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1. Data for Change in functional trait diversity mediates the effects of nutrient addition on grassland stability [Dataset]

Author: Chen, Q., Wang, S., Seabloom, E.W., Isbell, F., Borer, E.T., Bakker, J.D., Bharath, S., Roscher, Christiane, Peri, P.L., Power, S.A., Donohue, I., Stevens, C., Ebeling, A., Nogueira, C., Caldeira, M.C., MacDougall, A.S., Moore, J.L., Bagchi, S., Jentsch, A., Tedder, M., Kirkman, K., Alberti, J., Hautier, Y., Chen, Q., Wang, S., Seabloom, E.W., Isbell, F., Borer, E.T., Bakker, J.D., Bharath, S., Roscher, Christiane, Peri, P.L., Power, S.A., Donohue, I., Stevens, C., Ebeling, A., Nogueira, C., Caldeira, M.C., MacDougall, A.S., Moore, J.L., Bagchi, S., Jentsch, A., Tedder, M., Kirkman, K., Alberti, J., and Hautier, Y.
Abstract: Nutrient enrichment impacts grassland plant diversity such as species richness, functional trait composition and diversity, but whether and how these changes affect ecosystem stability in the face of increasing climate extremes remains largely unknown.We quantified the direct and diversity-mediated effects of nutrient addition (by nitrogen, phosphorus, and potassium) on the stability of above-ground biomass production in 10 long-term grassland experimental sites. We measured five facets of stability as the temporal invariability, resistance during and recovery after extreme dry and wet growing seasons.Leaf traits (leaf carbon, nitrogen, phosphorus, potassium, and specific leaf area) were measured under ambient and nutrient addition conditions in the field and were used to construct the leaf economic spectrum (LES). We calculated functional trait composition and diversity of LES and of single leaf traits. We quantified the contribution of intraspecific trait shifts and species replacement to change in functional trait composition as responses to nutrient addition and its implications for ecosystem stability.Nutrient addition decreased functional trait diversity and drove grassland communities to the faster end of the LES primarily through intraspecific trait shifts, suggesting that intraspecific trait shifts should be included for accurately predicting ecosystem stability. Moreover, the change in functional trait diversity of the LES in turn influenced different facets of stability. That said, these diversity-mediated effects were overall weak and/or overwhelmed by the direct effects of nutrient addition on stability. As a result, nutrient addition did not strongly impact any of the stability facets. These results were generally consistent using individual leaf traits but the dominant pathways differed. Importantly, major influencing pathways differed using average trait values extracted from global trait databases (e.g. TRY).Synthesis. Investigating changes in multi
Published: 2024

2. Change in functional trait diversity mediates the effects of nutrient addition on grassland stability

Author: Chen, Q., Wang, S., Seabloom, E.W., Isbell, F., Borer, E.T., Bakker, J.D., Bharath, S., Roscher, Christiane, Peri, P.L., Power, S.A., Donohue, I., Stevens, C., Ebeling, A., Nogueira, C., Caldeira, M.C., MacDougall, A.S., Moore, J.L., Bagchi, S., Jentsch, A., Tedder, M., Kirkman, K., Alberti, J., Hautier, Y., Chen, Q., Wang, S., Seabloom, E.W., Isbell, F., Borer, E.T., Bakker, J.D., Bharath, S., Roscher, Christiane, Peri, P.L., Power, S.A., Donohue, I., Stevens, C., Ebeling, A., Nogueira, C., Caldeira, M.C., MacDougall, A.S., Moore, J.L., Bagchi, S., Jentsch, A., Tedder, M., Kirkman, K., Alberti, J., and Hautier, Y.
Abstract: Nutrient enrichment impacts grassland plant diversity such as species richness, functional trait composition and diversity, but whether and how these changes affect ecosystem stability in the face of increasing climate extremes remains largely unknown.We quantified the direct and diversity-mediated effects of nutrient addition (by nitrogen, phosphorus, and potassium) on the stability of above-ground biomass production in 10 long-term grassland experimental sites. We measured five facets of stability as the temporal invariability, resistance during and recovery after extreme dry and wet growing seasons.Leaf traits (leaf carbon, nitrogen, phosphorus, potassium, and specific leaf area) were measured under ambient and nutrient addition conditions in the field and were used to construct the leaf economic spectrum (LES). We calculated functional trait composition and diversity of LES and of single leaf traits. We quantified the contribution of intraspecific trait shifts and species replacement to change in functional trait composition as responses to nutrient addition and its implications for ecosystem stability.Nutrient addition decreased functional trait diversity and drove grassland communities to the faster end of the LES primarily through intraspecific trait shifts, suggesting that intraspecific trait shifts should be included for accurately predicting ecosystem stability. Moreover, the change in functional trait diversity of the LES in turn influenced different facets of stability. That said, these diversity-mediated effects were overall weak and/or overwhelmed by the direct effects of nutrient addition on stability. As a result, nutrient addition did not strongly impact any of the stability facets. These results were generally consistent using individual leaf traits but the dominant pathways differed. Importantly, major influencing pathways differed using average trait values extracted from global trait databases (e.g. TRY).Synthesis. Investigating changes in multi
Published: 2024

3. Extreme drought impacts have been underestimated in grasslands and shrublands globally

Author: Smith, M.D., Wilkins, K.D., Holdrege, M.C., Wilfahrt, P., Collins, S.L., Knapp, A.K., Sala, O.E., Dukes, J.S., Phillips, R.P., Yahdjian, L., Gherardi, L.A., Ohlert, T., Beier, C., Fraser, L.H., Jentsch, A., Loik, M.E., Maestre, F.T., Power, S.A., Yu, Q., Felton, A.J., Munson, S.M., Luo, Y., Abdoli, H., Abedi, M., Alados, C.L., Alberti, J., Alon, M., An, H., Anacker, B., Anderson, M., Auge, Harald, Bachle, S., Bahalkeh, K., Bahn, M., Batbaatar, A., Bauerle, T., Beard, K.H., Behn, K., Beil, I., Biancari, L., Blindow, I., Bondaruk, V.F., Borer, E.T., Bork, E.W., Bruschetti, C.M., Byrne, K.M., Cahill jr., J.F., Calvo, D.A., Carbognani, M., Cardoni, A., Carlyle, C.N., Castillo-Garcia, M., Chang, S.X., Chieppa, J., Cianciaruso, M.V., Cohen, O., Cordeiro, A.L., Cusack, D.F., Dahlke, S., Daleo, P., D'Antonio, C.M., Dietterich, L.H., Doherty, T.S., Dubbert, M., Ebeling, A., Eisenhauer, N., Fischer, F.M., Forte, T.G.W., Gebauer, T., Gozalo, B., Greenville, A.C., Guidoni-Martins, K.G., Hannusch, H.J., Haugum, S.V., Hautier, Y., Hefting, M., Henry, H.A.L., Hoss, D., Ingrisch, J., Iribarne, O., Isbell, F., Johnson, Y., Jordan, S., Kelly, E.F., Kimmel, K., Kreyling, J., Kröel-Dulay, G., Kröpfl, A., Kübert, A., Kulmatiski, A., Lamb, E.G., Steenberg Larsen, K., Larson, J., Lawson, J., Leder, C.V., Linstädter, A., Liu, J., Liu, S., Lodge, A., Longo, G., Smith, M.D., Wilkins, K.D., Holdrege, M.C., Wilfahrt, P., Collins, S.L., Knapp, A.K., Sala, O.E., Dukes, J.S., Phillips, R.P., Yahdjian, L., Gherardi, L.A., Ohlert, T., Beier, C., Fraser, L.H., Jentsch, A., Loik, M.E., Maestre, F.T., Power, S.A., Yu, Q., Felton, A.J., Munson, S.M., Luo, Y., Abdoli, H., Abedi, M., Alados, C.L., Alberti, J., Alon, M., An, H., Anacker, B., Anderson, M., Auge, Harald, Bachle, S., Bahalkeh, K., Bahn, M., Batbaatar, A., Bauerle, T., Beard, K.H., Behn, K., Beil, I., Biancari, L., Blindow, I., Bondaruk, V.F., Borer, E.T., Bork, E.W., Bruschetti, C.M., Byrne, K.M., Cahill jr., J.F., Calvo, D.A., Carbognani, M., Cardoni, A., Carlyle, C.N., Castillo-Garcia, M., Chang, S.X., Chieppa, J., Cianciaruso, M.V., Cohen, O., Cordeiro, A.L., Cusack, D.F., Dahlke, S., Daleo, P., D'Antonio, C.M., Dietterich, L.H., Doherty, T.S., Dubbert, M., Ebeling, A., Eisenhauer, N., Fischer, F.M., Forte, T.G.W., Gebauer, T., Gozalo, B., Greenville, A.C., Guidoni-Martins, K.G., Hannusch, H.J., Haugum, S.V., Hautier, Y., Hefting, M., Henry, H.A.L., Hoss, D., Ingrisch, J., Iribarne, O., Isbell, F., Johnson, Y., Jordan, S., Kelly, E.F., Kimmel, K., Kreyling, J., Kröel-Dulay, G., Kröpfl, A., Kübert, A., Kulmatiski, A., Lamb, E.G., Steenberg Larsen, K., Larson, J., Lawson, J., Leder, C.V., Linstädter, A., Liu, J., Liu, S., Lodge, A., and Longo, G.
Abstract: Climate change is increasing the frequency and severity of short-term (~1 y) drought events—the most common duration of drought—globally. Yet the impact of this intensification of drought on ecosystem functioning remains poorly resolved. This is due in part to the widely disparate approaches ecologists have employed to study drought, variation in the severity and duration of drought studied, and differences among ecosystems in vegetation, edaphic and climatic attributes that can mediate drought impacts. To overcome these problems and better identify the factors that modulate drought responses, we used a coordinated distributed experiment to quantify the impact of short-term drought on grassland and shrubland ecosystems. With a standardized approach, we imposed ~a single year of drought at 100 sites on six continents. Here we show that loss of a foundational ecosystem function—aboveground net primary production (ANPP)—was 60% greater at sites that experienced statistically extreme drought (1-in-100-y event) vs. those sites where drought was nominal (historically more common) in magnitude (35% vs. 21%, respectively). This reduction in a key carbon cycle process with a single year of extreme drought greatly exceeds previously reported losses for grasslands and shrublands. Our global experiment also revealed high variability in drought response but that relative reductions in ANPP were greater in drier ecosystems and those with fewer plant species. Overall, our results demonstrate with unprecedented rigor that the global impacts of projected increases in drought severity have been significantly underestimated and that drier and less diverse sites are likely to be most vulnerable to extreme drought.
Published: 2024

4. Nutrient addition drives declines in grassland species richness primarily via enhanced species loss

Author: Muehleisen, A., Carmen, A., Shaw, G., Madelon, A., Lina, B., Reed, A., LaForgia, M., Borer, E.T., Seabloom, Eric W., Bakker, J.D., Arnillas, C.A., Biederman, L.A., Chen, Q.Q., Cleland, E.E., Fay, P.A., Hagenah, N., Harpole, W.S., Hautier, Y., Henning, Jeremiah A., Knops, J., Komatsu, K.J., MacDougall, A.S., Ladeuceur, E, McCulley, R., Moore, J., Ohlert, T., Power, S.A., Stevens, Carly, Wilfahrt, P.A., Hallett, L., Muehleisen, A., Carmen, A., Shaw, G., Madelon, A., Lina, B., Reed, A., LaForgia, M., Borer, E.T., Seabloom, Eric W., Bakker, J.D., Arnillas, C.A., Biederman, L.A., Chen, Q.Q., Cleland, E.E., Fay, P.A., Hagenah, N., Harpole, W.S., Hautier, Y., Henning, Jeremiah A., Knops, J., Komatsu, K.J., MacDougall, A.S., Ladeuceur, E, McCulley, R., Moore, J., Ohlert, T., Power, S.A., Stevens, Carly, Wilfahrt, P.A., and Hallett, L.
Abstract: Declines in grassland diversity in response to nutrient addition are a general consequence of global change. This decline in species richness may be driven by multiple underlying processes operating at different time-scales. Nutrient addition can reduce diversity by enhancing the rate of local extinction via competitive exclusion, or by reducing the rate of colonization by constraining the pool of species able to colonize under new conditions. Partitioning net change into extinction and colonization rates will better delineate the long-term effect of global change in grasslands. We synthesized changes in richness in response to experimental fertilization with nitrogen, phosphorus and potassium with micronutrients across 30 grasslands. We quantified changes in local richness, colonization, and extinction over 8–10 years of nutrient addition, and compared these rates against control conditions to isolate the effect of nutrient addition from background dynamics. Total richness at steady state in the control plots was the sum of equal, relatively high rates of local colonization and extinction. On aggregate, 30%–35% of initial species were lost and the same proportion of new species were gained at least once over a decade. Absolute turnover increased with site-level richness but was proportionately greater at lower-richness sites relative to starting richness. Loss of total richness with nutrient addition, especially N in combination with P or K, was driven by enhanced rates of extinction with a smaller contribution from reduced colonization. Enhanced extinction and reduced colonization were disproportionately among native species, perennials, and forbs. Reduced colonization plateaued after the first few (<5) years after nutrient addition, while enhanced extinction continued throughout the first decade. Synthesis. Our results indicate a high rate of colonizations and extinctions underlying the richness of ambient communities and that nutrient enhancement drives overall
Published: 2023

5. Nutrient addition impacts grassland productivity responses to dry and wet climate extremes despite functional diversity loss

Author: Chen, Q., Wang, S., Seabloom, E.W., Isbell, F., Borer, E.T., Bakker, J.D., Bharath, S., Roscher, Christiane, Peri, P.L., Power, S.A., Donohue, I., Stevens, C., Ebeling, A., Nogueira, C., Caldeira, M.C., MacDougall, A.S., Moore, J.L., Bagchi, S., Jentsch, A., Tedder, M., Kirkman, K., Hautier, Y., Chen, Q., Wang, S., Seabloom, E.W., Isbell, F., Borer, E.T., Bakker, J.D., Bharath, S., Roscher, Christiane, Peri, P.L., Power, S.A., Donohue, I., Stevens, C., Ebeling, A., Nogueira, C., Caldeira, M.C., MacDougall, A.S., Moore, J.L., Bagchi, S., Jentsch, A., Tedder, M., Kirkman, K., and Hautier, Y.
Abstract: Eutrophication impacts grassland diversity such as species richness, functional trait diversity and composition, but whether and how these changes affect ecosystem functional stability under increasing climate extremes is unknown. We quantify the direct and diversity-mediated effects of nutrient addition on functional stability of productivity as measured by resistance during and recovery after dry and wet growing seasons, and temporal invariability across 19 grasslands spanning four continents. We use leaf traits measured in the field to construct slow-fast leaf economic spectrum and calculate functional trait composition and diversity of the slow-fast trait. Nutrient addition increased resistance during dry growing seasons mainly through its direct effects. It also increased resistance during wet growing seasons directly, but these positive effects were weakened by indirect negative effects through reducing slow-fast functional diversity. Nutrient addition had weak effects on recovery after dry growing seasons, but it decreased recovery after wet growing seasons mainly through its direct effects. Nutrient addition increased temporal invariability through resistance, but decreased it through recovery and reducing species richness, leading to overall weak net effects. Thus, processes and influencing pathways independent of plant diversity should be carefully taken into account in understanding ecosystem stability in response to increasing global changes.
Published: 2023

