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5. Nitrogen availability and plant functional composition modify biodiversity-multifunctionality relationships

Author

Universidad de Alicante. Departamento de Ecología, Universidad de Alicante. Instituto Multidisciplinar para el Estudio del Medio "Ramón Margalef", Pichon, Noémie A., Cappelli, Seraina L., Soliveres, Santiago, Mannall, Tosca, Nwe, Thu Zar, Hölzel, Norbert, Klaus, Valentin H., Kleinebecker, Till, Vincent, Hugo, Allan, Eric, Universidad de Alicante. Departamento de Ecología, Universidad de Alicante. Instituto Multidisciplinar para el Estudio del Medio "Ramón Margalef", Pichon, Noémie A., Cappelli, Seraina L., Soliveres, Santiago, Mannall, Tosca, Nwe, Thu Zar, Hölzel, Norbert, Klaus, Valentin H., Kleinebecker, Till, Vincent, Hugo, and Allan, Eric

Abstract

Biodiversity typically increases multiple ecosystem functions simultaneously (multifunctionality) but variation in the strength and direction of biodiversity effects between studies suggests context dependency. To determine how different factors modulate the diversity effect on multifunctionality, we established a large grassland experiment manipulating plant species richness, resource addition, functional composition (exploitative vs. conservative species), functional diversity and enemy abundance. We measured ten above- and belowground functions and calculated ecosystem multifunctionality. Species richness and functional diversity both increased multifunctionality, but their effects were context dependent. Richness increased multifunctionality when communities were assembled with fast-growing species. This was because slow species were more redundant in their functional effects, whereas different fast species promoted different functions. Functional diversity also increased multifunctionality but this effect was dampened by nitrogen enrichment and enemy presence. Our study suggests that a shift towards fast-growing communities will not only alter ecosystem functioning but also the strength of biodiversity-functioning relationships.

Published
2024

6. Cumulative nitrogen enrichment alters the drivers of grassland overyielding

Author

Ecology and Biodiversity, Sub Ecology and Biodiversity, He, Miao, Barry, Kathryn E, Soons, Merel B, Allan, Eric, Cappelli, Seraina L, Craven, Dylan, Doležal, Jiří, Isbell, Forest, Lanta, Vojtěch, Lepš, Jan, Liang, Maowei, Mason, Norman, Palmborg, Cecilia, Pichon, Noémie A, da Silveira Pontes, Laíse, Reich, Peter B, Roscher, Christiane, Hautier, Yann, Ecology and Biodiversity, Sub Ecology and Biodiversity, He, Miao, Barry, Kathryn E, Soons, Merel B, Allan, Eric, Cappelli, Seraina L, Craven, Dylan, Doležal, Jiří, Isbell, Forest, Lanta, Vojtěch, Lepš, Jan, Liang, Maowei, Mason, Norman, Palmborg, Cecilia, Pichon, Noémie A, da Silveira Pontes, Laíse, Reich, Peter B, Roscher, Christiane, and Hautier, Yann

Published
2024

8. Multiple dimensions of biodiversity mediate effects of temperature on invertebrate herbivory in a montane grassland

Author

Halliday, Fletcher W; https://orcid.org/0000-0003-3953-0861, Cappelli, Seraina L; https://orcid.org/0000-0002-8141-404X, Laine, Anna‐Liisa; https://orcid.org/0000-0002-0703-5850, Halliday, Fletcher W; https://orcid.org/0000-0003-3953-0861, Cappelli, Seraina L; https://orcid.org/0000-0002-8141-404X, and Laine, Anna‐Liisa; https://orcid.org/0000-0002-0703-5850

Abstract

Invertebrate herbivores are important and diverse, and their abundance and impacts will likely shift under climate change. Yet, past studies of invertebrate herbivory have documented highly variable responses to changing temperature, making it challenging to predict the direction and magnitude of these shifts. One explanation for these responses is that changing environmental conditions drive concurrent changes in plant communities and herbivore traits. The impacts of changing temperature on herbivory might therefore depend on how temperature combines and interacts with characteristics of plant and herbivore communities. To test this, we surveyed damage to leaves by invertebrate herbivores on 4400 plant individuals in 220 sampling plots along a 1101 m elevational gradient. Increasing temperature drove community‐level herbivory via at least three overlapping mechanisms: increasing temperature directly reduced herbivory, indirectly affected herbivory by reducing plant‐community phylogenetic diversity, and indirectly affected herbivory by altering the effects of plant‐community functional and phylogenetic diversity on herbivory. Consequently, increasing plant functional diversity reduced herbivory in colder environments while increasing plant phylogenetic diversity increased herbivory in warmer environments. Moreover, different herbivore feeding guilds varied in their response to temperature and plant community composition. These results indicate that, even along a single elevation gradient in a single year, a variety of mechanisms can concurrently drive herbivory, thereby supporting the hypothesis that a universal response of herbivory to changing environmental conditions is unlikely to exist. Instead, our results highlight the importance of considering both plant and herbivore community context to predict how climate change will alter invertebrate herbivory.

