Your search keyword '"McCulley RL"' showing total 66 results

1. A continent-wide study reveals clear relationships between regional abiotic conditions and post-dispersal seed predation

Author

Orrock, JL, Borer, ET, Brudvig, LA, Firn, J, Macdougall, AS, Melbourne, BA, Yang, LH, Baker, DV, Bar-Massada, A, Crawley, MJ, Damschen, EI, Davies, KF, Gruner, DS, Kay, AD, Lind, E, Mcculley, RL, and Seabloom, EW

Subjects

AET, Annual actual evapotranspiration, Climate, Granivory, North America, Plant-consumer interactions, Precipitation, Seed predation, climate, granivory, plant-consumer interactions, precipitation, seed predation, Ecology, Earth Sciences, Environmental Sciences, Biological Sciences

Abstract

Aim: Large-scale patterns linking energy availability, biological productivity and diversity form a central focus of ecology. Despite evidence that the activity and abundance of animals may be limited by climatic variables associated with regional biological productivity (e.g. mean annual precipitation and annual actual evapotranspiration), it is unclear whether plant-granivore interactions are themselves influenced by these climatic factors across broad spatial extents. We evaluated whether climatic conditions that are known to alter the abundance and activity of granivorous animals also affect rates of seed removal. Location: Eleven sites across temperate North America. Methods: We used a common protocol to assess the removal of the same seed species (Avena sativa) over a 2-day period. Model selection via the Akaike information criterion was used to determine a set of candidate binomial generalized linear mixed models that evaluated the relationship between local climatic data and post-dispersal seed predation. Results: Annual actual evapotranspiration was the single best predictor of the proportion of seeds removed. Annual actual evapotranspiration and mean annual precipitation were both positively related to mean seed removal and were included in four and three of the top five models, respectively. Annual temperature range was also positively related to seed removal and was an explanatory variable in three of the top four models. Main conclusions: Our work provides the first evidence that energy and precipitation, which are known to affect consumer abundance and activity, also translate to strong, predictable patterns of seed predation across a continent. More generally, these findings suggest that future changes in temperature and precipitation could have widespread consequences for plant species composition in grasslands, through impacts on plant recruitment.

Published

2015

2. Nitrogen increases early-stage and slows late-stage decomposition across diverse grasslands

Author

Gill, AL, Adler, PB, Borer, ET, Buyarski, CR, Cleland, EE, D'Antonio, CM, Davies, KF, Gruner, DS, Harpole, WS, Hofmockel, KS, MacDougall, AS, McCulley, RL, Melbourne, BA, Moore, JL, Morgan, John, Risch, AC, Schütz, M, Seabloom, EW, Wright, JP, Yang, LH, Hobbie, SE, and Wiley-Blackwell Publishing Ltd.

Subjects

nitrogen deposition, 50399 Soil Sciences not elsewhere classified, FOS: Agriculture, forestry and fisheries, grasslands, Nutrient Network (NutNet), Life Sciences, litter decomposition, phosphorus, nitrogen

Abstract

To evaluate how increased anthropogenic nutrient inputs alter carbon cycling in grasslands, we conducted a litter decomposition study across 20 temperate grasslands on three continents within the Nutrient Network, a globally distributed nutrient enrichment experiment We determined the effects of addition of experimental nitrogen (N), phosphorus (P) and potassium plus micronutrient (Kμ) on decomposition of a common tree leaf litter in a long-term study (maximum of 7 years; exact deployment period varied across sites). The use of higher order decomposition models allowed us to distinguish between the effects of nutrients on early- versus late-stage decomposition. Across continents, the addition of N (but not other nutrients) accelerated early-stage decomposition and slowed late-stage decomposition, increasing the slowly decomposing fraction by 28% and the overall litter mean residence time by 58%. Synthesis. Using a novel, long-term cross-site experiment, we found widespread evidence that N enhances the early stages of above-ground plant litter decomposition across diverse and widespread temperate grassland sites but slows late-stage decomposition. These findings were corroborated by fitting the data to multiple decomposition models and have implications for N effects on soil organic matter formation. For example, following N enrichment, increased microbial processing of litter substrates early in decomposition could promote the production and transfer of low molecular weight compounds to soils and potentially enhance the stabilization of mineral-associated organic matter. By contrast, by slowing late-stage decomposition, N enrichment could promote particulate organic matter (POM) accumulation. Such hypotheses deserve further testing.

Published

2022

3. Plant species' origin predicts dominance and response to nutrient enrichment and herbivores in global grasslands

Author

Seabloom, EW, Borer, ET, Buckley, YM, Cleland, EE, Davies, KF, Firn, J, Harpole, WS, Hautier, Y, Lind, EM, MacDougall, AS, Orrock, JL, Prober, SM, Adler, PB, Anderson, TM, Bakker, JD, Biederman, LA, Blumenthal, DM, Brown, CS, Brudvig, LA, Cadotte, M, Chu, C, Cottingham, KL, Crawley, MJ, Damschen, EI, Dantonio, CM, DeCrappeo, NM, Du, G, Fay, PA, Frater, P, Gruner, DS, Hagenah, N, Hector, A, Hillebrand, H, Hofmockel, KS, Humphries, HC, Jin, VL, Kay, A, Kirkman, KP, Klein, JA, Knops, JMH, La Pierre, KJ, Ladwig, L, Lambrinos, JG, Li, Q, Li, W, Marushia, R, McCulley, RL, Melbourne, BA, Mitchell, CE, Moore, JL, Morgan, J, Mortensen, B, O'Halloran, LR, Pyke, DA, Risch, AC, Sankaran, M, Schuetz, M, Simonsen, A, Smith, MD, Stevens, CJ, Sullivan, L, Wolkovich, E, Wragg, PD, Wright, J, Yang, L, Seabloom, EW, Borer, ET, Buckley, YM, Cleland, EE, Davies, KF, Firn, J, Harpole, WS, Hautier, Y, Lind, EM, MacDougall, AS, Orrock, JL, Prober, SM, Adler, PB, Anderson, TM, Bakker, JD, Biederman, LA, Blumenthal, DM, Brown, CS, Brudvig, LA, Cadotte, M, Chu, C, Cottingham, KL, Crawley, MJ, Damschen, EI, Dantonio, CM, DeCrappeo, NM, Du, G, Fay, PA, Frater, P, Gruner, DS, Hagenah, N, Hector, A, Hillebrand, H, Hofmockel, KS, Humphries, HC, Jin, VL, Kay, A, Kirkman, KP, Klein, JA, Knops, JMH, La Pierre, KJ, Ladwig, L, Lambrinos, JG, Li, Q, Li, W, Marushia, R, McCulley, RL, Melbourne, BA, Mitchell, CE, Moore, JL, Morgan, J, Mortensen, B, O'Halloran, LR, Pyke, DA, Risch, AC, Sankaran, M, Schuetz, M, Simonsen, A, Smith, MD, Stevens, CJ, Sullivan, L, Wolkovich, E, Wragg, PD, Wright, J, and Yang, L

Abstract

Exotic species dominate many communities; however the functional significance of species' biogeographic origin remains highly contentious. This debate is fuelled in part by the lack of globally replicated, systematic data assessing the relationship between species provenance, function and response to perturbations. We examined the abundance of native and exotic plant species at 64 grasslands in 13 countries, and at a subset of the sites we experimentally tested native and exotic species responses to two fundamental drivers of invasion, mineral nutrient supplies and vertebrate herbivory. Exotic species are six times more likely to dominate communities than native species. Furthermore, while experimental nutrient addition increases the cover and richness of exotic species, nutrients decrease native diversity and cover. Native and exotic species also differ in their response to vertebrate consumer exclusion. These results suggest that species origin has functional significance, and that eutrophication will lead to increased exotic dominance in grasslands.

