Interaction Ecology Mon, 09 Oct 2023 00:00:00 +0200
Invertebrate decline reduces natural pest control and decomposition of organic matter https://idiv-biodiversity.de//en/news/news_single_view/5188.html Immediate protection measures are required to safeguard invertebrate communities and critical... Immediate protection measures are required to safeguard invertebrate communities and critical ecosystem services.

Leipzig. The decline in invertebrates also affects the functioning of ecosystems, including two critical ecosystem services: aboveground pest control and belowground decomposition of organic material, according to a new study published in Current Biology and led by researchers at the German Centre for Integrative Biodiversity Research (iDiv) and Leipzig University. The study provides evidence that loss of invertebrates leads to a reduction in important ecosystem services and to the decoupling of ecosystem processes, making immediate protection measures necessary.

Invertebrates, such as insects and also other arthropods, snails, slugs and nematodes, represent ~75% of all species described on Earth and are a fundamental part of ecosystems, providing many critical ecosystem functions and services, such as pollination, decomposition, and natural pest control. Human-caused environmental changes, in particular land-use change, landscape simplification, and urbanization, including habitat loss and chemical pollution, have been driving the global decline of invertebrates in recent decades. However, measuring the potential effect of this loss has so far proven difficult. “The manipulation of aboveground invertebrate communities has been a major challenge in ecological research, because of their functional diversity and mobility”, explains Nico Eisenhauer, lead author and professor for Experimental Interaction Ecology at iDiv and Leipzig University.

A team of researchers used the iDiv Ecotron, a joint research platform of iDiv and the Helmholtz Centre for Environmental Research (UFZ). It consists of several controlled mini-ecosystems (so-called EcoUnits), to study the effects of these complex communities. “Apart from offering a bridge between small-scale experiments under highly controlled conditions and less controllable large-scale field experiments or monitoring programs, the goal of the iDiv Ecotron was to enable experiments manipulating biodiversity changes at different levels of food webs in above- and belowground ecosystem compartments”, says iDiv Honorary Member Francois Buscot, professor emeritus at Leipzig University and former head of the UFZ department for Soil Ecology.

The researchers simulated and tested how various ecosystem services and plant diversity respond in 24 distinct grassland ecosystems across three levels of aboveground invertebrate biomass (100%, 36%, and 0%). A biomass level of 36% reflects the dramatic decline of invertebrates reported across German grasslands in the last decade. All plant and invertebrate species were collected from the same adjacent hay meadow, and the researchers simulated the natural turnover of aboveground invertebrate communities by exchanging invertebrate communities three times from May until November 2018. “I am particularly excited about this simulation of the phenology of invertebrate communities - something that has, to my knowledge, not been done before”, Nico Eisenhauer, head of the iDiv Ecotron, adds.

The researchers found that as the biomass of invertebrates decreases, so does the number of ecosystem services. For example, aboveground invertebrates play an important role in natural pest control. The researchers observed that declines in invertebrates went hand in hand with aphid outbreaks indicating that pest outbreaks may be a widespread consequence of biodiversity loss at higher trophic levels, with significant cascading effects on crop production and other ecosystem services.

Further, loss of aboveground invertebrates led to a significant reduction in belowground decomposition. “Aboveground and belowground processes are connected by invertebrates that consume plants and leaf litter. Loss of those connections will change nutrient cycling and how much carbon can be sequestered in ecosystems," explains Ecotron coordinator Dr Jes Hines from iDiv and Leipzig University. 

The amount of invertebrate biomass also affected the plants that were growing in the experimental grassland ecosystems. Aboveground plant biomass increased in the EcoUnits with reduced invertebrate biomass. This could be because invertebrates usually eat more of the plant aboveground. “This way, energy is channeled up from plants to higher trophic levels in intact invertebrate communities”, explains Jes Hines. The researchers also found that the concentration of carbon and nitrogen in plant tissue significantly decreased, which, in turn, may alter the quality of resources and nutrients fueling biological activity in soils.

“In a healthy ecosystem, biotic and biogeochemical properties are coupled. This study shows that a decrease in aboveground invertebrate biomass reduces this coupling, which might threaten species diversity, as well as animal, plant, and microbial nutrition”, says Nico Eisenhauer. Despite these alarming findings, ecosystems may recover following legislative changes that favor invertebrate diversity. For example, there is evidence of freshwater insect populations increasing following the Clean Water Act. Immediate protection measures stand to turn the tide on safeguarding diverse invertebrate communities and important ecosystem functions.

Kati Kietzmann

 

Original publication
(Researchers with iDiv affiliation and alumni in bold)

Nico Eisenhauer, Raúl Ochoa-Hueso, Yuanyuan Huang, Kathryn E. Barry, Alban Gebler, Carlos A. Guerra, Jes Hines, Malte Jochum, Karl Andraczek, Solveig Franziska Bucher, François Buscot, Marcel Ciobanu, Hongmei Chen, Robert Junker, Markus Lange, Anika Lehmann, Matthias Rillig, Christine Römermann, Josephine Ulrich, Alexandra Weigelt, Anja Schmidt, & Manfred Türke (2023). Ecosystem consequences of invertebrate decline. Current Biology, DOI: 10.1016/j.cub.2023.09.012

 

Contact:

Prof Dr Nico Eisenhauer
Head of the research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 97 33167
Email: nico.eisenhauer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/eisenhauer_nico.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Research iDiv Experimental Interaction Ecology Media Release TOP NEWS Tue, 26 Sep 2023 00:00:00 +0200
Big fish are shrinking and small fish are multiplying, a new study shows https://idiv-biodiversity.de//en/news/news_single_view/5184.html The body sizes of organisms around the world are becoming smaller over time, especially among fish,... The body sizes of organisms around the world are becoming smaller over time, especially among fish, with important implications for food webs and humans.

Based on a media release from the University of St. Andrews

St. Andrews/Leipzig. Organisms are becoming smaller through a combination of species replacement, and changes within species. Published in Science, the research looked at time series covering the past 60 years, from many types of animals and plants around the world. The study was conducted by an international team of scientists from 17 universities, as part of a working group funded by the German Centre for Integrative Biodiversity Research (iDiv), and led by scientists of the University of St Andrews, and the University of Nottingham.

Previous research showed that the size of trophy fish in fishing competitions is going down, and that many of the most threatened species are large. This study connects the dots and shows change in body size is the result of not only individuals within species becoming smaller, but also larger species being replaced by smaller ones. "Whether it's because of what humans prefer to eat or their habitats getting warmer, big fish just can't seem to catch a break,” explains the lead author Dr Inês Martins from the University of St. Andrews.

The researchers used two sources of body size trait data — direct measurements of biomass taken in the field and average body size estimates from major trait databases — to assess the body size change across over 5,000 ecological assemblage time series spanning 1960-2020. This allowed them to designate body size changes as either a within-species change or a compositional change. 

Shrinking was most common among fish, but among other groups of organisms – such as plants and invertebrates – changes were more varied. By looking across groups of species, this study reveals there are some complex changes taking place, with some organisms becoming bigger while others shrink. The authors believe this suggests that when large organisms disappear, other ones try to take up their place and use up the resources that become available. 

Reflecting on the importance of these results, co-author Prof Jonathan Chase from iDiv and Martin Luther University Halle-Wittenberg (MLU), adds: "As with most things, changes through time are not always ‘one-size-fits-all’. It is important to dig into the complexity of when organisms become smaller or bigger to more thoroughly understand how body size is changing through time.”

The study also noted the replacement of a few large organisms with many small ones, while keeping the total amount of life – known as biomass – constant. This surprising result supports the idea that ecosystems tend to compensate for change by keeping overall biomass of the studied species in a particular habitat stable. This stability is attributed to a trade-off between reductions in body size and concurrent increases in abundance among the organisms.

These findings have far-reaching implications for our understanding of how various organisms are adapting to the challenges posed by humans in the Anthropocene era.

The senior author of the paper, Prof Maria Dornelas from the University of St. Andrews, comments: “It is clear the widespread species replacement we see around the world is having measurable consequences. Organisms becoming smaller has important effects as the size of animals mediates their contribution to how ecosystems function, and how humans benefit from them. Bigger fish can usually feed more people than smaller fish.”

Currently, there is not enough data to draw clear conclusions for most organisms other than fish. Collecting similar measurements – especially when exploring food webs and other species interactions – stands to significantly benefit future research.

 

Original publication
(Researchers with iDiv affiliation and alumni bold)

Inês S. Martins, Franziska Schrodt, Shane A. Blowes, Amanda E. Bates, Anne D. Bjorkman, Viviana Brambilla, Juan Carvajal-Quintero, Cher F. Y. Chow, Gergana N. Daskalova, Kyle Edwards, Nico Eisenhauer, Richard Field, Ada Fontrodona-Eslava, Jonathan J. Henn, Roel van Klink, Joshua S. Madin, Anne E. Magurran, Michael McWilliam, Faye Moyes, Brittany Pugh, Alban Sagouis, Isaac Trindade-Santos, Brian McGill, Jonathan M. Chase, Maria Dornelas. (2023). Widespread shifts in body size within populations and assemblages, Science. DOI: 10.1126/science.adg6006

 

Contact:

Prof Dr Jonathan Chase
Head of the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733120

Email: jonathan.chase@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/synthesis.html

 

Dr Inês Martins
University of St. Andrews
Email: istmartins@gmail.com

 

Christin Coester
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: christin.coester@idiv.de

 

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iDiv Research Biodiversity Synthesis TOP NEWS Fri, 08 Sep 2023 00:00:00 +0200
iDiv’s early career researchers’ response to the proposed changes to the WissZeitVG https://idiv-biodiversity.de//en/news/news_single_view/5186.html iDiv's researchers1 are concerned about the already precarious working conditions in German...

iDiv's researchers1 are concerned about the already precarious working conditions in German academia and are alarmed that the proposed changes to the WissZeitVG will exacerbate this.

The WissZeitVG is a law that specifically determines the contract and working conditions of PhD students and postdocs at German universities and research institutes, ~90% of whom work under temporary contracts for 2-3 years.

These temporary positions create enormous pressure on scientists and compromise the quality of our research. At iDiv, the research addresses big challenges the world faces, such as species extinction, biodiversity loss, and climate change. Understanding these threats to ecosystems, economics, and society requires time and focus. Short-term contracts drastically reduce these and prevent scientists from contributing forward-looking research and solutions to these issues.

The problems of short-term contracts are manifold:

  • Interdisciplinary high-quality research and finding a common language that connects specialised researchers from different disciplines requires sufficient time and continuity (also in employment). This is something that especially affects us at iDiv.
  • Time pressure to deliver results needed to secure the next job or third-party funding: Excellent research needs time, getting to know colleagues, establishing collaborations, and getting acquainted with local processes. Proposals and job applications need careful preparation, an established team or support from others, and even marketing skills to present yourself and your ideas. Increased time pressure reduces the quality of scientific output and may increase academic misconduct. 
  • Mental health issues due to increasing pressure, instability, and lack of future perspectives; time loss due to frequent relocation; loss of familiar surroundings and friends and, therefore, more stress, which results in less productivity.
  • Risk of starting a family: The postdoc phase typically coincides with the phase of starting a family. The temporary reduction of time devoted to work exposes scientists who want to care for their kids to a higher risk of getting pushed out of science. Because women still often take on a larger share of childcare work than men, so fixed-term contracts discriminate against women more than men.
  • Legal instability of foreign researchers: Visas often expire immediately upon contract end. Thus a funding gap of only a month can already cause expulsion, and renewing (or getting a new) visa can take more than six months. This increases pressure and hampers the participation of scientists from the Global South, who most often need a visa even to enter the country.
  • Established postdocs often take on important roles as mentors, lecturers, co-supervisors, etc. Losing them can thus disrupt the education of students and doctoral students.  

If Germany wants to continue to produce internationally high quality research, and be considered a "research wonderland", it must enable its highly qualified scientists to do what they are good at: Science.

From our point of view, the current WissZeitVG proposal, together with the general political and financial setting for universities and research institutes in Germany, does not lead to more permanent positions and thus not to an improvement of the situation but instead to an aggravation. Accordingly, experienced scholars will have to leave the system even earlier. They will be replaced by less experienced junior researchers, which will be catastrophic for the quality of research and teaching.

Good science needs:

More permanent positions at universities and research institutes. After the doctorate, permanent employment in positions other than professorship should be possible, as in most countries (for example, France and England, see Kreckel 2016), where 70-90% of research positions are permanent. This is currently almost impossible in Germany because of, inter alia, numerous legal, bureaucratic but especially systemic and financial hurdles. 

We strongly encourage decision-makers and the BMBF to consider our concerns and commit to changing the law(s) so that more permanent positions arise in order to strengthen Germany as a leading science location with future-oriented top-level research.


1 This refers to all scientists who do not have a permanent position (usually a professorship). Among researchers in Germany under the age of 45 and without a professorship, this is 92%.

 

References

 

Contact:

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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iDiv TOP NEWS Media Release Fri, 08 Sep 2023 00:00:00 +0200
Most species are rare. But not very rare https://idiv-biodiversity.de//en/news/news_single_view/5171.html Species observations have unveiled a potentially universal pattern Over time, biodiversity observations around the world have unveiled a potential universal pattern of how many species are common, very rare or somewhere in-between

Halle/Saale, Fort Lauderdale. More than 100 years of observations in nature have revealed a universal pattern of species abundances: Most species are rare but not very rare, and only a few species are very common. These so-called global species abundance distributions have become fully unveiled for some well-monitored species groups, such as birds. For other species groups, such as insects, however, the veil remains partially unlifted. These are the findings of an international team of researchers led by the German Centre for Integrative Biodiversity Research (iDiv), the Martin Luther University Halle-Wittenberg (MLU) and the University of Florida (UF), published in the journal Nature Ecology and Evolution. The study demonstrates how important biodiversity monitoring is for detecting species abundances on planet Earth and for understanding how they change.

“Who can explain why one species ranges widely and is very numerous, and why another allied species has a narrow range and is rare?” This question was asked by Charles Darwin in his ground-breaking book “The Origin of Species”, published over 150 years ago. A related challenge has been to understand how many species are common (numerous) and how many are rare, the so-called global species abundance distribution (gSAD).

Two main gSAD models have been proposed in the last century: R. A. Fisher, a statistician and biologist, proposed that most species are very rare and that the number of species declines for more common species (so-called log-series model). On the other hand, F. W. Preston, an engineer and ecologist, argued that only few species are actually very rare and that most species have some intermediate level of commonness (so-called log-normal model). However, until now and despite decades of research, scientists did not know which model describes the planet’s true gSAD. 

Solving this problem calls for vast amounts of data. The study authors used data from the Global Biodiversity Information Facility (GBIF) and downloaded data representing over 1 billion species observations in nature from 1900 to 2019. 

“The GBIF database is an amazing resource for all sorts of biodiversity related research, particularly because it brings together both data collected from professional and citizen scientists all over the world,” says first author Dr Corey Callaghan. He began the study while working at iDiv and MLU and is now working at the UF. 

Callaghan and his fellow researchers divided the downloaded data into 39 species groups, for instance, birds, insects, or mammals. For each, they compiled the respective global species abundance distribution (gSAD). 

The researchers detected a potentially universal pattern, which emerges once the species abundance distribution is fully unveiled: Most species are rare but not very rare, and only a few species are very common, as predicted in the log-normal model. However, the researchers also found that the veil has been fully lifted only for a few species groups like cycads and birds. For all other species groups, the data are yet insufficient.

“If you don’t have enough data, it looks as though most species are very rare,” says senior author Prof Henrique Pereira, research group head at iDiv and the MLU. “But by adding more and more observations, the picture changes. You start seeing that there are, in fact, more rare species than very rare species. You can see this shift for cycads and birds when comparing the species observations from back in 1900, when less data was available, with the more comprehensive species observations we have today. It is fascinating: we can clearly see the phenomenon of unveiling the full species abundance distribution, as predicted by Preston several decades ago, but only now demonstrated at the scale of the entire planet.”