6. Multidimensional responses of ecological stability to eutrophication in grasslands

Author: Chen, Q., Wang, S., Borer, E.T., Bakker, J.D., Seabloom, E.W., Harpole, William Stanley ; orcid:0000-0002-3404-9174, Eisenhauer, N., Lekberg, Y., Buckley, Y.M., Catford, J.A., Roscher, Christiane, Donohue, I., Power, S.A., Daleo, P., Ebeling, A., Knops, J.M.H., Martina, J.P., Eskelinen, Anu Maria, Morgan, J.W., Risch, A.C., Caldeira, M.C., Bugalho, M.N., Virtanen, R., Barrio, I.C., Niu, Y., Jentsch, A., Stevens, C.J., Alberti, M., Hautier, Y., Chen, Q., Wang, S., Borer, E.T., Bakker, J.D., Seabloom, E.W., Harpole, William Stanley ; orcid:0000-0002-3404-9174, Eisenhauer, N., Lekberg, Y., Buckley, Y.M., Catford, J.A., Roscher, Christiane, Donohue, I., Power, S.A., Daleo, P., Ebeling, A., Knops, J.M.H., Martina, J.P., Eskelinen, Anu Maria, Morgan, J.W., Risch, A.C., Caldeira, M.C., Bugalho, M.N., Virtanen, R., Barrio, I.C., Niu, Y., Jentsch, A., Stevens, C.J., Alberti, M., and Hautier, Y.
Abstract: Eutrophication usually impacts biodiversity, species composition, and functioning of grassland communities. Whether such effects propagate to influence the stability of these community aspects is unknown. Using standardized experiments across 55 global grasslands, we quantified the effects of nutrient addition on five stability facets (i.e., temporal invariability and resistance during and recovery after dry and wet growing seasons) for three community aspects (i.e., aboveground biomass, community composition, and species richness). Nutrient addition reduced the temporal invariability and resistance of species richness and community composition, but not biomass, during dry and wet growing seasons. Temporal invariability and resistance during, but not recovery after, dry and wet growing seasons were strongly positively correlated in both ambient and eutrophic conditions. This indicates that maintaining and restoring the stability of plant communities requires increasing resistance rather than recovery. Harnessing the complexity of ecological stability provides new insights for grassland ecosystem sustainability in a changing world.
Published: 2023

7. Data package for NutNet project: Compositional variation in grassland plant communities (60 sites, 2007-2020) ver 1

Author: Bakker, J.D., Price, J.N., Henning, J.A., Batzer, E.E., Ohlert, T.J., Wainwright, C.E., Adler, P.B., Alberti, J., Arnillas, C.A., Biederman, L.A., Borer, E.T., Brudvig, L.A., Buckley, Y.M., Bugalho, M.N., Cadotte, M.W., Caldeira, M.C., Catford, J.A., Chen, Q., Crawley, M.J., Daleo, P., Dickman, C.R., Donohue, I., DuPre, M.E., Ebeling, A., Eisenhauer, N., Fay, P.A., Gruner, D.S., Haider, S., Hautier, Y., Jentsch, A., Kirkman, K., Knops, J.M.H., Lannes, L.S., MacDougall, A.S., McCulley, R.L., Mitchell, R.M., Moore, J.L., Morgan, J.W., Mortensen, B., Venterink, H.O., Peri, P.L., Power, S.A., Prober, S.M., Roscher, Christiane, Sankaran, M., Seabloom, E.W., Smith, M.D., Stevens, C., Sullivan, L.L., Tedder, M., Veen, G.F.C., Virtanen, R., Wardle, G.M., Bakker, J.D., Price, J.N., Henning, J.A., Batzer, E.E., Ohlert, T.J., Wainwright, C.E., Adler, P.B., Alberti, J., Arnillas, C.A., Biederman, L.A., Borer, E.T., Brudvig, L.A., Buckley, Y.M., Bugalho, M.N., Cadotte, M.W., Caldeira, M.C., Catford, J.A., Chen, Q., Crawley, M.J., Daleo, P., Dickman, C.R., Donohue, I., DuPre, M.E., Ebeling, A., Eisenhauer, N., Fay, P.A., Gruner, D.S., Haider, S., Hautier, Y., Jentsch, A., Kirkman, K., Knops, J.M.H., Lannes, L.S., MacDougall, A.S., McCulley, R.L., Mitchell, R.M., Moore, J.L., Morgan, J.W., Mortensen, B., Venterink, H.O., Peri, P.L., Power, S.A., Prober, S.M., Roscher, Christiane, Sankaran, M., Seabloom, E.W., Smith, M.D., Stevens, C., Sullivan, L.L., Tedder, M., Veen, G.F.C., Virtanen, R., and Wardle, G.M.
Abstract: Human activities are altering ecological communities around the globe. Understanding the implications of these changes requires that we consider the composition of those communities. However, composition can be summarized by many metrics which in turn are influenced by different ecological processes. For example, incidence-based metrics strongly reflect species gains or losses, while abundance-based metrics are minimally affected by changes in the abundance of small or uncommon species. Furthermore, metrics might be correlated with different predictors. We used a globally distributed experiment to examine variation in species composition within 60 grasslands on six continents. Each site had an identical experimental and sampling design: 24 plots × 4 years. We expressed compositional variation within each site—not across sites—using abundance- and incidence-based metrics of the magnitude of dissimilarity (Bray–Curtis and Sorensen, respectively), abundance- and incidence-based measures of the relative importance of replacement (balanced variation and species turnover, respectively), and species richness at two scales (per plot-year [alpha] and per site [gamma]). Average compositional variation among all plot-years at a site was high and similar to spatial variation among plots in the pretreatment year, but lower among years in untreated plots. For both types of metrics, most variation was due to replacement rather than nestedness. Differences among sites in overall within-site compositional variation were related to several predictors. Environmental heterogeneity (expressed as the CV of total aboveground plant biomass in unfertilized plots of the site) was an important predictor for most metrics. Biomass production was a predictor of species turnover and of alpha diversity but not of other metrics. Continentality (measured as annual temperature range) was a strong predictor of Sorensen dissimilarity. Metrics of compositional variation are moderately correlated: knowin
Published: 2023

8. Drivers of soil microbial and detritivore activity across global grasslands

Author: Siebert, J., Sünnemann, M., Hautier, Y., Risch, A.C., Bakker, J.D., Biederman, L., Blumenthal, D.M., Borer, E.T., Bugalho, M.N., Broadbent, A.A.D., Caldeira, M.C., Cleland, E., Davies, K.F., Eskelinen, Anu Maria, Hagenah, N., Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Moore, J.L., Power, S.A., Price, J.N., Seabloom, E.W., Standish, R., Stevens, C.J., Zimmermann, S., Eisenhauer, N., Siebert, J., Sünnemann, M., Hautier, Y., Risch, A.C., Bakker, J.D., Biederman, L., Blumenthal, D.M., Borer, E.T., Bugalho, M.N., Broadbent, A.A.D., Caldeira, M.C., Cleland, E., Davies, K.F., Eskelinen, Anu Maria, Hagenah, N., Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Moore, J.L., Power, S.A., Price, J.N., Seabloom, E.W., Standish, R., Stevens, C.J., Zimmermann, S., and Eisenhauer, N.
Abstract: Covering approximately 40% of land surfaces, grasslands provide critical ecosystem services that rely on soil organisms. However, the global determinants of soil biodiversity and functioning remain underexplored. In this study, we investigate the drivers of soil microbial and detritivore activity in grasslands across a wide range of climatic conditions on five continents. We apply standardized treatments of nutrient addition and herbivore reduction, allowing us to disentangle the regional and local drivers of soil organism activity. We use structural equation modeling to assess the direct and indirect effects of local and regional drivers on soil biological activities. Microbial and detritivore activities are positively correlated across global grasslands. These correlations are shaped more by global climatic factors than by local treatments, with annual precipitation and soil water content explaining the majority of the variation. Nutrient addition tends to reduce microbial activity by enhancing plant growth, while herbivore reduction typically increases microbial and detritivore activity through increased soil moisture. Our findings emphasize soil moisture as a key driver of soil biological activity, highlighting the potential impacts of climate change, altered grazing pressure, and eutrophication on nutrient cycling and decomposition within grassland ecosystems.
Published: 2023

9. The positive effect of plant diversity on soil carbon depends on climate

Author: Spohn, M., Bagchi, S., Biederman, L.A., Borer, E.T., Bråthen, K.A., Bugalho, M.N., Caldeira, M.C., Catford, J.A., Collins, S.L., Eisenhauer, N., Hagenah, N., Haider, S., Hautier, Y., Knops, J.M.H., Koerner, S.E., Laanisto, L., Lekberg, Y., Martina, J.P., Martinson, H., McCulley, R.L., Peri, P.L., Macek, P., Power, S.A., Risch, A.C., Roscher, Christiane, Seabloom, E.W., Stevens, C., Veen, G.F.C., Virtanen, R., Yahdjian, L., Spohn, M., Bagchi, S., Biederman, L.A., Borer, E.T., Bråthen, K.A., Bugalho, M.N., Caldeira, M.C., Catford, J.A., Collins, S.L., Eisenhauer, N., Hagenah, N., Haider, S., Hautier, Y., Knops, J.M.H., Koerner, S.E., Laanisto, L., Lekberg, Y., Martina, J.P., Martinson, H., McCulley, R.L., Peri, P.L., Macek, P., Power, S.A., Risch, A.C., Roscher, Christiane, Seabloom, E.W., Stevens, C., Veen, G.F.C., Virtanen, R., and Yahdjian, L.
Abstract: Little is currently known about how climate modulates the relationship between plant diversity and soil organic carbon and the mechanisms involved. Yet, this knowledge is of crucial importance in times of climate change and biodiversity loss. Here, we show that plant diversity is positively correlated with soil carbon content and soil carbon-to-nitrogen ratio across 84 grasslands on six continents that span wide climate gradients. The relationships between plant diversity and soil carbon as well as plant diversity and soil organic matter quality (carbon-to-nitrogen ratio) are particularly strong in warm and arid climates. While plant biomass is positively correlated with soil carbon, plant biomass is not significantly correlated with plant diversity. Our results indicate that plant diversity influences soil carbon storage not via the quantity of organic matter (plant biomass) inputs to soil, but through the quality of organic matter. The study implies that ecosystem management that restores plant diversity likely enhances soil carbon sequestration, particularly in warm and arid climates.
Published: 2023

10. Multidimensional responses of grassland stability to eutrophication

Author: Chen, Q., Wang, S., Borer, E.T., Bakker, J.D., Seabloom, E.W., Harpole, William Stanley, Eisenhauer, N., Lekberg, Y., Buckley, Y.M., Catford, J.A., Roscher, Christiane, Donohue, I., Power, S.A., Daleo, P., Ebeling, A., Knops, J.M.H., Martina, J.P., Eskelinen, Anu Maria, Morgan, J.W., Risch, A.C., Caldeira, M.C., Bugalho, M.N., Virtanen, R., Barrio, I.C., Niu, Y., Jentsch, A., Stevens, C.J., Gruner, D.S., MacDougall, A.S., Alberti, J., Hautier, Y., Chen, Q., Wang, S., Borer, E.T., Bakker, J.D., Seabloom, E.W., Harpole, William Stanley, Eisenhauer, N., Lekberg, Y., Buckley, Y.M., Catford, J.A., Roscher, Christiane, Donohue, I., Power, S.A., Daleo, P., Ebeling, A., Knops, J.M.H., Martina, J.P., Eskelinen, Anu Maria, Morgan, J.W., Risch, A.C., Caldeira, M.C., Bugalho, M.N., Virtanen, R., Barrio, I.C., Niu, Y., Jentsch, A., Stevens, C.J., Gruner, D.S., MacDougall, A.S., Alberti, J., and Hautier, Y.
Abstract: Eutrophication usually impacts grassland biodiversity, community composition, and biomass production, but its impact on the stability of these community aspects is unclear. One challenge is that stability has many facets that can be tightly correlated (low dimensionality) or highly disparate (high dimensionality). Using standardized experiments in 55 grassland sites from a globally distributed experiment (NutNet), we quantify the effects of nutrient addition on five facets of stability (temporal invariability, resistance during dry and wet growing seasons, recovery after dry and wet growing seasons), measured on three community aspects (aboveground biomass, community composition, and species richness). Nutrient addition reduces the temporal invariability and resistance of species richness and community composition during dry and wet growing seasons, but does not affect those of biomass. Different stability measures are largely uncorrelated under both ambient and eutrophic conditions, indicating consistently high dimensionality. Harnessing the dimensionality of ecological stability provides insights for predicting grassland responses to global environmental change.
Published: 2023

11. Compositional variation in grassland plant communities

Author: Bakker, J.D., Price, J.N., Henning, J.A., Batzer, E.E., Ohlert, T.J., Wainwright, C.E., Adler, P.B., Alberti, J., Arnillas, C.A., Biederman, L.A., Borer, E.T., Brudvig, L.A., Buckley, Y.M., Bugalho, M.N., Cadotte, M.W., Caldeira, M.C., Catford, J.A., Chen, Q., Crawley, M.J., Daleo, P., Dickman, C.R., Donohue, I., DuPre, M.E., Ebeling, A., Eisenhauer, N., Fay, P.A., Gruner, D.S., Haider, S., Hautier, Y., Jentsch, A., Kirkman, K., Knops, J.M.H., Lannes, L.S., MacDougall, A.S., McCulley, R.L., Mitchell, R.M., Moore, J.L., Morgan, J.W., Mortensen, B., Venterink, H.O., Peri, P.L., Power, S.A., Prober, S.M., Roscher, Christiane, Sankaran, M., Seabloom, E.W., Smith, M.D., Stevens, C., Sullivan, L.L., Tedder, M., Veen, G.F.C., Virtanen, R., Wardle, G.M., Bakker, J.D., Price, J.N., Henning, J.A., Batzer, E.E., Ohlert, T.J., Wainwright, C.E., Adler, P.B., Alberti, J., Arnillas, C.A., Biederman, L.A., Borer, E.T., Brudvig, L.A., Buckley, Y.M., Bugalho, M.N., Cadotte, M.W., Caldeira, M.C., Catford, J.A., Chen, Q., Crawley, M.J., Daleo, P., Dickman, C.R., Donohue, I., DuPre, M.E., Ebeling, A., Eisenhauer, N., Fay, P.A., Gruner, D.S., Haider, S., Hautier, Y., Jentsch, A., Kirkman, K., Knops, J.M.H., Lannes, L.S., MacDougall, A.S., McCulley, R.L., Mitchell, R.M., Moore, J.L., Morgan, J.W., Mortensen, B., Venterink, H.O., Peri, P.L., Power, S.A., Prober, S.M., Roscher, Christiane, Sankaran, M., Seabloom, E.W., Smith, M.D., Stevens, C., Sullivan, L.L., Tedder, M., Veen, G.F.C., Virtanen, R., and Wardle, G.M.
Abstract: Human activities are altering ecological communities around the globe. Understanding the implications of these changes requires that we consider the composition of those communities. However, composition can be summarized by many metrics which in turn are influenced by different ecological processes. For example, incidence-based metrics strongly reflect species gains or losses, while abundance-based metrics are minimally affected by changes in the abundance of small or uncommon species. Furthermore, metrics might be correlated with different predictors. We used a globally distributed experiment to examine variation in species composition within 60 grasslands on six continents. Each site had an identical experimental and sampling design: 24 plots × 4 years. We expressed compositional variation within each site—not across sites—using abundance- and incidence-based metrics of the magnitude of dissimilarity (Bray–Curtis and Sorensen, respectively), abundance- and incidence-based measures of the relative importance of replacement (balanced variation and species turnover, respectively), and species richness at two scales (per plot-year [alpha] and per site [gamma]). Average compositional variation among all plot-years at a site was high and similar to spatial variation among plots in the pretreatment year, but lower among years in untreated plots. For both types of metrics, most variation was due to replacement rather than nestedness. Differences among sites in overall within-site compositional variation were related to several predictors. Environmental heterogeneity (expressed as the CV of total aboveground plant biomass in unfertilized plots of the site) was an important predictor for most metrics. Biomass production was a predictor of species turnover and of alpha diversity but not of other metrics. Continentality (measured as annual temperature range) was a strong predictor of Sorensen dissimilarity. Metrics of compositional variation are moderately correlated: knowin
Published: 2023