Published

2015

4. Biochanin A feed supplementation alters dynamics of trace gas emissions from lamb urine-amended soil.

Author

Jacobs AA, Flythe MD, Ely DG, Munoz L, May JB, Nelson JA, Stanton V, McGrail RK, Pham K, and McCulley RL

Subjects

Animals, Sheep, Methane, Urine chemistry, Nitrous Oxide analysis, Soil chemistry, Animal Feed analysis, Dietary Supplements analysis, Genistein urine

Abstract

Sustainable growth in livestock production requires reductions in trace gas emissions on grazing lands. Urine excreta patches are hot spots for accelerated emissions of carbon and nitrogen. Ruminant dietary supplementation with the isoflavone biochanin A (BCA) has been shown to improve cattle weight gain. To determine if BCA supplementation affects urine N excretion and soil trace gas emissions, soil in microcosms was amended with urine from lambs fed 0, 0.45, or 0.90 g BCA day -1 . Soil gas emissions were measured over 60 days and analyzed with a linear mixed-effects model with repeated measures. On 2 days during the incubation, BCA addition across doses significantly reduced nitrous oxide emissions by 73% and methane by 98% compared to urine from non-dosed lambs. Cumulative ammonia volatilization was significantly reduced by 33% but cumulative nitrous oxide and methane emissions were not. Alterations in trace gas emissions occurred despite no change in urine N content with BCA feed supplementation. A separate laboratory incubation using urine from a non-supplemented lamb that was exogenously spiked with varying BCA concentrations supported these results: BCA significantly altered ammonia and methane emission dynamics and reduced cumulative nitrous oxide emissions by up to 41%. BCA did not change soil microbial community structure, suggesting alterations to other processes, such as soil enzyme activity, were affecting soil trace gas emissions. Overall, lamb BCA supplementation did not affect urine N but reduced ammonia volatilization, which may contribute to greater sustainability in livestock production systems., (© 2024 The Author(s). Journal of Environmental Quality © 2024 American Society of Agronomy, Crop Science Society of America, and Soil Science Society of America.)

Published

2024

5. Author Correction: Widening global variability in grassland biomass since the 1980s.

Author

MacDougall AS, Esch E, Chen Q, Carroll O, Bonner C, Ohlert T, Siewert M, Sulik J, Schweiger AK, Borer ET, Naidu D, Bagchi S, Hautier Y, Wilfahrt P, Larson K, Olofsson J, Cleland E, Muthukrishnan R, O'Halloran L, Alberti J, Anderson TM, Arnillas CA, Bakker JD, Barrio IC, Biederman L, Boughton EH, Brudvig LA, Bruschetti M, Buckley Y, Bugalho MN, Cadotte MW, Caldeira MC, Catford JA, D'Antonio C, Davies K, Daleo P, Dickman CR, Donohue I, DuPre ME, Elgersma K, Eisenhauer N, Eskelinen A, Estrada C, Fay PA, Feng Y, Gruner DS, Hagenah N, Haider S, Harpole WS, Hersch-Green E, Jentsch A, Kirkman K, Knops JMH, Laanisto L, Lannes LS, Laungani R, Lkhagva A, Macek P, Martina JP, McCulley RL, Melbourne B, Mitchell R, Moore JL, Morgan JW, Muraina TO, Niu Y, Pärtel M, Peri PL, Power SA, Price JN, Prober SM, Ren Z, Risch AC, Smith NG, Sonnier G, Standish RJ, Stevens CJ, Tedder M, Tognetti P, Veen GFC, Virtanen R, Wardle GM, Waring E, Wolf AA, Yahdjian L, and Seabloom EW

Published

2024

6. Widening global variability in grassland biomass since the 1980s.

Author

MacDougall AS, Esch E, Chen Q, Carroll O, Bonner C, Ohlert T, Siewert M, Sulik J, Schweiger AK, Borer ET, Naidu D, Bagchi S, Hautier Y, Wilfahrt P, Larson K, Olofsson J, Cleland E, Muthukrishnan R, O'Halloran L, Alberti J, Anderson TM, Arnillas CA, Bakker JD, Barrio IC, Biederman L, Boughton EH, Brudvig LA, Bruschetti M, Buckley Y, Bugalho MN, Cadotte MW, Caldeira MC, Catford JA, D'Antonio C, Davies K, Daleo P, Dickman CR, Donohue I, DuPre ME, Elgersma K, Eisenhauer N, Eskelinen A, Estrada C, Fay PA, Feng Y, Gruner DS, Hagenah N, Haider S, Harpole WS, Hersch-Green E, Jentsch A, Kirkman K, Knops JMH, Laanisto L, Lannes LS, Laungani R, Lkhagva A, Macek P, Martina JP, McCulley RL, Melbourne B, Mitchell R, Moore JL, Morgan JW, Muraina TO, Niu Y, Pärtel M, Peri PL, Power SA, Price JN, Prober SM, Ren Z, Risch AC, Smith NG, Sonnier G, Standish RJ, Stevens CJ, Tedder M, Tognetti P, Veen GFC, Virtanen R, Wardle GM, Waring E, Wolf AA, Yahdjian L, and Seabloom EW

Subjects

Climate Change, Seasons, Biodiversity, Grassland, Biomass

Abstract

Global change is associated with variable shifts in the annual production of aboveground plant biomass, suggesting localized sensitivities with unclear causal origins. Combining remotely sensed normalized difference vegetation index data since the 1980s with contemporary field data from 84 grasslands on 6 continents, we show a widening divergence in site-level biomass ranging from +51% to -34% globally. Biomass generally increased in warmer, wetter and species-rich sites with longer growing seasons and declined in species-poor arid areas. Phenological changes were widespread, revealing substantive transitions in grassland seasonal cycling. Grazing, nitrogen deposition and plant invasion were prevalent in some regions but did not predict overall trends. Grasslands are undergoing sizable changes in production, with implications for food security, biodiversity and carbon storage especially in arid regions where declines are accelerating., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

7. Primary productivity regulates rhizosphere soil organic carbon: Evidence from a chronosequence of subtropical Chinese fir (Cunninghamia lanceolata) plantation.

Author

Chen X, Chen S, Arthur MA, McCulley RL, Liu X, Xiong D, Xu C, Yang Z, and Yang Y

Subjects

China, Carbon Sequestration, Soil Microbiology, Cunninghamia, Rhizosphere, Soil chemistry, Carbon analysis

Abstract

Tree plantations worldwide are a large terrestrial carbon sink. Previous studies on the carbon sequestration capacity of plantations mainly focused on tree biomass carbon sequestration, but the importance of soil organic carbon (SOC) was relatively unclear. Living root carbon inputs influence SOC via plant-microbe interactions in the rhizosphere and play an essential role in nutrient cycling. Here, we compared SOC, including its fractions, microbial properties, and major nutrients in rhizosphere and bulk soils, and examined their relationships to net primary productivity (NPP) across three developmental stages of Chinese fir (Cunninghamia lanceolata) plantations (6, 18, and 42 years old) in subtropical China. Although NPP differed among the three plantations, SOC concentration in bulk soils did not vary significantly among them. However, SOC concentration and labile C pool I and recalcitrant C pool in rhizosphere soils were significantly (p < 0.05) higher in the young (6-year) and mature (42-year) plantations, both of which had lower (p < 0.05) NPP (-37.71 % and - 42.67 %) compared to the middle-aged (18-year) plantation, suggesting a decoupling of NPP from rhizosphere SOC in the plantations. The decoupling of NPP from rhizosphere SOC concentrations may be driven by nitrogen (N) and phosphorus (P) tree growth requirements, belowground C allocation, and resultant microbial activity in this highly weathered subtropical soil. Our study provides field-based evidence suggesting that rhizosphere SOC changes are primarily regulated by net primary production in subtropical forest plantations. We propose that accurate predictions of SOC dynamics in forest plantations require an improved understanding of rhizosphere processes during plantation development., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Zhijie Yang reports was provided by National Natural Funding of China (Nos. 31670623 and 31930071). If there are other authors, they declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

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

Author

Siebert J, Sünnemann M, Hautier Y, Risch AC, Bakker JD, Biederman L, Blumenthal DM, Borer ET, Bugalho MN, Broadbent AAD, Caldeira MC, Cleland E, Davies KF, Eskelinen A, Hagenah N, Knops JMH, MacDougall AS, McCulley RL, Moore JL, Power SA, Price JN, Seabloom EW, Standish R, Stevens CJ, Zimmermann S, and Eisenhauer N

Subjects

Soil chemistry, Soil Microbiology, Biodiversity, Ecosystem, Grassland

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., (© 2023. The Author(s).)