“Even though we have been recording observations for decades, we have only lifted the veil for a few species groups,” says Callaghan. “We still have a long way to go. But GBIF and the sharing of data really represents the future of biodiversity research and monitoring, to me.”

The new study's findings enable scientists to assess how far the gSADs have been unveiled for different species groups. This allows for answering another long-standing research question: How many species are out there? This study finds that while for some groups like birds, nearly all species have been identified, this is not the case for other taxa such as insects and cephalopods.

The researchers believe that their findings may help in answering Darwin’s question of why some species are rare, and others are common. The universal pattern they found may point to general ecological or evolutionary mechanisms that govern the commonness and rarity of species. While more research is being done, humans continue to alter the planet’s surface and the abundance of species, for instance, by making common species less common. This complicates the researchers’ task: They need not only to understand how species abundances evolve naturally but also how human impacts are altering these patterns simultaneously. There may still be a long way to go before Darwin’s question is finally answered.
Volker Hahn

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

 

Original publication:
(Researchers with iDiv affiliation bold)
Callaghan, C. T., Borda-de-Água, L., van Klink, R., Rozzi, R., Pereira, H. M. (2023). Unveiling the global species abundance distributions of Eukaryotes, Nature Ecology and Evolution. DOI: 10.1038/s41559-023-02173-y

 

Contact:

Dr Corey Callaghan
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Email: corey.callaghan@idiv.de

 

Prof Dr Henrique Miguel Pereira (speaks English and Portuguese)
Head of Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Email: henrique.pereira@idiv.de
Web: https://www.idiv.de/en/profile/132.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Biodiversity Conservation Biodiversity Synthesis Media Release TOP NEWS Mon, 04 Sep 2023 00:00:00 +0200
New map on potentially groundwater-dependent vegetation in the Mediterranean biome https://idiv-biodiversity.de//en/news/news_single_view/5182.html Report by Léonard El-Hokayem, doctoral student at Martin Luther University Halle-Wittenberg...

Report by Léonard El-Hokayem, doctoral student at Martin Luther University Halle-Wittenberg and the German Centre for Integrative Biodiversity Research (iDiv)

Halle. Decreasing rainfall and increased groundwater use are threatening vegetation and ultimately biodiversity in the Mediterranean biome. Plants that depend on groundwater are particularly vulnerable. We have developed a novel, easy-to-use index to map potentially groundwater dependent vegetation (pGDV) based on environmental site conditions and vegetation characteristics. Our concept combines globally-available geodata and remote sensing and has recently been published in Science of The Total Environment. The results indicate that 31 % of the natural vegetation in the Mediterranean likely depends on groundwater. A biome-wise map of pGDV is important to prioritise areas for detailed identification of actual GDV and biodiversity conservation.

Vegetation that relies on groundwater for its health and survival often forms biodiversity hotspots, provides critical habitat and sustains human livelihoods and ecosystem services.

However, there is a lack of harmonised biome-wise mapping of the distribution and extent of pGDV in the Mediterranean. To address this challenge, we integrated global geodata on groundwater-vegetation interaction, soil, topography, land cover and hydrogeology with a simple index. Our index allows the detection of areas with suitable conditions to hold pGDV where vegetation behaviour also indicates groundwater use.

The Mediterranean map reveals that regions with high pGDV are distributed throughout the entire biome. We also see an increased occurrence in coastal lowlands and in riverine landscapes. These areas indicate precipitation-independent high vitality and evapotranspiration of natural vegetation in low permeable valleys or on low slopes where water accumulates and the groundwater table is shallow while soil properties allow infiltration.

We were surprised that the proportion of high pGDV (31 %) was lower than estimated in a recent global meta-analysis (50 %). However, only one tenth of the catchments in the biome have an area share of high pGDV above 50 %. These catchments may be prioritised for further analysis of GDV. We tested the plausibility of our results against known GDV locations in Italy and California and found good agreement.

Reliable identification of GDV requires big data and high computational power when applied on a large scale. Using the pGDV index, regional authorities or researchers can select regions of interest where the proportion of pGDV is high and detailed analysis is required. The index is initially designed for the Mediterranean biome, but is ideally adaptable to other semi-arid climates. With minor adjustments to the geodata and the vegetation characteristics, the concept could also be transferred to temperate or tropical regions. 

 

Original publication
(Researchers with iDiv affiliation are in bold)

El-Hokayem, L., De Vita, P., Usman, M., Link, A. and Conrad, C. (2023) Mapping Potentially Groundwater-Dependent Vegetation in the Mediterranean Biome Using Global Geodata Targeting Site Conditions and Vegetation Characteristics. Science of The Total Environment, 898, 166397. DOI: 10.1016/j.scitotenv.2023.166397.

 

Contact:

Léonard El-Hokayem
Doctoral researcher
Martin Luther University Halle-Wittenberg
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: leonard.el-hokayem@geo.uni-halle.de
Web: https://www.idiv.de/en/profile/1651.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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TOP NEWS iDiv Fri, 01 Sep 2023 00:00:00 +0200
A global observatory to monitor Earth's biodiversity https://idiv-biodiversity.de//en/news/news_single_view/5179.html A new interconnected system to monitor biodiversity around the world is urgently needed to direct... A new interconnected system to monitor biodiversity around the world is urgently needed to direct and focus conservation action.

Based on a media release of GEO BON

The Global Biodiversity Observing System (GBiOS) is a proposal developed by scientists from the Group on Earth Observations Biodiversity Observation Network (GEO BON), and its partners, including the German Center for Integrative Biodiversity Research (iDiv). It will combine technology, data, and knowledge from around the world to foster collaboration and data sharing among countries and to provide the data urgently needed to monitor biodiversity change and target action. The proposal for this novel system was published in Nature Ecology & Evolution.

At a time of nature crisis driven by unparalleled rates of biodiversity loss, a new interconnected system to monitor biodiversity around the world is urgently needed to direct and focus conservation action.

"The lethal combination of habitat loss, the exploitation of natural populations, pollution, and climate change is causing species extinction rates not seen since the last mass extinction 65 million years ago," said Prof. Andrew Gonzalez, Liber Ero Chair in Conservation Biology at McGill University, and co-Chair of GEO BON. "We lack the means to monitor these impacts fast enough across most areas of the planet."

Operating much like the existing global network of weather stations that monitor climate change and its impacts, the Global Biodiversity Observing System (GBiOS), is a proposal developed by scientists from the Group on Earth Observations Biodiversity Observation Network (GEO BON), and its partners, that will combine technology, data, and knowledge from around the world to foster collaboration and data sharing among countries and to provide the data urgently needed to monitor biodiversity change and target action.

GBiOS can galvanize collaboration on the critical issue of biodiversity data access, sharing, and equitable use. "It can provide the information we need at the pace we need it to support countries as they make progress towards their biodiversity goals", said Prof. Alice Hughes, Associate Professor at The University of Hong Kong, and one of the dozens of scientists who collaborated to develop the proposal for GBiOS. GBiOS is a missing piece of the science-policy puzzle needed to support the Kunming-Montreal Global Biodiversity Framework agreed upon at the COP-15 conference in Montreal last year, contributing to a representative and inclusive understanding of biodiversity change and supporting effective implementation of policies that are designed to reverse biodiversity loss and achieve the global goals for nature in the coming decades.

“It is now clear that in order to effectively implement the Kumming-Montreal Biodiversity Framework, a Global Biodiversity Observing System needs to be created. iDiv has been taking a leadership role in these efforts both globally in GEO BON and by coordinating the development of the European Biodiversity Observation Network (EuropaBON)”, said co-author Professor Henrique Pereira from iDiv and Martin Luther University Halle-Wittenberg.


Original publication
(Researchers with iDiv affiliation and alumni are in bold)
Andrew Gonzalez, Petteri Vihervaara, Patricia Balvanera, Amanda E. Bates, Elisa Bayraktarov, Peter J. Bellingham, Andreas Bruder, Jillian Campbell, Michael D. Catchen, Jeannine Cavender-Bares, Jonathan Chase, Nicholas Coops, Mark J. Costello, Maria Dornelas, Grégoire Dubois, Emmett J. Duffy, Hilde Eggermont, Nestor Fernandez, Simon Ferrier, Gary N. Geller, Michael Gill, Dominique Gravel, Carlos A. Guerra, Robert Guralnick, Michael Harfoot, Tim Hirsch, Sean Hoban, Alice C. Hughes, Margaret E. Hunter, Forest Isbell, Walter Jetz, Norbert Juergens, W. Daniel Kissling, Cornelia B. Krug, Yvan Le Bras, Brian Leung, Maria Cecilia Londoño-Murcia, Jean-Michel Lord, Michel Loreau, Amy Luers, Keping Ma, Anna J. MacDonald, Melodie McGeoch, Katie L. Millette, Zsolt Molnar, Akira S. Mori, Frank E. Muller-Karger, Hiroyuki Muraoka, Laetitia Navarro, Tim Newbold, Aidin Niamir, David Obura, Mary O’Connor, Marc Paganini, Henrique Pereira, Timothée Poisot, Laura J. Pollock, Andy Purvis, Adriana Radulovici, Duccio Rocchini, Michael Schaepman, Gabriela Schaepman-Strub, Dirk S. Schmeller, Ute Schmiedel, Fabian D. Schneider, Mangal Man Shakya, Andrew Skidmore, Andrew L. Skowno, Yayoi Takeuchi, Mao-Ning Tuanmu, Eren Turak, Woody Turner, Mark C. Urban, Nicolás Urbina-Cardona, Ruben Valbuena, Basile van Havre, Elaine Wright (2023). A global biodiversity observing system to unite monitoring and guide action. Nature Ecol Evol. DOI: 10.1038/s41559-023-02171-0

 

Contact:

Prof Andrew Gonzalez
Liber Ero Chair in Biodiversity Conservation
Co-Chair GEO BON
Email: andrew.gonzalez@mcgill.ca

 

Prof Dr Henrique Miguel Pereira (speaks English and Portuguese)
Head of Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Email: henrique.pereira@idiv.de
Web: https://www.idiv.de/en/profile/132.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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iDiv Media Release TOP NEWS Fri, 25 Aug 2023 00:00:00 +0200
1000 new species for Nigeria https://idiv-biodiversity.de//en/news/news_single_view/5177.html New study reveals that over 1000 vascular plants in Nigeria may be undescribed. New study reveals that over 1000 vascular plants in Nigeria may be undescribed.

Leipzig/Katsina. To date, over 1000 vascular plants in Nigeria may be undescribed, making it impossible to know whether or not these plants are endangered and in need of protection. This is one of the key results of a new study led by researchers from the German Center for Integrative Biodiversity Research (iDiv) and Leipzig University, published in Annals of Botany. In order to meet the targets of the CBD’s Global Biodiversity Framework, urgent measures are required that promote local taxonomic activities.

Africa is one of the most biodiverse regions on Earth, hosting a quarter of global biodiversity. The continent is home to 8 of the world’s 34 biodiversity hotspots, and of many endemic and endangered species. One of these biodiversity hotspots is the Niger Delta mangrove forest in Nigeria. Nigeria is home to over 4,700 vascular plants – and likely many more undocumented species. “Documenting the full account of plant diversity is essential for protecting threatened species and ensuring they can sustain human needs before they become extinct”, says senior author Professor Muellner-Riehl from Leipzig University, who is also an iDiv Member.

A team of researchers from iDiv and Leipzig University set out to update species diversity data from Nigeria, thus supporting plant-species-related indicators in the post-2020 Global Biodiversity Framework (GBF) of the Convention on Biological Diversity (CBD). This framework calls for urgent action to recover biodiversity by 2030 for the benefit of both the planet and people, and a key part of the Kunming–Montreal GBF is the goal of a tenfold reduction of the rate of species extinction and risk by 2050. Many international organizations, including the International Union for the Conservation of Nature (IUCN), have called for speeding up species description to better understand and protect biodiversity.

To find out more about this process in Nigeria, the researchers analysed the numbers of species described per year in a time series starting as early as 1753 and ending in 2020. They then simulated various trends and forecasted future descriptions until 2070. They found that there may be over 1000 as-yet-undescribed vascular plants in Nigeria, based on the current level of taxonomic activity. This bears the potential of an approximate 20% increase in the recognised species of vascular plants in Nigeria over the next 50 years. “To achieve the forecasted value of 1140 species by 2070, each taxonomist active in Nigeria from the year 2000 to the present day would need to describe at least two new species per year”, says Associate Professor Abubakar Bello, first author of the study. “However, over 90% of the taxonomists responsible for documenting Nigeria's vascular plants are non-residents who no longer work within the country. Without further actions, this goal will not be reached.”

Urgent and stringent measures are therefore necessary for Nigeria and other developing economies in tropical Africa to overcome this taxonomic challenge, thereby fulfilling the expectations outlined in their commitments to the CBD's Global Biodiversity Framework vision for 2050. The researchers also outline several key pathways to achieve this objective which could be implemented across tropical African countries, such as leveraging funding opportunities, fostering collaborations, investing in education and training, promoting public engagement, and recognizing local expertise.

This work was supported by a call of iDiv’s Flexpool, which encouraged proposals supporting capacity building, and specifically topics focused on communities and regions that are underrepresented in science. The focus of this call was initiated by iDiv’s Internationalisation and Capacity Building Committee.

Kati Kietzmann

 

Original publication

Abubakar Bello, Stewart M. Edie, Kowiyou Yessoufou, Alexandra Nora Muellner-Riehl (2023). Trends in botanical exploration in Nigeria forecast over 1000 yet undescribed vascular plant species. Annals of Botany, DOI: 10.1093/aob/mcad106

 

Contact:

Prof. Dr. Abubakar Bello
German Centre for Integrative Biodiversity Research (iDiv) Helle-Jena-Leipzig
Leipzig University
Umaru Musa Yar’adua University
Email: abubakar.bello@idiv.de

 

Prof Alexandra Muellner-Riehl
Leipzig University
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +493419738581
Email: muellner-riehl@uni-leipzig.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Media Release Research TOP NEWS iDiv iDiv Members Wed, 23 Aug 2023 00:00:00 +0200
Some plants do not shed their leaves in autumn, for good reason https://idiv-biodiversity.de//en/news/news_single_view/5174.html Retention of dead biomass by plants likely to serve function in carbon and nutrient cycling Retention of dead biomass by plants likely to serve function in carbon and nutrient cycling

Report by Dr Gerrit Angst, postdoctoral researcher of the Experimental Interaction Ecology at iDiv, Leipzig University, and the Czech Academy of Sciences and co-author:

Leipzig/Budweis/Prague. Retention of dead biomass by plants is common in the temperate herbaceous flora and can be related to certain plant traits, indicating relevance to ecosystem functioning. These are the main findings of an experimental study on more than 100 plant species jointly performed by researchers from the German Centre for Integrative Biodiversity Research (iDiv), Leipzig University, the Czech Academy of Sciences, and the Charles University, Prague. The study has recently been published in the Journal of Ecology.

As the winter approaches and first freezing temperatures sweep across temperate climates, plants become dormant and shed their leaves. However, some trees and grasses retain their leaves and stalks during autumn and winter, although already pale and without colour. This phenomenon, termed marcescence, can be recognized all around when walking through a snowy landscape. But has marcescence a function in nature or is it a remnant from the bygone summer without specific meaning? 

We knew that marcescence had been relatively well researched in arid ecosystems, in which solar radiation strongly degrades difficult-to-decompose compounds in retained biomass. This facilitates decomposition of and nutrient release from that biomass once shed, with potential competitive advantages for the respective plants. In temperate regions, however, research has been scarce and mainly focused on tree species, with few exceptions, and virtually nothing is known about marcescence in the temperate herbaceous flora, although simple observations indicate that it is widespread. We thus asked ourselves how common marcescence is in our latitudes and whether it can be linked to certain plant traits.