12. Predicting harmful algal blooms through a combined modelling approach

Author: Halteren, Machiel van, Hautier, Y. (Thesis Advisor), Halteren, Machiel van, and Hautier, Y. (Thesis Advisor)
Abstract: The increasing intensity and frequency of harmful cyanobacterial blooms due to climate change and anthropogenically induced nutrient input is a well-studied and documented issue. Within the Netherlands, a protocol is in place to guarantee the safety of bathers based in part on cyano associated chlorophyll-a concentrations, measured in situ. Weather effects such as wind speed, precipitation or irradiance affect cyanobacteria presence. To increase the efficacy of the protocol measures and efficiency of the measurements a forecast through a combination of mechanistic models is proposed in this research. The combination of models should be able to translate weather forecasts into accurate and precise results of cyanobacteria presence. The combined models are ECMWF forecasts, the physical lake model General Lake Model (GLM) and the ecological model PCLake+. 50 different forecasts of ECMWF are used as input for GLM, which together provide input on water temperature, evaporation, wind speed, irradiation and precipitation for PCLake+. The important output variables of the models together will be a forecast on cyano associated chlorophyll-a and total chlorophyll-a concentration. Historical data as input for the models resulted in accurate model results for GLM. PCLake+ modelled a total chlorophyll-a concentration accurately but on cyano associated chlorophyll-a the accuracy decreased markedly. The effect of weather forecasts translates well to the total chlorophyll-a variance. Uncertainties concerning weather events present in early forecasts but removed in later forecasts resulted in a decrease in variance in the output. Future improvements on the combined models should focus on modelling the correct dominant group of algae. A suggested improvement to the model is an inclusion of a weather dependent groundwater model. Once the model is improved, the cyanobacteria forecasts can help improve the efficacy of Dutch water management practices.
Published: 2023

13. Soil net nitrogen mineralisation across global grasslands

Author: Risch, A. C., Zimmermann, S., Ochoa-Hueso, R., Schütz, M., Frey, B., Firn, J. L., Fay, P. A., Hagedorn, F., Borer, E. T., Seabloom, E. W., Harpole, W. S., Knops, J. M. H., McCulley, R. L., Broadbent, A. A. D., Stevens, C. J., Silveira, M. L., Adler, P. B., Báez, S., Biederman, L. A., Blair, J. M., Brown, C. S., Caldeira, M. C., Collins, S. L., Daleo, P., di Virgilio, A., Ebeling, A., Eisenhauer, N., Esch, E., Eskelinen, A., Hagenah, N., Hautier, Y., Kirkman, K. P., MacDougall, A. S., Moore, J. L., Power, S. A., Prober, S. M., Roscher, C., Sankaran, M., Siebert, J., Speziale, K. L., Tognetti, P. M., Virtanen, R., Yahdjian, L., and Moser, B.
Published: 2019
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14. Evolutionary history of grazing and resources determine herbivore exclusion effects on plant diversity

Author: Price, J., Sitters, J., Ohlert, Timothy, Tognetti, P.M., Brown, C, Seabloom, Eric W., Borer, Elizabeth, Prober, S., Bakker, L., MacDougall, Andrew S., Yahdjian, L., Gruner, Daniel S., Olde Venterink, Harry, Barrio, Isabel C., Graff, P., Bagchi, Sumanta, Arnillas, C.A., Bakker, J.D., Blumenthal, Dana M., Boughton, Elizabeth H., Brudvig, Lars A., Bugalho, Miguel N., Cadotte, Marc, Caldeira, M.C., Dickman, C. R., Donohue, Ian, Gregory, S., Hautier, Y., Jónsdóttir, Ingibjörg S., Lannes, L.S., Mcculley, Rebecca, Power, S.A., Risch, A., Schütz, Martin, Standish, Rachel J., Stevens, Carly, Veen, G.F., Virtanen, Risto, Wardle, Glenda M., Price, J., Sitters, J., Ohlert, Timothy, Tognetti, P.M., Brown, C, Seabloom, Eric W., Borer, Elizabeth, Prober, S., Bakker, L., MacDougall, Andrew S., Yahdjian, L., Gruner, Daniel S., Olde Venterink, Harry, Barrio, Isabel C., Graff, P., Bagchi, Sumanta, Arnillas, C.A., Bakker, J.D., Blumenthal, Dana M., Boughton, Elizabeth H., Brudvig, Lars A., Bugalho, Miguel N., Cadotte, Marc, Caldeira, M.C., Dickman, C. R., Donohue, Ian, Gregory, S., Hautier, Y., Jónsdóttir, Ingibjörg S., Lannes, L.S., Mcculley, Rebecca, Power, S.A., Risch, A., Schütz, Martin, Standish, Rachel J., Stevens, Carly, Veen, G.F., Virtanen, Risto, and Wardle, Glenda M.
Published: 2022

15. Nutrient identity modifies the destabilising effects of eutrophication in grasslands

Author: Carroll, O., Batzer, E., Bharath, S., Borer, E.T., Campana, S., Esch, E., Hautier, Y., Ohlert, T., Seabloom, E.W., Adler, P.B., Bakker, J.D., Biederman, L., Bugalho, M.N., Caldeira, M., Chen, Q., Davies, K.F., Fay, P.A., Knops, J.M.H., Komatsu, K., Martina, J.P., McCann, K.S., Moore, J.L., Morgan, J.W., Muraina, T.O., Osborne, B., Risch, A.C., Stevens, C., Wilfahrt, P.A., Yahdjian, L., MacDougall, A.S., Carroll, O., Batzer, E., Bharath, S., Borer, E.T., Campana, S., Esch, E., Hautier, Y., Ohlert, T., Seabloom, E.W., Adler, P.B., Bakker, J.D., Biederman, L., Bugalho, M.N., Caldeira, M., Chen, Q., Davies, K.F., Fay, P.A., Knops, J.M.H., Komatsu, K., Martina, J.P., McCann, K.S., Moore, J.L., Morgan, J.W., Muraina, T.O., Osborne, B., Risch, A.C., Stevens, C., Wilfahrt, P.A., Yahdjian, L., and MacDougall, A.S.
Abstract: Nutrient enrichment can simultaneously increase and destabilise plant biomass production, with co-limitation by multiple nutrients potentially intensifying these effects. Here, we test how factorial additions of nitrogen (N), phosphorus (P) and potassium with essential nutrients (K+) affect the stability (mean/standard deviation) of aboveground biomass in 34 grasslands over 7 years. Destabilisation with fertilisation was prevalent but was driven by single nutrients, not synergistic nutrient interactions. On average, N-based treatments increased mean biomass production by 21–51% but increased its standard deviation by 40–68% and so consistently reduced stability. Adding P increased interannual variability and reduced stability without altering mean biomass, while K+ had no general effects. Declines in stability were largest in the most nutrient-limited grasslands, or where nutrients reduced species richness or intensified species synchrony. We show that nutrients can differentially impact the stability of biomass production, with N and P in particular disproportionately increasing its interannual variability.
Published: 2022

16. Evolutionary history of grazing and resources determine herbivore exclusion effects on plant diversity

Author: Price, J.N., Sitters, J., Ohlert, T., Tognetti, P.M., Brown, C.S., Seabloom, E.W., Borer, E.T., Prober, S.M., Bakker, E.S., MacDougall, A.S., Yahdjian, L., Gruner, D.S., Olde Venterink, H., Barrio, I.C., Graff, P., Bagchi, S., Arnillas, C.A., Bakker, J.D., Blumenthal, D.M., Boughton, E.H., Brudvig, L.A., Bugalho, M.N., Cadotte, M.W., Caldeira, M.C., Dickman, C.R., Donohue, I., Gregory, S., Hautier, Y., Jónsdóttir, I.S., Lannes, L.S., McCulley, R.L., Moore, J.L., Power, S.A., Risch, A.C., Schutz, M., Standish, R., Stevens, C.J., Veen, G.F., Virtanen, R., Wardle, G.M., Price, J.N., Sitters, J., Ohlert, T., Tognetti, P.M., Brown, C.S., Seabloom, E.W., Borer, E.T., Prober, S.M., Bakker, E.S., MacDougall, A.S., Yahdjian, L., Gruner, D.S., Olde Venterink, H., Barrio, I.C., Graff, P., Bagchi, S., Arnillas, C.A., Bakker, J.D., Blumenthal, D.M., Boughton, E.H., Brudvig, L.A., Bugalho, M.N., Cadotte, M.W., Caldeira, M.C., Dickman, C.R., Donohue, I., Gregory, S., Hautier, Y., Jónsdóttir, I.S., Lannes, L.S., McCulley, R.L., Moore, J.L., Power, S.A., Risch, A.C., Schutz, M., Standish, R., Stevens, C.J., Veen, G.F., Virtanen, R., and Wardle, G.M.
Abstract: Ecological models predict that the effects of mammalian herbivore exclusion on plant diversity depend on resource availability and plant exposure to ungulate grazing over evolutionary time. Using an experiment replicated in 57 grasslands on six continents, with contrasting evolutionary history of grazing, we tested how resources (mean annual precipitation and soil nutrients) determine herbivore exclusion effects on plant diversity, richness and evenness. Here we show that at sites with a long history of ungulate grazing, herbivore exclusion reduced plant diversity by reducing both richness and evenness and the responses of richness and diversity to herbivore exclusion decreased with mean annual precipitation. At sites with a short history of grazing, the effects of herbivore exclusion were not related to precipitation but differed for native and exotic plant richness. Thus, plant species’ evolutionary history of grazing continues to shape the response of the world’s grasslands to changing mammalian herbivory.
Published: 2022

17. Light competition drives herbivore and nutrient effects on plant diversity

Author: Eskelinen, A. (Anu), Harpole, W. S. (W. Stanley), Jessen, M.-T. (Maria-Theresa), Virtanen, R. (Risto), Hautier, Y. (Yann), Eskelinen, A. (Anu), Harpole, W. S. (W. Stanley), Jessen, M.-T. (Maria-Theresa), Virtanen, R. (Risto), and Hautier, Y. (Yann)
Abstract: Enrichment of nutrients and loss of herbivores are assumed to cause a loss of plant diversity in grassland ecosystems because they increase plant cover, which leads to a decrease of light in the understory1–3. Empirical tests of the role of competition for light in natural systems are based on indirect evidence, and have been a topic of debate for the last 40 years. Here we show that experimentally restoring light to understory plants in a natural grassland mitigates the loss of plant diversity that is caused by either nutrient enrichment or the absence of mammalian herbivores. The initial effect of light addition on restoring diversity under fertilization was transitory and outweighed by the greater effect of herbivory on light levels, indicating that herbivory is a major factor that controls diversity, partly through light. Our results provide direct experimental evidence, in a natural system, that competition for light is a key mechanism that contributes to the loss of biodiversity after cessation of mammalian herbivory. Our findings also show that the effects of herbivores can outpace the effects of fertilization on competition for light. Management practices that target maintaining grazing by native or domestic herbivores could therefore have applications in protecting biodiversity in grassland ecosystems, because they alleviate competition for light in the understory.
Published: 2022

18. Evolutionary history of grazing and resources determine herbivore exclusion effects on plant diversity

Author: Price, J. N. (Jodi N.), Sitters, J. (Judith), Ohlert, T. (Timothy), Tognetti, P. M. (Pedro M.), Brown, C. S. (Cynthia S.), Seabloom, E. W. (Eric W.), Borer, E. T. (Elizabeth T.), Prober, S. M. (Suzanne M.), Bakker, E. S. (Elisabeth S.), MacDougall, A. S. (Andrew S.), Yahdjian, L. (Laura), Gruner, D. S. (Daniel S.), Olde Venterink, H. (Harry), Barrio, I. C. (Isabel C.), Graff, P. (Pamela), Bagchi, S. (Sumanta), Arnillas, C. A. (Carlos Alberto), Bakker, J. D. (Jonathan D.), Blumenthal, D. M. (Dana M.), Boughton, E. H. (Elizabeth H.), Brudvig, L. A. (Lars A.), Bugalho, M. N. (Miguel N.), Cadotte, M. W. (Marc W.), Caldeira, M. C. (Maria C.), Dickman, C. R. (Chris R.), Donohue, I. (Ian), Grégory, S. (Sonnier), Hautier, Y. (Yann), Jónsdóttir, I. S. (Ingibjörg S.), Lannes, L. S. (Luciola S.), McCulley, R. L. (Rebecca L.), Moore, J. L. (Joslin L.), Power, S. A. (Sally A.), Risch, A. C. (Anita C.), Schütz, M. (Martin), Standish, R. (Rachel), Stevens, C. J. (Carly J.), Veen, G. F. (G. F.), Virtanen, R. (Risto), Wardle, G. M. (Glenda M.), Price, J. N. (Jodi N.), Sitters, J. (Judith), Ohlert, T. (Timothy), Tognetti, P. M. (Pedro M.), Brown, C. S. (Cynthia S.), Seabloom, E. W. (Eric W.), Borer, E. T. (Elizabeth T.), Prober, S. M. (Suzanne M.), Bakker, E. S. (Elisabeth S.), MacDougall, A. S. (Andrew S.), Yahdjian, L. (Laura), Gruner, D. S. (Daniel S.), Olde Venterink, H. (Harry), Barrio, I. C. (Isabel C.), Graff, P. (Pamela), Bagchi, S. (Sumanta), Arnillas, C. A. (Carlos Alberto), Bakker, J. D. (Jonathan D.), Blumenthal, D. M. (Dana M.), Boughton, E. H. (Elizabeth H.), Brudvig, L. A. (Lars A.), Bugalho, M. N. (Miguel N.), Cadotte, M. W. (Marc W.), Caldeira, M. C. (Maria C.), Dickman, C. R. (Chris R.), Donohue, I. (Ian), Grégory, S. (Sonnier), Hautier, Y. (Yann), Jónsdóttir, I. S. (Ingibjörg S.), Lannes, L. S. (Luciola S.), McCulley, R. L. (Rebecca L.), Moore, J. L. (Joslin L.), Power, S. A. (Sally A.), Risch, A. C. (Anita C.), Schütz, M. (Martin), Standish, R. (Rachel), Stevens, C. J. (Carly J.), Veen, G. F. (G. F.), Virtanen, R. (Risto), and Wardle, G. M. (Glenda M.)
Abstract: Ecological models predict that the effects of mammalian herbivore exclusion on plant diversity depend on resource availability and plant exposure to ungulate grazing over evolutionary time. Using an experiment replicated in 57 grasslands on six continents, with contrasting evolutionary history of grazing, we tested how resources (mean annual precipitation and soil nutrients) determine herbivore exclusion effects on plant diversity, richness and evenness. Here we show that at sites with a long history of ungulate grazing, herbivore exclusion reduced plant diversity by reducing both richness and evenness and the responses of richness and diversity to herbivore exclusion decreased with mean annual precipitation. At sites with a short history of grazing, the effects of herbivore exclusion were not related to precipitation but differed for native and exotic plant richness. Thus, plant species’ evolutionary history of grazing continues to shape the response of the world’s grasslands to changing mammalian herbivory.
Published: 2022