Published
2023

9. Nitrogen availability and plant functional composition modify biodiversity‐multifunctionality relationships.

Author

Pichon, Noémie A., Cappelli, Seraina L., Soliveres, Santiago, Mannall, Tosca, Nwe, Thu Zar, Hölzel, Norbert, Klaus, Valentin H., Kleinebecker, Till, Vincent, Hugo, and Allan, Eric

Subjects
*CHEMICAL composition of plants, *SPECIES diversity, *PLANT species, *NITROGEN, *GRASSLANDS, *PLANT species diversity, *BIODIVERSITY
Abstract

Biodiversity typically increases multiple ecosystem functions simultaneously (multifunctionality) but variation in the strength and direction of biodiversity effects between studies suggests context dependency. To determine how different factors modulate the diversity effect on multifunctionality, we established a large grassland experiment manipulating plant species richness, resource addition, functional composition (exploitative vs. conservative species), functional diversity and enemy abundance. We measured ten above‐ and belowground functions and calculated ecosystem multifunctionality. Species richness and functional diversity both increased multifunctionality, but their effects were context dependent. Richness increased multifunctionality when communities were assembled with fast‐growing species. This was because slow species were more redundant in their functional effects, whereas different fast species promoted different functions. Functional diversity also increased multifunctionality but this effect was dampened by nitrogen enrichment and enemy presence. Our study suggests that a shift towards fast‐growing communities will not only alter ecosystem functioning but also the strength of biodiversity‐functioning relationships. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Plant biodiversity promotes sustainable agriculture directly and via belowground effects

Author

Seraina L. Cappelli, Luiz A. Domeignoz-Horta, Viviana Loaiza, Anna-Liisa Laine, University of Zurich, and Cappelli, Seraina L

Subjects
Soil, 10127 Institute of Evolutionary Biology and Environmental Studies, 1110 Plant Science, 570 Life sciences, biology, 590 Animals (Zoology), Agriculture, Biodiversity, Plant Science, Plants, Ecosystem
Abstract

While the positive relationship between plant biodiversity and ecosystem functioning (BEF) is well established, the extent to which this is mediated via belowground microbial processes is poorly understood. Growing evidence suggests that plant community structure influences soil microbial diversity, which in turn promotes functions desired for sustainable agriculture. Here, we outline the 'plant-directed' and soil microbe-mediated mechanisms expected to promote positive BEF. We identify how this knowledge can be utilized in plant diversification schemes to maximize ecosystem functioning in agroecosystems, which are typically species poor and sensitive to biotic and abiotic stressors. In the face of resource overexploitation and global change, bridging the gaps between biodiversity science and agricultural practices is crucial to meet food security in the Anthropocene.

Published
2022
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11. Effects of abiotic environment on invertebrate herbivory depend on plant community context in a montane grassland

Author

Fletcher W. Halliday, Seraina L Cappelli, Anna-Liisa Laine, and University of Zurich

Subjects
10127 Institute of Evolutionary Biology and Environmental Studies, 570 Life sciences, biology, 590 Animals (Zoology)
Abstract

Invertebrate herbivores are important and diverse, and their abundance and impacts are expected to undergo unprecedented shifts under climate change. Yet, past studies of invertebrate herbivory have documented a wide variety of responses to changing temperature, making it challenging to predict the direction and magnitude of these shifts. One explanation for these idiosyncratic responses is that changing environmental conditions may drive concurrent changes in plant communities and herbivore traits. Thus, the impacts of changing temperature on herbivory might depend on how temperature combines and interacts with characteristics of plant communities and the herbivores that occupy them. Here, we test this hypothesis by surveying invertebrate herbivory in 220, 0.5 meter-diameter herbaceous plant communities along a 1101-meter elevational gradient. Our results suggest that increasing temperature can drive community-level herbivory via at least three overlapping mechanisms: increasing temperature directly reduced herbivory, indirectly affected herbivory by reducing phylogenetic diversity of the plant community, and indirectly affected herbivory by altering the effects of functional and phylogenetic diversity on herbivory. Consequently, increasing functional diversity of plant communities had a negative effect on herbivory, but only in colder environments while a positive effect of increasing phylogenetic diversity was observed in warmer environments. Moreover, accounting for differences among herbivore feeding guilds considerably improved model fit, because different herbivore feeding guilds varied in their response to temperature and plant community composition. Together, these results highlight the importance of considering both plant and herbivore community context in order to predict how climate change will alter invertebrate herbivory.