Fortunately, we had access to a large common garden experiment that was running at the botanical gardens in Prague. The experiment was ideal to tackle our research question as a large variety of plants were grown in the same soil substrate and under the same climate. We created a battle plan and finally sampled dead biomass from 127 plants shortly before the start of the subsequent growing season, determined the proportion of marcescence for each of these plants, and related this proportion to plant functional traits.

To our surprise, almost all of the investigated plants (123 of 127) kept at least part of their biomass marcescent, indicating the commonness of marcescence in the temperate flora. Marcescence particularly predominated in tall plant species with small leaves and high carbon concentrations in their tissues and in those commonly preferring intensely disturbed sites. Marcescence may thus provide advantages for certain plants in the initial stages of succession and might influence carbon and nutrient cycling. As we are just beginning to understand the determinants and function of marcescence in temperate regions, intensified research efforts are crucially needed to disentangle the relevance of this widely overlooked phenomenon to ecosystem functioning. 

 

Original publication
(Researcher with iDiv affiliation and alumni in bold)

Ondřej Mudrák, Šárka Angst, Gerrit Angst, Hana Veselá, Renáta Schnablová, Tomáš Herben, Jan Frouz (2023). Ecological significance of standing dead phytomass: Marcescence as a puzzle piece to the nutrient cycle in temperate ecosystems. Journal of Ecology, DOI: 10.1111/1365-2745.14174

 

Contact:

Dr Gerrit Angst
Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Institute of Soil Biology and Biogeochemistry
Biology Centre of the Czech Academy of Sciences
Phone: +49 341 9739179
Email: gerrit.angst@idiv.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Media Release TOP NEWS Tue, 15 Aug 2023 00:00:00 +0200
Satellite documentation of effects of heat waves on plants https://idiv-biodiversity.de//en/news/news_single_view/5173.html Researchers record large-scale shift in photosynthesis activity for the first time Researchers record large-scale shift in photosynthesis activity for the first time

 

The full text is only available in German.

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TOP NEWS sDiv Media Release Tue, 08 Aug 2023 00:00:00 +0200
Remote plant worlds https://idiv-biodiversity.de//en/news/news_single_view/5165.html International research team compares form and function of island and mainland plants International research team compares form and function of island and mainland plants

Based on a media release by the University of Göttingen

Oceanic islands provide useful models for ecology, biogeography and evolutionary research. Many ground-breaking findings – including Darwin's theory of evolution – have emerged from the study of species on islands and their interplay with their living and non-living environment. Now, an international research team led by researchers from the University of Göttingen and the German Centre for Integrative Biodiversity Research (iDiv) has investigated the flora of the Canary Island of Tenerife. The results were surprising: the island's plant-life exhibits a remarkable diversity of forms. However, the plants differ little from mainland plants in functional terms. However, unlike the flora of the mainland, the flora of Tenerife is dominated by slow-growing, woody shrubs with a “low-risk” life strategy. The results were published in Nature.

The researchers investigated how the plants of Tenerife differ in functional terms from plants from other parts of the world. They conducted extensive field research and measurements at over 500 sites using the most up-to-date methods of functional ecology. The sites were scattered all over the island at altitudes ranging from sea level to mountainous regions above 3,300 metres. The scientists recorded about 80% of Tenerife's native seed plants, and surveyed eight plant characteristics: plant size, specific wood density, leaf thickness, absolute and specific leaf area, leaf dry matter, nitrogen concentration in leaf tissue, and seed weight. They compared their data with data on more than 2,000 plant species found on the mainland. 

"Our study shows, for the first time and contrary to all expectations, that species groups that evolved on the Canary Islands do not contribute to the expansion of the breadth of different traits. This means they do not lead to more functional diversity," explains the lead of the study, Professor Holger Kreft from Göttingen University. Previous comparisons show that species occurring on islands can differ significantly from their relatives on the mainland. A well-known example is provided by the Galapagos giant tortoise: the species is only found on the Galapagos Islands and, as a result of adaptation to its environmental conditions, is much larger than tortoises from the mainland. The research team expected similar differences between island and mainland plants, but this was not the case. "Rather, we see that most species follow the constraints of the island climate. Thus, medium-sized, woody species develop. These tend to live with the limited resources and high risks of extinction on the island. That is, they grow slowly. The high functional diversity is mainly due to the species that are widespread on the island and the nearby mainland," explains Kreft.

"At the beginning of our research, we assumed that island plants would show fundamental differences and would be characterised by rather limited diversity in terms of function due to their geographical isolation," explains first author Dr Paola Barajas Barbosa, who is now working as a researcher at iDiv. The results are part of her doctoral thesis, which she did at the University of Göttingen. "We were all the more surprised to find that the plants of Tenerife have a comparatively high functional diversity.”

 

Original publication
(Researchers with iDiv affiliation and alumni in bold)

Martha Paola Barajas Barbosa, Dylan Craven, Patrick Weigelt, Pierre Denelle, Rüdiger Otto, Sandra Díaz, Jonathan Price, José María Fernández-Palacios, Holger Kreft (2023). Assembly of functional diversity in an oceanic island flora. Nature. DOI: 10.1038/s41586-023-06305-z

 

Contact:

Dr Martha Paola Barajas Barbosa
Biodiversity Synthesis
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733254
Email: paola.barajas@idiv.de

 

Prof Dr Holger Kreft
University of Göttingen
Biodiversity, Macroecology and Biogeography Research Group
Phone: +49 551 39-28757
Email: hkreft@uni-goettingen.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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iDiv TOP NEWS Media Release Wed, 12 Jul 2023 00:00:00 +0200
Holistic management is key to increase carbon sequestration in soils https://idiv-biodiversity.de//en/news/news_single_view/5151.html Novel framework allows for a more effective management of soils as carbon sinks Novel framework allows for a more effective management of soils as carbon sinks

Report by Dr Gerrit Angst, postdoctoral researcher of the Experimental Interaction Ecology at iDiv, Leipzig University, and the Czech Academy of Sciences and first author:

Leipzig/Budweis/Copenhagen. Increased carbon sequestration in soil to help mitigate climate change can only be achieved by a more holistic management. This is the conclusion from our opinion paper conceptualized together with colleagues from the German Centre for Integrative Biodiversity Research (iDiv), Leipzig University, the Czech Academy of Sciences, and the University of Copenhagen. We developed a novel framework that can guide informed and effective management of soils as carbon sinks. The study has recently been published in Nature Communications.

A key question for land management is how to sustain and increase the vast amounts of carbon stored in soil to help mitigate climate change. In contrast to carbon contained in partly decomposed plant fragments, which is considered labile and remains in the soil for a few days to years, carbon associated with minerals, which can persist for centuries to millennia in soil, has received specific attention as a potential management target. Undifferentiated focus on this “stabilized” carbon, however, falls short of establishing soils as carbon sinks because various environmental factors, such as related to land use or specific soil types, render management of this carbon inefficient. We were puzzled by the strong emphasis on mineral-associated carbon in the literature, whose context-independent valuation hampers informed and targeted management of soils as carbon sinks. Together with colleagues from Germany, the Czech Republic, the United States, and Denmark, we thus developed a framework for the contextualization of management strategies that considers the diversity and complexity of soils.

Our framework specifically highlights the relevance of labile carbon in partly decomposed plant fragments as a management target in various environmental contexts. For example, the capacity of some soils to accumulate rather stable, mineral-associated carbon is very low; some soils also feature conditions that hamper the formation of stabilized carbon but favor the accumulation of labile carbon. Management that is aimed at increasing and perpetuating labile carbon in such soils will be more effective in increasing carbon sequestration than that focused on stabilized carbon. We cannot overemphasize the need to consider context-dependent environmental conditions for an effective management of soils as carbon sinks, which constrain whether management should target labile or stabilized carbon, or both.

We expect contextualization of management strategies within the novel framework to maximize carbon sequestration in soil and generate synergies with related management targets, such as related to soil health, biodiversity, or crop performance. Only if we see soils as a complex, holistic system with its specific chemical, physical, and biological features, will we be able to successfully manage them in a rapidly changing environment.

 

Original publication
(Scientists with iDiv affiliation in bold)

Angst, G., Mueller, K.E., Castellano, M.J., Vogel, C., Wiesmeier, M., Mueller, C.W. (2023): Unlocking complex soil systems as carbon sinks: multi-pool management as the key. Nature Communications. DOI: 10.1038/s41467-023-38700-5

 

Contact:

Dr Gerrit Angst
Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Institute of Soil Biology and Biogeochemistry
Biology Centre of the Czech Academy of Sciences
Phone: +49 341 9739179
Email: gerrit.angst@idiv.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Experimental Interaction Ecology Media Release TOP NEWS Thu, 15 Jun 2023 00:00:00 +0200
Diverse landscapes help insects cope with heat stress https://idiv-biodiversity.de//en/news/news_single_view/5140.html Habitat diversity can mitigate effects of climate change on insects Habitat diversity can mitigate effects of climate change on insects

Leipzig/Jena/Bad Lauchstädt. Global warming is affecting terrestrial insects in multiple ways. In response to increasingly frequent heat extremes, they have to either reduce their activity or seek shelter in more suitable microhabitats. A new study led by researchers from the German Centre for Integrative Biodiversity Research (iDiv) and Friedrich Schiller University Jena shows: The more diverse these microhabitats are, the better for the insects. For their study, published in Global Change Biology, they developed a new approach to accurately track insect movements and activity.

Anthropogenic global warming has far-reaching implications for the world we live in. Some of these changes might be less obvious and often go unnoticed for a long time. For example, a warming climate is also affecting terrestrial insects such as beetles, ants, and butterflies. To survive under great heat, they have to either reduce their physical activity to conserve energy, or seek shelter in a cooler environment. A natural and diverse ecosystem offers many microhabitats that provide more favourable climate conditions as well as food for insects. But in the face of land-use changes, the diversity of these microhabitats is declining. This is not only affecting terrestrial insects, but also the important ecosystem services they are providing, such as pollination, the formation of humus and general improvement of soil quality.

A team led by researchers from iDiv and Friedrich Schiller University Jena studied the effects of a warming climate and the availability of microhabitats on the activity of terrestrial insects. For their study, they used the iDiv Ecotron, which consists of several isolated ecosystems (so-called EcoUnits). Here, environmental conditions such as light, nutrients and humidity can be controlled and manipulated. The researchers studied six insect species that can be found in the surrounding area of Leipzig (Germany), including the beetle species Carabus coriaceus, firebugs (Pyrrhocoris apterus), and house crickets (Acheta domesticus).

Accurate activity tracking based on Radio Frequency Identification

To accurately track the movements of a total of 465 insect individuals, the researchers developed a new tracking method based on Radio Frequency Identification (RFID). “Heavy GPS collars that are typically used for large mammals are not suitable for small animals such as insects. With the help of a very light RFID tag, we can now also track movement patterns of insects in complex habitats”, says first author Jördis Terlau, who led the study as a doctoral researcher at iDiv and Friedrich Schiller University Jena.

Within the EcoUnits, the researchers simulated heat extremes based on data that had been recorded by the Deutscher Wetterdienst (DWD) in 2018 and 2019. Temperatures were reaching a maximum of 38.7 °C. They also added leaf litter from four different tree species to the EcoUnits – the litter was either separated or well-mixed. With the help of the RFID tracking, they found that insects apply different strategies in response to heat extremes, depending on the microhabitat conditions. In mixed litter conditions, the insects significantly reduced their activity. In contrast, they increased their activity when the leaf litter was spatially separated. “We assume that mixed leaf litter not only provides protection from heat, but also various food sources. Insects can move less and still find enough food, which helps them save energy”, says Jördis Terlau.  

Diverse microhabitats can mitigate the effects of heat extremes

However, in environments with spatially separated leaf litter, the insects had to move more in order to find enough food and leave their shelter. This, in turn, increased their energy consumption, which is of disadvantage under extreme heat and increases the risk of overheating. “This stresses the importance of diverse habitats and microhabitats. In this way, the effects of extreme heat on insects can be significantly mitigated”, says last author Dr Myriam Hirt from iDiv and Friedrich Schiller University Jena. The study also highlights the various benefits of heterogeneous habitats such as mixed forests. They provide terrestrial insects with favourable conditions and food, and help ensure that important ecosystem services can be provided in the future also in the face of climate change.


This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118)

Kati Kietzmann

 

Original publication
(Researchers with iDiv affiliation and alumni are in bold)

Jördis F. Terlau, Ulrich Brose, Nico Eisenhauer, Angelos Amyntas, Thomas Boy, Alexander Dyer, Alban Gebler, Christian Hof, Tao Liu, Christoph Scherber, Ulrike E. Schlägel, Anja Schmidt, Myriam R. Hirt (2023). Microhabitat conditions remedy heat stress effects on insect activity. Global Change Biology, DOI: 10.1111/gcb.16712

 

Contact:

Jördis Terlau
Leibniz Institute for the Analysis of Biodiversity Change
Centre for Biodiversity Monitoring and Conservation Science (zbm)
Email: joerdis.terlau@gmail.com

 

Dr Myriam Hirt
Research group Theory in Biodiversity Science
German Centre for Integrative Biodiversity Research (iDiv) and Friedrich-Schiller-University Jena
Phone: +49 341 9733206
Email: myriam.hirt@idiv.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Research iDiv TOP NEWS Theory in Biodiversity Science Media Release Wed, 26 Apr 2023 00:00:00 +0200
iDiv celebrates its 10th anniversary https://idiv-biodiversity.de//en/news/news_single_view/5139.html Over 300 guests from politics, science and civil society Chancellor, Minister of State, and Prime Ministers acknowledge the success of international biodiversity research in Central Germany

The German Centre for Integrative Biodiversity Research (iDiv) celebrated its 10th anniversary today with a ceremony in the Leipzig University Paulinum. Over 300 guests from politics, science and civil society took part, including the ministers-president of Saxony, Saxony-Anhalt and Thuringia, Michael Kretschmer, Dr Reiner Haseloff and Bodo Ramelow as well as the Federal Government Commissioner for eastern Germany, Carsten Schneider. They acknowledged the research centre’s important contributions to the protection of biological diversity. In his welcoming message, Federal Chancellor Olaf Scholz stressed the importance of “world-class basic research” for international biodiversity policy.

Alongside the contributions from politicians, biodiversity research itself was an important feature of the event. Scientists presented highlights of iDiv research and their significance for the development of effective measures to combat the biodiversity crisis. Guest speaker, Ana María Hernández Salgar, Chair of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services IPBES, emphasised the importance of iDiv’s findings for evidence-based biodiversity policy at local, national and global levels. All speakers affirmed the excellence and worldwide visibility of the research centre.

Olaf Scholz, Federal Chancellor: “Congratulations on ten years of world-class basic research! This is how scientific excellence is created, excellence which the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services and the Intergovernmental Panel on Climate Change turn to again and again. This strengthens the German voice on the international stage.”

Carsten Schneider, Minister of State and Federal Government Commissioner for eastern Germany: “The creation of iDiv was possible because this form of cooperation enjoys the express support of the three federal states and the federal government. Excellent science needs outstanding conditions. This form of 7 cooperation can stand as a model for the whole of eastern Germany, indeed for the entire Federal Republic. We need more ‘iDiv’”.

Michael Kretschmer, Minister President of the Free State of Saxony: “iDiv is unique in the complex area of biodiversity research. It bundles the activities of many stakeholders from science across national borders most impressively and clearly shows what the focusing of research, scientific cooperation and keen collaboration can achieve for the common goal.”

Dr Reiner Haseloff, Minister President of Saxony-Anhalt: “Today, iDiv stands as one of the world’s leading locations for biodiversity research. It attracts the best scientists from all over the world and has become a magnet for research and a beacon for our region. Here, biodiversity is examined in its full complexity. I wish this were the standard approach for all issues, especially those of relevance to society as a whole.”

Bodo Ramelow, Minister President of the Free State of Thuringia: “For 10 years now, iDiv has been researching and developing – also with considerable support from Thuringia – the fundamentals of the preservation of biodiversity and thus the basis of all life on earth. Our planet is dynamic – and, given the current biodiversity crisis, unfortunately also in a negative way. The research achievements of the last few years can, therefore, not be overestimated. I say, ‘Congratulations!’”