19. Nutrients and herbivores impact grassland stability across spatial scales through different pathways

Author: Chen, Q. (Qingqing), Wang, S. (Shaopeng), Seabloom, E. W. (Eric W.), MacDougall, A. S. (Andrew S.), Borer, E. T. (Elizabeth T.), Bakker, J. D. (Jonathan D.), Donohue, I. (Ian), Knops, J. M. (Johannes M. H.), Morgan, J. W. (John W.), Carroll, O. (Oliver), Crawley, M. (Mick), Bugalho, M. N. (Miguel N.), Power, S. A. (Sally A.), Eskelinen, A. (Anu), Virtanen, R. (Risto), Risch, A. C. (Anita C.), Schütz, M. (Martin), Stevens, C. (Carly), Caldeira, M. C. (Maria C.), Bagchi, S. (Sumanta), Alberti, J. (Juan), Hautier, Y. (Yann), Chen, Q. (Qingqing), Wang, S. (Shaopeng), Seabloom, E. W. (Eric W.), MacDougall, A. S. (Andrew S.), Borer, E. T. (Elizabeth T.), Bakker, J. D. (Jonathan D.), Donohue, I. (Ian), Knops, J. M. (Johannes M. H.), Morgan, J. W. (John W.), Carroll, O. (Oliver), Crawley, M. (Mick), Bugalho, M. N. (Miguel N.), Power, S. A. (Sally A.), Eskelinen, A. (Anu), Virtanen, R. (Risto), Risch, A. C. (Anita C.), Schütz, M. (Martin), Stevens, C. (Carly), Caldeira, M. C. (Maria C.), Bagchi, S. (Sumanta), Alberti, J. (Juan), and Hautier, Y. (Yann)
Abstract: Nutrients and herbivores are well-known drivers of grassland diversity and stability in local communities. However, whether they interact to impact the stability of aboveground biomass and whether these effects depend on spatial scales remain unknown. It is also unclear whether nutrients and herbivores impact stability via different facets of plant diversity including species richness, evenness, and changes in community composition through time and space. We used a replicated experiment adding nutrients and excluding herbivores for 5 years in 34 global grasslands to explore these questions. We found that both nutrient addition and herbivore exclusion alone reduced stability at the larger spatial scale (aggregated local communities; gamma stability), but through different pathways. Nutrient addition reduced gamma stability primarily by increasing changes in local community composition over time, which was mainly driven by species replacement. Herbivore exclusion reduced gamma stability primarily by decreasing asynchronous dynamics among local communities (spatial asynchrony). Their interaction weakly increased gamma stability by increasing spatial asynchrony. Our findings indicate that disentangling the processes operating at different spatial scales may improve conservation and management aiming at maintaining the ability of ecosystems to reliably provide functions and services for humanity.
Published: 2022

20. Data from nutrients and herbivores impact grassland stability across spatial scales through different pathways [Dataset]

Author: Chen, Q., Wang, S., Seabloom, E.W., MacDougall, A.S., Borer, E.T., Bakker, J.D., Donohue, I., Knops, J.M.H., Morgan, J.W., Carroll, O., Crawley, M., Bugalho, M.N., Power, S.A., Eskelinen, Anu Maria, Virtanen, Risto, Risch, A.C., Schütz, M., Stevens, C., Caldeira, M.C., Alberti, J., Bagchi, S., Hautier, Y., Chen, Q., Wang, S., Seabloom, E.W., MacDougall, A.S., Borer, E.T., Bakker, J.D., Donohue, I., Knops, J.M.H., Morgan, J.W., Carroll, O., Crawley, M., Bugalho, M.N., Power, S.A., Eskelinen, Anu Maria, Virtanen, Risto, Risch, A.C., Schütz, M., Stevens, C., Caldeira, M.C., Alberti, J., Bagchi, S., and Hautier, Y.
Abstract: Nutrients and herbivores are well-known drivers of grassland diversity and stability in local communities. However, whether they interact to impact the stability of aboveground biomass and whether these effects depend on spatial scales remain unknown. It is also unclear whether nutrients and herbivores impact stability via different facets of plant diversity including species richness, evenness, and changes in community composition through time and space. We used a replicated experiment adding nutrients and excluding herbivores for 5 years in 34 global grasslands to explore these questions. We found that both nutrient addition and herbivore exclusion alone reduced stability at the larger spatial scale (aggregated local communities; gamma stability), but through different pathways. Nutrient addition reduced gamma stability primarily by increasing changes in local community composition over time, which was mainly driven by species replacement. Herbivore exclusion reduced gamma stability primarily by decreasing asynchronous dynamics among local communities (spatial asynchrony). Their interaction weakly increased gamma stability by increasing spatial asynchrony. Our findings indicate that disentangling the processes operating at different spatial scales may improve conservation and management aiming at maintaining the ability of ecosystems to reliably provide functions and services for humanity.
Published: 2022

21. Data from: Grazing and light modify Silene latifolia responses to nutrients and future climate [Dataset]

Author: Jessen, Maria-Theresa ; orcid:0000-0002-5238-7118, Auge, Harald, Harpole, William Stanley ; orcid:0000-0002-3404-9174, Hautier, Y., Eskelinen, Anu Maria, Jessen, Maria-Theresa ; orcid:0000-0002-5238-7118, Auge, Harald, Harpole, William Stanley ; orcid:0000-0002-3404-9174, Hautier, Y., and Eskelinen, Anu Maria
Abstract: Altered climate, nutrient enrichment and changes in grazing patterns are important environmental and biotic changes in temperate grassland systems. Singly and in concert these factors can influence plant performance and traits, with consequences for species competitive ability, and thus for species coexistence, community composition and diversity. However, we lack experimental tests of the mechanisms, such as competition for light, driving plant performance and traits under nutrient enrichment, grazer exclusion and future climate. We used transplants of Silene latifolia, a widespread grassland forb in Europe, to study plant responses to interactions among climate, nutrients, grazing and light. We recorded transplant biomass, height, specific leaf area (SLA) and foliar carbon to nitrogen ratio (C:N) in full-factorial combinations of future climate treatment, fertilization, grazer exclusion and light addition via LED-lamps. Future climate and fertilization together increased transplant height but only in unlighted plots. Light addition increased SLA in ambient climate, and decreased C:N in unfertilized plots. Further, transplants had higher biomass in future climatic conditions when protected from grazers. In general, grazing had a strong negative effect on all measured variables regardless of added nutrients and light. Our results show that competition for light may lead to taller individuals and interacts with climate and nutrients to affect traits related to resource-use. Furthermore, our study suggests grazing may counteract the benefits of future climate on the biomass of species such as Silene latifolia. Consequently, grazers and light may be important modulators of individual plant performance and traits under nutrient enrichment and future climatic conditions.
Published: 2022

22. Data for: Light competition drives herbivore and nutrient effects on plant diversity

Author: Eskelinen, Anu Maria, Harpole, William Stanley ; orcid:0000-0002-3404-9174, Jessen, Maria-Theresa ; orcid:0000-0002-5238-7118, Virtanen, R., Hautier, Y., Eskelinen, Anu Maria, Harpole, William Stanley ; orcid:0000-0002-3404-9174, Jessen, Maria-Theresa ; orcid:0000-0002-5238-7118, Virtanen, R., and Hautier, Y.
Abstract: Enrichment of nutrients and loss of herbivores are assumed to cause a loss of plant diversity in grassland ecosystems because they increase plant cover, which leads to a decrease of light in the understory1,2,3. Empirical tests of the role of competition for light in natural systems are based on indirect evidence, and have been a topic of debate for the last 40 years. Here we show that experimentally restoring light to understory plants in a natural grassland mitigates the loss of plant diversity that is caused by either nutrient enrichment or the absence of mammalian herbivores. The initial effect of light addition on restoring diversity under fertilization was transitory and outweighed by the greater effect of herbivory on light levels, indicating that herbivory is a major factor that controls diversity, partly through light. Our results provide direct experimental evidence, in a natural system, that competition for light is a key mechanism that contributes to the loss of biodiversity after cessation of mammalian herbivory. Our findings also show that the effects of herbivores can outpace the effects of fertilization on competition for light. Management practices that target maintaining grazing by native or domestic herbivores could therefore have applications in protecting biodiversity in grassland ecosystems, because they alleviate competition for light in the understory.
Published: 2022

23. Long-term N-addition alters the community structure of functionally important N-cycling soil microorganisms across global grasslands

Author: Frey, B. (Beat), Moser, B. (Barbara), Tytgat, B. (Bjorn), Zimmermann, S. (Stephan), Alberti, J. (Juan), Biederman, L. A. (Lori A.), Borer, E. T. (Elizabeth T.), Broadbent, A. A. (Arthur A. D.), Caldeira, M. C. (Maria C.), Davies, K. F. (Kendi F.), Eisenhauer, N. (Nico), Eskelinen, A. (Anu), Fay, P. A. (Philip A.), Hagedorn, F. (Frank), Hautier, Y. (Yann), MacDougall, A. S. (Andrew S.), McCulley, R. L. (Rebecca L.), Moore, J. L. (Joslin L.), Nepel, M. (Maximilian), Power, S. A. (Sally A.), Seabloom, E. W. (Eric W.), Vázquez, E. (Eduardo), Virtanen, R. (Risto), Yahdjian, L. (Laura), Risch, A. C. (Anita C.), Frey, B. (Beat), Moser, B. (Barbara), Tytgat, B. (Bjorn), Zimmermann, S. (Stephan), Alberti, J. (Juan), Biederman, L. A. (Lori A.), Borer, E. T. (Elizabeth T.), Broadbent, A. A. (Arthur A. D.), Caldeira, M. C. (Maria C.), Davies, K. F. (Kendi F.), Eisenhauer, N. (Nico), Eskelinen, A. (Anu), Fay, P. A. (Philip A.), Hagedorn, F. (Frank), Hautier, Y. (Yann), MacDougall, A. S. (Andrew S.), McCulley, R. L. (Rebecca L.), Moore, J. L. (Joslin L.), Nepel, M. (Maximilian), Power, S. A. (Sally A.), Seabloom, E. W. (Eric W.), Vázquez, E. (Eduardo), Virtanen, R. (Risto), Yahdjian, L. (Laura), and Risch, A. C. (Anita C.)
Abstract: Anthropogenic nitrogen (N) input is known to alter the soil microbiome, but how N enrichment influences the abundance, alpha-diversity and community structure of N-cycling functional microbial communities in grasslands remains poorly understood. Here, we collected soils from plant communities subjected to up to 9 years of annual N-addition (10 g N m⁻² per year using urea as a N-source) and from unfertilized plots (control) in 30 grasslands worldwide spanning a large range of climatic and soil conditions. We focused on three key microbial groups responsible for two essential processes of the global N cycle: N₂ fixation (soil diazotrophs) and nitrification (AOA: ammonia-oxidizing archaea and AOB: ammonia-oxidizing bacteria). We targeted soil diazotrophs, AOA and AOB using Illumina MiSeq sequencing and measured the abundance (gene copy numbers) using quantitative PCR. N-addition shifted the structure of the diazotrophic communities, although their alpha-diversity and abundance were not affected. AOA and AOB responded differently to N-addition. The abundance and alpha-diversity of AOB increased, and their community structure shifted with N-addition. In contrast, AOA were not affected by N-addition. AOA abundance outnumbered AOB in control plots under conditions of low N availability, whereas N-addition favoured copiotrophic AOB. Overall, N-addition showed a low impact on soil diazotrophs and AOA while effects for AOB communities were considerable. These results reveal that long-term N-addition has important ecological implications for key microbial groups involved in two critical soil N-cycling processes. Increased AOB abundance and community shifts following N-addition may change soil N-cycling, as larger population sizes may promote higher rates of ammonia oxidation and subsequently increase N loss via gaseous and soil N-leaching. These findings bring us a step closer to predicting the responses and feedbacks of microbial-mediated N-cycling processes to long
Published: 2022

24. Linking changes in species composition and biomass in a globally distributed grassland experiment

Author: Ladeuceur, E, Blowes, S, Chase, J, Clark, A., Grabowski, M, Alberti, Juan, Arnillas, C.A., Bharath, Siddharth, Borer, E.T., Brudvig, Lars A., Cadotte, Marc, Chen, Q.Q., Collins, Scott, Dickman, C. R., Donohue, C, Du, GZ, Ebling, A, Eisenhauer, N., Fay, P.A., Hagenah, N., Hautier, Y., Anke, J, Jonsottir, I.S., Komatsu, K.J., MacDougall, A.S., Martina, J.P., Moore, J., Morgan, J., Peri, Paolo, Power, S.A., Zhengwei, R, Risch, A., Roscher, C., Schuchardt, C, Seabloom, Eric W., Stevens, Carly, Veen, C, Virtanen, R, Wardle, Glenda M., Wilfahrt, P.A., Harpole, W.S., Ladeuceur, E, Blowes, S, Chase, J, Clark, A., Grabowski, M, Alberti, Juan, Arnillas, C.A., Bharath, Siddharth, Borer, E.T., Brudvig, Lars A., Cadotte, Marc, Chen, Q.Q., Collins, Scott, Dickman, C. R., Donohue, C, Du, GZ, Ebling, A, Eisenhauer, N., Fay, P.A., Hagenah, N., Hautier, Y., Anke, J, Jonsottir, I.S., Komatsu, K.J., MacDougall, A.S., Martina, J.P., Moore, J., Morgan, J., Peri, Paolo, Power, S.A., Zhengwei, R, Risch, A., Roscher, C., Schuchardt, C, Seabloom, Eric W., Stevens, Carly, Veen, C, Virtanen, R, Wardle, Glenda M., Wilfahrt, P.A., and Harpole, W.S.
Published: 2022

25. Grazing and light modify Silene latifolia responses to nutrients and future climate

Author: Jessen, Maria-Theresa, Auge, Harald, Harpole, William Stanley, Hautier, Y., Eskelinen, Anu Maria, Jessen, Maria-Theresa, Auge, Harald, Harpole, William Stanley, Hautier, Y., and Eskelinen, Anu Maria
Abstract: Altered climate, nutrient enrichment and changes in grazing patterns are important environmental and biotic changes in temperate grassland systems. Singly and in concert these factors can influence plant performance and traits, with consequences for species competitive ability, and thus for species coexistence, community composition and diversity. However, we lack experimental tests of the mechanisms, such as competition for light, driving plant performance and traits under nutrient enrichment, grazer exclusion and future climate. We used transplants of Silene latifolia, a widespread grassland forb in Europe, to study plant responses to interactions among climate, nutrients, grazing and light. We recorded transplant biomass, height, specific leaf area (SLA) and foliar carbon to nitrogen ratio (C:N) in full-factorial combinations of future climate treatment, fertilization, grazer exclusion and light addition via LED-lamps. Future climate and fertilization together increased transplant height but only in unlighted plots. Light addition increased SLA in ambient climate, and decreased C:N in unfertilized plots. Further, transplants had higher biomass in future climatic conditions when protected from grazers. In general, grazing had a strong negative effect on all measured variables regardless of added nutrients and light. Our results show that competition for light may lead to taller individuals and interacts with climate and nutrients to affect traits related to resource-use. Furthermore, our study suggests grazing may counteract the benefits of future climate on the biomass of species such as Silene latifolia. Consequently, grazers and light may be important modulators of individual plant performance and traits under nutrient enrichment and future climatic conditions.
Published: 2022