Published

2023

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

Author

Spohn M, Bagchi S, Biederman LA, Borer ET, Bråthen KA, Bugalho MN, Caldeira MC, Catford JA, Collins SL, Eisenhauer N, Hagenah N, Haider S, Hautier Y, Knops JMH, Koerner SE, Laanisto L, Lekberg Y, Martina JP, Martinson H, McCulley RL, Peri PL, Macek P, Power SA, Risch AC, Roscher C, Seabloom EW, Stevens C, Veen GFC, Virtanen R, and Yahdjian L

Subjects

Carbon, Biodiversity, Biomass, Plants, Nitrogen, Ecosystem, Soil

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., (© 2023. Springer Nature Limited.)

Published

2023

10. Publisher Correction: Clarifying the effect of biodiversity on productivity in natural ecosystems with longitudinal data and methods for causal inference.

Author

Dee LE, Ferraro PJ, Severen CN, Kimmel KA, Borer ET, Byrnes JEK, Clark AT, Hautier Y, Hector A, Raynaud X, Reich PB, Wright AJ, Arnillas CA, Davies KF, MacDougall A, Mori AS, Smith MD, Adler PB, Bakker JD, Brauman KA, Cowles J, Komatsu K, Knops JMH, McCulley RL, Moore JL, Morgan JW, Ohlert T, Power SA, Sullivan LL, Stevens C, and Loreau M

Published

2023

11. Clarifying the effect of biodiversity on productivity in natural ecosystems with longitudinal data and methods for causal inference.

Author

Dee LE, Ferraro PJ, Severen CN, Kimmel KA, Borer ET, Byrnes JEK, Clark AT, Hautier Y, Hector A, Raynaud X, Reich PB, Wright AJ, Arnillas CA, Davies KF, MacDougall A, Mori AS, Smith MD, Adler PB, Bakker JD, Brauman KA, Cowles J, Komatsu K, Knops JMH, McCulley RL, Moore JL, Morgan JW, Ohlert T, Power SA, Sullivan LL, Stevens C, and Loreau M

Subjects

Plants, Causality, Biomass, Ecosystem, Biodiversity

Abstract

Causal effects of biodiversity on ecosystem functions can be estimated using experimental or observational designs - designs that pose a tradeoff between drawing credible causal inferences from correlations and drawing generalizable inferences. Here, we develop a design that reduces this tradeoff and revisits the question of how plant species diversity affects productivity. Our design leverages longitudinal data from 43 grasslands in 11 countries and approaches borrowed from fields outside of ecology to draw causal inferences from observational data. Contrary to many prior studies, we estimate that increases in plot-level species richness caused productivity to decline: a 10% increase in richness decreased productivity by 2.4%, 95% CI [-4.1, -0.74]. This contradiction stems from two sources. First, prior observational studies incompletely control for confounding factors. Second, most experiments plant fewer rare and non-native species than exist in nature. Although increases in native, dominant species increased productivity, increases in rare and non-native species decreased productivity, making the average effect negative in our study. By reducing the tradeoff between experimental and observational designs, our study demonstrates how observational studies can complement prior ecological experiments and inform future ones., (© 2023. The Author(s).)

Published

2023

12. Environmental heterogeneity modulates the effect of plant diversity on the spatial variability of grassland biomass.

Author

Daleo P, Alberti J, Chaneton EJ, Iribarne O, Tognetti PM, Bakker JD, Borer ET, Bruschetti M, MacDougall AS, Pascual J, Sankaran M, Seabloom EW, Wang S, Bagchi S, Brudvig LA, Catford JA, Dickman CR, Dickson TL, Donohue I, Eisenhauer N, Gruner DS, Haider S, Jentsch A, Knops JMH, Lekberg Y, McCulley RL, Moore JL, Mortensen B, Ohlert T, Pärtel M, Peri PL, Power SA, Risch AC, Rocca C, Smith NG, Stevens C, Tamme R, Veen GFC, Wilfahrt PA, and Hautier Y

Subjects

Biomass, Biodiversity, Reproducibility of Results, Plants, Ecosystem, Grassland

Abstract

Plant productivity varies due to environmental heterogeneity, and theory suggests that plant diversity can reduce this variation. While there is strong evidence of diversity effects on temporal variability of productivity, whether this mechanism extends to variability across space remains elusive. Here we determine the relationship between plant diversity and spatial variability of productivity in 83 grasslands, and quantify the effect of experimentally increased spatial heterogeneity in environmental conditions on this relationship. We found that communities with higher plant species richness (alpha and gamma diversity) have lower spatial variability of productivity as reduced abundance of some species can be compensated for by increased abundance of other species. In contrast, high species dissimilarity among local communities (beta diversity) is positively associated with spatial variability of productivity, suggesting that changes in species composition can scale up to affect productivity. Experimentally increased spatial environmental heterogeneity weakens the effect of plant alpha and gamma diversity, and reveals that beta diversity can simultaneously decrease and increase spatial variability of productivity. Our findings unveil the generality of the diversity-stability theory across space, and suggest that reduced local diversity and biotic homogenization can affect the spatial reliability of key ecosystem functions., (© 2023. The Author(s).)

Published

2023

13. Climate change alters slug abundance but not herbivory in a temperate grassland.

Author

Weber D, McGrail RK, Carlisle AE, Harwood JD, and McCulley RL

Subjects

Animals, Grassland, Climate Change, Plants, Ecosystem, Gastropoda

Abstract

Climate change will significantly impact the world's ecosystems, in part by altering species interactions and ecological processes, such as herbivory and plant community dynamics, which may impact forage quality and ecosystem production. Yet relatively few field experimental manipulations assessing all of these parameters have been performed to date. To help fill this knowledge gap, we evaluated the effects of increased temperature (+3°C day and night, year-round) and precipitation (+30% of mean annual rainfall) on slug herbivory and abundance and plant community dynamics biweekly in a pasture located in central Kentucky, U.S.A. Warming increased slug abundance once during the winter, likely due to improving conditions for foraging, whereas warming reduced slug abundance at times in late spring, mid-summer, and early fall (from 62-95% reduction depending on month). We found that warming and increased precipitation did not significantly modify slug herbivory at our site, despite altering slug abundance and affecting plant community composition and forage quality. Climate change will alter seasonal patterns of slug abundance through both direct effects on slug biology and indirect effects mediated by changes in the plant community, suggesting that pasture management practices may have to adapt., Competing Interests: The authors have declared no competing interests exist., (Copyright: © 2023 Weber et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

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

Author

Price JN, Sitters J, Ohlert T, Tognetti PM, Brown CS, Seabloom EW, Borer ET, Prober SM, Bakker ES, MacDougall AS, Yahdjian L, Gruner DS, Olde Venterink H, Barrio IC, Graff P, Bagchi S, Arnillas CA, Bakker JD, Blumenthal DM, Boughton EH, Brudvig LA, Bugalho MN, Cadotte MW, Caldeira MC, Dickman CR, Donohue I, Grégory S, Hautier Y, Jónsdóttir IS, Lannes LS, McCulley RL, Moore JL, Power SA, Risch AC, Schütz M, Standish R, Stevens CJ, Veen GF, Virtanen R, and Wardle GM

Subjects

Animals, Mammals, Plants, Soil, Biodiversity, Herbivory

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., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

15. Do trade-offs govern plant species' responses to different global change treatments?

Author

Langley JA, Grman E, Wilcox KR, Avolio ML, Komatsu KJ, Collins SL, Koerner SE, Smith MD, Baldwin AH, Bowman W, Chiariello N, Eskelinen A, Harmens H, Hovenden M, Klanderud K, McCulley RL, Onipchenko VG, Robinson CH, and Suding KN

Subjects

Acclimatization, Temperature, Water, Nitrogen, Plants

Abstract

Plants are subject to trade-offs among growth strategies such that adaptations for optimal growth in one condition can preclude optimal growth in another. Thus, we predicted that a plant species that responds positively to one global change treatment would be less likely than average to respond positively to another treatment, particularly for pairs of treatments that favor distinct traits. We examined plant species' abundances in 39 global change experiments manipulating two or more of the following: CO 2 , nitrogen, phosphorus, water, temperature, or disturbance. Overall, the directional response of a species to one treatment was 13% more likely than expected to oppose its response to a another single-factor treatment. This tendency was detectable across the global data set, but held little predictive power for individual treatment combinations or within individual experiments. Although trade-offs in the ability to respond to different global change treatments exert discernible global effects, other forces obscure their influence in local communities., (© 2021 The Ecological Society of America.)