Published
2022

12. Partitioning the effects of plant diversity on ecosystem functions at different trophic levels

Author

Cappelli, S. L. (Seraina L.), Pichon, N. A. (Noémie A.), Mannall, T. (Tosca), Allan, E. (Eric), Cappelli, S. L. (Seraina L.), Pichon, N. A. (Noémie A.), Mannall, T. (Tosca), and Allan, E. (Eric)

Abstract

Biodiversity effects on ecosystem functioning can be partitioned into complementarity effects, driven by many species, and selection effects, driven by few. Selection effects occur through interspecific abundance shifts (dominance) and intraspecific shifts in functioning. Complementarity and selection effects are often calculated for biomass, but very rarely for secondary productivity, that is, energy transfer to higher trophic levels. We calculated diversity effects for three functions: aboveground biomass, insect herbivory and pathogen infection, the latter two as proxies for energy transfer to higher trophic levels, in a grassland experiment (PaNDiv) manipulating species richness, functional composition, nitrogen enrichment, and fungicide treatment. Complementarity effects were, on average, positive and selection effects negative for biomass production and pathogen infection and multiple species contributed to diversity effects in mixtures. Diversity effects were, on average, less pronounced for herbivory. Diversity effects for the three functions were not correlated, because different species drove the different effects. Benefits (and costs) from growing in diverse communities, be it reduced herbivore or pathogen damage or increased productivity either due to abundance increases or increased productivity per area were distributed across different plant species, leading to highly variable contributions of single species to effects of diversity on different functions. These results show that different underlying ecological mechanisms can result in similar overall diversity effects across functions.

Published
2022

13. Intraspecific trait changes have large impacts on community functional composition but do not affect ecosystem function

Author

Pichon, N. A. (Noémie A.), Cappelli, S. L. (Seraina L.), Allan, E. (Eric), Pichon, N. A. (Noémie A.), Cappelli, S. L. (Seraina L.), and Allan, E. (Eric)

Abstract

1. Plant functional traits can provide a mechanistic understanding of community responses to global change and of community effects on ecosystem functions. Nitrogen enrichment typically shifts trait composition by promoting the dominance of acquisitive plants (high specific leaf area [SLA] and low leaf dry matter content [LDMC]), translating into high biomass production. Changes in mean trait values can be due to shifts in species identity, relative abundances and/or intraspecific trait values. However, we do not know the relative importance of these shifts in determining trait responses to environmental changes, or trait effects on ecosystem functioning, such as biomass production. 2. We quantified the relative importance of species composition, abundance and intraspecific shifts in driving variation in SLA and LDMC, and how these shifts affected above- and below-ground biomass. We measured traits in a grassland experiment manipulating nitrogen fertilisation, plant species richness, foliar fungal pathogen removal and sown functional composition (slow vs. fast species). We fitted structural equation models to test the importance of abundance and intraspecific shifts in determining (a) responses of functional composition to treatments and (b) effects on above- and below-ground biomass. 3. We found that species intraspecific shifts were as important as abundance shifts in determining the overall change in functional composition (community weighted mean trait values), and even had large effects compared to substantial initial variation in sown trait composition. Intraspecific trait shifts resulted in convergence towards intermediate SLA in diverse communities; although convergence was reduced by nitrogen addition and enhanced by pathogen removal. In contrast, large intraspecific shifts in LDMC were not influenced by the treatments. However, despite large responses, intraspecific trait shifts had no effect on above- or below-ground biomass. Only interspecific t

Published
2022

14. Effects of abiotic environment on invertebrate herbivory depend on plant community context in a montane grassland

Author

Halliday, Fletcher W; https://orcid.org/0000-0003-3953-0861, Cappelli, Seraina L; https://orcid.org/0000-0002-8141-404X, Laine, Anna-Liisa; https://orcid.org/0000-0002-0703-5850, Halliday, Fletcher W; https://orcid.org/0000-0003-3953-0861, Cappelli, Seraina L; https://orcid.org/0000-0002-8141-404X, and Laine, Anna-Liisa; https://orcid.org/0000-0002-0703-5850

Abstract

Invertebrate herbivores are important and diverse, and their abundance and impacts are expected to undergo unprecedented shifts under climate change. Yet, past studies of invertebrate herbivory have documented a wide variety of responses to changing temperature, making it challenging to predict the direction and magnitude of these shifts. One explanation for these idiosyncratic responses is that changing environmental conditions may drive concurrent changes in plant communities and herbivore traits. Thus, the impacts of changing temperature on herbivory might depend on how temperature combines and interacts with characteristics of plant communities and the herbivores that occupy them. Here, we test this hypothesis by surveying invertebrate herbivory in 220, 0.5 meter-diameter herbaceous plant communities along a 1101-meter elevational gradient. Our results suggest that increasing temperature can drive community-level herbivory via at least three overlapping mechanisms: increasing temperature directly reduced herbivory, indirectly affected herbivory by reducing phylogenetic diversity of the plant community, and indirectly affected herbivory by altering the effects of functional and phylogenetic diversity on herbivory. Consequently, increasing functional diversity of plant communities had a negative effect on herbivory, but only in colder environments while a positive effect of increasing phylogenetic diversity was observed in warmer environments. Moreover, accounting for differences among herbivore feeding guilds considerably improved model fit, because different herbivore feeding guilds varied in their response to temperature and plant community composition. Together, these results highlight the importance of considering both plant and herbivore community context in order to predict how climate change will alter invertebrate herbivory.