Dr Heide Ahrens, Secretary General of the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation): “iDiv fulfils everything the DFG understands as excellent research. It is an outstanding intermediary between science and politics. In the face of devastated ecosystems and biological impoverishment, it would be highly desirable if iDiv were significantly strengthened by the three federal states and the federal government in the future.”

Prof Dr Walter Rosenthal, Chairman of the iDiv Board of Trustees and President of the Friedrich Schiller University Jena: “Ten years of iDiv - that's ten years of internationally competitive research on one of humanity’s most pressing issues: the preservation of biodiversity. In the last decade, almost 1,000 researchers have worked to identify the drivers and consequences of changes in biodiversity, and to develop models and concrete proposals for measures to effectively counteract the changes. The fact that iDiv enjoys the highest international 8 reputation is evident from the many high-profile publications in the most renowned journals, and from its participation in important committees dealing with the issue of biodiversity.”

Prof Dr Christian Wirth, iDiv Speaker: “These have been an eventful and moving few years. 10 years for the future, because the last 10 years were really just the beginning: The tasks of stopping biodiversity loss and using its potential to move forward sustainably are enormous. Political will has grown, but implementation will continue to require excellent research in the future. We are ready for that.”

 

Background:
Changes in ecosystems and biotic communities, and the loss of species are among the greatest challenges of our time. Changes in land use, direct exploitation, climate change, and pollution threaten the biological diversity of the planet. The Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services estimates that around one eighth of all animal and plant species are threatened with extinction – with negative consequences for the functioning of ecosystems.

For 10 years, iDiv scientists have been researching global changes in biological diversity and developing the foundations of evidence-based policy and practice. The research centre integrates a wide range of research fields, from molecular interactions between animals and plants to global trends in biodiversity change. For example, iDiv researchers recently found that species with small areas of distribution are at particularly high risk, while at the same time, the threat is reduced when these species live in protected areas.

iDiv has developed into a globally visible beacon of biodiversity science. More than 300 employees from 40 nations currently work at the research centre. In addition, more than 150 member groups of the scientific network conduct research at various locations in Halle, Jena and Leipzig. iDiv is run together with the Martin Luther University Halle-Wittenberg and the Friedrich Schiller University Jena, as well as in cooperation with the Helmholtz Centre for Environmental Research – UFZ; seven Leibniz and Max Planck institutes are involved as cooperation partners. Up to now, iDiv has been funded by the German Research Foundation (DFG). In 2024, the three states of Saxony, Saxony-Anhalt and Thuringia, together with other partners, will take over the basic financing of the research centre.

 

Contact:

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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TOP NEWS iDiv Media Release Thu, 20 Apr 2023 00:00:00 +0200
Large animals travel more slowly because they can't keep cool https://idiv-biodiversity.de//en/news/news_single_view/5136.html New study suggests fragmentation and climate warming could disadvantage large animals due to their... New study suggests fragmentation and climate warming could disadvantage large animals due to their limited traveling speeds

Leipzig. Whether an animal is flying, running or swimming, its traveling speed is limited by how effectively it sheds the excess heat generated by its muscles, according to a new study led by Alexander Dyer from the German Centre for Integrative Biodiversity Research (iDiv) and the Friedrich Schiller University Jena, published in the open access journal PLOS Biology.

An animal’s capacity to travel is a crucial part of its survival and dictates where – and how far – it can migrate, find food and mates, and spread into new territories. This becomes even more challenging in a human-dominated world characterized by increasingly fragmented habitats and limited food and water resources under climate change. 

Dyer and his colleagues developed a model to look at the relationship between animal size and traveling speed, using data from 532 species. While larger animals should be able to travel faster due to their longer wings, legs or tails, the researchers found it is particularly the medium-sized animals that typically have the fastest sustained speeds. The researchers attribute this to the fact that larger animals require more time to dissipate the heat that their muscles produce while moving, they have to travel more slowly to avoid overheating. They conclude that any animal’s traveling speed can be jointly explained by how efficiently it uses energy and sheds heat.

“The new study provides a way to understand animal movement capacities across species and can be used to estimate any animal’s traveling speed based on its size”, says first author Dyer, doctoral researcher at iDiv and Friedrich Schiller University Jena. “For example, this approach can be applied to predict whether an animal might be able to move between habitats fragmented by human development, even when the details of its biology are unknown”. Last author Dr Myriam Hirt from iDiv and the University of Jena adds, “We anticipate that large animals are potentially more susceptible to the effects of habitat fragmentation in a warming climate than previously anticipated and therefore more prone to extinction. But this needs further investigation.”

 

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118 as well as research unit DynaCom, FOR 2716) and the Open Access Publication Fund of the Thüringer Universitäts- and Landesbibliothek Jena.

 

Original publication
(Researchers with iDiv affiliation are in bold)

Alexander Dyer, Ulrich Brose, Emilio Berti, Benjamin Rosenbaum, Myriam R. Hirt (2023). The travel speeds of large animals are limited by their heat-dissipation capacities. PLOS Biology, DOI: 10.1371/journal.pbio.3001820

 

Contact:

Alexander Dyer
German Centre for Integrative Biodiversity Research (iDiv)
Friedrich Schiller University Jena
Email: dyer.alexander@protonmail.com

 

Dr Myriam Hirt
Research group Theory in Biodiversity Science
German Centre for Integrative Biodiversity Research (iDiv) and Friedrich-Schiller-University Jena
Phone: +49 341 9733206
Email: myriam.hirt@idiv.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Theory in Biodiversity Science Research Media Release TOP NEWS iDiv Wed, 19 Apr 2023 00:00:00 +0200
New ideas for biodiversity research: ecologist Jonathan Chase receives ERC Advanced Grant https://idiv-biodiversity.de//en/news/news_single_view/5129.html Research project "MetaChange" will be funded with almost 2.5 million euros over the next five years Research project "MetaChange" will be funded with almost 2.5 million euros over the next five years

Joint media release of the German Centre for Integrative Biodiversity Research (iDiv) and Martin Luther University Halle-Wittenberg

The European Research Council (ERC) announced that Prof. Dr. Jonathan Chase will be awarded one of the prestigious ERC Advanced Grants. The scientist will receive almost 2.5 million euros over the next five years to fund his research project "MetaChange". With this project, he plans to develop new concepts, tools and analyses for a better understanding of biodiversity and its change. Chase has been conducting research and teaching at the German Centre for Integrative Biodiversity Research (iDiv) and Martin Luther University Halle-Wittenberg (MLU) since 2014. 

"Jonathan Chase is one of the most distinguished researchers at the University of Halle. He is the author of acclaimed studies and his work makes a significant contribution to making biodiversity research from central Germany known worldwide. We are proud that his scientific work has now been awarded an Advanced Grant from the European Research Council. This is a great signal for MLU and iDiv," says MLU Rector Prof. Dr. Claudia Becker.

Prof. Dr. Henrique Pereira, iDiv speaker and professor at MLU, adds: “Jon Chase’s work at iDiv has had a far-ranging impact on biodiversity research. He has led several global synthesis analysis and has shown how the scale of analysis affects different metrics of biodiversity change. The ERC Advanced Grant recognises his extraordinary achievements and provides support for the continuation of his work."

"I thank the ERC for the great trust placed in me with the Advanced Grant. I will use the funding to close important knowledge gaps in how biodiversity is changing through time," says Prof. Dr. Jonathan Chase. His new research project will use a common problem of biodiversity research as a starting point: even though extensive data on local and global biodiversity exists, these are often not comparable with each other. "Studies often disagree on the question of what is actually meant by biodiversity and what it means that it is changing. The differences are magnified because studies are so different when it comes to the species studied, the methods used and the analytical procedures," says Chase. This makes it difficult to make concrete statements about how and where biodiversity is changing, and importantly, to identify the reasons for these changes. "There is no question that biodiversity is changing in many ways around the world, and that these changes are ongoing because of the actions of people. However, we lack a clear and consistent way to quantify exactly what these changes are and how to attribute potential causes of these changes," Chase continues. This knowledge, however, is required for accurate and effective conservation measures, which have also been mandated by the recent international agreements at the UN.

One of Chase's fields of expertise is the synthesis of large data sets on the distribution and abundance of species from across the world with the help of computer-assisted methods. With this synthesis, new insights are gained. With the help of the ERC funding, Chase now wants to take this work to a new level: "One of the biggest challenges we have in biodiversity science is that we are getting much better at understanding what has happened to biodiversity in the past, and we’re starting to provide some answers as to the potential causes of those changes. However, we are particularly bad at forecasting biodiversity change into the future. There are many ways to try this, although which ones work best is anyone’s guess." By compiling biodiversity change through time from many thousands of sites across the planet, and combining it with new statistical tools, the researcher hopes to  provide better forecasts for how biodiversity might change in the future.

Jonathan Chase was born in the USA. After studying at the University of Michigan and Utah State University, he completed his doctorate at the University of Chicago in 1998. After several years of teaching and doing research at various US universities, Chase was appointed Professor of Biodiversity Synthesis at MLU and iDiv in Germany in 2014. He is the author of more than 138 scientific articles published in renowned journals such as Nature, Science and PNAS, as well as two foundational books. Clarivate Analytics included Chase in the list of "highly cited researchers 2022", representing the most frequently cited researchers worldwide.

The ERC Advanced Grants are among the most prestigious and coveted research awards in Europe. The European Research Council awards them to world-leading scientists who applied for funding of their highly ambitious and promising research projects. A total of almost 1,650 project proposals was submitted in this round of ERC Advanced Grants, from which 218 were selected for funding across Europe. The funding rate is thus 13.2 percent.

 

Contact:

Prof Dr Jonathan Chase
Head of the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733120

Email: jonathan.chase@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/synthesis.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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iDiv Biodiversity Synthesis Media Release TOP NEWS Thu, 30 Mar 2023 00:00:00 +0200
sDiv welcomed the 2500th working group participant https://idiv-biodiversity.de//en/news/news_single_view/5121.html On 15 March 2023 sDiv - the synthesis centre of iDiv welcomed its 2500th participant at an sDiv... On 15 March 2023 sDiv - the synthesis centre of iDiv welcomed its 2500th participant at an sDiv working group meeting. The lucky one was Dr. Steven Bachman who travelled from the Royal Botanic Gardens, Kew in the UK to attend the second in-person meeting of the sDiv working group sRedList at the iDiv headquarters. This meeting was co-incidentally the 150th meeting that was organised by sDiv. Dr. Bachmann was very surprised and of course happy to receive the famous iDiv mug, chocolate and a very official handshake from Dr. Marten Winter.

sDiv head Marten Winter summarized “2500 participations within 10 years is a huge achievement and shows the continuing demand of the research community for those collaborative synthesis projects. But it also shows how successful we as iDiv community support the sDiv mechanism at all levels to make it happen in the end (e.g. participation, leadership, admin, governance, advertisements of calls etc)”

Carolin Kögler

Contact:

Dr Marten Winter
sDiv - Synthesis Centre
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 9733129
Email: marten.winter@idiv.de

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iDiv sDiv TOP NEWS Mon, 20 Mar 2023 13:57:05 +0100
Widespread species gaining ground https://idiv-biodiversity.de//en/news/news_single_view/5118.html More widely distributed species benefit from anthropogenic changes More widely distributed species benefit from anthropogenic changes

Leipzig/Halle. Human activities are accelerating biodiversity change and promoting a rapid turnover in species composition. A team of researchers led by the German Centre for Integrative Biodiversity Research (iDiv) and Martin Luther University Halle-Wittenberg (MLU) has now shown that more widespread species tend to benefit from anthropogenic changes and increase the number of sites they occupy, whereas more narrowly distributed species decrease. Their results, which were published in Nature Communications, are based on an extensive dataset of over 200 studies and provide evidence that habitat protection can mitigate some effects of biodiversity change and reduce the systematic decrease of small-ranged species.

Every living species on the planet has its own unique geographic range, with some species occurring over large parts of the globe, while others inhabiting only a few select areas. But does the range size of a species influence how it responds to human activities and changes in the number of sites it occupies through time?

A team led by researchers from iDiv and MLU set out to evaluate the connection between the size of a species’ range and the changes in their regional occupancy over time. To do so, the researchers used an extensive dataset of 238 studies that monitored plant and animal species assemblages from across many sites for 10-90 years. From these time series, they were able to determine which species were increasing in the numbers of sites they occupied through time, which were decreasing in their site occupancy, and which stayed the same. They then wanted to compare the trends of species to the size of their ranges to see if there was a connection. To determine the range sizes of nearly 19,000 species from across the tree-of-life that were identified in the time series, they used data from the Global Biodiversity Information Facility (GBIF), which includes data on the occurrences of species from across the world, including data collected from popular smartphone apps like iNaturalist and eBird.

Species with larger ranges tend to increase in occupancy

The researchers found that on average across all studies, species with larger ranges tended to increase in occupancy through time, whereas small-ranged species decreased. For example, in a study from northern Australia, species that were native to only a small part of the region, such as red cabbage palm (Livistona mariae), lost ground from when they were first surveyed in the 1990s, while more widely distributed species, such as Polynesian arrowroot (Tacca leontopetaloides) and diamond burbark (Triumfetta rhomboidea), were found at more sites. Likewise, narrowly distributed fish in the kelp beds off the coast of Santa Barbara, California, like the rainbow perch (Hypsurus caryi) were found at fewer sites since monitoring started in 2000, while more widespread species like Scropaenichthys marmoratus occurred at more sites. “One reason could be because widespread species tend to have wider niche breadth, meaning that they live in many different kinds of habitats. These species can more rapidly disperse across sites than more narrowly distributed species, and thus are more likely to persist or even increase in response to global environmental changes”, says first author Dr. Wubing Xu from iDiv and MLU. These relationships were stronger in marine than in terrestrial and freshwater realms. “One reason could be that marine species are often more sensitive to environmental changes such as climate warming”, explains Wubing Xu.

These results also help resolve previous discrepancies. Professor Anne Magurran and Professor Maria Dornelas, both from the University of St. Andrews and co-authors on the new study, led an earlier study that compiled time series of biodiversity data from across the world into a database that they called BioTIME. The new study added many new datasets to that compilation. “Our work with the first versions of BioTIME showed no clear general trend one way or the other in local species richness, but this does not mean the world is not changing and that humans are not having a dramatic impact on biodiversity”, said Dornelas. “We saw substantial changes in species composition, and what is nice about these new results is that we were able to show that these changes are associated with characteristics of the species that are winning and losing through time. It is clear that to understand biodiversity change we need to use multiple metrics at multiple scales.”

Protected status can mitigate biodiversity change

To date, ~17% of terrestrial areas and inland waters and ~8% of coastal and marine areas are designated as ‘protected’ in some way. Recent international agreements at the United Nations Biodiversity Conference aim to increase this substantially in the next decade. By comparing the trends inside and outside of protected areas, the researchers found that changes in occupancy were less extreme in terrestrial protected areas. For example, the investigators found that more narrow-ranged bird species like Little bustard (Tetrax tetrax) increased their occupancy through time in an area given special protection status in Portugal, whereas they were declining in a nearby intensively farmed region. “Reducing anthropogenic pressures by establishing protected areas can temper the decreases in occupancy of small-ranged species that we often observe”, says senior author Professor Jonathan Chase from iDiv and MLU. “This is why it is imperative that the international community follow through on its promise to increase the amount of habitat protected and restored across the world.”