Published

2022

16. Global Grassland Diazotrophic Communities Are Structured by Combined Abiotic, Biotic, and Spatial Distance Factors but Resilient to Fertilization.

Author

Nepel M, Angel R, Borer ET, Frey B, MacDougall AS, McCulley RL, Risch AC, Schütz M, Seabloom EW, and Woebken D

Abstract

Grassland ecosystems cover around 37% of the ice-free land surface on Earth and have critical socioeconomic importance globally. As in many terrestrial ecosystems, biological dinitrogen (N 2 ) fixation represents an essential natural source of nitrogen (N). The ability to fix atmospheric N 2 is limited to diazotrophs, a diverse guild of bacteria and archaea. To elucidate the abiotic (climatic, edaphic), biotic (vegetation), and spatial factors that govern diazotrophic community composition in global grassland soils, amplicon sequencing of the dinitrogenase reductase gene- nifH -was performed on samples from a replicated standardized nutrient [N, phosphorus (P)] addition experiment in 23 grassland sites spanning four continents. Sites harbored distinct and diverse diazotrophic communities, with most of reads assigned to diazotrophic taxa within the Alphaproteobacteria (e.g., Rhizobiales ), Cyanobacteria (e.g., Nostocales ), and Deltaproteobacteria (e.g., Desulforomonadales ) groups. Likely because of the wide range of climatic and edaphic conditions and spatial distance among sampling sites, only a few of the taxa were present at all sites. The best model describing the variation among soil diazotrophic communities at the OTU level combined climate seasonality (temperature in the wettest quarter and precipitation in the warmest quarter) with edaphic (C:N ratio, soil texture) and vegetation factors (various perennial plant covers). Additionally, spatial variables (geographic distance) correlated with diazotrophic community variation, suggesting an interplay of environmental variables and spatial distance. The diazotrophic communities appeared to be resilient to elevated nutrient levels, as 2-4 years of chronic N and P additions had little effect on the community composition. However, it remains to be seen, whether changes in the community composition occur after exposure to long-term, chronic fertilization regimes., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Nepel, Angel, Borer, Frey, MacDougall, McCulley, Risch, Schütz, Seabloom and Woebken.)

Published

2022

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

Author

Wilfahrt PA, Asmus AL, Seabloom EW, Henning JA, Adler P, Arnillas CA, Bakker JD, Biederman L, Brudvig LA, Cadotte M, Daleo P, Eskelinen A, Firn J, Harpole WS, Hautier Y, Kirkman KP, Komatsu KJ, Laungani R, MacDougall A, McCulley RL, Moore JL, Morgan JW, Mortensen B, Ochoa Hueso R, Ohlert T, Power SA, Price J, Risch AC, Schuetz M, Shoemaker L, Stevens C, Strauss AT, Tognetti PM, Virtanen R, and Borer ET

Subjects

Humans, Extinction, Biological, Plants

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., (© 2021 by the Ecological Society of America.)

Published

2021

18. Determinants of community compositional change are equally affected by global change.

Author

Avolio ML, Komatsu KJ, Collins SL, Grman E, Koerner SE, Tredennick AT, Wilcox KR, Baer S, Boughton EH, Britton AJ, Foster B, Gough L, Hovenden M, Isbell F, Jentsch A, Johnson DS, Knapp AK, Kreyling J, Langley JA, Lortie C, McCulley RL, McLaren JR, Reich PB, Seabloom EW, Smith MD, Suding KN, Suttle KB, and Tognetti PM

Subjects

Plants, Biodiversity, Ecosystem

Abstract

Global change is impacting plant community composition, but the mechanisms underlying these changes are unclear. Using a dataset of 58 global change experiments, we tested the five fundamental mechanisms of community change: changes in evenness and richness, reordering, species gains and losses. We found 71% of communities were impacted by global change treatments, and 88% of communities that were exposed to two or more global change drivers were impacted. Further, all mechanisms of change were equally likely to be affected by global change treatments-species losses and changes in richness were just as common as species gains and reordering. We also found no evidence of a progression of community changes, for example, reordering and changes in evenness did not precede species gains and losses. We demonstrate that all processes underlying plant community composition changes are equally affected by treatments and often occur simultaneously, necessitating a wholistic approach to quantifying community changes., (© 2021 The Authors. Ecology Letters published by John Wiley & Sons Ltd.)

Published

2021

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

Author

Tognetti PM, Prober SM, Báez S, Chaneton EJ, Firn J, Risch AC, Schuetz M, Simonsen AK, Yahdjian L, Borer ET, Seabloom EW, Arnillas CA, Bakker JD, Brown CS, Cadotte MW, Caldeira MC, Daleo P, Dwyer JM, Fay PA, Gherardi LA, Hagenah N, Hautier Y, Komatsu KJ, McCulley RL, Price JN, Standish RJ, Stevens CJ, Wragg PD, and Sankaran M

Subjects

Biodiversity, Biomass, Fabaceae drug effects, Probability, Fabaceae physiology, Grassland, Internationality, Nitrogen pharmacology, Phosphorus pharmacology

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., Competing Interests: The authors declare no competing interest.

Published

2021

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

Author

Seabloom EW, Adler PB, Alberti J, Biederman L, Buckley YM, Cadotte MW, Collins SL, Dee L, Fay PA, Firn J, Hagenah N, Harpole WS, Hautier Y, Hector A, Hobbie SE, Isbell F, Knops JMH, Komatsu KJ, Laungani R, MacDougall A, McCulley RL, Moore JL, Morgan JW, Ohlert T, Prober SM, Risch AC, Schuetz M, Stevens CJ, and Borer ET

Subjects

Biomass, Grassland, Nitrogen analysis, Nutrients, Soil, Biodiversity, Ecosystem

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., (© 2020 by the Ecological Society of America.)

Published

2021

21. Author Correction: General destabilizing effects of eutrophication on grassland productivity at multiple spatial scales.

Author

Hautier Y, Zhang P, Loreau M, Wilcox KR, Seabloom EW, Borer ET, Byrnes JEK, Koerner SE, Komatsu KJ, Lefcheck JS, Hector A, Adler PB, Alberti J, Arnillas CA, Bakker JD, Brudvig LA, Bugalho MN, Cadotte M, Caldeira MC, Carroll O, Crawley M, Collins SL, Daleo P, Dee LE, Eisenhauer N, Eskelinen A, Fay PA, Gilbert B, Hansar A, Isbell F, Knops JMH, MacDougall AS, McCulley RL, Moore JL, Morgan JW, Mori AS, Peri PL, Pos ET, Power SA, Price JN, Reich PB, Risch AC, Roscher C, Sankaran M, Schütz M, Smith M, Stevens C, Tognetti PM, Virtanen R, Wardle GM, Wilfahrt PA, and Wang S

Published

2021

22. Global impacts of fertilization and herbivore removal on soil net nitrogen mineralization are modulated by local climate and soil properties.