Published
2022

15. Plant biodiversity promotes sustainable agriculture directly and via belowground effects

Author

Cappelli, Seraina L; https://orcid.org/0000-0002-8141-404X, Domeignoz-Horta, Luiz A, Loaiza, Viviana, Laine, Anna-Liisa; https://orcid.org/0000-0002-0703-5850, Cappelli, Seraina L; https://orcid.org/0000-0002-8141-404X, Domeignoz-Horta, Luiz A, Loaiza, Viviana, and Laine, Anna-Liisa; https://orcid.org/0000-0002-0703-5850

Abstract

While the positive relationship between plant biodiversity and ecosystem functioning (BEF) is well established, the extent to which this is mediated via belowground microbial processes is poorly understood. Growing evidence suggests that plant community structure influences soil microbial diversity, which in turn promotes functions desired for sustainable agriculture. Here, we outline the ‘plant-directed’ and soil microbe-mediated mechanisms expected to promote positive BEF. We identify how this knowledge can be utilized in plant diversification schemes to maximize ecosystem functioning in agroecosystems, which are typically species poor and sensitive to biotic and abiotic stressors. In the face of resource overexploitation and global change, bridging the gaps between biodiversity science and agricultural practices is crucial to meet food security in the Anthropocene.

Published
2022

19. Both diversity and functional composition affect productivity and water use efficiency in experimental temperate grasslands

Author

Noémie A. Pichon, Manuel Walde, Seraina L. Cappelli, Margaux Didion-Gency, Charlotte Grossiord, Arthur Gessler, Marco M. Lehmann, Eric Allan, and Organismal and Evolutionary Biology Research Programme

Subjects
0106 biological sciences, ecosystem-function, productivity, C-13, biodiversity-ecosystem functioning, Biodiversity, Plant Science, 580 Plants (Botany), Biology, trait relationships, 010603 evolutionary biology, 01 natural sciences, Grassland, resistance, biodiversity loss, Ecosystem, Water-use efficiency, nitrogen use, Ecology, Evolution, Behavior and Systematics, complementarity, 2. Zero hunger, geography, Biomass (ecology), geography.geographical_feature_category, photosynthesis, soil biogeochemistry, Ecology, Resistance (ecology), biomass, n-15, c-13, 15. Life on land, stability, plant diversity, nitrogen uptake, communities, Productivity (ecology), 13. Climate action, 1181 Ecology, evolutionary biology, 13C, 15N, Biodiversity–ecosystem functioning, Complementarity, Nitrogen uptake, Photosynthesis, Productivity, Species richness, N-15, 010606 plant biology & botany
Abstract

1. Many experiments have shown that biodiversity promotes ecosystem functioning and stability and that this relationship varies with resource availability. However, we still have a poor understanding of the underlying physiological and ecological mechanisms driving diversity effects and how they may interact with soil nutrient availability. 2. We collected data in a grassland experiment factorially manipulating fertilization, species richness (SR), functional composition (slow-growing vs. fast-growing species) and functional diversity in resource economic traits. We measured above-ground productivity (AP), nitrogen (N) uptake, photosynthesis and water use efficiency by combining a 15N labelling approach with productivity, gas exchange and stable isotope measurements in 3 years differing in rainfall. 3. We found that sown SR increased AP, N uptake and photosynthesis, suggesting that SR is the most important driver of ecosystem productivity and nutrient cycling. Similarly, photosynthesis was affected by functional composition but not by functional diversity. Water use efficiency was reduced by sown SR for communities dominated by slow-growing species but not for communities dominated by fast-growing species. Fertilization increased productivity, N uptake and water use efficiency. The positive effects of high SR on ecosystem functions were independent of fertility levels. 4. Synthesis. Our results provide evidence that high species richness in temperate grasslands could enhance productivity and reduce the negative impacts of drought events. Multiple factors and community characteristics are important in driving enhanced ecosystem functioning in biodiverse grasslands and seem to affect functioning and stability through different mechanisms. ISSN:0022-0477

Published
2021
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21. Author response for 'Both diversity and functional composition affect productivity and water use efficiency in experimental temperate grasslands'

Author

Manuel Walde, Marco M. Lehmann, Charlotte Grossiord, Noémie A. Pichon, Margaux Didion-Gency, Arthur Gessler, Seraina L. Cappelli, and Eric Allan