 

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

Kati Kietzmann

 

Original publication
(Researchers with iDiv affiliation and alumni are in bold)

Wu-Bing Xu, Shane A. Blowes, Viviana Brambilla, Cher F. Y. Chow, Ada Fontrodona-Eslava, Inês S. Martins, Daniel McGlinn, Faye Moyes, Alban Sagouis, Hideyasu Shimadzu, Roel van Klink, Anne E. Magurran, Nicholas J. Gotelli, Brian J. McGill, Maria Dornelas, Jonathan M. Chase (2023). Regional occupancy increases for widespread species but decreases for narrowly distributed species in metacommunity time series. Nature Communications. Doi: 10.1038/s41467-023-37127-2

 

Contact:

Dr Wubing Xu
Biodiversity Synthesis
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Email: Wubing.xu@idiv.de

 

Prof Dr Jonathan Chase
Head of the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733120

Email: jonathan.chase@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/synthesis.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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iDiv Biodiversity Synthesis TOP NEWS Research Media Release Mon, 20 Mar 2023 00:00:00 +0100
How fishermen benefit from reversing evolution of cod https://idiv-biodiversity.de//en/news/news_single_view/5116.html Under long-term fisheries management, evolutionary change, that has resulted in smaller maturation... Under long-term fisheries management, evolutionary change, that has resulted in smaller maturation sizes, can be reversed profitably.

Leipzig. Intense fishing and overexploitation have led to evolutionary changes in fish stocks like cod, reducing both their productivity and value on the market. These changes can be reversed by more sustainable and far-sighted fisheries management. The new study by researchers from the German Centre for Integrative Biodiversity Research (iDiv), Leipzig University and the Institute of Marine Research in Tromsø, which was published in Nature Sustainability, shows that reversal of evolutionary change would only slightly reduce the profit of fishing, but would help regain and conserve natural genetic diversity.

The impact of global fisheries on marine ecosystems is severe: fish stocks have declined and the degradation of marine habitats as well as the loss of biodiversity have been accelerated. Less visible, intense fishing has also affected the age and size structure of fish stocks and caused evolutionary change, often towards lower growth rates, smaller maturation sizes and earlier reproduction age. For example, cod in the North Sea, which has been heavily exploited in the past, matures at sizes just above 50 cm, compared to more than 70 cm expected in an unfished population.

Earlier reproduction can increase stock resilience in the short-term, but over time results in populations with smaller fish that have less offspring. “At the end of the day, this can reduce both the productivity of a stock and the value on the market,” says first author Hanna Schenk from iDiv and Leipzig University. “Apart from this, we don’t know much about potential consequences such as trophic cascades and other ecosystem changes that feed back onto the harvested species and may interfere with critical ecological functions.”

Only long-term planning can reverse evolutionary decline 

But evolution is not a one-way street. This is why the researchers from iDiv, Leipzig University and the Institute of Marine Research in Tromsø (Norway) wanted to find out what it takes to reverse evolutionary decline after decades of intensive exploitation, in particular with regard to planning horizons in fisheries management. For this, they developed a model that took various processes into account: Biological growth and reproduction as well as economic harvesting costs and consumer preferences. The researchers also analysed potential trade-offs between economic profit and conservation targets.

They found that evolutionary decline is profitable to reverse under century-long planning horizons. With more typical short-term planning, stock recovery in terms of biomass is achieved, but evolutionary decline continues, albeit at much lower rates. “Fisheries typically consider short planning horizons of a few years. This stands in contrast to long-term sustainability and biodiversity targets”, says Hanna Schenk. The researchers found that more far-sighted planning horizons would help to rebuild the stock but evolutionary decline continues. According to Schenk, reversing this process takes much longer than the recovery of the stock biomass and is only achieved with century-long planning horizons.

Appropriate conservation targets only slightly reduce profit 

The researchers also show that setting conservation targets for restoring not only fish stocks, but also their genetic composition would only slightly reduce profits. The cost and time of evolutionary reversal could be reduced further if fisheries can select fish depending on their genes, which may be possible to some extent by choosing the time and place of harvest. However, current conservation agendas do not include the restoration of genetic diversity, for example target 14 of the Sustainable Development Goals (SGDs), which calls for an end to overfishing.

“More selective fishing could reverse evolutionary decline in the long term”, says senior author Professor Martin Quaas from iDiv and Leipzig University. Economic incentives alone may not be sufficient to achieve these sustainability goals, which is why genetic diversity and conservation should be included explicitly in sustainable development goals and UN biodiversity targets. “From an economist’s perspective, fishing should have largely avoided undesired evolutionary changes. Now that these changes have taken place, they are costly to reverse in the short run, but in the long run, this would pay off in economic terms.”

 

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

Kati Kietzmann


Original publication
(Researchers with iDiv affiliation are in bold)

Hanna Schenk, Fabian Zimmermann, Martin Quaas (2023). The Economics of reversing fisheries-induced evolution. Nature Sustainability. Doi: 10.1038/s41893-023-01078-9

 

Contact:

Dr Hanna Schenk
Biodiversity Economics
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 9733168
Email: hanna.schenk@idiv.de

 

Prof Dr Martin Quaas
Head of research group Biodiversity Economics
German Centre for Integrative Biodiversity Research (iDiv)
Leipzig University
Phone: Please contact the iDiv Media and Communications department
Email: martin.quaas@idiv.de

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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Research iDiv TOP NEWS Media Release Biodiversity Economics Thu, 16 Mar 2023 00:00:00 +0100
Dwarfs and giants on islands more likely to go extinct https://idiv-biodiversity.de//en/news/news_single_view/5110.html Higher extinction rates of insular mammals after arrival of modern human Higher extinction rates of insular mammals after arrival of modern human

Leipzig/Halle. Islands are “laboratories of evolution” and home to animal species with many unique features, including dwarfs that evolved to very small sizes compared to their mainland relatives, and giants that evolved to large sizes. A team of researchers led by the German Centre for Integrative Biodiversity Research (iDiv) and Martin Luther University Halle-Wittenberg (MLU) has now found that species that evolved to more extreme body sizes compared to their mainland relatives have a higher risk of extinction than those that evolved to less extreme sizes. Their study, which was published in Science, also shows that extinction rates of mammals on islands worldwide increased significantly after the arrival of modern humans. 

Islands are hotspots for biodiversity – they cover less than 7% of the Earth’s land area, but account for up to 20% of all terrestrial species on the planet. However, islands are also hotspots for species extinction as 50% of today’s IUCN threatened species are native to islands. 

In response to the unique characteristics of island environments, many organisms undergo remarkable evolutionary changes, among the most notable of which include extreme modifications of body size. This phenomenon is known as gigantism or dwarfism – in general, relatives of large continental species tend to become smaller on islands and small species tend to become larger. Some of these are already extinct evolutionary marvels such as dwarf mammoths and hippos that shrunk to less than one-tenth the size of their mainland ancestors, and rodents and gymnures of unusual size that increased by over 100-fold. These also include dwarf and giant species currently threatened with extinction, such as the tamaraw of Mindoro (Bubalus mindorensis), a dwarf buffalo with a shoulder height of approximately 100 cm, and the giant Jamaican hutia (Geocapromys brownii), a rat-like mammal about the size of a rabbit. 

A team of researchers led by iDiv and MLU now confirmed that evolution towards these features frequently goes hand in hand with increased susceptibility to extinctions. “On the one hand, phyletic giants might provide bigger reward for hunting”, explains Dr Roberto Rozzi, former postdoctoral researcher at iDiv’s synthesis centre sDiv and at the Berlin Museum of Natural History, and now Curator of Palaeontology at the ZNS of Martin Luther University Halle-Wittenberg. “On the other hand, dwarfed species seem to have less deterrence power, facilitating hunting or predation by introduced predators.”

Higher extinction risk of extreme dwarfs and giants

To quantify how evolution towards dwarfism and gigantism may have affected the risk and rate of extinction (before and after human arrival), the researchers used data on fossil and living island mammals including over 1,200 extant and 350 extinct species of insular mammals on 182 islands and paleo-islands (formerly isolated landmasses that are now part of the mainland areas) worldwide.

Their findings indicate a previously unknown result that those species that underwent more extreme body size shifts, either larger or smaller, were more likely to be endangered or to go extinct on islands. Comparison between the two directions of body size change showed that insular giant species have a slightly higher extinction risk than insular dwarfs. However, this difference was only significant when extinct species were included. Since the European expansion around the globe, extinctions have similarly affected dwarfed and giant insular mammals. “This likely reflects the impact of more intense and multifaceted human pressures, such as overexploitation and accelerated habitat loss, but also introductions of novel diseases and invasive predators”, says Dr Roberto Rozzi.

Overlap of human colonization and increased extinction rates of insular mammals

The researchers also analysed the global fossil record of mammals on islands over the last 23 million years (late Cenozoic) and found a clear correlation between island extinctions at a global level and the arrival of modern humans. “We recorded an abrupt shift in the extinction regime from pre-sapiens to sapiens-dominated island ecosystems. Time overlap of insular mammals with H. sapiens increased their extinction rates more than 10-fold. However, our results at the global level do not rule out the concomitant contribution of environmental drivers such as climate change on local extinctions of island mammals”, says senior author Prof Jonathan Chase from iDiv and MLU. “While it is important to acquire more paleontological field data to further refine extinction chronologies, conservation agendas should, at the same time, give special priority to protecting the most extreme insular giants and dwarfs, many of which are already threatened with extinction.”

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

Kati Kietzmann

 

Original publication
(Researchers with iDiv affiliation and alumni are in bold)

Roberto Rozzi, Mark V. Lomolino, Alexandra A. E. van der Geer, Daniele Silvestro, S. Kathleen Lyons, Pere Bover, Josep A. Alcover, Ana Benítez-López, Cheng-Hsiu Tsai, Masaki Fujita, Mugino O. Kubo, Janine Ochoa, Matthew E. Scarborough, Samuel T. Turvey, Alexander Zizka, Jonathan M. Chase (2023). Dwarfism and gigantism drive human-mediated extinctions on islands. Science. DOI: 10.1126/science.add8606

 

Contact:

Dr Roberto Rozzi
Zentralmagazin Naturwissenschaftlicher Sammlungen
Martin Luther University Halle-Wittenberg
Phone: +49(0)345 55-26073
Email: roberto.rozzi@zns.uni-halle.de

 

Prof Dr Jonathan Chase
Head of the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733120

Email: jonathan.chase@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/synthesis.html

 

Kati Kietzmann
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9739222
Email: kati.kietzmann@idiv.de

 

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iDiv TOP NEWS Media Release Biodiversity Synthesis Thu, 09 Mar 2023 00:00:00 +0100
Global climate data insufficiently explain composition of local plant species https://idiv-biodiversity.de//en/news/news_single_view/5114.html The effects of climate change on the Earth’s vegetation depend to a large degree on local conditions The effects of climate change on the Earth’s vegetation depend to a large degree on local conditions

Based on a media release of Martin Luther University Halle-Wittenberg

The global climate influences regional plant growth – but not to the same extent in all habitats. This finding was made by geobotanists at Martin Luther University Halle-Wittenberg (MLU) and members of the German Centre for Integrative Biodiversity Research (iDiv) after analysing over 300,000 European vegetation plots. Their conclusion: No general prediction can be made about the effects of climate change on the Earth’s vegetation; instead, the effects depend to a large degree on local conditions and the habitat under investigation. The findings were published in the renowned journal Nature Communications.

Ever since Alexander von Humboldt’s voyages of exploration, it has been clear that the characteristics of plants depend heavily on the Earth’s climate zones. For example, giant trees and plants with enormous leaves can be found in tropical rainforests, while desert or subarctic vegetation grows lower to the ground and has smaller leaves to withstand drought or cold temperatures. Climate change is causing these zones to shift – raising questions as to how higher temperatures and altered periods of precipitation affect the composition of plant species at a given location. “Studies have found relatively weak correlations between global climate gradients and the characteristics of local plant communities,” explains Dr Stephan Kambach, research associate at MLU and former postdoctoral researcher at iDiv. “It is possible that the global effects are being obscured by local factors such as plant composition, soil conditions, microclimate, groundwater levels or human land use.” 

To get to the heart of this phenomenon, the researchers have compiled over 300,000 vegetation plots from all over Europe that contain complete information on the predominant plant species and climate data. This has been done as part of the Biodiversa programme “FeedBaCks”. The raw data were taken from the CHELSA climate database and the European Vegetation Archive (EVA), which includes over 1.7 million vegetation plots of nearly 14,000 plant species. “First, we examined nine main types of habitats, for example forests, moorlands or wetlands,” explains Kambach. “Then we subdivided these habitats into two additional sub-levels, for example deciduous forests on the second level and poplar floodplain forests on the third level.” In order to compare the vegetation in the different habitats, four key vegetation characteristics were defined: height of growth, leaf area, root length and seed mass. 

Stephan Kambach used linear regression to investigate the influence of climate variables, especially temperature and precipitation, on vegetation. Linear regression is a statistical tool that can be used to describe major dependencies between influencing and target variables. The analysis revealed some surprising results: When all vegetation types are considered, climate is a significant predictor of plant characteristics. In the Mediterranean region or along Europe’s coasts, plants grow taller on average, produce more seed mass and have longer roots, however their leaf area is smaller. A look at the individual habitats, however, reveals exceptions: In forests, for example, plant height decreases as temperatures increase, in wetlands the leaf area is getting larger, and in moorlands the roots are getting shorter. “Here the opposing influences between the trends at the global and local levels become apparent,” explains Professor Helge Bruelheide, who heads the FeedBaCks project at MLU and is also an iDiv Member.  “In southern regions, growth is generally facilitated by a higher light intensity and longer growing seasons, however decreased availability of water can lead to the opposite effect in certain habitats. In contrast, low levels of precipitation seem to have little effect on wetlands.” 

The more one “zooms in” on the habitats, the harder it is to make generalisations about climate effects. “When it comes to leaf area and root length, climate appears to have a strong effect in more tightly defined habitats,” says Kambach. “But what we see in the main habitat types is not necessarily reflected in the subtypes.” For example, the analysis revealed that the mean height of growth in grasslands increases towards the Mediterranean, but not in seasonally wet meadows. The situation is similar in wetlands: Here, plants grow taller as temperatures increase, but this is not the case in exposed riparian zones. 

“We were able to show that the global climate is definitely a significant indicator for local plant communities,” states Kambach. “However, if we want to prepare for changing climate conditions, especially in agriculture and forestry, we have to look very closely at habitats with similar floristic compositions, a common evolutionary history, and comparable environmental conditions.” 

A total of seven European partner institutions are taking part in the FeedBaCks project (Feedbacks between Biodiversity and Climate, biodiv-feedbacks.org), which is coordinated at WSL in Zurich. The general aim of the project is to investigate the feedback mechanisms of biodiversity on climate. 

 

Original Publication
(Researchers with iDiv affiliation and alumni are in bold)

Stephan Kambach, Francesco Maria Sabatini, Fabio Attorre, Idoia Biurrun, Gerhard Boenisch, Gianmaria Bonari, Andraž Čarni, Maria Laura Carranza, Alessandro Chiarucci, Milan Chytrý, Jürgen Dengler, Emmanuel Garbolino, Valentin Golub, Behlül Güler, Ute Jandt, Jan Jansen, Anni Jašková, Borja Jiménez-Alfaro, Dirk Nikolaus Karger, Jens Kattge, Ilona Knollová, Gabriele Midolo, Jesper Erenskjold Moeslund, Remigiusz Pielech, Valerijus Rašomavičius, Solvita Rūsiņa, Jozef Šibík, Zvjezdana Stančić, Angela Stanisci, Jens-Christian Svenning, Sergey Yamalov, Niklaus E. Zimmermann, Helge Bruelheide (2023). Climate-trait relationships exhibit strong habitat specificity in plant communities across Europe, Nature Communications, DOI.org/10.1038/s41467-023-36240-6

 

Contact:

Dr Stephan Kambach
Martin Luther University Halle-Wittenberg
German Center for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: stephan.kambach@botanik.uni-halle.de

 

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Media Release iDiv Members MLU News Research TOP NEWS Thu, 09 Mar 2023 00:00:00 +0100
Plant roots fuel tropical soil animal communities https://idiv-biodiversity.de//en/news/news_single_view/5112.html New study reveals that living roots are as important as dead leaves in sustaining tropical soil... New study reveals that living roots are as important as dead leaves in sustaining tropical soil biodiversity

Based on a media release by the University of Göttingen

Göttingen/Leipzig. Soil animal communities in the tropics are driven by plant roots and the resources derived from them. This is the main finding of a new study of a research team led by the University of Göttingen, the German Centre for Integrative Biodiversity Research (iDiv) and Leipzig University. Millions of small creatures toiling in a single hectare of soil including earthworms, springtails, mites, insects, and other arthropods are crucial for decomposition and soil health. For a long time, it has been believed that leaf litter is the primary resource for these animals. However, this recent study published in the journal Ecology Letters shows that litter doesn’t play any crucial role at all for the tropical soil fauna.