Author

Risch AC, Zimmermann S, Moser B, Schütz M, Hagedorn F, Firn J, Fay PA, Adler PB, Biederman LA, Blair JM, Borer ET, Broadbent AAD, Brown CS, Cadotte MW, Caldeira MC, Davies KF, di Virgilio A, Eisenhauer N, Eskelinen A, Knops JMH, MacDougall AS, McCulley RL, Melbourne BA, Moore JL, Power SA, Prober SM, Seabloom EW, Siebert J, Silveira ML, Speziale KL, Stevens CJ, Tognetti PM, Virtanen R, Yahdjian L, and Ochoa-Hueso R

Subjects

Animals, Ecosystem, Fertilization, Grassland, Herbivory, Humans, Nitrogen analysis, Soil

Abstract

Soil nitrogen (N) availability is critical for grassland functioning. However, human activities have increased the supply of biologically limiting nutrients, and changed the density and identity of mammalian herbivores. These anthropogenic changes may alter net soil N mineralization (soil net N min ), that is, the net balance between N mineralization and immobilization, which could severely impact grassland structure and functioning. Yet, to date, little is known about how fertilization and herbivore removal individually, or jointly, affect soil net N min across a wide range of grasslands that vary in soil and climatic properties. Here we collected data from 22 grasslands on five continents, all part of a globally replicated experiment, to assess how fertilization and herbivore removal affected potential (laboratory-based) and realized (field-based) soil net N min . Herbivore removal in the absence of fertilization did not alter potential and realized soil net N min . However, fertilization alone and in combination with herbivore removal consistently increased potential soil net N min. Realized soil net N min , in contrast, significantly decreased in fertilized plots where herbivores were removed. Treatment effects on potential and realized soil net N min were contingent on site-specific soil and climatic properties. Fertilization effects on potential soil net N min were larger at sites with higher mean annual precipitation (MAP) and temperature of the wettest quarter (T.q.wet). Reciprocally, realized soil net N min declined most strongly with fertilization and herbivore removal at sites with lower MAP and higher T.q.wet. In summary, our findings show that anthropogenic nutrient enrichment, herbivore exclusion and alterations in future climatic conditions can negatively impact soil net N min across global grasslands under realistic field conditions. This is an important context-dependent knowledge for grassland management worldwide., (© 2020 John Wiley & Sons Ltd.)

Published

2020

23. Environmental factors influencing fine-scale distribution of Antarctica's only endemic insect.

Author

Potts LJ, Gantz JD, Kawarasaki Y, Philip BN, Gonthier DJ, Law AD, Moe L, Unrine JM, McCulley RL, Lee RE Jr, Denlinger DL, and Teets NM

Subjects

Animals, Antarctic Regions, Islands, Plants, Ecosystem, Soil

Abstract

Species distributions are dependent on interactions with abiotic and biotic factors in the environment. Abiotic factors like temperature, moisture, and soil nutrients, along with biotic interactions within and between species, can all have strong influences on spatial distributions of plants and animals. Terrestrial Antarctic habitats are relatively simple and thus good systems to study ecological factors that drive species distributions and abundance. However, these environments are also sensitive to perturbation, and thus understanding the ecological drivers of species distribution is critical for predicting responses to environmental change. The Antarctic midge, Belgica antarctica, is the only endemic insect on the continent and has a patchy distribution along the Antarctic Peninsula. While its life history and physiology are well studied, factors that underlie variation in population density within its range are unknown. Previous work on Antarctic microfauna indicates that distribution over broad scales is primarily regulated by soil moisture, nitrogen content, and the presence of suitable plant life, but whether these patterns are true over smaller spatial scales has not been investigated. Here we sampled midges across five islands on the Antarctic Peninsula and tested a series of hypotheses to determine the relative influences of abiotic and biotic factors on midge abundance. While historical literature suggests that Antarctic organisms are limited by the abiotic environment, our best-supported hypothesis indicated that abundance is predicted by a combination of abiotic and biotic conditions. Our results are consistent with a growing body of literature that biotic interactions are more important in Antarctic ecosystems than historically appreciated.

Published

2020

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

Author

Hautier Y, Zhang P, Loreau M, Wilcox KR, Seabloom EW, Borer ET, Byrnes JEK, Koerner SE, Komatsu KJ, Lefcheck JS, Hector A, Adler PB, Alberti J, Arnillas CA, Bakker JD, Brudvig LA, Bugalho MN, Cadotte M, Caldeira MC, Carroll O, Crawley M, Collins SL, Daleo P, Dee LE, Eisenhauer N, Eskelinen A, Fay PA, Gilbert B, Hansar A, Isbell F, Knops JMH, MacDougall AS, McCulley RL, Moore JL, Morgan JW, Mori AS, Peri PL, Pos ET, Power SA, Price JN, Reich PB, Risch AC, Roscher C, Sankaran M, Schütz M, Smith M, Stevens C, Tognetti PM, Virtanen R, Wardle GM, Wilfahrt PA, and Wang S

Subjects

Biodiversity, Biomass, Fertilization, Models, Biological, Plants, Biota, Ecosystem, Eutrophication, Grassland

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

25. Microbial processing of plant remains is co-limited by multiple nutrients in global grasslands.

Author

Ochoa-Hueso R, Borer ET, Seabloom EW, Hobbie SE, Risch AC, Collins SL, Alberti J, Bahamonde HA, Brown CS, Caldeira MC, Daleo P, Dickman CR, Ebeling A, Eisenhauer N, Esch EH, Eskelinen A, Fernández V, Güsewell S, Gutierrez-Larruga B, Hofmockel K, Laungani R, Lind E, López A, McCulley RL, Moore JL, Peri PL, Power SA, Price JN, Prober SM, Roscher C, Sarneel JM, Schütz M, Siebert J, Standish RJ, Velasco Ayuso S, Virtanen R, Wardle GM, Wiehl G, Yahdjian L, and Zamin T

Subjects

Carbon, Nitrogen analysis, Nutrients, Soil, Ecosystem, Grassland

Abstract

Microbial processing of aggregate-unprotected organic matter inputs is key for soil fertility, long-term ecosystem carbon and nutrient sequestration and sustainable agriculture. We investigated the effects of adding multiple nutrients (nitrogen, phosphorus and potassium plus nine essential macro- and micro-nutrients) on decomposition and biochemical transformation of standard plant materials buried in 21 grasslands from four continents. Addition of multiple nutrients weakly but consistently increased decomposition and biochemical transformation of plant remains during the peak-season, concurrent with changes in microbial exoenzymatic activity. Higher mean annual precipitation and lower mean annual temperature were the main climatic drivers of higher decomposition rates, while biochemical transformation of plant remains was negatively related to temperature of the wettest quarter. Nutrients enhanced decomposition most at cool, high rainfall sites, indicating that in a warmer and drier future fertilized grassland soils will have an even more limited potential for microbial processing of plant remains., (© 2020 John Wiley & Sons Ltd.)

Published

2020

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

Author

Sitters J, Wubs ERJ, Bakker ES, Crowther TW, Adler PB, Bagchi S, Bakker JD, Biederman L, Borer ET, Cleland EE, Eisenhauer N, Firn J, Gherardi L, Hagenah N, Hautier Y, Hobbie SE, Knops JMH, MacDougall AS, McCulley RL, Moore JL, Mortensen B, Peri PL, Prober SM, Riggs C, Risch AC, Schütz M, Seabloom EW, Siebert J, Stevens CJ, and Veen GFC

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-atmosphere interactions under future climate change., (© 2020 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2020

27. Time in pasture rotation alters soil microbial community composition and function and increases carbon sequestration potential in a temperate agroecosystem.

Author

Lin D, McCulley RL, Nelson JA, Jacobsen KL, and Zhang D

Subjects

Climate Change, Kentucky, Microbiota, Agriculture methods, Carbon Sequestration, Ecosystem, Soil Microbiology

Abstract

Soil carbon (C) sequestration plays an important role in mitigating global climate change, and certain land utilization strategies can exert a pronounced effect on carbon storage. Land use practices, such as planting previously cropped lands into perennial grasslands, can increase soil C sequestration; however, the temporal response of soil C pools to such changes in land use are likely complex and not well quantified. In the current study, a space-for-time approach was used to assess the response of soil C sequestration and microbial community composition during a five-year grazed pasture rotation following three years of vegetable production on a central Kentucky farm. After 5 years in pasture, soil organic C and N in the top 15 cm increased 20.6% and 20.1%, respectively, from year 1 levels, and particulate organic matter C (POM C) increased 53.5%. A carbon mineralization (CM) assay indicated that the potential release of CO 2 also increased with time in pasture rotation. When compared to permanent pasture (not previously used for vegetable production), soil microbial community composition differed in rotation years 1-3 but became similar in years 4 and 5. Multi-response permutation procedure (MRPP) analysis showed that CM and POM were key factors affecting microbial community composition. Soil microbial community composition also varied with time of year (season), but to a lesser degree than with pasture duration. Overall, incorporation of perennial pasture into cropping systems can have profound effects on microbial community composition and function, increasing soil organic C, and consequently enhancing the potential for C sequestration; however, whether these increases in C storage persist throughout the full cropping sequence (i.e., once the pasture has been returned to vegetables) and/or how these changes influence subsequent vegetable production remains to be evaluated., (Published by Elsevier B.V.)