Subjects
Temperate grassland, Ecology, Environmental science, Composition (visual arts), Water-use efficiency, Affect (psychology), Productivity, Diversity (business)
Published
2021
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22. Intraspecific trait changes have large impacts on community functional composition but do not affect ecosystem function

Author

Eric Allan, Seraina L. Cappelli, and Noémie A. Pichon

Subjects
2. Zero hunger, 0106 biological sciences, Biomass (ecology), Specific leaf area, Ecology, 15. Life on land, Biology, 010603 evolutionary biology, 01 natural sciences, Intraspecific competition, Abundance (ecology), Trait, Ecosystem, Species richness, Relative species abundance, 010606 plant biology & botany
Abstract

Plant functional traits can provide a more mechanistic understanding of community responses to global change and effects on ecosystem functions. In particular, nitrogen enrichment shifts trait composition by promoting dominance of fast growing, acquisitive plants (with high specific leaf area [SLA] and low leaf dry matter content [LDMC]), and such fast species have higher aboveground biomass production. Changes in mean trait values can be due to a shift in species identity, a shift in species relative abundance and/or a shift in intraspecific trait values. However, we do not know the relative importance of these three shifts in determining responses to global change and effects on function.We quantified the relative importance of composition, abundance and intraspecific shifts in driving variation in SLA and LDMC. We collected leaf samples in a large grassland experiment, which factorially manipulates functional composition (slow vs. fast species), plant species richness, nitrogen enrichment and foliar fungal pathogen removal. We fitted structural equation models to test the relative importance of abundance shifts, intraspecific shifts and sown trait composition in contributing to overall variation in community weighted mean traits and aboveground and belowground biomass production.We found that intraspecific shifts were as important as abundance shifts in determining community weighted mean traits, and even had large effects relative to a wide initial gradient in trait composition. Intraspecific trait shifts resulted in convergence towards intermediate SLA, in diverse communities, although convergence was reduced by nitrogen addition and enhanced by pathogen removal. In contrast, large intraspecific shifts in LDMC were not influenced by the treatments. Belowground biomass was reduced by SLA and increased by LDMC, while aboveground biomass increased in communities dominated by high SLA species. However, despite large intraspecific trait shifts, intraspecific variation in these traits had no effect on above or belowground biomass production.Our results add to a growing body of literature showing large intraspecific trait variation and emphasise the importance of using field sampled data to determine community composition. However, they also show that intraspecific variation does not affect ecosystem functioning and therefore trait response-effect relationships may differ between vs. within species.

Published
2021
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24. Nitrogen availability and plant functional composition modify biodiversity-multifunctionality relationships

Author

Tosca Mannall, Till Kleinebecker, Noémie A. Pichon, Eric Allan, Hugo Vincent, Norbert Hölzel, Valentin H. Klaus, Seraina L. Cappelli, Santiago Soliveres, and Thu Zar Nwe

Subjects
0106 biological sciences, 2. Zero hunger, 0303 health sciences, Nutrient cycle, Specific leaf area, Ecology, Biodiversity, Context (language use), 15. Life on land, Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Abundance (ecology), Ecosystem, Species richness, 030304 developmental biology, Trophic level
Abstract

The ability of an ecosystem to deliver multiple functions at high levels (multifunctionality) typically increases with biodiversity but there is substantial variation in the strength and direction of biodiversity effects, suggesting context-dependency. A better understanding of the drivers of this context dependency is essential to predict effects of global change on ecosystems. To determine how different factors modulate the effect of diversity on multifunctionality, we established a large grassland experiment with 216 communities, crossing a manipulation of plant species richness (1, 4, 8, 20 species) with manipulations of resources (nitrogen enrichment), plant functional composition (gradient in mean specific leaf area [SLA] to manipulate abundances of exploitative, fast-growing vs. conservative, slow-growing species), plant functional diversity (variance in SLA) and enemy abundance (foliar fungal pathogen removal). We measured ten above- and belowground functions, related to productivity, nutrient cycling and energy transfer between trophic levels, and calculated ecosystem multifunctionality. Plant species richness and functional diversity both increased multifunctionality, but their effects were context dependent. Species richness increased multifunctionality only when communities were assembled with fast growing (high SLA) species. This was because slow species were more redundant in their functional effects, whereas different fast species tended to promote different functions. Functional diversity also increased multifunctionality but this effect was dampened by nitrogen enrichment. However, unfertilised, functionally diverse communities still delivered more functions than low diversity, fertilised communities. Our study suggests that a shift towards fast-growing exploitative communities will not only alter ecosystem functioning but also the strength of biodiversity-functioning relationships, which highlights the potentially complex effects of global change on multifunctionality.