The researchers isolated plots within natural ecosystems and separated the plots from accessing plant roots with a plastic barrier (a technique known as ‘root trenching’). Their study included rainforest, as well as both rubber and oil palm plantations in Sumatra, Indonesia. As a comparison, they removed all dead leaves, the main resource of decomposer animals, from other experimental plots. They found that without living roots, animal abundance in the rainforest plots decreases by 42 percent and in plantations by 30 percent. 

By contrast, removing the dead leaves has almost no effect on the animals in the underlying soil, but decreased the total animal abundance (in the soil and dead leaves) by 60 percent in rainforest and rubber plantations due to physical litter removal. However, the effects of plant litter removal were not observed in oil palm plantations, where litter is very scarce in any case. The study also revealed that living roots are especially important for the smaller soil animals, such as mites and springtails. Interestingly, after adding artificial plastic leaves in oil palm plantations, abundance of some animal groups – such as prostigmata – increased, highlighting that improving habitat structure, for instance by mulching, can promote soil food networks and the services they provide.

“The study provides novel perspectives for the management of the resources provided by plant litter in tropical plantations, fostering soil animal biodiversity. This is important to develop sustainable agricultural landscapes in the tropics,” says Professor Stefan Scheu, head of the Animal Ecology Working Group at the University of Göttingen.

“This study's findings are significant not only for the conservation of tropical soil biodiversity, but also for the development of global ecosystem models describing carbon cycling in the tropics. We need a better understanding of the complex ecological systems that support life on Earth,” adds Dr Anton Potapov, head of the ‘Soil Biodiversity and Functions’ research group at the German Centre for Integrative Biodiversity Research (iDiv). 

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

 

Original publication: 
(Researchers with iDiv affiliation bold)

Zheng Zhou, Jing-Zhong Lu, Jooris Preiser, Rahayu Widyastuti, Stefan Scheu, Anton Potapov (2023): Plant roots fuel tropical soil animal communities. Ecology Letters, DOI: 10.1111/ele.14191

 

Contact:

Dr Anton Potapov
Head of Junior Research Group "Soil Biological Diversity and Functions"
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Email: anton.potapov@idiv.de

 

Sebastian Tilch
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33197
Email: sebastian.tilch@idiv.de
Web: https://www.idiv.de/media

 

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TOP NEWS Media Release Tue, 07 Mar 2023 00:00:00 +0100
European conservation leaders gather to boost collective dialogue for a Trans-European Nature Network https://idiv-biodiversity.de//en/news/news_single_view/5108.html NaturaConnect Stakeholder Event in Brussels brings over 70 leading EU policy and governmental... NaturaConnect Stakeholder Event in Brussels brings over 70 leading EU policy and governmental decision-makers

Based on a media release by the International Institute for Applied Systems Analysis (IIASA)

Brussels, 28 February 2023. More than 70 leading EU policy and governmental decision-makers joined to lay the foundation for a bold new vision for Europe's nature protection in the first NaturaConnect Stakeholder Event this year. Organised by the Horizon Europe NaturaConnect project, the event welcomed a diverse range of influential stakeholders, from country representatives to European Union delegates and international and European conservation organisations. At the heart of the NaturaConnect project is the goal of supporting the creation of a Trans-European Nature Network (TEN-N) of protected and connected areas that conserve at least 30% of land in the EU and benefit both nature and people. The new project is conducted by international partners from research and environmental organisations, led by the International Institute for Applied Systems Analysis (IIASA), the German Centre for Integrative Biodiversity Research (iDiv) and the Martin-Luther University Halle-Wittenberg (MLU).

By providing technical support and data, tools and knowledge, NaturaConnect can help EU Member States revise their protected area pledges and implement them on the ground. NaturaConnect is also tasked with assisting with the evaluation of the first round of Member States’ protected area pledges under the EU Biodiversity Strategy for 2030. In an ambitious and far-reaching program of measures, the Strategy aims to halt and reverse biodiversity loss in the EU. The event provided participants with the chance to initiate conversations between actors from science, public administration, and non-governmental organizations, to engage in dialogue aimed at determining how to implement the EU Biodiversity Strategy for 2030, including the design and management of the TEN-N. 

Neil McIntosh, representing the EUROPARC Federation, welcomed participants to the event, noting that the day would be focused on “building the dialogue necessary to protect and preserve biodiversity, and connect areas, nature and people, through a variety of participatory processes.”

As a representative of NaturaConnect's leading organization, Piero Visconti from the International Institute for Applied Systems Analysis (IIASA) emphasised NaturaConnect's key role in supporting EU Member States in their TEN-N design.

The participants then had small group discussions on what the specific needs are for the realisation of a coherent and resilient TEN-N. Governance and financial gridlocks were extensively discussed. Among the key takeaways from the session on the future TEN-N were the value of co-creation of knowledge and guidance for TEN-N together with those responsible for planning and implementation and the need for a long-term perspective on area-based conservation planning in Europe, which prioritizes the quality of conserved areas. 

"The ample engagement in this event of members from the European Commission, National administrations and NGOs demonstrates great policy expectations and interest in the scientific outputs that the NaturaConnect will offer", said the project's deputy coordinator Néstor Fernández from iDiv and MLU. 

Frank Vassen from the European Commission Directorate-General for Environment highlighted the critical role that science, and this project in particular, will have in supporting effective protected area policies in Europe.

Background: 

NaturaConnect aims to design and develop a blueprint for a truly coherent Trans-European Nature Network (TEN-N) of conserved areas that protect at least 30% of land in the European Union, with at least one-third of it under strict protection. Our project unites universities and research institutes, government bodies and non-governmental organizations, working together with key stakeholders to create targeted knowledge and tools and build the capacity needed to support European Union Member States in realising an ecologically representative, resilient and well-connected network of conserved areas across Europe.


Contact:

naturaconnect@iiasa.ac.at

www.naturaconnect.eu

 

Contact:

Sebastian Tilch
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33197
Email: sebastian.tilch@idiv.de
Web: https://www.idiv.de/media

 

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TOP NEWS Biodiversity Conservation Media Release Wed, 01 Mar 2023 00:00:00 +0100
How does biodiversity change globally? Detecting accurate trends may be currently unfeasible https://idiv-biodiversity.de//en/news/news_single_view/5070.html Study finds that current monitoring data may be far too incomplete and deficient to provide a... Study finds that current monitoring data may be far too incomplete and deficient to provide a precise global picture of local biodiversity richness trends

Leipzig/Halle. Existing data are too biased to provide a reliable picture of the global average of local species richness trends. This is the conclusion of an international research team led by the German Centre for Integrative Biodiversity Research (iDiv) and the Martin Luther University Halle-Wittenberg (MLU). The authors recommend prioritising local and regional assessments of biodiversity change instead of attempting to quantify global change and advocate standardised monitoring programmes, supported by models that take measurement errors and spatial biases into account. The study was published in the journal Ecography

The global loss of biodiversity has been recognised by society and politicians as one of the most urgent challenges facing humanity in the coming generations. At the World Biodiversity Conference COP15 that recently took place in Montréal, the member states of the UN Convention on Biological Diversity (CBD) adopted new goals and rules accordingly to slow down and eventually reverse this decline. In order to be able to measure the successes of this new agreement, one of these targets calls for improved biodiversity monitoring to record and evaluate trends.

While there are many different ways to measure biodiversity, the most common is species richness at the local scale. However, although species are being lost at alarming rates at the global level, this does not always reflect what is occurring at the local scale. Previous global syntheses have indicated conflicting results on the extent and even direction to which local species richness is changing. 
“There has been a heated debate on the scientific community on why major global syntheses so far have not found negative trends of local species richness,” states Prof Henrique Pereira, head of the Biodiversity and Conservation Research Group at iDiv and MLU and last author of the study. “We show that the declines in local species richness are likely to be much smaller than many anticipated and that, in those conditions, even minor spatial biases and errors in monitoring lead to the lack of detection of global trends.”

In order to create a global picture of what is occurring at the local scale, all available observation data must be compiled and evaluated across time. “The occurrence of species is recorded locally all over the world by many different people and organisations,” says first author Dr Jose Valdez, a postdoctoral researcher at iDiv and MLU. “The problem with the data is that they were and are recorded under completely different conditions and mostly not under standardised rules. If you then pile them together, the errors and deviations add up, making the result very inaccurate.”

The researchers were able to show that the monitoring results are significantly influenced by various factors, such as the time intervals between sampling, the size of the sampling sites, or small errors in counting the number of species at a site. A significant problem in recording global biodiversity trends is also the regional imbalance. For example, most of the data is collected in world regions such as Europe and the United States, particularly habitats such as temperate deciduous and mixed forests. The underrepresentation of the tropical regions and habitats, areas with the highest species richness and also the largest losses, can lead to a significantly distorted impression of the global biodiversity status.

To find out whether and how these biases can be compensated for, the researchers simulated thousands of monitoring networks that varied in the above-mentioned factors. The basis for this was provided by the PREDICTS projections of local species richness trends, based on a model developed with a globally comprehensive compilation of data from over 32,000 sites worldwide and over 51,000 species. The researchers found that global changes in biodiversity could theoretically be determined in hundreds of perfectly sampled sites within a decade and thousands of sites within a 3-year period.

Changes in species richness on a global scale only detectable with unrealistically many sampling sites

However, perfect sampling does not exist in reality. Studies show that monitoring data typically contain 10% to 30% errors due to missing or misidentifying species during sampling. By just adding very small measurement errors of up to 5%, the researchers found that it drastically reduced the ability to detect any global change. With more realistic errors and further imprecision factors, detecting the average global trend may simply be impossible.

“Our results demonstrate that capturing accurate trends in local species richness would require monitoring an unfeasibly large number of perfectly sampled sites,” adds Jose Valdez. “However, the question is whether this would even be useful or meaningful for effective and responsive biodiversity conservation. Conservation strategies and measures are coordinated and implemented not on a global level, but at local and national scales. Measuring biodiversity trends at these smaller scales is not only more practical but also helps in understanding the drivers of biodiversity loss and assessing the progress of conservation policies.”

“A substantial increase of biodiversity monitoring is needed, combined with analysis that uses models to fill in data gaps”, says Henrique Pereira. The authors advise establishing a representative network of sampling sites around the world that provides independent, integrated, and regularly updated biodiversity data. Such an approach is currently being developed for the European Union with the EuropaBON project.

This research was funded by the German Research Foundation (DFG; FZT-118) and the European Union's Horizon 2020 research and innovation programme EuropaBON Project under grant agreement number 101003553.
Sebastian Tilch

Original publication:
(Researchers with iDiv affiliation and alumni in bold)
Valdez, J., Callaghan, C.T., Junker, J., Andy Purvis, Samantha L.L. Hill, Pereira, H. M. (2022): The undetectability of global biodiversity trends using local species richness. Ecography, DOI: 10.1111/ecog.06604

 

Contact:

Dr Jose W. Valdez (speaks English and Spanish)
Postdoctoral Researcher
Research group Biodiversity Conservation
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9739168
Email: jose.valdez@idiv.de
Web: https://www.idiv.de/en/profile/1290.html

 

Prof Dr Henrique Miguel Pereira (speaks English and Portuguese)
Head of Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Email: henrique.pereira@idiv.de
Web: https://www.idiv.de/en/profile/132.html

 

Sebastian Tilch
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33197
Email: sebastian.tilch@idiv.de
Web: https://www.idiv.de/media

 

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Biodiversity Conservation TOP NEWS Media Release Fri, 10 Feb 2023 00:00:00 +0100
How could we evolve such a huge brain? https://idiv-biodiversity.de//en/news/news_single_view/5098.html Specialised foraging skills could have made the essential difference Specialised foraging skills could have made the essential difference

Based on a media release by the University of Amsterdam

Amsterdam/Leipzig/Jena. A new study, published in the journal Frontiers in Ecology and Evolution, investigated the foraging behaviour of children in a present-day forager society. Already from an early age, there was a gender-specific development of foraging skills. These new findings, combined with the high level of food sharing in forager societies, support the embodied capital theory, offering an explanation for the substantially larger brains in humans. Foraging skills could have provided humans with a more stable energy and nutrient supply, which may ultimately have enabled large resource investments into the brain. The research was led by the University of Amsterdam (UvA), the German Centre for Integrative Biodiversity Research (iDiv), the Max Planck Institute for Evolutionary Anthropology, the Helmholtz Centre for Environmental Research (UFZ), and the Friedrich Schiller University Jena. 

Humans have brains three times the size of other primate species. A diverse, high-quality diet and a prolonged childhood with sufficient time to learn complex food acquisition skills are thought to be important evolutionary drivers of our large brains. In contrast to the diet of other primates, the human diet is characterised by a diverse variety of high-quality and difficult-to-acquire foods, such as meat and fish, as well as tubers or many species of nuts and caterpillars. To collect these, complex foraging skills are needed that are thought to be developed from an early age. 

To better understand how humans learn these foraging skills, the international research team accompanied 27 children of a modern forager society, the BaYaka, in the Republic of the Congo for one year. The children start foraging independently in peer groups from as young as five years old. The researchers investigated the children’s foraging methods, dietary composition, and botanical knowledge on their daily food-finding trips. Besides observing the behaviour, they also conducted nutritional analyses of the collected food. To achieve this, the researchers set up an interdisciplinary collaboration between a botanist and cognitive behavioural ecologists from the University of Leiden and Amsterdam, chemical ecologists from iDiv, the University of Jena, and UFZ, anthropologists from the Max Planck Institute for Evolutionary Anthropology in Leipzig and nutritional ecologist from the Charles Perkins Centre from the University of Sydney. The fieldwork resulted in a unique dataset containing 798 hours of observational data.

The BaYaka children spent one-third of their time searching and acquiring food. Half of that time, they searched independently from adults and showed a high level of autonomy. “I was impressed to see how skilled the children were already at a very young age”, says Jorin Veen, first author of the paper, who performed this study for his Master thesis at the UvA. “The largest share of the food were fallen fruits, seeds, and tubers, but the children also climbed 40 meters high trees to collect honey or fruits, which can be a risky endeavour.” 

Differences between boys and girls

The results revealed an early onset in the specialisation in foraging skills. Foraging groups with more boys were more likely to eat fruits and seeds, which often requires risky climbing skills. Girls were more likely to collect tubers than boys. “Collecting tubers requires exceptional digging skills, as the lianas that lead to tubers are not easy to recognize and keep track off”, explains Prof Karline Janmaat, supervisor of the lead author and researcher at the Institute for Biodiversity and Ecosystem Dynamics at the UvA. “This early onset of a gendered-based specialisation of foraging skills, combined with the high level of food sharing in forager societies, likely enabled the human species to have a more stable energy and nutrient supply – a supply that could have ultimately enabled us to afford a substantially larger brain than our closest living relatives.” 

“Our analyses revealed that especially the fruits, which made up 40 per cent of the children’s diet, contained more sugars, especially glucose and fructose, compared to other plant items”, says co-author Prof Nicole van Dam. “No wonder that they put so much effort into obtaining them.” Van Dam, who led the molecular analyses, headed the Molecular Interaction Ecology group at iDiv and the University of Jena until 2022, when she became the director of the Leibniz Institute of Vegetable and Ornamental Crops (IGZ) in Grossbeeren. 