Published

2020

28. Soil net nitrogen mineralisation across global grasslands.

Author

Risch AC, Zimmermann S, Ochoa-Hueso R, Schütz M, Frey B, Firn JL, Fay PA, Hagedorn F, Borer ET, Seabloom EW, Harpole WS, Knops JMH, McCulley RL, Broadbent AAD, Stevens CJ, Silveira ML, Adler PB, Báez S, Biederman LA, Blair JM, Brown CS, Caldeira MC, Collins SL, Daleo P, di Virgilio A, Ebeling A, Eisenhauer N, Esch E, Eskelinen A, Hagenah N, Hautier Y, Kirkman KP, MacDougall AS, Moore JL, Power SA, Prober SM, Roscher C, Sankaran M, Siebert J, Speziale KL, Tognetti PM, Virtanen R, Yahdjian L, and Moser B

Abstract

Soil nitrogen mineralisation (N min ), the conversion of organic into inorganic N, is important for productivity and nutrient cycling. The balance between mineralisation and immobilisation (net N min ) varies with soil properties and climate. However, because most global-scale assessments of net N min are laboratory-based, its regulation under field-conditions and implications for real-world soil functioning remain uncertain. Here, we explore the drivers of realised (field) and potential (laboratory) soil net N min across 30 grasslands worldwide. We find that realised N min is largely explained by temperature of the wettest quarter, microbial biomass, clay content and bulk density. Potential N min only weakly correlates with realised N min , but contributes to explain realised net N min when combined with soil and climatic variables. We provide novel insights of global realised soil net N min and show that potential soil net N min data available in the literature could be parameterised with soil and climate data to better predict realised N min .

Published

2019

29. Tall Fescue and E. coenophiala Genetics Influence Root-Associated Soil Fungi in a Temperate Grassland.

Author

Slaughter LC, Nelson JA, Carlisle AE, Bourguignon M, Dinkins RD, Phillips TD, and McCulley RL

Abstract

A constitutive, host-specific symbiosis exists between the aboveground fungal endophyte Epichloë coenophiala (Morgan-Jones & W. Gams) and the cool-season grass tall fescue ( Lolium arundinaceum (Schreb.) Darbysh.), which is a common forage grass in the United States, Australia, New Zealand, and temperate European grasslands. New cultivars of tall fescue are continually developed to improve pasture productivity and animal health by manipulating both grass and E. coenophiala genetics, yet how these selected grass-endophyte combinations impact other microbial symbionts such as mycorrhizal and dark septate fungi remains unclear. Without better characterizing how genetically distinct grass-endophyte combinations interact with belowground microorganisms, we cannot determine how adoption of new E. coenophiala -symbiotic cultivars in pasture systems will influence long-term soil characteristics and ecosystem function. Here, we examined how E. coenophiala presence and host × endophyte genetic combinations control root colonization by belowground symbiotic fungi and associated plant nutrient concentrations and soil properties in a 2-year manipulative field experiment. We used four vegetative clone pairs of tall fescue that consisted of one endophyte-free (E-) and one E. coenophiala -symbiotic (E+) clone each, where E+ clones within each pair contained one of four endophyte genotypes: CTE14, CTE45, NTE16, or NTE19. After 2 years of growth in field plots, we measured root colonization of arbuscular mycorrhizal fungi (AMF) and dark septate endophytes (DSE), extraradical AMF hyphae in soil, total C, N, and P in root and shoot samples, as well as C and N in associated soils. Although we observed no effects of E. coenophiala presence or symbiotic genotype on total AMF or DSE colonization rates in roots, different grass-endophyte combinations altered AMF arbuscule presence and extraradical hyphal length in soil. The CTE45 genotype hosted the fewest AMF arbuscules regardless of endophyte presence, and E+ clones within NTE19 supported significantly greater soil extraradical hyphae compared to E- clones. Because AMF are often associated with improved soil physical characteristics and C sequestration, our results suggest that development and use of unique grass-endophyte combinations may cause divergent effects on long-term ecosystem properties., (Copyright © 2019 Slaughter, Nelson, Carlisle, Bourguignon, Dinkins, Phillips and McCulley.)

Published

2019

30. Global change effects on plant communities are magnified by time and the number of global change factors imposed.

Author

Komatsu KJ, Avolio ML, Lemoine NP, Isbell F, Grman E, Houseman GR, Koerner SE, Johnson DS, Wilcox KR, Alatalo JM, Anderson JP, Aerts R, Baer SG, Baldwin AH, Bates J, Beierkuhnlein C, Belote RT, Blair J, Bloor JMG, Bohlen PJ, Bork EW, Boughton EH, Bowman WD, Britton AJ, Cahill JF Jr, Chaneton E, Chiariello NR, Cheng J, Collins SL, Cornelissen JHC, Du G, Eskelinen A, Firn J, Foster B, Gough L, Gross K, Hallett LM, Han X, Harmens H, Hovenden MJ, Jagerbrand A, Jentsch A, Kern C, Klanderud K, Knapp AK, Kreyling J, Li W, Luo Y, McCulley RL, McLaren JR, Megonigal JP, Morgan JW, Onipchenko V, Pennings SC, Prevéy JS, Price JN, Reich PB, Robinson CH, Russell FL, Sala OE, Seabloom EW, Smith MD, Soudzilovskaia NA, Souza L, Suding K, Suttle KB, Svejcar T, Tilman D, Tognetti P, Turkington R, White S, Xu Z, Yahdjian L, Yu Q, Zhang P, and Zhang Y

Subjects

Bayes Theorem, Climate Change, Human Activities, Humans, Biodiversity, Ecosystem, Plants

Abstract

Global change drivers (GCDs) are expected to alter community structure and consequently, the services that ecosystems provide. Yet, few experimental investigations have examined effects of GCDs on plant community structure across multiple ecosystem types, and those that do exist present conflicting patterns. In an unprecedented global synthesis of over 100 experiments that manipulated factors linked to GCDs, we show that herbaceous plant community responses depend on experimental manipulation length and number of factors manipulated. We found that plant communities are fairly resistant to experimentally manipulated GCDs in the short term (<10 y). In contrast, long-term (≥10 y) experiments show increasing community divergence of treatments from control conditions. Surprisingly, these community responses occurred with similar frequency across the GCD types manipulated in our database. However, community responses were more common when 3 or more GCDs were simultaneously manipulated, suggesting the emergence of additive or synergistic effects of multiple drivers, particularly over long time periods. In half of the cases, GCD manipulations caused a difference in community composition without a corresponding species richness difference, indicating that species reordering or replacement is an important mechanism of community responses to GCDs and should be given greater consideration when examining consequences of GCDs for the biodiversity-ecosystem function relationship. Human activities are currently driving unparalleled global changes worldwide. Our analyses provide the most comprehensive evidence to date that these human activities may have widespread impacts on plant community composition globally, which will increase in frequency over time and be greater in areas where communities face multiple GCDs simultaneously., Competing Interests: The authors declare no conflict of interest.

Published

2019

31. Effects of nutrient supply, herbivory, and host community on fungal endophyte diversity.

Author

Seabloom EW, Condon B, Kinkel L, Komatsu KJ, Lumibao CY, May G, McCulley RL, and Borer ET

Subjects

Biodiversity, Fungi, Nutrients, Endophytes, Herbivory

Abstract

The microbes contained within free-living organisms can alter host growth, reproduction, and interactions with the environment. In turn, processes occurring at larger scales determine the local biotic and abiotic environment of each host that may affect the diversity and composition of the microbiome community. Here, we examine variation in the diversity and composition of the foliar fungal microbiome in the grass host, Andropogon gerardii, across four mesic prairies in the central United States. Composition of fungal endophyte communities differed among sites and among individuals within a site, but was not consistently affected by experimental manipulation of nutrient supply to hosts (A. gerardii) or herbivore reduction via fencing. In contrast, mean fungal diversity was similar among sites but was limited by total plant biomass at the plot scale. Our work demonstrates that distributed experiments motivated by ecological theory are a powerful tool to unravel the multiscale processes governing microbial community composition and diversity., (© 2019 by the Ecological Society of America.)