26. Data from: Grazing and light modify Silene latifolia responses to nutrients and future climate [Dataset]

Author: Jessen, Maria-Theresa, Auge, Harald, Harpole, William Stanley, Hautier, Y., Eskelinen, Anu Maria, Jessen, Maria-Theresa, Auge, Harald, Harpole, William Stanley, Hautier, Y., and Eskelinen, Anu Maria
Abstract: Altered climate, nutrient enrichment and changes in grazing patterns are important environmental and biotic changes in temperate grassland systems. Singly and in concert these factors can influence plant performance and traits, with consequences for species competitive ability, and thus for species coexistence, community composition and diversity. However, we lack experimental tests of the mechanisms, such as competition for light, driving plant performance and traits under nutrient enrichment, grazer exclusion and future climate. We used transplants of Silene latifolia, a widespread grassland forb in Europe, to study plant responses to interactions among climate, nutrients, grazing and light. We recorded transplant biomass, height, specific leaf area (SLA) and foliar carbon to nitrogen ratio (C:N) in full-factorial combinations of future climate treatment, fertilization, grazer exclusion and light addition via LED-lamps. Future climate and fertilization together increased transplant height but only in unlighted plots. Light addition increased SLA in ambient climate, and decreased C:N in unfertilized plots. Further, transplants had higher biomass in future climatic conditions when protected from grazers. In general, grazing had a strong negative effect on all measured variables regardless of added nutrients and light. Our results show that competition for light may lead to taller individuals and interacts with climate and nutrients to affect traits related to resource-use. Furthermore, our study suggests grazing may counteract the benefits of future climate on the biomass of species such as Silene latifolia. Consequently, grazers and light may be important modulators of individual plant performance and traits under nutrient enrichment and future climatic conditions.
Published: 2022

27. Long-term N-addition alters the community structure of functionally important N-cycling soil microorganisms across global grasslands

Author: Frey, B., Moser, B., Tytgat, B., Zimmermann, S., Alberti, J., Biederman, L.A., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Hautier, Y., MacDougall, A.S., McCulley, R.L., Moore, J.L., Nepel, M., Power, S.A., Seabloom, E.W., Vázquez, E., Virtanen, R., Yahdjian, L., Risch, A.C., Frey, B., Moser, B., Tytgat, B., Zimmermann, S., Alberti, J., Biederman, L.A., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Hautier, Y., MacDougall, A.S., McCulley, R.L., Moore, J.L., Nepel, M., Power, S.A., Seabloom, E.W., Vázquez, E., Virtanen, R., Yahdjian, L., and Risch, A.C.
Abstract: Anthropogenic nitrogen (N) input is known to alter the soil microbiome, but how N enrichment influences the abundance, alpha-diversity and community structure of N-cycling functional microbial communities in grasslands remains poorly understood. Here, we collected soils from plant communities subjected to up to 9 years of annual N-addition (10 g N m−2 per year using urea as a N-source) and from unfertilized plots (control) in 30 grasslands worldwide spanning a large range of climatic and soil conditions. We focused on three key microbial groups responsible for two essential processes of the global N cycle: N2 fixation (soil diazotrophs) and nitrification (AOA: ammonia-oxidizing archaea and AOB: ammonia-oxidizing bacteria). We targeted soil diazotrophs, AOA and AOB using Illumina MiSeq sequencing and measured the abundance (gene copy numbers) using quantitative PCR. N-addition shifted the structure of the diazotrophic communities, although their alpha-diversity and abundance were not affected. AOA and AOB responded differently to N-addition. The abundance and alpha-diversity of AOB increased, and their community structure shifted with N-addition. In contrast, AOA were not affected by N-addition. AOA abundance outnumbered AOB in control plots under conditions of low N availability, whereas N-addition favoured copiotrophic AOB. Overall, N-addition showed a low impact on soil diazotrophs and AOA while effects for AOB communities were considerable. These results reveal that long-term N-addition has important ecological implications for key microbial groups involved in two critical soil N-cycling processes. Increased AOB abundance and community shifts following N-addition may change soil N-cycling, as larger population sizes may promote higher rates of ammonia oxidation and subsequently increase N loss via gaseous and soil N-leaching. These findings bring us a step closer to predicting the responses and feedbacks of microbial-mediated N-cycling processes
Published: 2022

28. Nutrient addition drives declines in grassland species richness primarily via enhanced species loss

Author: Muehleisen, A.J., Watkins, C.R.E., Altmire, G.R., Shaw, E.A., Case, M.F., Aoyama, L., Brambila, A., Reed, P.B., LaForgia, M., Borer, E.T., Seabloom, E.W., Bakker, J.D., Amillas, C.A., Biederman, L., Chen, Q., Cleland, E.E., Fay, P.A., Hagenah, N., Harpole, William Stanley, Hautier, Y., Henning, J.A., Knops, J.M.H., Komatsu, K.J., Ladouceur, Emma, MacDougall, A., McCulley, R.L., Moore, J.L., Ohlert, T., Power, S.A., Stevens, C.J., Wilfahrt, P., Hallett, L.M., Muehleisen, A.J., Watkins, C.R.E., Altmire, G.R., Shaw, E.A., Case, M.F., Aoyama, L., Brambila, A., Reed, P.B., LaForgia, M., Borer, E.T., Seabloom, E.W., Bakker, J.D., Amillas, C.A., Biederman, L., Chen, Q., Cleland, E.E., Fay, P.A., Hagenah, N., Harpole, William Stanley, Hautier, Y., Henning, J.A., Knops, J.M.H., Komatsu, K.J., Ladouceur, Emma, MacDougall, A., McCulley, R.L., Moore, J.L., Ohlert, T., Power, S.A., Stevens, C.J., Wilfahrt, P., and Hallett, L.M.
Abstract: (1) Declines in grassland diversity in response to nutrient addition are a general consequence of global change. This decline in species richness may be driven by multiple underlying processes operating at different timescales. Nutrient addition can reduce diversity by enhancing the rate of local extinction via competitive exclusion, or by reducing the rate of colonization by constraining the pool of species able to colonize under new conditions. Partitioning net change into extinction and colonization rates will better delineate the long-term effect of global change in grasslands. (2) We synthesized changes in richness in response to experimental fertilization with nitrogen, phosphorus and potassium with micronutrients across 30 grasslands. We quantified changes in local richness, colonization, and extinction over 8-10 years of nutrient addition, and compared these rates against control conditions to isolate the effect of nutrient addition from background dynamics. (3) Total richness at steady state in the control plots was the sum of equal, relatively high rates of local colonization and extinction. On aggregate, 30-35% of initial species were lost and the same proportion of new species were gained at least once over a decade. Absolute turnover increased with site-level richness, but was proportionately greater at lower richness sites relative to starting richness. Loss of total richness with nutrient addition, especially N in combination with P or K, was driven by enhanced rates of extinction with a smaller contribution from reduced colonization. Enhanced extinction and reduced colonization were disproportionately among native species, perennials, and forbs. Reduced colonization plateaued after the first few (< 5) years after nutrient addition, while enhanced extinction continued throughout the first decade. (4) Synthesis. Our results indicate a high rate of colonizations and extinctions underlying the richness of ambient communities, and that nutrient enh
Published: 2022

29. Expert perspectives on global biodiversity loss and its drivers and impacts on people

Author: Isbell, F., Balvanera, P., Mori, A.S., He, J.-S., Bullock, J.M., Regmi, G.R., Seabloom, E.W., Ferrier, S., Sala, O.E., Guerrero-Ramírez, N.R., Tavella, J., Larkin, D.J., Schmid, B., Outhwaite, C.L., Pramual, P., Borer, E.T., Loreau, M., Omotoriogun, T.C., Obura, D.O., Anderson, M., Portales-Reyes, C., Kirkman, K., Vergara, P.M., Clark, Adam Thomas, Komatsu, K.J., Petchey, O.L., Weiskopf, S.R., Williams, L.J., Collins, S.L., Eisenhauer, N., Trisos, C.H., Renard, D., Wright, A.J., Tripathi, P., Cowles, J., Byrnes, J.E.K., Reich, P.B., Purvis, A., Sharip, Z., O’Connor, M.I., Kazanski, C.E., Haddad, N.M., Soto, E.H., Dee, L.E., Díaz, S., Zirbel, C.R., Avolio, M.L., Wang, S., Ma, Z., Liang, J., Farah, H.C., Johnson, J.A., Miller, B.W., Hautier, Y., Smith, M.D., Knops, J.M.H., Myers, B.J.E., Harmáčková, Z.V., Cortés, J., Harfoot, M.B.J., Gonzalez, A., Newbold, T., Oehri, J., Mazón, M., Dobbs, C., Palmer, M.S., Isbell, F., Balvanera, P., Mori, A.S., He, J.-S., Bullock, J.M., Regmi, G.R., Seabloom, E.W., Ferrier, S., Sala, O.E., Guerrero-Ramírez, N.R., Tavella, J., Larkin, D.J., Schmid, B., Outhwaite, C.L., Pramual, P., Borer, E.T., Loreau, M., Omotoriogun, T.C., Obura, D.O., Anderson, M., Portales-Reyes, C., Kirkman, K., Vergara, P.M., Clark, Adam Thomas, Komatsu, K.J., Petchey, O.L., Weiskopf, S.R., Williams, L.J., Collins, S.L., Eisenhauer, N., Trisos, C.H., Renard, D., Wright, A.J., Tripathi, P., Cowles, J., Byrnes, J.E.K., Reich, P.B., Purvis, A., Sharip, Z., O’Connor, M.I., Kazanski, C.E., Haddad, N.M., Soto, E.H., Dee, L.E., Díaz, S., Zirbel, C.R., Avolio, M.L., Wang, S., Ma, Z., Liang, J., Farah, H.C., Johnson, J.A., Miller, B.W., Hautier, Y., Smith, M.D., Knops, J.M.H., Myers, B.J.E., Harmáčková, Z.V., Cortés, J., Harfoot, M.B.J., Gonzalez, A., Newbold, T., Oehri, J., Mazón, M., Dobbs, C., and Palmer, M.S.
Abstract: Despite substantial progress in understanding global biodiversity loss, major taxonomic and geographic knowledge gaps remain. Decision makers often rely on expert judgement to fill knowledge gaps, but are rarely able to engage with sufficiently large and diverse groups of specialists. To improve understanding of the perspectives of thousands of biodiversity experts worldwide, we conducted a survey and asked experts to focus on the taxa and freshwater, terrestrial, or marine ecosystem with which they are most familiar. We found several points of overwhelming consensus (for instance, multiple drivers of biodiversity loss interact synergistically) and important demographic and geographic differences in specialists’ perspectives and estimates. Experts from groups that are underrepresented in biodiversity science, including women and those from the Global South, recommended different priorities for conservation solutions, with less emphasis on acquiring new protected areas, and provided higher estimates of biodiversity loss and its impacts. This may in part be because they disproportionately study the most highly threatened taxa and habitats.
Published: 2022

30. Light competition drives herbivore and nutrient effects on plant diversity

Author: Eskelinen, Anu Maria, Harpole, William Stanley, Jessen, Maria-Theresa, Virtanen, R., Hautier, Y., Eskelinen, Anu Maria, Harpole, William Stanley, Jessen, Maria-Theresa, Virtanen, R., and Hautier, Y.
Abstract: Enrichment of nutrients and loss of herbivores are assumed to cause a loss of plant diversity in grassland ecosystems because they increase plant cover, which leads to a decrease of light in the understory1,2,3. Empirical tests of the role of competition for light in natural systems are based on indirect evidence, and have been a topic of debate for the last 40 years. Here we show that experimentally restoring light to understory plants in a natural grassland mitigates the loss of plant diversity that is caused by either nutrient enrichment or the absence of mammalian herbivores. The initial effect of light addition on restoring diversity under fertilization was transitory and outweighed by the greater effect of herbivory on light levels, indicating that herbivory is a major factor that controls diversity, partly through light. Our results provide direct experimental evidence, in a natural system, that competition for light is a key mechanism that contributes to the loss of biodiversity after cessation of mammalian herbivory. Our findings also show that the effects of herbivores can outpace the effects of fertilization on competition for light. Management practices that target maintaining grazing by native or domestic herbivores could therefore have applications in protecting biodiversity in grassland ecosystems, because they alleviate competition for light in the understory.
Published: 2022

31. Linking changes in species composition and biomass in a globally distributed grassland experiment

Author: Ladouceur, Emma, Blowes, S.A., Chase, J.M., Clark, Adam Thomas, Garbowski, Magda, Alberti, J., Arnillas, C.A., Bakker, J.D., Barrio, I.C., Bharath, S., Borer, E.T., Brudvig, L.A., Cadotte, M.W., Chen, Q., Collins, S.L., Dickman, C.R., Donohue, I., Du, G., Ebeling, A., Eisenhauer, N., Fay, P.A., Hagenah, N., Hautier, Y., Jentsch, A., Jónsdóttir, I.S., Komatsu, K., MacDougall, A., Martina, J.P., Moore, J.L., Morgan, J.W., Peri, P.L., Power, S.A., Ren, Z., Risch, A.C., Roscher, Christiane, Schuchardt, M.A., Seabloom, E.W., Stevens, C.J., Veen, G.F.C., Virtanen, R., Wardle, G.M., Wilfahrt, P.A., Harpole, William Stanley, Ladouceur, Emma, Blowes, S.A., Chase, J.M., Clark, Adam Thomas, Garbowski, Magda, Alberti, J., Arnillas, C.A., Bakker, J.D., Barrio, I.C., Bharath, S., Borer, E.T., Brudvig, L.A., Cadotte, M.W., Chen, Q., Collins, S.L., Dickman, C.R., Donohue, I., Du, G., Ebeling, A., Eisenhauer, N., Fay, P.A., Hagenah, N., Hautier, Y., Jentsch, A., Jónsdóttir, I.S., Komatsu, K., MacDougall, A., Martina, J.P., Moore, J.L., Morgan, J.W., Peri, P.L., Power, S.A., Ren, Z., Risch, A.C., Roscher, Christiane, Schuchardt, M.A., Seabloom, E.W., Stevens, C.J., Veen, G.F.C., Virtanen, R., Wardle, G.M., Wilfahrt, P.A., and Harpole, William Stanley
Abstract: Global change drivers, such as anthropogenic nutrient inputs, are increasing globally. Nutrient deposition simultaneously alters plant biodiversity, species composition and ecosystem processes like aboveground biomass production. These changes are underpinned by species extinction, colonisation and shifting relative abundance. Here, we use the Price equation to quantify and link the contributions of species that are lost, gained or that persist to change in aboveground biomass in 59 experimental grassland sites. Under ambient (control) conditions, compositional and biomass turnover was high, and losses (i.e. local extinctions) were balanced by gains (i.e. colonisation). Under fertilisation, the decline in species richness resulted from increased species loss and decreases in species gained. Biomass increase under fertilisation resulted mostly from species that persist and to a lesser extent from species gained. Drivers of ecological change can interact relatively independently with diversity, composition and ecosystem processes and functions such as aboveground biomass due to the individual contributions of species lost, gained or persisting.
Published: 2022

32. Nutrients and herbivores impact grassland stability across spatial scales through different pathways

Author: Chen, Q., Wang, S., Seabloom, E.W., MacDougall, A.S., Borer, E.T., Bakker, J.D., Donohue, I., Knops, J.M.H., Morgan, J.W., Carroll, O., Crawley, M., Bugalho, M.N., Power, S.A., Eskelinen, Anu Maria, Virtanen, R., Risch, A.C., Schütz, M., Stevens, C., Caldeira, M.C., Bagchi, S., Alberti, J., Hautier, Y., Chen, Q., Wang, S., Seabloom, E.W., MacDougall, A.S., Borer, E.T., Bakker, J.D., Donohue, I., Knops, J.M.H., Morgan, J.W., Carroll, O., Crawley, M., Bugalho, M.N., Power, S.A., Eskelinen, Anu Maria, Virtanen, R., Risch, A.C., Schütz, M., Stevens, C., Caldeira, M.C., Bagchi, S., Alberti, J., and Hautier, Y.
Abstract: Nutrients and herbivores are well-known drivers of grassland diversity and stability in local communities. However, whether they interact to impact the stability of aboveground biomass and whether these effects depend on spatial scales remain unknown. It is also unclear whether nutrients and herbivores impact stability via different facets of plant diversity including species richness, evenness, and changes in community composition through time and space. We used a replicated experiment adding nutrients and excluding herbivores for 5 years in 34 global grasslands to explore these questions. We found that both nutrient addition and herbivore exclusion alone reduced stability at the larger spatial scale (aggregated local communities; gamma stability), but through different pathways. Nutrient addition reduced gamma stability primarily by increasing changes in local community composition over time, which was mainly driven by species replacement. Herbivore exclusion reduced gamma stability primarily by decreasing asynchronous dynamics among local communities (spatial asynchrony). Their interaction weakly increased gamma stability by increasing spatial asynchrony. Our findings indicate that disentangling the processes operating at different spatial scales may improve conservation and management aiming at maintaining the ability of ecosystems to reliably provide functions and services for humanity.
Published: 2022