Published
2020
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25. Consistent biodiversity effects across ecosystem functions

Author

Eric Allan, Seraina L. Cappelli, Noémie A. Pichon, and Tosca Mannall

Subjects
Biomass (ecology), Ecology, Abundance (ecology), Complementarity (molecular biology), Biodiversity, Ecosystem, Species richness, Interspecific competition, Biology, human activities, Intraspecific competition
Abstract

Biodiversity affects ecosystem functioning through complementarity effects, driven by many species, and selection effects, driven by few. Selection effects occur through interspecific abundance shifts (dominance) and intraspecific shifts in functioning. Complementarity and selection are often calculated for biomass, but we know little about how diversity affects other ecosystem functions. We calculated diversity effects for aboveground biomass, insect herbivory, pathogen infection and two leaf traits as nutrient cycling proxies, in a grassland experiment (PaNDiv) manipulating species richness, functional composition, nitrogen enrichment and fungicide treatment. Complementarity effects were always positive, showing that multiple species contribute to diversity effects. Intraspecific selection effects were always negative because species converged in their functioning in polyculture. Despite these overall consistencies, diversity effects for the five functions were not correlated, suggesting different species drive the different functions. These results show that different underlying mechanisms can result in similar overall diversity effects across functions.

Published
2020
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26. Both diversity and functional composition affect productivity and water use efficiency in experimental temperate grasslands

Author

Walde, M. (Manuel), Allan, E. (Eric), Cappelli, S. L. (Seraina L.), Didion-Gency, M. (Margaux), Gessler, A. (Arthur), Lehmann, M. M. (Marco M.), Pichon, N. A. (Noémie A.), Grossiord, C. (Charlotte), Walde, M. (Manuel), Allan, E. (Eric), Cappelli, S. L. (Seraina L.), Didion-Gency, M. (Margaux), Gessler, A. (Arthur), Lehmann, M. M. (Marco M.), Pichon, N. A. (Noémie A.), and Grossiord, C. (Charlotte)

Abstract

1. Many experiments have shown that biodiversity promotes ecosystem functioning and stability and that this relationship varies with resource availability. However, we still have a poor understanding of the underlying physiological and ecological mechanisms driving diversity effects and how they may interact with soil nutrient availability. 2. We collected data in a grassland experiment factorially manipulating fertilization, species richness (SR), functional composition (slow-growing vs. fast-growing species) and functional diversity in resource economic traits. We measured above-ground productivity (AP), nitrogen (N) uptake, photosynthesis and water use efficiency by combining a ¹⁵N labelling approach with productivity, gas exchange and stable isotope measurements in 3 years differing in rainfall. 3. We found that sown SR increased AP, N uptake and photosynthesis, suggesting that SR is the most important driver of ecosystem productivity and nutrient cycling. Similarly, photosynthesis was affected by functional composition but not by functional diversity. Water use efficiency was reduced by sown SR for communities dominated by slow-growing species but not for communities dominated by fast-growing species. Fertilization increased productivity, N uptake and water use efficiency. The positive effects of high SR on ecosystem functions were independent of fertility levels. 4. Synthesis. Our results provide evidence that high species richness in temperate grasslands could enhance productivity and reduce the negative impacts of drought events. Multiple factors and community characteristics are important in driving enhanced ecosystem functioning in biodiverse grasslands and seem to affect functioning and stability through different mechanisms.

Published
2021

32. Decomposition disentangled: a test of the multiple mechanisms by which nitrogen enrichment alters litter decomposition

Author

Eric Allan, Seraina L. Cappelli, Norbert Hölzel, Noémie A. Pichon, Valentin H. Klaus, Santiago Soliveres, Till Kleinebecker, Universidad de Alicante. Departamento de Ecología, Universidad de Alicante. Instituto Multidisciplinar para el Estudio del Medio 'Ramón Margalef', and Gestión de Ecosistemas y de la Biodiversidad (GEB)

Subjects
0106 biological sciences, Field experiment, Biology, 580 Plants (Botany), 010603 evolutionary biology, 01 natural sciences, Grassland, Nutrient, Ecosystem, Ecology, Evolution, Behavior and Systematics, Litter nutrients, Abiotic component, geography, Decomposition, Biotic component, geography.geographical_feature_category, Ecología, Soil quality, Agronomy, Environmental science, Ecosystem function, Species richness, Nitrogen enrichment, Litterbag, Functional traits, 010606 plant biology & botany
Abstract

Functional Ecology, 34 (7), ISSN:0269-8463, ISSN:1365-2435

Published
2020
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33. Sick plants in grassland communities: a growth-defense trade-off is the main driver of fungal pathogen abundance

Author

Anne Kempel, Seraina L. Cappelli, Eric Allan, and Noémie A. Pichon

Subjects
0106 biological sciences, Biodiversity, Biology, Generalist and specialist species, Trade-off, 010603 evolutionary biology, 01 natural sciences, Grassland, Dominance (ecology), Biomass, Pathogen, Ecology, Evolution, Behavior and Systematics, 2. Zero hunger, geography, geography.geographical_feature_category, Ecology, 010604 marine biology & hydrobiology, Fungi, food and beverages, Plant community, 15. Life on land, Plants, Fungicide, 13. Climate action
Abstract