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

 

Original publication:
(Researchers with iDiv affiliation and alumni in bold)

Jorin Veen, Haneul Jang, David Raubenheimer, Bryndan O.C.M. van Pinxteren, Vidrige Kandza, Patrick G. Meirmans, Nicole M. van Dam, Susanne Dunker, Petra Hoffmann, Anja Worrich, Karline R.L. Janmaat (2023) Development of embodied capital: diet composition, foraging skills, and botanical knowledge of forager children in the Congo Basin”, Frontiers in Ecology and Evolution. DOI: 10.3389/fevo.2023.935987

 

Contact:

Jorin Veen
Department of Theoretical and Computational Ecology
Institute for Biodiversity and Ecosystem Dynamics (IBED)
University of Amsterdam
Email: jorinveen@outlook.com

 

Prof Dr Nicole van Dam
Leibniz Institute for Vegetable and Ornamental Crops (IGZ)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Friedrich Schiller-University Jena
Email: nicole.vandam@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/van_dam_nicole.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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Physiological Diversity Media Release TOP NEWS Molecular Interaction Ecology Thu, 09 Feb 2023 00:00:00 +0100
Plant diversity may never fully recover from agriculture without a helping hand https://idiv-biodiversity.de//en/news/news_single_view/5078.html Even many years after being abandoned, plant diversity of former agricultural sites is still... Even many years after being abandoned, plant diversity of former agricultural sites is still incomplete compared to undisturbed sites

Leipzig/Minnesota. Agriculture is considered a major disturbance for ecological systems – the recovery of degraded or formally used agricultural land might take a long time. However, without any active restoration interventions, this recovery can take an exceedingly long time and is often incomplete, as shown by a team of researchers led by the German Centre for Integrative Biodiversity Research (iDiv), Leipzig University (UL), Martin Luther University Halle-Wittenberg (MLU) and the Helmholtz Centre for Environmental Research (UFZ). Their study, which was published in the Journal of Ecology, sheds light on the recovery process at different scales in former agricultural sites, pointing to specific restoration interventions that could help biodiversity to recovery.

Land use such as transforming natural habitats into agricultural areas is the most important driver for biodiversity loss worldwide. However, one might assume that, given enough time, removal of major anthropogenic disturbances will allow biodiversity to recover. Ecological restoration is the science and practice of directing and speeding up the recovery of disturbed ecosystems. In accordance with Target 2 of the recently adopted Global Biodiversity Framework of the UN Convention on Biodiversity (CBD), at least 30% of areas of degraded terrestrial, inland water, and coastal and marine ecosystems should be under effective restoration by 2030.

To find out more about this recovery process in former agricultural sites, the researchers measured the recovery of biodiversity and species composition in 17 temperate grasslands in Minnesota (US). These grasslands were ploughed and used for agriculture, but different fields were abandoned between 1927 and 2015 so that natural succession and recovery of the vegetation could be followed. The researchers compared these abandoned sites to sites that were never ploughed, which acted as a reference and for what natural systems could look like. “What we wanted to know was how fast and how completely disturbed grasslands can regain their biodiversity if they are left to recover. Understanding that recovery process can give us insights into how we can assist and speed it up using restoration”, says first author Dr Emma Ladouceur from iDiv, MLU and UL, who is also a guest researcher at the UFZ.

After 80 years, species richness was still lagging behind

The researchers found that even after 80 years, the abandoned fields had not recovered on their own compared to never-ploughed sites. The number of different species in old fields was on average 65% of that in never-ploughed sites. In addition, the types of plant species that lived at the site recovered over time, but not completely. When the fields were first recovering, they were colonised by species that were unique to old field sites, like many weedy and disturbance-tolerant species. After some time, many species characteristic of the never disturbed sites colonized and increased through time. However, across the whole study, there were 63 native species unique to the never-ploughed sites, and the recovering old fields had more introduced grasses and weeds.

In their study, the researchers focused on the recovery of old fields without any active restoration efforts to promote this process. With the help of this information, restoration actions can be designed to help these systems better recover. “By looking closely at the recovery of species composition at different scales, we can get a better idea of what species could be targeted in restoration treatments, and how we could help these systems recover best”, explains co-author Prof Dr Stan Harpole, head of the Physiological Diversity research group at UFZ, iDiv, and MLU. “Specific restoration measures could include the seeding or planting of species that we know are not part of the composition of recovering fields, combined with the management of exotic species to reduce competition with native species”, adds Dr Emma Ladouceur.

Informed advice for policy

“With our study, we show that using valuable and rare data across a long-time scale and looking at important spatially-dependent patterns can lead to practical outcomes that are directly relevant for policy. For example, our results can be used to provide important context for understanding restoration outcomes and targets as part of international forums such as the recent United National Biodiversity Conference (COP15)”, says senior author Prof Dr Jonathan Chase, head of the Biodiversity Synthesis research group at iDiv and MLU.


This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118).

Kati Kietzmann

 

Original publication
(iDiv researchers and alumni in bold)

Ladouceur, Emma; Forest, Isbell; Clark, Adam; Harpole, W. Stanley; Reich, Peter; Tilman, David; Chase, Jonathan (2023); The recovery of plant community composition following passive restoration across spatial scales. Journal of Ecology, DOI: 10.1111/1365-2745.14063

 

Contact:

Dr Emma Ladouceur
Postdoctoral Researcher in the Physiological Diversity & Biodiversity Synthesis Research Groups
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Helmholtz Centre for Environmental Research – UFZ
Alexander von Humboldt Foundation
Martin Luther University Halle-Wittenberg
Leipzig University
Phone: +49 341 9733255
Email: emma.ladouceur@idiv.de

 

Prof Dr Jonathan Chase
Head of the Biodiversity Synthesis research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg
Phone: +49 341 9733120

Email: jonathan.chase@idiv.de
Web: https://www.idiv.de/en/groups-and-people/core-groups/synthesis.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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Biodiversity Synthesis Physiological Diversity TOP NEWS Media Release Tue, 07 Feb 2023 00:00:00 +0100
76 per cent of assessed insect species not adequately covered by protected areas https://idiv-biodiversity.de//en/news/news_single_view/5096.html Researchers propose to consider insects in the expansion and new designation of protected areas Researchers propose to consider insects in the expansion and new designation of protected areas

Leipzig/Jena. Insect numbers have been declining over the past decades in many parts of the world. Protected areas could safeguard threatened insects, but a team of researchers led by the German Centre for Integrative Biodiversity Research (iDiv), the Helmholtz Centre for Environmental Research (UFZ), the Friedrich Schiller University Jena and the University of Queensland now found that 76 per cent of globally assessed insect species are not adequately covered by protected areas worldwide. In the journal One Earth, the researchers encourage decision-makers to give more consideration to the by far biggest species group in implementing the new goals of the UN Convention on Biological Diversity.

Over 80 per cent of all animal species are estimated to be insects. This species group plays crucial roles in almost every ecosystem. Insects pollinate more than 80 per cent of plants, play a key role in the natural nutrient cycle and in pest control, and are a major source of food for thousands of vertebrate species. However, insects have been historically overlooked by conservation programmes, and they comprise only 8 per cent of the species assessed for the IUCN Red List of Threatened Species. 

Previous studies proved that protected areas can preserve insect populations if they are tailored to that goal and coincide with their distribution areas. To determine what proportion of insect species is covered by protected areas, a team of researchers led by iDiv, UFZ and the Universities of Jena and Queensland overlaid species distribution data of 89,151 insect species registered in the largest biodiversity data repository, the Global Biodiversity Information Facility (GBIF), with global maps of protected areas. A benchmark for sufficient species coverage by protected areas is provided by the IUCN Global Standards for the Identification of Key Biodiversity Areas. 

The researchers found that 76 per cent of these insect species are inadequately represented in protected areas, including several critically endangered species such as the Australian dinosaur ant (Nothomyrmecia macrops), the crimson Hawaiian damselfly (Megalagrion leptodemas), and the harnessed tiger moth (Apantesis phalerata). Furthermore, the global distributions of 1,876 species from 225 families do not overlap with protected areas at all. 

First author Dr Shawan Chowdhury, a postdoctoral researcher at iDiv, the UFZ, and the University of Jena, was surprised by the degree of underrepresentation. “A lot of insect data come from protected areas, so we thought that the proportion of species covered by protected areas would be higher,” says Chowdhury. “The shortfall is also much more severe than for vertebrate species, for which a similar analysis found that 57 per cent were inadequately covered.”

In some regions, insects were better protected than others. Relatively high proportions of insect species received adequate protection in Amazonia, South and Central America, Sub-Saharan Africa, Western Australia and Central Europe, but protection fell short for many species in North America, Eastern Europe, South and Southeast Asia and parts of Australia.

“Insects have often been neglected as a focal group when designating new protected areas,” says Chowdhury. “The focus is usually on vertebrates, and their requirements for habitat are usually quite different from insects. For a species group that contains a vast proportion of the animal kingdom and performs diverse ecosystem functions, that is worrying.”

The member states of the UN Convention on Biological Diversity (CBD) just have approved a new Global Biodiversity framework. Target 3 calls for at least 30 per cent of terrestrial, inland water, and coastal and marine areas to be effectively conserved through protected areas. According to the authors, insects should be given much more consideration in the selection and planning of new areas.

“However, in order to implement this globally and to effectively evaluate success, much better data is needed, especially in regions with high biodiversity, such as the tropics, which have so far been completely underrepresented in monitoring programmes,” says senior author Prof Richard Fuller from the University of Queensland. “Citizen science could have an enormous impact in filling the data gap on insect distributions. Scientists and policymakers must now step up and help with this challenge of identifying sites of importance for insect conservation.”

This research was financed inter alia by the Deutsche Forschungsgemeinschaft (DFG; FZT-118). It is a product of the sDiv working group sMon. iDiv’s synthesis centre sDiv supports working group meetings where international scientists work together on scientific issues.
Sebastian Tilch

Original publication:
(Researchers with iDiv affiliation in bold)

Chowdhury, S., Zalucki, M. P., Hanson, J. O., Tiatragul, S., Green, D., Watson, J. E. M., Fuller, R. A. (2023): Three quarters of insect species are insufficiently represented by protected areas. One Earth. DOI: 10.1016/j.oneear.2022.12.003

 

Contact:

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Media Release TOP NEWS Biodiversity and People Wed, 01 Feb 2023 00:00:00 +0100
Implementing global biodiversity targets in Germany – with support from research https://idiv-biodiversity.de//en/news/news_single_view/5085.html iDiv invited to a parliamentary evening in Berlin to discuss possible action iDiv invited to a parliamentary evening in Berlin to discuss possible action

Berlin. Implementation of the recently agreed UN nature conservation targets will only succeed if all stakeholders – from policy and practice, civil society, business and science - work together. Science provides the knowledge base for effective action, thus playing a key role in the implementation of these global objectives. This was the tenor of discussion at the parliamentary evening on 17 January in the State Representation of Saxony-Anhalt in Berlin, to which the German Centre for Integrative Biodiversity Research (iDiv) and the Saxony-Anhalt Ministry of Science, Energy, Climate Protection and the Environment had invited. The scientists call for a high-level national biodiversity council as an essential element in making the conservation of biological diversity a core political issue across all relevant ministries. 

It is about nothing less than the very foundations of life. Many animal and plant species are threatened with extinction. Many ecosystems are under pressure. With them, the services which biological diversity provides, and on which human well-being depends, are in danger of disappearing. To reverse the decline in global biodiversity loss, the 196 member states of the UN Convention on Biological Diversity (CBD) adopted a new agreement on biodiversity, setting global targets up to 2030 at the COP15 UN Biodiversity Conference in Montréal last December.

“We now have good, ambitious international biodiversity goals, which the German government has also helped to promote,” says iDiv Professor Aletta Bonn, head of the Department of Ecosystem Services at the Helmholtz Centre for Environmental Research (UFZ), iDiv and Friedrich Schiller University Jena. However, experience shows that even the best and most ambitious global targets are pointless if they are not implemented at the national level with effective measures involving stakeholders from all areas of society. “We must now actively push ahead with the implementation of these global targets. This can only succeed if policy, business, civil society and research work together and invest ambitiously in our environment in order to safeguard our health, and our children and grandchildren’s future.”
At the parliamentary evening in the Saxony-Anhalt State Representation, the Secretary of State of the Federal Ministry for the Environment Bettina Hoffmann, the chair of Friends of the Earth Germany (BUND) Olaf Bandt as well as Andreas Jahn, CEO of the Bundesverband mittelständische Wirtschaft, discussed with members of the Bundestag and representatives from research, business and civil society, which actions need to be taken now by which groups in order for Germany to make its contribution to achieving the global targets.

With a letter signed by more than 500 scientists from all over Germany, the researchers call for setting up a politically high-ranking national biodiversity council, which will help make the conservation of biodiversity, our foundation of life, a core issue across all ministries together with young people.

“The best available scientific evidence can guide the identification of measures to reverse current negative biodiversity trends,” says iDiv speaker Prof Henrique Pereira from the Martin Luther University Halle-Wittenberg. “Whether the measures adopted are then implemented, and have an effect, must be consistently evaluated. For this, we need systematic and effective biodiversity monitoring. We are happy that the federal government has established the National Monitoring Centre for Biodiversity (NMZB) in Leipzig right on our doorstep.”

Prof Christian Wirth, iDiv speaker from Leipzig University, also sees long-term, guaranteed funding of basic research as an essential prerequisite for enabling the achievement of global biodiversity goals. “Our planet is changing faster than we would like, and with that, its biological diversity. What is considered reliable knowledge today is already outdated tomorrow. It is the task of basic research to not only observe these changes, but to understand them in real-time so we remain capable of acting to save the planet, both now and in the future”.

Co-host of the parliamentary evening, Prof Armin Willingmann, Saxony-Anhalt Minister for Science, Energy, Climate Protection and the Environment, stated, “The conservation of biodiversity is one of the most urgent challenges worldwide. With iDiv, we established a beacon for biodiversity research in Central Germany. iDiv is now also at the international forefront of this research. Especially regarding the implementation of the agreement on biodiversity achieved in Montréal in December 2022, I strongly urge the federal government to join the states of Saxony-Anhalt, Saxony and Thuringia, in order to secure the long-term funding of iDiv.”

“iDiv is an outstanding example of how cross-border synergies in research and its funding can be utilised,” says Prof Eva Inés Obergfell, rector of Leipzig University and vice chairperson of the iDiv Board of Trustees. “We would like to extend this formula for success beyond federal limits and involve other partners, such as Germany’s federal government, in research funding. The biodiversity crisis will keep us busy for a long time. iDiv's excellent research provides the basis for courses of action to rise to this challenge for humanity.” 

You can find the Federal Secretary of State’s speech at the event here

Background 
In the ten years since it was founded, iDiv has developed into an internationally renowned research institution. 350 employees from 40 nations, nine professors and four junior research groups create the scientific basis for a sustainable approach to biological diversity. ‘Biodiversity’ encompasses the entire variety of life – not only species diversity, but also genetic diversity, diversity of functions, interactions and ecosystems. As well as the employees at the core centre in Leipzig, there are over 150 members; researchers at the three participating universities – the Martin Luther University Halle-Wittenberg, Friedrich Schiller University Jena and Leipzig University, as well as the Helmholtz Centre for Environmental Research (UFZ) and seven other institutions - who work on integrative biodiversity research issues. Through their expertise, they significantly support iDiv’s scientific uniqueness.

iDiv research findings create the basis for the conservation of biodiversity. They are relevant in a number of societal areas, including politics; internationally, for example, through contributions to the World Biodiversity Council IPBES, the Convention on Biological Diversity (CBD) and analyses of the EU's Common Agricultural Policy. Also at the federal level, by, for example, helping to shape national biodiversity monitoring, and at the state level through policy consultation in the state parliaments. 
Sebastian Tilch 

 

Contact:

Prof Dr Aletta Bonn
Head of Department Ecosystem Services
Helmholtz Centre for Environmental Research (UFZ)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Friedrich Schiller University Jena
Phone: +49 341 9733153
Email: aletta.bonn@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/137.html

 

Sebastian Tilch
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33197
Email: sebastian.tilch@idiv.de
Web: https://www.idiv.de/media

 

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iDiv TOP NEWS Media Release Tue, 17 Jan 2023 00:00:00 +0100
Grassland ecosystems become more resilient with age https://idiv-biodiversity.de//en/news/news_single_view/5080.html Biodiversity–stability relationships strengthen over time in a long-term grassland experiment Biodiversity–stability relationships strengthen over time in a long-term grassland experiment

Based on a media release of the University of Zurich

Zurich/Leipzig. Recent experiments have shown that the loss of species from a plant community can reduce ecosystem functions and services such as productivity, carbon storage and soil health. With the loss of functioning the ecosystem may also become destabilized in its ability to maintain ecosystem functions and services in the long-term. However, assessing this is only possible if experiments can be maintained for a sufficient length of time.