Published

2019

32. Sensitivity of global soil carbon stocks to combined nutrient enrichment.

Author

Crowther TW, Riggs C, Lind EM, Borer ET, Seabloom EW, Hobbie SE, Wubs J, Adler PB, Firn J, Gherardi L, Hagenah N, Hofmockel KS, Knops JMH, McCulley RL, MacDougall AS, Peri PL, Prober SM, Stevens CJ, and Routh D

Subjects

Ecosystem, Nitrogen, Nutrients, Carbon, Soil chemistry

Abstract

Soil stores approximately twice as much carbon as the atmosphere and fluctuations in the size of the soil carbon pool directly influence climate conditions. We used the Nutrient Network global change experiment to examine how anthropogenic nutrient enrichment might influence grassland soil carbon storage at a global scale. In isolation, enrichment of nitrogen and phosphorous had minimal impacts on soil carbon storage. However, when these nutrients were added in combination with potassium and micronutrients, soil carbon stocks changed considerably, with an average increase of 0.04 KgCm -2  year -1 (standard deviation 0.18 KgCm -2  year -1 ). These effects did not correlate with changes in primary productivity, suggesting that soil carbon decomposition may have been restricted. Although nutrient enrichment caused soil carbon gains most dry, sandy regions, considerable absolute losses of soil carbon may occur in high-latitude regions that store the majority of the world's soil carbon. These mechanistic insights into the sensitivity of grassland carbon stocks to nutrient enrichment can facilitate biochemical modelling efforts to project carbon cycling under future climate scenarios., (© 2019 John Wiley & Sons Ltd/CNRS.)

Published

2019

33. Cross-biome patterns in soil microbial respiration predictable from evolutionary theory on thermal adaptation.

Author

Bradford MA, McCulley RL, Crowther TW, Oldfield EE, Wood SA, and Fierer N

Subjects

Acclimatization, Models, Biological, Soil chemistry, United States, Biological Evolution, Carbon Cycle, Carbon Dioxide analysis, Global Warming, Microbiota physiology, Soil Microbiology standards

Abstract

Climate warming may stimulate microbial metabolism of soil carbon, causing a carbon-cycle-climate feedback whereby carbon is redistributed from the soil to atmospheric CO 2 . The magnitude of this feedback is uncertain, in part because warming-induced shifts in microbial physiology and/or community composition could retard or accelerate soil carbon losses. Here, we measure microbial respiration rates for soils collected from 22 sites in each of 3 years, at locations spanning boreal to tropical climates. Respiration was measured in the laboratory with standard temperatures, moisture and excess carbon substrate, to allow physiological and community effects to be detected independent of the influence of these abiotic controls. Patterns in respiration for soils collected across the climate gradient are consistent with evolutionary theory on physiological responses that compensate for positive effects of temperature on metabolism. Respiration rates per unit microbial biomass were as much as 2.6 times higher for soils sampled from sites with a mean annual temperature of -2.0 versus 21.7 °C. Subsequent 100-d incubations suggested differences in the plasticity of the thermal response among microbial communities, with communities sampled from sites with higher mean annual temperature having a more plastic response. Our findings are consistent with adaptive metabolic responses to contrasting thermal regimes that are also observed in plants and animals. These results may help build confidence in soil-carbon-climate feedback projections by improving understanding of microbial processes represented in biogeochemical models.

Published

2019

34. Spatial heterogeneity in species composition constrains plant community responses to herbivory and fertilisation.

Author

Hodapp D, Borer ET, Harpole WS, Lind EM, Seabloom EW, Adler PB, Alberti J, Arnillas CA, Bakker JD, Biederman L, Cadotte M, Cleland EE, Collins S, Fay PA, Firn J, Hagenah N, Hautier Y, Iribarne O, Knops JMH, McCulley RL, MacDougall A, Moore JL, Morgan JW, Mortensen B, La Pierre KJ, Risch AC, Schütz M, Peri P, Stevens CJ, Wright J, and Hillebrand H

Subjects

Biodiversity, Herbivory, Plants

Abstract

Environmental change can result in substantial shifts in community composition. The associated immigration and extinction events are likely constrained by the spatial distribution of species. Still, studies on environmental change typically quantify biotic responses at single spatial (time series within a single plot) or temporal (spatial beta diversity at single time points) scales, ignoring their potential interdependence. Here, we use data from a global network of grassland experiments to determine how turnover responses to two major forms of environmental change - fertilisation and herbivore loss - are affected by species pool size and spatial compositional heterogeneity. Fertilisation led to higher rates of local extinction, whereas turnover in herbivore exclusion plots was driven by species replacement. Overall, sites with more spatially heterogeneous composition showed significantly higher rates of annual turnover, independent of species pool size and treatment. Taking into account spatial biodiversity aspects will therefore improve our understanding of consequences of global and anthropogenic change on community dynamics., (© 2018 John Wiley & Sons Ltd/CNRS.)

Published

2018

35. Herbivory and eutrophication mediate grassland plant nutrient responses across a global climatic gradient.

Author

Anderson TM, Griffith DM, Grace JB, Lind EM, Adler PB, Biederman LA, Blumenthal DM, Daleo P, Firn J, Hagenah N, Harpole WS, MacDougall AS, McCulley RL, Prober SM, Risch AC, Sankaran M, Schütz M, Seabloom EW, Stevens CJ, Sullivan LL, Wragg PD, and Borer ET

Subjects

Animals, Biomass, Ecosystem, Eutrophication, Humans, Nitrogen, Nutrients, Grassland, Herbivory

Abstract

Plant stoichiometry, the relative concentration of elements, is a key regulator of ecosystem functioning and is also being altered by human activities. In this paper we sought to understand the global drivers of plant stoichiometry and compare the relative contribution of climatic vs. anthropogenic effects. We addressed this goal by measuring plant elemental (C, N, P and K) responses to eutrophication and vertebrate herbivore exclusion at eighteen sites on six continents. Across sites, climate and atmospheric N deposition emerged as strong predictors of plot-level tissue nutrients, mediated by biomass and plant chemistry. Within sites, fertilization increased total plant nutrient pools, but results were contingent on soil fertility and the proportion of grass biomass relative to other functional types. Total plant nutrient pools diverged strongly in response to herbivore exclusion when fertilized; responses were largest in ungrazed plots at low rainfall, whereas herbivore grazing dampened the plant community nutrient responses to fertilization. Our study highlights (1) the importance of climate in determining plant nutrient concentrations mediated through effects on plant biomass, (2) that eutrophication affects grassland nutrient pools via both soil and atmospheric pathways and (3) that interactions among soils, herbivores and eutrophication drive plant nutrient responses at small scales, especially at water-limited sites., (© 2018 by the Ecological Society of America.)

Published

2018

36. Cover Crops and Fertilization Alter Nitrogen Loss in Organic and Conventional Conservation Agriculture Systems.

Author

Shelton RE, Jacobsen KL, and McCulley RL

Abstract

Agroecosystem nitrogen (N) loss produces greenhouse gases, induces eutrophication, and is costly for farmers; therefore, conservation agricultural management practices aimed at reducing N loss are increasingly adopted. However, the ecosystem consequences of these practices have not been well-studied. We quantified N loss via leaching, NH 3 volatilization, N 2 O emissions, and N retention in plant and soil pools of corn conservation agroecosystems in Kentucky, USA. Three systems were evaluated: (1) an unfertilized, organic system with cover crops hairy vetch ( Vicia villosa ), winter wheat ( Triticum aestivum ), or a mix of the two (bi-culture); (2) an organic system with a hairy vetch cover crop employing three fertilization schemes (0 N, organic N, or a fertilizer N-credit approach); and (3) a conventional system with a winter wheat cover crop and three fertilization schemes (0 N, urea N, or organic N). In the unfertilized organic system, cover crop species affected NO 3 -N leaching (vetch > bi-culture > wheat) and N 2 O-N emissions and yield during corn growth (vetch, bi-culture > wheat). Fertilization increased soil inorganic N, gaseous N loss, N leaching, and yield in the organic vetch and conventional wheat systems. Fertilizer scheme affected the magnitude of growing season N 2 O-N loss in the organic vetch system (organic N > fertilizer N-credit) and the timing of loss (organic N delayed N 2 O-N loss vs. urea) and NO 3 -N leaching (urea >> organic N) in the conventional wheat system, but had no effect on yield. Cover crop selection and N fertilization techniques can reduce N leaching and greenhouse gas emissions without sacrificing yield, thereby enhancing N conservation in both organic and conventional conservation agriculture systems.