Aboveground fungal pathogens can substantially reduce biomass production in grasslands. However, we lack a mechanistic understanding of the drivers of fungal pathogen infection and impact. Using a grassland global change and biodiversity experiment we show that the trade-off between plant growth and defense is the main determinant of infection incidence. In contrast, nitrogen addition only indirectly increased incidence via shifting plant communities towards faster growing species. Plant diversity did not decrease incidence, likely because spillover of generalist pathogens or dominance of susceptible plants counteracted negative diversity effects. A fungicide treatment increased plant biomass production and high levels of infection incidence were associated with reduced biomass. However, pathogen impact was context dependent and infection incidence reduced biomass more strongly in diverse communities. Our results show that a growth-defense trade-off is the key driver of pathogen incidence, but pathogen impact is determined by several mechanisms and may depend on pathogen community composition.

Published
2019

34. Decomposition disentangled: A test of the multiple mechanisms by which nitrogen enrichment alters litter decomposition

Author

Universidad de Alicante. Departamento de Ecología, Universidad de Alicante. Instituto Multidisciplinar para el Estudio del Medio "Ramón Margalef", Pichon, Noémie A., Cappelli, Seraina L., Soliveres, Santiago, Hölzel, Norbert, Klaus, Valentin H., Kleinebecker, Till, Allan, Eric, Universidad de Alicante. Departamento de Ecología, Universidad de Alicante. Instituto Multidisciplinar para el Estudio del Medio "Ramón Margalef", Pichon, Noémie A., Cappelli, Seraina L., Soliveres, Santiago, Hölzel, Norbert, Klaus, Valentin H., Kleinebecker, Till, and Allan, Eric

Abstract

1. Nitrogen (N) enrichment has direct effects on ecosystem functioning by altering soil abiotic conditions and indirect effects by reducing plant diversity and shifting plant functional composition from dominance by slow to fast growing species. Litter decomposition is a key ecosystem function and is affected by N enrichment either by a change in litter quality (the recalcitrance of the plant material) or through a change in soil quality (the abiotic and biotic components of the soil that affect decomposition). How the direct and indirect effects of N alter soil and litter quality remains poorly known. 2. We designed a large grassland field experiment manipulating N enrichment, plant species richness and functional composition in a full factorial design. We used three complementary litterbag experiments, combined in a structural equation model (SEM), to quantify the effects of the treatments and various measures of functional composition and diversity on litter and soil quality and overall decomposition. 3. Our results revealed multiple drivers of litter quality and showed that nutrient concentrations (N and calcium) were about twice as important as structural components (leaf dry matter content, fibres) in determining litter quality. Overall the experimental results suggest that N enrichment increases litter decomposition mostly indirectly through a shift in functional composition toward faster growing plant species, producing higher quality litter. N enrichment also altered soil quality and thereby litter decomposition, through its effects on vegetation cover. 4. Our approach provides a mechanistic tool to test the drivers of litter decomposition across different ecosystems. Our results show that litter quality is determined by several nutrient and structure traits and highlight the importance of considering shifts in plant species composition when assessing the effects of N enrichment on decomposition.

Published
2020

35. Sick plants in grassland communities: a growth-defense trade-off is the main driver of fungal pathogen abundance and impact

Author

Seraina L. Cappelli, Noémie A. Pichon, Eric Allan, and Anne Kempel

Subjects
geography, geography.geographical_feature_category, Ecology, fungi, Biodiversity, food and beverages, Plant community, Biology, 580 Plants (Botany), Generalist and specialist species, Trade-off, Grassland, Fungicide, Dominance (ecology), Pathogen
Abstract

Aboveground fungal pathogens can substantially reduce biomass production in grasslands. However, we lack a mechanistic understanding of the drivers of fungal infection and impact. Using a global change biodiversity experiment we show that the trade-off between plant growth and defense is the main determinant of fungal infection in grasslands. Nitrogen addition only indirectly increased infection via shifting plant communities towards more fast growing species. Plant diversity did not decrease infection, likely because the spillover of generalist pathogens or dominance of susceptible species counteracted dilution effects. There was also evidence that fungal pathogens reduced biomass more strongly in diverse communities. Further, fungicide altered plant-pathogen interactions beyond just removing pathogens, probably by removing certain fungi more efficiently than others. Our results show that fungal pathogens have large effects on plant functional composition and biomass production and highlight the importance of considering changes in pathogen community composition to understand their effects.