33. Review for "Multiple global changes drive grassland productivity and stability: A meta‐analysis"

Author: Hautier, Y, primary
Published: 2022
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34. Opposing community assembly patterns for dominant and jonnondominant plant species in herbaceous ecosystems globally

Author: Arnillas, CA, Borer, ET, Seabloom, EW, Alberti, J, Baez, S, Bakker, JD, Boughton, EH, Buckley, YM, Bugalho, MN, Donohue, I, Dwyer, J, Eskelinen, A, Firn, J, Gridzak, R, Hagenah, N, Hautier, Y, Helm, A, Jentsch, A, Knops, JMH, Komatsu, KJ, Laanisto, L, Laungani, R, McCulley, R, Moore, JL, Morgan, John, Peri, PL, Power, SA, Price, Jodi, Sankaran, M, Schamp, B, Speziale, K, Standish, R, Virtanen, R, Cadotte, MW, Sub Ecology and Biodiversity, and Ecology and Biodiversity
Subjects: Nutrient Network, Ecology, grasslands, community assembly, evolutionary strategies, species dominance, species nondominance, phylogenetic relatedness, Ecology, Evolution, Behavior and Systematics, biodiversity, Nature and Landscape Conservation, Uncategorized
Abstract: Biotic and abiotic factors interact with dominant plants��the locally most frequent or with the largest coverage��and nondominant plants differently, partially because dominant plants modify the environment where nondominant plants grow. For instance, if dominant plants compete strongly, they will deplete most resources, forcing nondominant plants into a narrower niche space. Conversely, if dominant plants are constrained by the environment, they might not exhaust available resources but instead may ameliorate environmental stressors that usually limit nondominants. Hence, the nature of interactions among nondominant species could be modified by dominant species. Furthermore, these differences could translate into a disparity in the phylogenetic relatedness among dominants compared to the relatedness among nondominants. By estimating phylogenetic dispersion in 78 grasslands across five continents, we found that dominant species were clustered (e.g., co-dominant grasses), suggesting dominant species are likely organized by environmental filtering, and that nondominant species were either randomly assembled or overdispersed. Traits showed similar trends for those sites (
Published: 2022
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35. General stabilizing effects of plant diversity on grassland productivity through population asynchrony and overyielding

Author: Hector, A., Hautier, Y., Saner, P., Wacker, L., Bagchi, R., Joshi, J., Scherer-Lorenzen, M., Spehn, E. M., Bazeley-White, E., Weilenmann, M., Caldeira, M. C., Dimitrakopoulos, P. G., Finn, J. A., Huss-Danell, K., Jumpponen, A., Mulder, C. P. H., Palmborg, C., Pereira, J. S., Siamantziouras, A. S. D., Terry, A. C., Troumbis, A. Y., Schmid, B., and Loreau, M.
Published: 2010

36. Negative effects of nitrogen override positive effects of phosphorus on grassland legumes worldwide

Author: Tognetti, P.M., Prober, S.M., Báez, S., Chaneton, E.J., Firn, J., Risch, A.C., Schuetz, M., Simonsen, A.K., Yahdjian, L., Borer, E.T., Seabloom, E.W., Arnillas, C.A., Bakker, J.D., Brown, C.S., Cadotte, M.W., Caldeira, M.C., Daleo, P., Dwyer, J.M., Fay, P.A., Gherardi, L.A., Hagenah, N., Hautier, Y., Komatsu, K.J., McCulley, R.L., Price, J.N., Standish, R.J., Stevens, C.J., Wragg, P.D., Sankaran, M., Tognetti, P.M., Prober, S.M., Báez, S., Chaneton, E.J., Firn, J., Risch, A.C., Schuetz, M., Simonsen, A.K., Yahdjian, L., Borer, E.T., Seabloom, E.W., Arnillas, C.A., Bakker, J.D., Brown, C.S., Cadotte, M.W., Caldeira, M.C., Daleo, P., Dwyer, J.M., Fay, P.A., Gherardi, L.A., Hagenah, N., Hautier, Y., Komatsu, K.J., McCulley, R.L., Price, J.N., Standish, R.J., Stevens, C.J., Wragg, P.D., and Sankaran, M.
Abstract: Anthropogenic nutrient enrichment is driving global biodiversity decline and modifying ecosystem functions. Theory suggests that plant functional types that fix atmospheric nitrogen have a competitive advantage in nitrogen-poor soils, but lose this advantage with increasing nitrogen supply. By contrast, the addition of phosphorus, potassium, and other nutrients may benefit such species in low-nutrient environments by enhancing their nitrogen-fixing capacity. We present a global-scale experiment confirming these predictions for nitrogen-fixing legumes (Fabaceae) across 45 grasslands on six continents. Nitrogen addition reduced legume cover, richness, and biomass, particularly in nitrogen-poor soils, while cover of non–nitrogen-fixing plants increased. The addition of phosphorous, potassium, and other nutrients enhanced legume abundance, but did not mitigate the negative effects of nitrogen addition. Increasing nitrogen supply thus has the potential to decrease the diversity and abundance of grassland legumes worldwide regardless of the availability of other nutrients, with consequences for biodiversity, food webs, ecosystem resilience, and genetic improvement of protein-rich agricultural plant species.
Published: 2021

37. Temporal rarity is a better predictor of local extinction risk than spatial rarity

Author: Wilfahrt, P.A., Asmus, A.L., Seabloom, E.W., Henning, J.A., Adler, P., Arnillas, C.A., Bakker, J.D., Biederman, L., Brudvig, L.A., Cadotte, M., Daleo, P., Eskelinen, A., Firn, J., Harpole, W.S., Hautier, Y., Kirkman, K.P., Komatsu, K.J., Laungani, R., MacDougall, A., McCulley, R.L., Moore, J.L., Morgan, J.W., Mortensen, B., Ochoa Hueso, R., Ohlert, T., Power, S.A., Price, J., Risch, A.C., Schuetz, M., Shoemaker, L., Stevens, C., Strauss, A.T., Tognetti, P.M., Virtanen, R., Borer, E.T., Wilfahrt, P.A., Asmus, A.L., Seabloom, E.W., Henning, J.A., Adler, P., Arnillas, C.A., Bakker, J.D., Biederman, L., Brudvig, L.A., Cadotte, M., Daleo, P., Eskelinen, A., Firn, J., Harpole, W.S., Hautier, Y., Kirkman, K.P., Komatsu, K.J., Laungani, R., MacDougall, A., McCulley, R.L., Moore, J.L., Morgan, J.W., Mortensen, B., Ochoa Hueso, R., Ohlert, T., Power, S.A., Price, J., Risch, A.C., Schuetz, M., Shoemaker, L., Stevens, C., Strauss, A.T., Tognetti, P.M., Virtanen, R., and Borer, E.T.
Abstract: Spatial rarity is often used to predict extinction risk, but rarity can also occur temporally. Perhaps more relevant in the context of global change is whether a species is core to a community (persistent) or transient (intermittently present), with transient species often susceptible to human activities that reduce niche space. Using 5–12 yr of data on 1,447 plant species from 49 grasslands on five continents, we show that local abundance and species persistence under ambient conditions are both effective predictors of local extinction risk following experimental exclusion of grazers or addition of nutrients; persistence was a more powerful predictor than local abundance. While perturbations increased the risk of exclusion for low persistence and abundance species, transient but abundant species were also highly likely to be excluded from a perturbed plot relative to ambient conditions. Moreover, low persistence and low abundance species that were not excluded from perturbed plots tended to have a modest increase in abundance following perturbance. Last, even core species with high abundances had large decreases in persistence and increased losses in perturbed plots, threatening the long-term stability of these grasslands. Our results demonstrate that expanding the concept of rarity to include temporal dynamics, in addition to local abundance, more effectively predicts extinction risk in response to environmental change than either rarity axis predicts alone.
Published: 2021

38. Opposing community assembly patterns for dominant and jonnondominant plant species in herbaceous ecosystems globally

Author: Arnillas, C.A., Borer, E.T., Seabloom, E.W., Alberti, J., Báez, S., Bakker, J.D., Boughton, E.H., Buckley, Y.M., Bugalho, M.N., Donohue, I., Dwyer, J., Eskelinen, A., Firn, J., Gridzak, R., Hagenah, N., Hautier, Y., Helm, A., Jentsch, A., Knops, J.M.H., Komatsu, K.J., Laanisto, L., Laungani, R., McCulley, R., Moore, J.L., Morgan, J.W., Peri, P.L., Power, S.A., Price, J., Sankaran, M., Schamp, B., Speziale, K., Standish, R., Virtanen, R., Cadotte, M.W., Arnillas, C.A., Borer, E.T., Seabloom, E.W., Alberti, J., Báez, S., Bakker, J.D., Boughton, E.H., Buckley, Y.M., Bugalho, M.N., Donohue, I., Dwyer, J., Eskelinen, A., Firn, J., Gridzak, R., Hagenah, N., Hautier, Y., Helm, A., Jentsch, A., Knops, J.M.H., Komatsu, K.J., Laanisto, L., Laungani, R., McCulley, R., Moore, J.L., Morgan, J.W., Peri, P.L., Power, S.A., Price, J., Sankaran, M., Schamp, B., Speziale, K., Standish, R., Virtanen, R., and Cadotte, M.W.
Abstract: Biotic and abiotic factors interact with dominant plants—the locally most frequent or with the largest coverage—and nondominant plants differently, partially because dominant plants modify the environment where nondominant plants grow. For instance, if dominant plants compete strongly, they will deplete most resources, forcing nondominant plants into a narrower niche space. Conversely, if dominant plants are constrained by the environment, they might not exhaust available resources but instead may ameliorate environmental stressors that usually limit nondominants. Hence, the nature of interactions among nondominant species could be modified by dominant species. Furthermore, these differences could translate into a disparity in the phylogenetic relatedness among dominants compared to the relatedness among nondominants. By estimating phylogenetic dispersion in 78 grasslands across five continents, we found that dominant species were clustered (e.g., co-dominant grasses), suggesting dominant species are likely organized by environmental filtering, and that nondominant species were either randomly assembled or overdispersed. Traits showed similar trends for those sites (<50%) with sufficient trait data. Furthermore, several lineages scattered in the phylogeny had more nondominant species than expected at random, suggesting that traits common in nondominants are phylogenetically conserved and have evolved multiple times. We also explored environmental drivers of the dominant/nondominant disparity. We found different assembly patterns for dominants and nondominants, consistent with asymmetries in assembly mechanisms. Among the different postulated mechanisms, our results suggest two complementary hypotheses seldom explored: (1) Nondominant species include lineages adapted to thrive in the environment generated by dominant species. (2) Even when dominant species reduce resources to nondominant ones, dominant species could have a stronger positive effect on some nondominant
Published: 2021

39. Increasing effects of chronic nutrient enrichment on plant diversity loss and ecosystem productivity over time

Author: Seabloom, E.W., Adler, P.B., Alberti, J., Biederman, L., Buckley, Y.M., Cadotte, M.W., Collins, S.L., Dee, L., Fay, P.A., Firn, J., Hagenah, N., Harpole, W.S., Hautier, Y., Hector, A., Hobbie, S.E., Isbell, F., Knops, J.M.H., Komatsu, K.J., Laungani, R., MacDougall, A., McCulley, R.L., Moore, J.L., Morgan, J.W., Ohlert, T., Prober, S.M., Risch, A.C., Schuetz, M., Stevens, C.J., Borer, E.T., Seabloom, E.W., Adler, P.B., Alberti, J., Biederman, L., Buckley, Y.M., Cadotte, M.W., Collins, S.L., Dee, L., Fay, P.A., Firn, J., Hagenah, N., Harpole, W.S., Hautier, Y., Hector, A., Hobbie, S.E., Isbell, F., Knops, J.M.H., Komatsu, K.J., Laungani, R., MacDougall, A., McCulley, R.L., Moore, J.L., Morgan, J.W., Ohlert, T., Prober, S.M., Risch, A.C., Schuetz, M., Stevens, C.J., and Borer, E.T.
Abstract: Human activities are enriching many of Earth’s ecosystems with biologically limiting mineral nutrients such as nitrogen (N) and phosphorus (P). In grasslands, this enrichment generally reduces plant diversity and increases productivity. The widely demonstrated positive effect of diversity on productivity suggests a potential negative feedback, whereby nutrient-induced declines in diversity reduce the initial gains in productivity arising from nutrient enrichment. In addition, plant productivity and diversity can be inhibited by accumulations of dead biomass, which may be altered by nutrient enrichment. Over longer time frames, nutrient addition may increase soil fertility by increasing soil organic matter and nutrient pools. We examined the effects of 5–11 yr of nutrient addition at 47 grasslands in 12 countries. Nutrient enrichment increased aboveground live biomass and reduced plant diversity at nearly all sites, and these effects became stronger over time. We did not find evidence that nutrient-induced losses of diversity reduced the positive effects of nutrients on biomass; however, nutrient effects on live biomass increased more slowly at sites where litter was also increasing, regardless of plant diversity. This work suggests that short-term experiments may underestimate the long-term nutrient enrichment effects on global grassland ecosystems.
Published: 2021