In a new study published in Nature Communications, researchers from the University of Zurich and colleagues from Leipzig and Jena analyzed the stability of plant biomass production over two decades in one of the longest-running grassland biodiversity experiments in the world, the Jena Experiment in Germany. After more than a decade, plant species in more diverse experimental communities complemented each other in producing stable biomass at the community level. At low plant diversity, by contrast, this “compensatory” effect was not realized and community biomass varied much more from year to year. During the first decade of the experiment species-rich communities had not yet stabilized because of large fluctuations in species populations. This long-term research shows that biodiversity plays an increasingly important role in stabilizing ecosystem productivity over time as plant communities mature. Because ecosystem stability incurs resilience in the face of environmental perturbations, it follows that in a changing world, older, more diverse ecosystems should be particularly highly valued.

The first author, Dr. Cameron Wagg from the University of Zurich, says: “We now realize that the mechanisms by which diverse species communities maintain ecosystem functioning in the long-term are continually developing even two decades later. Such findings in this study highlight the importance of long-term research studies to fully appreciate the invaluable role of biodiversity for supporting ecosystem functions and services into the future.” The corresponding author, Prof. Dr. Bernhard Schmid from the University of Zurich, adds: “These novel results fit with other recent findings of our research group, suggesting that over time evolutionary processes in diverse plant communities select the most “collaborative” plant genotypes among the different species, thus increasing division of labor, community productivity and ecosystem stability.” Prof. Dr. Nico Eisenhauer from iDiv and Leipzig University and speaker of the Jena Experiment, highlights: “Only such long-term studies can draw a realistic and comprehensive picture of the relevance of biodiversity for ecosystems and human well-being”.

 

Original Publication
(Researchers with iDiv affiliation and alumni are in bold)

Cameron Wagg, Christiane Roscher, Alexandra Weigelt, Anja Vogel, Anne Ebeling, Enrica de Luca, Anna Roeder, Clemens Kleinspehn, Vicky M. Temperton, Sebastian T. Meyer, Michael Scherer-Lorenzen, Nina Buchmann, Markus Fischer, Wolfgang W. Weisser, Nico Eisenhauer, Bernhard Schmid (2022). Biodiversity–stability relationships strengthen over time in a long-term grassland experiment. Nature Communications. Doi: 10.1038/s41467-022-35189-2.

 

Contact:

Prof Dr Bernhard Schmid
Department of Geography
Remote Sensing Laboratories
University of Zürich
Email: bernhard.schmid@uzh.ch

 

Prof Dr Nico Eisenhauer
Head of the research group Experimental Interaction Ecology
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Phone: +49 341 97 33167
Email: nico.eisenhauer@idiv.de
Web: https://www.idiv.de/en/groups_and_people/employees/details/eshow/eisenhauer_nico.html

 

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Media Release iDiv Experimental Interaction Ecology Research TOP NEWS Fri, 13 Jan 2023 00:00:00 +0100
Fewer moths, more flies https://idiv-biodiversity.de//en/news/news_single_view/5067.html The complex relationships between plants and their pollinators have changed dramatically across the... The complex relationships between plants and their pollinators have changed dramatically across the last century.

In the far north of the planet, climate change is clearly noticeable. A new study in Finland now shows that in parallel there have been dramatic changes in pollinating insects. Researchers from the Martin Luther University Halle-Wittenberg (MLU), the Helmholtz Centre for Environmental Research (UFZ), and the German Centre for Integrative Biodiversity Research Halle-Jena-Leipzig (iDiv) have discovered that the network of plants and their pollinators there has changed considerably since the end of the 19th century. As the scientists warn in an article published in Nature Ecology & Evolution, this could lead to plants being pollinated less effectively. This, in turn, would adversely affect their reproduction.

Their service is invaluable. The army of insects and other animals that pollinates the numerous plants of this earth has an essential function. Without these flower visitors, numerous wild plants could reproduce only poorly – or not at all. Ecosystems would thus no longer be able to function in their current form. More than three quarters of the most important crops depend on pollinators in order to be able to produce a high yield and good quality. A loss of pollinators would therefore also lead to economic losses amounting to billions.

It remains unclear whether the pollinators will still be able to provide their usual service. That’s because plants and their pollinators are intertwined in an elaborate network in which the distribution and abundance of the species involved as well as their seasonal occurrence, physiology, and behaviour are finely tuned. Even small changes could throw everything out of balance. Experts thus fear that human influences such as changes in climate and land use could lead to less effective pollination services.

However, because few studies have investigated the interaction between plants and different pollinator groups over longer periods of time, it is difficult to say whether and to what extent such developments are already under way. This makes the more than 120-year-old data from Finland on which the new study is based all the more exciting. Between 1895 and 1900, in the vicinity of Kittilä (a village that lies about 120 km north of the Arctic Circle), forester Frans Silén systematically recorded which insects visited which flowers and how often.

“I am passionate about working with historical datasets like this”, says senior author Prof. Tiffany Knight from iDiv and UFZ. “If you repeat the historic studies again today, it’s often the only way to learn about long-term ecological processes”. For her, such work also challenges the imagination. “I am trying to understand what motivated the people who collected the data in the past and what challenges they faced”, she explains. “This information can then be used to plan a comparable modern study”.

The scientists thus first looked around Kittilä for sites where Silén had also made observations – and where the 17 plant species he studied best still grow today. At these sites, the team repeated the pollinator census in 2018 and 2019. The area remains sparsely populated, and little has changed in terms of land use. However, it has not escaped the consequences of climate change. “We have noticed drastic changes in the networks of pollinators”, says first author Leana Zoller from MLU and iDiv. Only 7% of the flower visits observed involved the same species of insects and plants as back then. “That is surprisingly little”, says Zoller. 

For example, hoverflies and moths appear much less frequently on the flowers around the village today than they used to. This is probably not good news. That’s because these two groups have some particularly effective pollinators among them. These include the bumblebee hoverfly (Volucella bombylans) – a large, furry fly resembling a bumblebee. In Silén’s time, this species was the most frequent visitor to the Arctic raspberry (Rubus arcticus) and the woodland geranium (Geranium sylvaticum). The bumblebee hoverfly was likely able to effectively transfer the pollen of these species from one plant to the next. 

Also moths use a physical advantage during pollination: with their long proboscis, they can also reach the nectar from the base of tubular flowers. This is why they used to be the most frequent visitors of the fringed pink (Dianthus superbus) and bladder campion (Silene vulgaris), both of which have such flowers. 

Whilst these insects have become rarer, the flowers around Kittilä are now getting considerably more visits from bumblebees and certain flies. Whether these animals work as effectively as the earlier pollinators is not yet known. However, one trend in particular concerns the researchers. There are now considerably fewer insects that are specialists for certain flower shapes. These have been replaced by flies of the genus Thricops, which visit many different plants. Such generalists are often more robust when it comes to environmental changes; if one of their host plants is lacking, they can easily switch to others. But they also carry the pollen of various other plant species onto a flower, thereby potentially providing a less effective pollination service than the specialists. 

“So far, the pollinator network in our study area still seems to be working well”, says Zoller. “There is no evidence so far that the plants are getting too little pollen and are thus less capable of reproducing”. But according to the scientists, this can change in the future if changes in the insect communities continues. So far, the flies there seem to be coping with the rising temperatures. But further north in the high Arctic, one study has revealed a massive decrease in the number of flies. “If this also happens in our study area, it could become a problem”, says Zoller. Because at some point, the plants will no longer be able to compensate for the losses in their pollinator network.

 

Original Publication
(Researchers with iDiv affiliation and alumni are in bold)

Leana Zoller, Joanne Bennett, Tiffany M. Knight (2022): Plant-pollinator network change across a century in the subarctic. Nature Ecology and Evolution. DOI: 10.1038/s41559-022-01928-3

 

Contact:

Leana Zoller
Martin Luther University Halle-Wittenberg (MLU)
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: leana.zoller@idiv.de

 

Prof Tiffany Knight
Helmholtz Centre for Environmental Research – UFZ
Martin Luther University Halle-Wittenberg
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 9733158
Email: tiffany.knight@idiv.de

 

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Media Release UFZ News TOP NEWS Species Interaction Ecology Tue, 03 Jan 2023 00:00:00 +0100
wildE: Restoring wild habitats in Europe against climate change https://idiv-biodiversity.de//en/news/news_single_view/4861.html European project started to assess ecological restoration through rewilding European project started to assess ecological restoration through rewilding

Based on a media release by INRAE 

Cestas/Halle. Terrestrial ecosystems throughout Europe face the twin threats of climate change and the loss of biodiversity. “Rewilding” could be an important ecological restoration solution to mitigate both of these issues, but up to now, it is mostly restricted to local initiatives scattered across the continent focussing on biodiversity objectives alone. The wildE project aims to assess the synergies between climate change mitigation, adaptation and biodiversity and thus to improve the potential of climate-smart rewilding as a nature-based solution for ecological restoration in Europe. wildE is funded by the EU Horizon programme and coordinated by the French National Research Institute for Agriculture, Food and Environment INRAE with the participation of the German Centre for Integrative Biodiversity Research (iDiv) and the Martin Luther University Halle-Wittenberg.

The rewilding approach proposes to “let nature (re)take care of itself”, often with temporary help at first, and benefit from natural processes to adapt ecosystems to climate change and support their biodiversity. This multidisciplinary research and innovation programme will address the link between climate and biodiversity in close association with the socio-economic dimension of large-scale restoration. It compares scenarios from various land uses, assesses associated risks and opportunities, and explores new approaches to make ecological restoration a socially and economically viable solution for local actors and communities.

wildE will provide scientific knowledge, methods and tools for different geographical, ecological and social contexts based on Europe-wide studies as well as individual case studies. Inter alia, a German case study in collaboration with Wageningen University and BSWR - Biologische Station Westliches Ruhrgebiet e.V. will focus on “urban rewilding” as a nature-based solution in the Ruhrgebiet area. Other case studies focus on large-scale remote areas such as the Tatra Mountains.

The project aims to help policymakers (the EU, national governments, regions, and local communities) and commercial companies to integrate ecological restoration through rewilding into their policy or management to achieve carbon neutrality, strengthen climate adaptation and reverse biodiversity loss. 

These results will be widely communicated to a broad range of stakeholders (landowners, conservation managers, companies, society at large, etc.) to improve everyone's knowledge of these challenges and opportunities. This interactive sharing will be made possible in particular through a collaborative web platform, which will also function as a shared workspace for stakeholders. 

wildE is supported by a team of 22 academic and non-academic partners (NGOs, companies, etc.) from 12 European and coordinated at INRAE in France. 

“Climate mitigation by restoring ecosystems only works with large-scale measures. Rewilding can deliver the kind of upscaling that is needed for significant climate mitigation of European ecosystems,” says Prof Henrique Pereira, head of the Biodiversity Conservation Group at iDiv and leader of the wildE work package the conceptual framework on climate-smart rewilding. “This project will be the first to assess the potential of rewilding for climate mitigation in Europe. And to facilitate the implementation of climate-smart rewilding, we will identify priority areas.”

The Project is funded via the EU Horizon Europe programme with 8.5 Million Euros for four years.

Original media release by INRAE

 

Contact:

Dr Néstor Fernández (speaks English and Spanish)
Scientific Employee Biodiversity Conservation Group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Phone: +49 341 97 33229
Email: nestor.fernandez@idiv.de
Web: https://www.idiv.de/en/profile/342.html

 

Prof Dr Henrique Miguel Pereira
Head of Biodiversity Conservation research group
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Martin Luther University Halle-Wittenberg (MLU)
Email: henrique.pereira@idiv.de
Web: https://www.idiv.de/en/profile/132.html

 

Sebastian Tilch
Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33197
Email: sebastian.tilch@idiv.de
Web: https://www.idiv.de/media

 

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Biodiversity Conservation TOP NEWS Mon, 02 Jan 2023 00:00:00 +0100
Identification of groundwater-dependent vegetation via satellites https://idiv-biodiversity.de//en/news/news_single_view/5045.html New framework to identify groundwater-dependent vegetation

Report by Léonard El-Hokayem (doctoral researcher at MLU and iDiv)

Halle. Groundwater in (semi)-arid regions plays a key role in sustaining important terrestrial ecosystems, providing drinking water and supporting agriculture. We developed a new multi-instrument framework to identify groundwater-dependent vegetation (GDV) in these regions. Therefore, a combination of satellite images and other environmental data got tested and validated in a Mediterranean study area in Southern Italy. The developed concept was recently published in Ecological Indicators. It allows for the identification and study of vegetation that relies on groundwater, and thus can help protect these biodiversity hotspots and the ecosystem services they provide.

Groundwater is an important resource for terrestrial vegetation. 50% of the vegetation in the semi-arid Mediterranean biome is known to use groundwater. As these ecosystems are threatened by climate change and pressure from land use, on-the-ground identification is necessary. 

Our final map of the study area shows that GDV is located more frequently in broadleaf and coniferous forests standing on low permeable rocks with surficial groundwater circulation. Data from a botanical field campaign in summer 2021 was used to further validate the results. By analysing vegetation surveys, we could show that significant differences between GDV and non-GDV detected from remote sensing were also visible in the field. In GDV, tree species that are known to use groundwater (phreatophytes) dominate. In non-GDV the most important plants are drought-adapted shrubs. In general, GDV indicated areas with better water supply during the annual dry period. We also saw that plant diversity is actually higher in ecosystems reliant on groundwater. Surprisingly, two oak species occurred in both groundwater-influenced areas and non-dependent ecosystems. We further analysed the vitality of both species in the field. Our results show that the oaks, which according to our map are more likely to be GDV, are also more vital on the ground. 

Methods to locate GDV using remote sensing and geodata have gained importance in recent years, as they allow covering larger areas at a relatively lower cost. However, a comprehensive combination of different indicators was still pending. Our mapping framework combines vegetation, topography, hydrogeology and climate for the first time. Furthermore, we introduced a new simple ecohydrological rule set (phreatophyte cover and mean moisture value of non-phreatophyte species) to classify vegetation in the field and optimise our final map.

From our results, we learned that while remote sensing can identify GDV, in situ validation data is still needed. Areas that were identified as GDV can contribute to the development of adapted water management methods and pinpoint systems worthy of conservation. Our framework can be understood as a step towards the creation of a harmonised GDV map for the whole Mediterranean biome.
Léonard El-Hokayem


Original publication:
(iDiv researchers bold)
El-Hokayem, L., De Vita, P. and Conrad, C. (2022) Local Identification of Groundwater Dependent Vegetation Using High-Resolution Sentinel-2 Data – A Mediterranean Case Study. Ecological Indicators, 146, 109784. https://doi.org/10.1016/j.ecolind.2022.109784

 

Contact:

Léonard El-Hokayem
Doctoral researcher
Martin Luther University Halle-Wittenberg
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Email: leonard.el-hokayem@geo.uni-halle.de
Web: https://www.idiv.de/en/profile/1651.html

 

Dr Volker Hahn
Head of Media and Communications
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Phone: +49 341 97 33154
Email: volker.hahn@idiv.de
Web: https://www.idiv.de/media

 

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TOP NEWS iDiv Members Thu, 15 Dec 2022 00:00:00 +0100