Published
2019
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37. Both diversity and functional composition affect productivity and water use efficiency in experimental temperate grasslands

Author

Walde, Manuel, Allan, Eric, Cappelli, Seraina L., Didion-Gency, Margaux, Gessler, Arthur, Lehmann, Marco M., Pichon, Noémie A., and Grossiord, Charlotte

Subjects
2. Zero hunger, soil biogeochemistry, 13. Climate action, 15N, Biodiversity–ecosystem functioning, Complementarity, 15. Life on land, Photosynthesis, 13C, Nitrogen uptake, Productivity
Abstract

1. Many experiments have shown that biodiversity promotes ecosystem functioning and stability and that this relationship varies with resource availability. However, we still have a poor understanding of the underlying physiological and ecological mechanisms driving diversity effects and how they may interact with soil nutrient availability. 2. We collected data in a grassland experiment factorially manipulating fertilization, species richness (SR), functional composition (slow-growing vs. fast-growing species) and functional diversity in resource economic traits. We measured above-ground productivity (AP), nitrogen (N) uptake, photosynthesis and water use efficiency by combining a 15N labelling approach with productivity, gas exchange and stable isotope measurements in 3 years differing in rainfall. 3. We found that sown SR increased AP, N uptake and photosynthesis, suggesting that SR is the most important driver of ecosystem productivity and nutrient cycling. Similarly, photosynthesis was affected by functional composition but not by functional diversity. Water use efficiency was reduced by sown SR for communities dominated by slow-growing species but not for communities dominated by fast-growing species. Fertilization increased productivity, N uptake and water use efficiency. The positive effects of high SR on ecosystem functions were independent of fertility levels. 4. Synthesis. Our results provide evidence that high species richness in temperate grasslands could enhance productivity and reduce the negative impacts of drought events. Multiple factors and community characteristics are important in driving enhanced ecosystem functioning in biodiverse grasslands and seem to affect functioning and stability through different mechanisms., Journal of Ecology, 109 (11), ISSN:0022-0477

38. Both diversity and functional composition affect productivity and water use efficiency in experimental temperate grasslands

Author

Walde, Manuel, Allan, Eric, Cappelli, Seraina L., Didion-Gency, Margaux, Gessler, Arthur, Lehmann, Marco M., Pichon, Noémie A., and Grossiord, Charlotte

Subjects
2. Zero hunger, 13. Climate action, 15. Life on land, 580 Plants (Botany)
Abstract

Many experiments have shown that biodiversity promotes ecosystem functioning and stability and that this relationship varies with resource availability. However, we still have a poor understanding of the underlying physiological and ecological mechanisms driving diversity effects and how they may interact with soil nutrient availability. We collected data in a grassland experiment factorially manipulating fertilization, species richness (SR), functional composition (slow-growing vs. fast-growing species) and functional diversity in resource economic traits. We measured above-ground productivity (AP), nitrogen (N) uptake, photosynthesis and water use efficiency by combining a N-15 labelling approach with productivity, gas exchange and stable isotope measurements in 3 years differing in rainfall. We found that sown SR increased AP, N uptake and photosynthesis, suggesting that SR is the most important driver of ecosystem productivity and nutrient cycling. Similarly, photosynthesis was affected by functional composition but not by functional diversity. Water use efficiency was reduced by sown SR for communities dominated by slow-growing species but not for communities dominated by fast-growing species. Fertilization increased productivity, N uptake and water use efficiency. The positive effects of high SR on ecosystem functions were independent of fertility levels. Synthesis. Our results provide evidence that high species richness in temperate grasslands could enhance productivity and reduce the negative impacts of drought events. Multiple factors and community characteristics are important in driving enhanced ecosystem functioning in biodiverse grasslands and seem to affect functioning and stability through different mechanisms.

39. Sick plants in grassland communities: a growth‐defense trade‐off is the main driver of fungal pathogen abundance

Author

Cappelli, Seraina L., Pichon, Noémie A., Kempel, Anne, and Allan, Eric

Subjects
2. Zero hunger, 13. Climate action, food and beverages, 15. Life on land, 580 Plants (Botany)
Abstract

Aboveground fungal pathogens can substantially reduce biomass production in grasslands. However, we lack a mechanistic understanding of the drivers of fungal pathogen infection and impact. Using a grassland global change and biodiversity experiment we show that the trade-off between plant growth and defense is the main determinant of infection incidence. In contrast, nitrogen addition only indirectly increased incidence via shifting plant communities towards faster growing species. Plant diversity did not decrease incidence, likely because spillover of generalist pathogens or dominance of susceptible plants counteracted negative diversity effects. A fungicide treatment increased plant biomass production and high levels of infection incidence were associated with reduced biomass. However, pathogen impact was context dependent and infection incidence reduced biomass more strongly in diverse communities. Our results show that a growth-defense trade-off is the key driver of pathogen incidence, but pathogen impact is determined by several mechanisms and may depend on pathogen community composition.

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