40. Opposing community assembly patterns for dominant and nondominant plant species in herbaceous ecosystems globally

Author: Arnillas, C. A. (Carlos Alberto), Borer, E. T. (Elizabeth T.), Seabloom, E. W. (Eric W.), Alberti, J. (Juan), Baez, S. (Selene), Bakker, J. D. (Jonathan D.), Boughton, E. H. (Elizabeth H.), Buckley, Y. M. (Yvonne M.), Bugalho, M. N. (Miguel Nuno), Donohue, I. (Ian), Dwyer, J. (John), Firn, J. (Jennifer), Gridzak, R. (Riley), Hagenah, N. (Nicole), Hautier, Y. (Yann), Helm, A. (Aveliina), Jentsch, A. (Anke), Knops, J. M. (Johannes M. H.), Komatsu, K. J. (Kimberly J.), Laanisto, L. (Lauri), Laungani, R. (Ramesh), McCulley, R. (Rebecca), Moore, J. L. (Joslin L.), Morgan, J. W. (John W.), Peri, P. L. (Pablo Luis), Power, S. A. (Sally A.), Price, J. (Jodi), Sankaran, M. (Mahesh), Schamp, B. (Brandon), Speziale, K. (Karina), Standish, R. (Rachel), Virtanen, R. (Risto), Cadotte, M. W. (Marc W.), Arnillas, C. A. (Carlos Alberto), Borer, E. T. (Elizabeth T.), Seabloom, E. W. (Eric W.), Alberti, J. (Juan), Baez, S. (Selene), Bakker, J. D. (Jonathan D.), Boughton, E. H. (Elizabeth H.), Buckley, Y. M. (Yvonne M.), Bugalho, M. N. (Miguel Nuno), Donohue, I. (Ian), Dwyer, J. (John), Firn, J. (Jennifer), Gridzak, R. (Riley), Hagenah, N. (Nicole), Hautier, Y. (Yann), Helm, A. (Aveliina), Jentsch, A. (Anke), Knops, J. M. (Johannes M. H.), Komatsu, K. J. (Kimberly J.), Laanisto, L. (Lauri), Laungani, R. (Ramesh), McCulley, R. (Rebecca), Moore, J. L. (Joslin L.), Morgan, J. W. (John W.), Peri, P. L. (Pablo Luis), Power, S. A. (Sally A.), Price, J. (Jodi), Sankaran, M. (Mahesh), Schamp, B. (Brandon), Speziale, K. (Karina), Standish, R. (Rachel), Virtanen, R. (Risto), and Cadotte, M. W. (Marc W.)
Abstract: Biotic and abiotic factors interact with dominant plants—the locally most frequent or with the largest coverage—and nondominant plants differently, partially because dominant plants modify the environment where nondominant plants grow. For instance, if dominant plants compete strongly, they will deplete most resources, forcing nondominant plants into a narrower niche space. Conversely, if dominant plants are constrained by the environment, they might not exhaust available resources but instead may ameliorate environmental stressors that usually limit nondominants. Hence, the nature of interactions among nondominant species could be modified by dominant species. Furthermore, these differences could translate into a disparity in the phylogenetic relatedness among dominants compared to the relatedness among nondominants. By estimating phylogenetic dispersion in 78 grasslands across five continents, we found that dominant species were clustered (e.g., co-dominant grasses), suggesting dominant species are likely organized by environmental filtering, and that nondominant species were either randomly assembled or overdispersed. Traits showed similar trends for those sites (<50%) with sufficient trait data. Furthermore, several lineages scattered in the phylogeny had more nondominant species than expected at random, suggesting that traits common in nondominants are phylogenetically conserved and have evolved multiple times. We also explored environmental drivers of the dominant/nondominant disparity. We found different assembly patterns for dominants and nondominants, consistent with asymmetries in assembly mechanisms. Among the different postulated mechanisms, our results suggest two complementary hypotheses seldom explored: (1) Nondominant species include lineages adapted to thrive in the environment generated by dominant species. (2) Even when dominant species reduce resources to nondominant ones, dominant species could have a stronger positive effect on some
Published: 2021

41. Temporal rarity is a better predictor of local extinction risk than spatial rarity

Author: Wilfahrt, P. A. (Peter A.), Asmus, A. L. (Ashley L.), Seabloom, E. W. (Eric W.), Henning, J. A. (Jeremiah A.), Adler, P. (Peter), Arnillas, C. A. (Carlos A.), Bakker, J. D. (Jonathan D.), Biederman, L. (Lori), Brudvig, L. A. (Lars A.), Cadotte, M. (Marc), Daleo, P. (Pedro), Eskelinen, A. (Anu), Firn, J. (Jennifer), Harpole, W. S. (W. Stanley), Hautier, Y. (Yann), Kirkman, K. P. (Kevin P.), Komatsu, K. J. (Kimberly J.), Laungani, R. (Ramesh), MacDougall, A. (Andrew), McCulley, R. L. (Rebecca L.), Moore, J. L. (Joslin L.), Morgan, J. W. (John W.), Mortensen, B. (Brent), Hueso, R. O. (Raul Ochoa), Ohlert, T. (Timothy), Power, S. A. (Sally A.), Price, J. (Jodi), Risch, A. C. (Anita C.), Schuetz, M. (Martin), Shoemaker, L. (Lauren), Stevens, C. (Carly), Strauss, A. T. (Alexander T.), Tognetti, P. M. (Pedro M.), Virtanen, R. (Risto), Borer, E. T. (Elizabeth T.), Wilfahrt, P. A. (Peter A.), Asmus, A. L. (Ashley L.), Seabloom, E. W. (Eric W.), Henning, J. A. (Jeremiah A.), Adler, P. (Peter), Arnillas, C. A. (Carlos A.), Bakker, J. D. (Jonathan D.), Biederman, L. (Lori), Brudvig, L. A. (Lars A.), Cadotte, M. (Marc), Daleo, P. (Pedro), Eskelinen, A. (Anu), Firn, J. (Jennifer), Harpole, W. S. (W. Stanley), Hautier, Y. (Yann), Kirkman, K. P. (Kevin P.), Komatsu, K. J. (Kimberly J.), Laungani, R. (Ramesh), MacDougall, A. (Andrew), McCulley, R. L. (Rebecca L.), Moore, J. L. (Joslin L.), Morgan, J. W. (John W.), Mortensen, B. (Brent), Hueso, R. O. (Raul Ochoa), Ohlert, T. (Timothy), Power, S. A. (Sally A.), Price, J. (Jodi), Risch, A. C. (Anita C.), Schuetz, M. (Martin), Shoemaker, L. (Lauren), Stevens, C. (Carly), Strauss, A. T. (Alexander T.), Tognetti, P. M. (Pedro M.), Virtanen, R. (Risto), and Borer, E. T. (Elizabeth T.)
Abstract: Spatial rarity is often used to predict extinction risk, but rarity can also occur temporally. Perhaps more relevant in the context of global change is whether a species is core to a community (persistent) or transient (intermittently present), with transient species often susceptible to human activities that reduce niche space. Using 5–12 yr of data on 1,447 plant species from 49 grasslands on five continents, we show that local abundance and species persistence under ambient conditions are both effective predictors of local extinction risk following experimental exclusion of grazers or addition of nutrients; persistence was a more powerful predictor than local abundance. While perturbations increased the risk of exclusion for low persistence and abundance species, transient but abundant species were also highly likely to be excluded from a perturbed plot relative to ambient conditions. Moreover, low persistence and low abundance species that were not excluded from perturbed plots tended to have a modest increase in abundance following perturbance. Last, even core species with high abundances had large decreases in persistence and increased losses in perturbed plots, threatening the long-term stability of these grasslands. Our results demonstrate that expanding the concept of rarity to include temporal dynamics, in addition to local abundance, more effectively predicts extinction risk in response to environmental change than either rarity axis predicts alone.
Published: 2021

42. Author Correction: Leaf nutrients, not specific leaf area, are consistent indicators of elevated nutrient inputs (Nature Ecology & Evolution, (2019), 3, 3, (400-406), 10.1038/s41559-018-0790-1)

Author: Firn, J., McGree, J.M., Harvey, E., Flores-Moreno, H., Schütz, M., Buckley, Y.M., Borer, E.T., Seabloom, E.W., Pierre, K.J. La, MacDougall, A.M., Prober, S.M., Stevens, Carly, Sullivan, L.L., Porter, E., Ladouceur, E., Allen, C., Moromizato, K.H., Morgan, J.W., Harpole, W.S., Hautier, Y., Eisenhauer, N., Wright, J.P., Adler, P.B., Arnillas, C.A., Bakker, J.D., Biederman, L., Broadbent, Arthur A. D., Brown, C.S., Bugalho, M.N., Caldeira, M.C., Cleland, E.E., Ebeling, A., Fay, P.A., Hagenah, N., Kleinhesselink, A.R., Mitchell, R., Moore, J.L., Nogueira, C., Peri, P.L., Roscher, C., Smith, M.D., Wragg, P.D., and Risch, A.C.
Subjects: TheoryofComputation_ANALYSISOFALGORITHMSANDPROBLEMCOMPLEXITY
Abstract: In the version of this Article originally published, there were unit conversion errors in the dataset when calculating specific leaf area (SLA) values at 10 of the 27 sites; errors were made when converting SLA from cm 2 g –1 to mm 2 g –1 and from mm 2 mg –1 to mm 2 g –1. This resulted in two incorrect data points: Phleum pratense in plot 27 at the Frue.ch site (SLA >300,000 mm 2 g –1) and Poa secunda in plot 31 at the shps.us site (SLA >60 mm 2 g –1). These two values were changed to ‘NA’ in the dataset, and therefore some reported estimates were changed, resulting in changes to the data points in Fig. 2a, the top bar of Fig. 3 and several values in the text.
Published: 2020

43. Resource‐enhancing global changes drive a whole‐ecosystem shift to faster cycling but decrease diversity

Author: Eskelinen, A. (Anu), Gravuer, K. (Kelly), Harpole, W. S. (W Stanley), Harrison, S. (Susan), Virtanen, R. (Risto), and Hautier, Y. (Yann)
Subjects: nutrient enrichment, climate change, fast transition, native diversity, whole‐ecosystem shift, exotics, ecological multifunctionality, slow transition, multiple global changes
Abstract: Many global changes take the form of resource enhancements that have potential to transform multiple aspects of ecosystems from slower to faster cycling, including a suite of both above‐ and belowground variables. We developed a novel analytic approach to measure integrated ecosystem responses to resource‐enhancing global changes, and how such whole ecosystem slow‐to‐fast transitions are linked to diversity and exotic invasions in real‐world ecosystems. We asked how 5‐yr experimental rainfall and nutrient enhancements in a natural grassland system affected 16 ecosystem functions, pools, and stoichiometry variables considered to indicate slow vs. fast cycling. We combined these metrics into a novel index we termed “slow‐fast multifunctionality” and assessed its relationship to plant community diversity and exotic plant dominance. Nutrient and rainfall addition interacted to affect average slow‐fast multifunctionality. Nutrient addition alone pushed the system toward faster cycling, but this effect weakened with the joint addition of rainfall and nutrients. Variables associated with soil nutrient pools and cycling most strongly contributed to this antagonistic interaction. Nutrient and water addition together, respectively, had additive or synergistic effects on plant trait composition and productivity, demonstrating divergence of above‐ and belowground ecosystem responses. Our novel metric of faster cycling was strongly associated with decreased plant species richness and increased exotic species dominance. These results demonstrate the breadth of interacting community and ecosystem changes that ensue when resource limitation is relaxed.
Published: 2020

44. Dominant native and non-native graminoids differ in key leaf traits irrespective of nutrient availability

Author: Broadbent, A.A.D., Firn, J., McGree, J.M., Borer, E.T., Buckley, Y.M., Harpole, W.S., Komatsu, K.J., MacDougall, A.S., Orwin, K.H., Ostle, N.J., Seabloom, E.W., Bakker, J.D., Biederman, L., Caldeira, M.C., Eisenhauer, N., Hagenah, N., Hautier, Y., Moore, J.L., Nogueira, C., Peri, P.L., Risch, A.C., Roscher, C., Schütz, M., Stevens, C.J., Broadbent, A.A.D., Firn, J., McGree, J.M., Borer, E.T., Buckley, Y.M., Harpole, W.S., Komatsu, K.J., MacDougall, A.S., Orwin, K.H., Ostle, N.J., Seabloom, E.W., Bakker, J.D., Biederman, L., Caldeira, M.C., Eisenhauer, N., Hagenah, N., Hautier, Y., Moore, J.L., Nogueira, C., Peri, P.L., Risch, A.C., Roscher, C., Schütz, M., and Stevens, C.J.
Abstract: Aim: Nutrient enrichment is associated with plant invasions and biodiversity loss. Functional trait advantages may predict the ascendancy of invasive plants following nutrient enrichment but this is rarely tested. Here, we investigate (a) whether dominant native and non-native plants differ in important morphological and physiological leaf traits, (b) how their traits respond to nutrient addition, and (c) whether responses are consistent across functional groups. Location: Australia, Europe, North America and South Africa. Time period: 2007–2014. Major taxa studied: Graminoids and forbs. Methods: We focused on two types of leaf traits connected to resource acquisition: morphological features relating to light-foraging surfaces and investment in tissue (specific leaf area, SLA) and physiological features relating to internal leaf chemistry as the basis for producing and utilizing photosynthate. We measured these traits on 503 leaves from 151 dominant species across 27 grasslands on four continents. We used an identical nutrient addition treatment of nitrogen (N), phosphorus (P) and potassium (K) at all sites. Sites represented a broad range of grasslands that varied widely in climatic and edaphic conditions. Results: We found evidence that non-native graminoids invest in leaves with higher nutrient concentrations than native graminoids, particularly at sites where native and non-native species both dominate. We found little evidence that native and non-native forbs differed in the measured leaf traits. These results were consistent in natural soil fertility levels and nutrient-enriched conditions, with dominant species responding similarly to nutrient addition regardless of whether they were native or non-native. Main conclusions: Our work identifies the inherent physiological trait advantages that can be used to predict non-native graminoid establishment, potentially because of higher efficiency at taking up crucial nutrients into their leaves. Most importantly, the
Published: 2020

45. Nutrient availability controls the impact of mammalian herbivores on soil carbon and nitrogen pools in grasslands

Author: Sitters, J., Wubs, E.R.J., Bakker, E.S., Crowther, T.W., Adler, P.B., Bagchi, S., Bakker, J.D., Biederman, L., Borer, E.T., Cleland, E.E., Eisenhauer, N., Firn, J., Gherardi, L., Hagenah, N., Hautier, Y., Hobbie, S.E., Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Moore, J.L., Mortensen, B., Peri, P.L., Prober, S.M., Riggs, C., Risch, A.C., Schütz, M., Seabloom, E.W., Siebert, J., Stevens, C.J., Veen, G.F., Sitters, J., Wubs, E.R.J., Bakker, E.S., Crowther, T.W., Adler, P.B., Bagchi, S., Bakker, J.D., Biederman, L., Borer, E.T., Cleland, E.E., Eisenhauer, N., Firn, J., Gherardi, L., Hagenah, N., Hautier, Y., Hobbie, S.E., Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Moore, J.L., Mortensen, B., Peri, P.L., Prober, S.M., Riggs, C., Risch, A.C., Schütz, M., Seabloom, E.W., Siebert, J., Stevens, C.J., and Veen, G.F.
Abstract: Grasslands are subject to considerable alteration due to human activities globally, including widespread changes in populations and composition of large mammalian herbivores and elevated supply of nutrients. Grassland soils remain important reservoirs of carbon (C) and nitrogen (N). Herbivores may affect both C and N pools and these changes likely interact with increases in soil nutrient availability. Given the scale of grassland soil fluxes, such changes can have striking consequences for atmospheric C concentrations and the climate. Here, we use the Nutrient Network experiment to examine the responses of soil C and N pools to mammalian herbivore exclusion across 22 grasslands, under ambient and elevated nutrient availabilities (fertilized with NPK + micronutrients). We show that the impact of herbivore exclusion on soil C and N pools depends on fertilization. Under ambient nutrient conditions, we observed no effect of herbivore exclusion, but under elevated nutrient supply, pools are smaller upon herbivore exclusion. The highest mean soil C and N pools were found in grazed and fertilized plots. The decrease in soil C and N upon herbivore exclusion in combination with fertilization correlated with a decrease in aboveground plant biomass and microbial activity, indicating a reduced storage of organic matter and microbial residues as soil C and N. The response of soil C and N pools to herbivore exclusion was contingent on temperature – herbivores likely cause losses of C and N in colder sites and increases in warmer sites. Additionally, grasslands that contain mammalian herbivores have the potential to sequester more N under increased temperature variability and nutrient enrichment than ungrazed grasslands. Our study highlights the importance of conserving mammalian herbivore populations in grasslands worldwide. We need to incorporate local-scale herbivory, and its interaction with nutrient enrichment and climate, within global-scale models to better predict land–atm
Published: 2020

46. Nutrient availability controls the impact of mammalian herbivores on soil carbon and nitrogen pools in grasslands

Author: Nutrient Network, Sitters, Judith, Wubs, E.R.J., Bakker, E.S., Crowther, Thomas W., Adler, Peter B., Bagchi, Sumanta, Bakker, Jonathan D., Biederman, L., Borer, Elizabeth T., Cleland, Elsa E., Eisenhauer, Nico, Firn, J, Gherardi, Laureano, Hagenah, Nicole, Hautier, Y., Hobbie, Sarah, Knops, Johannes M. H., MacDougall, A.S., McCulley, R.L., Moore, Joslin L., Mortensen, Brent, Peri, Pablo L., Prober, S.M., Riggs, C, Risch, Anita C., Schütz, Martin, Seabloom, Eric W., Siebert, Julia, Stevens, C.J., Veen, G.F., Nutrient Network, Sitters, Judith, Wubs, E.R.J., Bakker, E.S., Crowther, Thomas W., Adler, Peter B., Bagchi, Sumanta, Bakker, Jonathan D., Biederman, L., Borer, Elizabeth T., Cleland, Elsa E., Eisenhauer, Nico, Firn, J, Gherardi, Laureano, Hagenah, Nicole, Hautier, Y., Hobbie, Sarah, Knops, Johannes M. H., MacDougall, A.S., McCulley, R.L., Moore, Joslin L., Mortensen, Brent, Peri, Pablo L., Prober, S.M., Riggs, C, Risch, Anita C., Schütz, Martin, Seabloom, Eric W., Siebert, Julia, Stevens, C.J., and Veen, G.F.
Abstract: Grasslands are subject to considerable alteration due to human activities globally, including widespread changes in populations and composition of large mammalian herbivores and elevated supply of nutrients. Grassland soils remain important reservoirs of carbon (C) and nitrogen (N). Herbivores may affect both C and N pools and these changes likely interact with increases in soil nutrient availability. Given the scale of grassland soil fluxes, such changes can have striking consequences for atmospheric C concentrations and the climate. Here, we use the Nutrient Network experiment to examine the responses of soil C and N pools to mammalian herbivore exclusion across 22 grasslands, under ambient and elevated nutrient availabilities (fertilized with NPK + micronutrients). We show that the impact of herbivore exclusion on soil C and N pools depends on fertilization. Under ambient nutrient conditions, we observed no effect of herbivore exclusion, but under elevated nutrient supply, pools are smaller upon herbivore exclusion. The highest mean soil C and N pools were found in grazed and fertilized plots. The decrease in soil C and N upon herbivore exclusion in combination with fertilization correlated with a decrease in aboveground plant biomass and microbial activity, indicating a reduced storage of organic matter and microbial residues as soil C and N. The response of soil C and N pools to herbivore exclusion was contingent on temperature – herbivores likely cause losses of C and N in colder sites and increases in warmer sites. Additionally, grasslands that contain mammalian herbivores have the potential to sequester more N under increased temperature variability and nutrient enrichment than ungrazed grasslands. Our study highlights the importance of conserving mammalian herbivore populations in grasslands worldwide. We need to incorporate local‐scale herbivory, and its interaction with nutrient enrichment and climate, within global‐scale models to better predict land–atm
Published: 2020

47. General destabilizing effects of eutrophication on grassland productivity at multiple spatial scales

Author: Hautier, Y. (Yann), Zhang, P. (Pengfei), Loreau, M. (Michel), Wilcox, K. R. (Kevin R.), Seabloom, E. W. (Eric W.), Borer, E. T. (Elizabeth T.), Byrnes, J. E. (Jarrett E. K.), Koerner, S. E. (Sally E.), Komatsu, K. J. (Kimberly J.), Lefcheck, J. S. (Jonathan S.), Hector, A. (Andy), Adler, P. B. (Peter B.), Alberti, J. (Juan), Arnillas, C. A. (Carlos A.), Bakker, J. D. (Jonathan D.), Brudvig, L. A. (Lars A.), Bugalho, M. N. (Miguel N.), Cadotte, M. (Marc), Caldeira, M. C. (Maria C.), Carroll, O. (Oliver), Crawley, M. (Mick), Collins, S. L. (Scott L.), Daleo, P. (Pedro), Dee, L. E. (Laura E.), Eisenhauer, N. (Nico), Eskelinen, A. (Anu), Fay, P. A. (Philip A.), Gilbert, B. (Benjamin), Hansar, A. (Amandine), Isbell, F. (Forest), Knops, J. M. (Johannes M. H.), MacDougall, A. S. (Andrew S.), McCulley, R. L. (Rebecca L.), Moore, J. L. (Joslin L.), Morgan, J. W. (John W.), Mori, A. S. (Akira S.), Peri, P. L. (Pablo L.), Pos, E. T. (Edwin T.), Power, S. A. (Sally A.), Price, J. N. (Jodi N.), Reich, P. B. (Peter B.), Risch, A. C. (Anita C.), Roscher, C. (Christiane), Sankaran, M. (Mahesh), Schutz, M. (Martin), Smith, M. (Melinda), Stevens, C. (Carly), Tognetti, P. M. (Pedro M.), Virtanen, R. (Risto), Wardle, G. M. (Glenda M.), Wilfahrt, P. A. (Peter A.), Wang, S. (Shaopeng), Hautier, Y. (Yann), Zhang, P. (Pengfei), Loreau, M. (Michel), Wilcox, K. R. (Kevin R.), Seabloom, E. W. (Eric W.), Borer, E. T. (Elizabeth T.), Byrnes, J. E. (Jarrett E. K.), Koerner, S. E. (Sally E.), Komatsu, K. J. (Kimberly J.), Lefcheck, J. S. (Jonathan S.), Hector, A. (Andy), Adler, P. B. (Peter B.), Alberti, J. (Juan), Arnillas, C. A. (Carlos A.), Bakker, J. D. (Jonathan D.), Brudvig, L. A. (Lars A.), Bugalho, M. N. (Miguel N.), Cadotte, M. (Marc), Caldeira, M. C. (Maria C.), Carroll, O. (Oliver), Crawley, M. (Mick), Collins, S. L. (Scott L.), Daleo, P. (Pedro), Dee, L. E. (Laura E.), Eisenhauer, N. (Nico), Eskelinen, A. (Anu), Fay, P. A. (Philip A.), Gilbert, B. (Benjamin), Hansar, A. (Amandine), Isbell, F. (Forest), Knops, J. M. (Johannes M. H.), MacDougall, A. S. (Andrew S.), McCulley, R. L. (Rebecca L.), Moore, J. L. (Joslin L.), Morgan, J. W. (John W.), Mori, A. S. (Akira S.), Peri, P. L. (Pablo L.), Pos, E. T. (Edwin T.), Power, S. A. (Sally A.), Price, J. N. (Jodi N.), Reich, P. B. (Peter B.), Risch, A. C. (Anita C.), Roscher, C. (Christiane), Sankaran, M. (Mahesh), Schutz, M. (Martin), Smith, M. (Melinda), Stevens, C. (Carly), Tognetti, P. M. (Pedro M.), Virtanen, R. (Risto), Wardle, G. M. (Glenda M.), Wilfahrt, P. A. (Peter A.), and Wang, S. (Shaopeng)
Abstract: Eutrophication is a widespread environmental change that usually reduces the stabilizing effect of plant diversity on productivity in local communities. Whether this effect is scale dependent remains to be elucidated. Here, we determine the relationship between plant diversity and temporal stability of productivity for 243 plant communities from 42 grasslands across the globe and quantify the effect of chronic fertilization on these relationships. Unfertilized local communities with more plant species exhibit greater asynchronous dynamics among species in response to natural environmental fluctuations, resulting in greater local stability (alpha stability). Moreover, neighborhood communities that have greater spatial variation in plant species composition within sites (higher beta diversity) have greater spatial asynchrony of productivity among communities, resulting in greater stability at the larger scale (gamma stability). Importantly, fertilization consistently weakens the contribution of plant diversity to both of these stabilizing mechanisms, thus diminishing the positive effect of biodiversity on stability at differing spatial scales. Our findings suggest that preserving grassland functional stability requires conservation of plant diversity within and among ecological communities.
Published: 2020

48. Climate and local environment structure asynchrony and the stability of primary production in grasslands

Author: Gilbert, B., MacDougall, A.S., Kadoya, T., Akasaka, M., Bennett, J.R., Lind, E.M., Flores-Moreno, H., Firn, J., Hautier, Y., Borer, E.T., Seabloom, E.W., Adler, P.B., Cleland, E.E., Grace, J.B., Harpole, William Stanley, Esch, E.H., Moore, J.L., Knops, J., McCulley, R., Mortensen, B., Bakker, J., Fay, P.A., Gilbert, B., MacDougall, A.S., Kadoya, T., Akasaka, M., Bennett, J.R., Lind, E.M., Flores-Moreno, H., Firn, J., Hautier, Y., Borer, E.T., Seabloom, E.W., Adler, P.B., Cleland, E.E., Grace, J.B., Harpole, William Stanley, Esch, E.H., Moore, J.L., Knops, J., McCulley, R., Mortensen, B., Bakker, J., and Fay, P.A.
Abstract: Aim Climate variability threatens to destabilize production in many ecosystems. Asynchronous species dynamics may buffer against such variability when a decrease in performance by some species is offset by an increase in performance of others. However, high climatic variability can eliminate species through stochastic extinctions or cause similar stress responses among species that reduce buffering. Local conditions, such as soil nutrients, can also alter production stability directly or by influencing asynchrony. We test these hypotheses using a globally distributed sampling experiment. Location Grasslands in North America, Europe and Australia. Time period Annual surveys over 5 year intervals occurring between 2007 and 2014. Major taxa studied Herbaceous plants. Methods We sampled annually the per species cover and aboveground community biomass [net primary productivity (NPP)], plus soil chemical properties, in 29 grasslands. We tested how soil conditions, combined with variability in precipitation and temperature, affect species richness, asynchrony and temporal stability of primary productivity. We used bivariate relationships and structural equation modelling to examine proximate and ultimate relationships. Results Climate variability strongly predicted asynchrony, whereas NPP stability was more related to soil conditions. Species richness was structured by both climate variability and soils and, in turn, increased asynchrony. Variability in temperature and precipitation caused a unimodal asynchrony response, with asynchrony being lowest at low and high climate variability. Climate impacted stability indirectly, through its effect on asynchrony, with stability increasing at higher asynchrony owing to lower inter‐annual variability in NPP. Soil conditions had no detectable effect on asynchrony but increased stability by increasing the mean NPP, especially when soil organic matter was high. Main conclusions We found globally consistent evidence that clim
Published: 2020

49. General destabilizing effects of eutrophication on grassland productivity at multiple spatial scales

Author: Hautier, Y., Zhang, P., Loreau, M., Wilcox, K.R., Seabloom, E.W., Borer, E.T., Byrnes, J.E.K., Koerner, S.E., Komatsu, K.J., Lefcheck, J.S., Hector, A., Adler, P.B., Alberti, J., Arnillas, C.A., Bakker, J.D., Brudvig, L.A., Bugalho, M.N., Cadotte, M., Caldeira, M.C., Carroll, O., Crawley, M., Collins, S.L., Daleo, P., Dee, L.E., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Gilbert, B., Hansar, A., Isbell, F., Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Moore, J.L., Morgan, J.W., Mori, A.S., Peri, P.L., Pos, E.T., Power, S.A., Price, J.N., Reich, P.B., Risch, A.C., Roscher, Christiane, Sankaran, M., Schütz, M., Smith, M., Stevens, C., Tognetti, P.M., Virtanen, R., Wardle, G.M., Wilfahrt, P.A., Wang, S., Hautier, Y., Zhang, P., Loreau, M., Wilcox, K.R., Seabloom, E.W., Borer, E.T., Byrnes, J.E.K., Koerner, S.E., Komatsu, K.J., Lefcheck, J.S., Hector, A., Adler, P.B., Alberti, J., Arnillas, C.A., Bakker, J.D., Brudvig, L.A., Bugalho, M.N., Cadotte, M., Caldeira, M.C., Carroll, O., Crawley, M., Collins, S.L., Daleo, P., Dee, L.E., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Gilbert, B., Hansar, A., Isbell, F., Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Moore, J.L., Morgan, J.W., Mori, A.S., Peri, P.L., Pos, E.T., Power, S.A., Price, J.N., Reich, P.B., Risch, A.C., Roscher, Christiane, Sankaran, M., Schütz, M., Smith, M., Stevens, C., Tognetti, P.M., Virtanen, R., Wardle, G.M., Wilfahrt, P.A., and Wang, S.
Abstract: Eutrophication is a widespread environmental change that usually reduces the stabilizing effect of plant diversity on productivity in local communities. Whether this effect is scale dependent remains to be elucidated. Here, we determine the relationship between plant diversity and temporal stability of productivity for 243 plant communities from 42 grasslands across the globe and quantify the effect of chronic fertilization on these relationships. Unfertilized local communities with more plant species exhibit greater asynchronous dynamics among species in response to natural environmental fluctuations, resulting in greater local stability (alpha stability). Moreover, neighborhood communities that have greater spatial variation in plant species composition within sites (higher beta diversity) have greater spatial asynchrony of productivity among communities, resulting in greater stability at the larger scale (gamma stability). Importantly, fertilization consistently weakens the contribution of plant diversity to both of these stabilizing mechanisms, thus diminishing the positive effect of biodiversity on stability at differing spatial scales. Our findings suggest that preserving grassland functional stability requires conservation of plant diversity within and among ecological communities.
Published: 2020

50. Increasing effects of chronic nutrient enrichment on plant diversity loss and ecosystem productivity over time

Author: Seabloom, E.W., Adler, P.B., Alberti, J., Biederman, L., Buckley, Y.M., Cadotte, M.W., Collins, S.L., Dee, L., Fay, P.A., Firn, J., Hagenah, N., Harpole, William Stanley, Hautier, Y., Hector, A., Hobbie, S.E., Isbell, F., Knops, J.M.H., Komatsu, K.J., Laungani, R., MacDougall, A., McCulley, R.L., Moore, J.L., Morgan, J.W., Ohlert, T., Prober, S.M., Risch, A.C., Schuetz, M., Stevens, C.J., Borer, E.T., Seabloom, E.W., Adler, P.B., Alberti, J., Biederman, L., Buckley, Y.M., Cadotte, M.W., Collins, S.L., Dee, L., Fay, P.A., Firn, J., Hagenah, N., Harpole, William Stanley, Hautier, Y., Hector, A., Hobbie, S.E., Isbell, F., Knops, J.M.H., Komatsu, K.J., Laungani, R., MacDougall, A., McCulley, R.L., Moore, J.L., Morgan, J.W., Ohlert, T., Prober, S.M., Risch, A.C., Schuetz, M., Stevens, C.J., and Borer, E.T.
Abstract: Human activities are enriching many of Earth’s ecosystems with biologically limiting mineral nutrients such as nitrogen (N) and phosphorus (P). In grasslands, this enrichment generally reduces plant diversity and increases productivity. The widely demonstrated positive effect of diversity on productivity suggests a potential negative feedback, whereby nutrient‐induced declines in diversity reduce the initial gains in productivity arising from nutrient enrichment. In addition, plant productivity and diversity can be inhibited by accumulations of dead biomass, which may be altered by nutrient enrichment. Over longer timeframes, nutrient addition may increase soil fertility by increasing soil organic matter and nutrient pools. We examined the effects of 5‐11 years of nutrient addition at 47 grasslands in twelve countries. Nutrient enrichment increased aboveground live biomass and reduced plant diversity at nearly all sites, and these effects became stronger over time. We did not find evidence that nutrient‐induced losses of diversity reduced the positive effects of nutrients on biomass, however nutrient effects on live biomass increased more slowly at sites where litter was also increasing, regardless of plant diversity. This work suggests that short‐term experiments may underestimate the long‐term nutrient enrichment effects on global, grassland ecosystems.
Published: 2020

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