Published

2018

37. Local loss and spatial homogenization of plant diversity reduce ecosystem multifunctionality.

Author

Hautier Y, Isbell F, Borer ET, Seabloom EW, Harpole WS, Lind EM, MacDougall AS, Stevens CJ, Adler PB, Alberti J, Bakker JD, Brudvig LA, Buckley YM, Cadotte M, Caldeira MC, Chaneton EJ, Chu C, Daleo P, Dickman CR, Dwyer JM, Eskelinen A, Fay PA, Firn J, Hagenah N, Hillebrand H, Iribarne O, Kirkman KP, Knops JMH, La Pierre KJ, McCulley RL, Morgan JW, Pärtel M, Pascual J, Price JN, Prober SM, Risch AC, Sankaran M, Schuetz M, Standish RJ, Virtanen R, Wardle GM, Yahdjian L, and Hector A

Subjects

Models, Biological, Spatial Analysis, Biodiversity, Grassland, Plants

Abstract

Biodiversity is declining in many local communities while also becoming increasingly homogenized across space. Experiments show that local plant species loss reduces ecosystem functioning and services, but the role of spatial homogenization of community composition and the potential interaction between diversity at different scales in maintaining ecosystem functioning remains unclear, especially when many functions are considered (ecosystem multifunctionality). We present an analysis of eight ecosystem functions measured in 65 grasslands worldwide. We find that more diverse grasslands-those with both species-rich local communities (α-diversity) and large compositional differences among localities (β-diversity)-had higher levels of multifunctionality. Moreover, α- and β-diversity synergistically affected multifunctionality, with higher levels of diversity at one scale amplifying the contribution to ecological functions at the other scale. The identity of species influencing ecosystem functioning differed among functions and across local communities, explaining why more diverse grasslands maintained greater functionality when more functions and localities were considered. These results were robust to variation in environmental drivers. Our findings reveal that plant diversity, at both local and landscape scales, contributes to the maintenance of multiple ecosystem services provided by grasslands. Preserving ecosystem functioning therefore requires conservation of biodiversity both within and among ecological communities.

Published

2018

38. Aboveground Epichloë coenophiala-Grass Associations Do Not Affect Belowground Fungal Symbionts or Associated Plant, Soil Parameters.

Author

Slaughter LC and McCulley RL

Subjects

Carbon metabolism, Ecosystem, Endophytes physiology, Epichloe pathogenicity, Fungi growth & development, Grassland, Hyphae growth & development, Kentucky, Mycorrhizae physiology, Neotyphodium, Nitrogen metabolism, Plant Roots microbiology, Water chemistry, Epichloe physiology, Fungi physiology, Plants microbiology, Poaceae microbiology, Soil chemistry, Soil Microbiology, Symbiosis

Abstract

Cool season grasses host multiple fungal symbionts, such as aboveground Epichloë endophytes and belowground arbuscular mycorrhizal fungi (AMF) and dark septate endophytes (DSEs). Asexual Epichloë endophytes can influence root colonization by AMF, but the type of interaction-whether antagonistic or beneficial-varies. In Schedonorus arundinaceus (tall fescue), Epichloë coenophiala can negatively affect AMF, which may impact soil properties and ecosystem function. Within field plots of S. arundinaceus that were either E. coenophiala-free (E-), infected with the common, mammal-toxic E. coenophiala strain (CTE+), or infected with one of two novel, non-toxic strains (AR542 NTE+ and AR584 NTE+), we hypothesized that (1) CTE+ would decrease AMF and DSE colonization rates and reduce soil extraradical AMF hyphae compared to E- or NTE+, and (2) this would lead to E- and NTE+ plots having greater water stable soil aggregates and C than CTE+. E. coenophiala presence and strain did not significantly alter AMF or DSE colonization, nor did it affect extraradical AMF hypha length, soil aggregates, or aggregate-associated C and N. Soil extraradical AMF hypha length negatively correlated with root AMF colonization. Our results contrast with previous demonstrations that E. coenophiala symbiosis inhibits belowground AMF communities. In our mesic, relatively nutrient-rich grassland, E. coenophiala symbiosis did not antagonize belowground symbionts, regardless of strain. Manipulating E. coenophiala strains within S. arundinaceus may not significantly alter AMF communities and nutrient cycling, yet we must further explore these relationships under different soils and environmental conditions given that symbiont interactions can be important in determining ecosystem response to global change.

Published

2016

39. Addition of multiple limiting resources reduces grassland diversity.

Author

Harpole WS, Sullivan LL, Lind EM, Firn J, Adler PB, Borer ET, Chase J, Fay PA, Hautier Y, Hillebrand H, MacDougall AS, Seabloom EW, Williams R, Bakker JD, Cadotte MW, Chaneton EJ, Chu C, Cleland EE, D'Antonio C, Davies KF, Gruner DS, Hagenah N, Kirkman K, Knops JM, La Pierre KJ, McCulley RL, Moore JL, Morgan JW, Prober SM, Risch AC, Schuetz M, Stevens CJ, and Wragg PD

Subjects

Biomass, Food, Light, Plants radiation effects, Poaceae classification, Poaceae drug effects, Poaceae growth & development, Poaceae radiation effects, Biodiversity, Fertilizers, Grassland, Plants classification, Plants metabolism

Abstract

Niche dimensionality provides a general theoretical explanation for biodiversity-more niches, defined by more limiting factors, allow for more ways that species can coexist. Because plant species compete for the same set of limiting resources, theory predicts that addition of a limiting resource eliminates potential trade-offs, reducing the number of species that can coexist. Multiple nutrient limitation of plant production is common and therefore fertilization may reduce diversity by reducing the number or dimensionality of belowground limiting factors. At the same time, nutrient addition, by increasing biomass, should ultimately shift competition from belowground nutrients towards a one-dimensional competitive trade-off for light. Here we show that plant species diversity decreased when a greater number of limiting nutrients were added across 45 grassland sites from a multi-continent experimental network. The number of added nutrients predicted diversity loss, even after controlling for effects of plant biomass, and even where biomass production was not nutrient-limited. We found that elevated resource supply reduced niche dimensionality and diversity and increased both productivity and compositional turnover. Our results point to the importance of understanding dimensionality in ecological systems that are undergoing diversity loss in response to multiple global change factors.

Published

2016

40. Infection with a Shoot-Specific Fungal Endophyte (Epichloë) Alters Tall Fescue Soil Microbial Communities.

Author

Rojas X, Guo J, Leff JW, McNear DH Jr, Fierer N, and McCulley RL

Subjects

Archaea classification, Archaea isolation & purification, Archaea metabolism, Bacteria classification, Bacteria isolation & purification, Bacteria metabolism, Chytridiomycota classification, Chytridiomycota isolation & purification, Chytridiomycota metabolism, Endophytes isolation & purification, Endophytes metabolism, Epichloe isolation & purification, Epichloe metabolism, High-Throughput Nucleotide Sequencing, Soil chemistry, Symbiosis, Endophytes classification, Epichloe classification, Festuca microbiology, Soil Microbiology

Abstract

Tall fescue (Schedonorus arundinaceus) is a widespread grass that can form a symbiotic relationship with a shoot-specific fungal endophyte (Epichloë coenophiala). While the effects of fungal endophyte infection on fescue physiology and ecology have been relatively well studied, less attention has been given to how this relationship may impact the soil microbial community. We used high-throughput DNA sequencing and phospholipid fatty acid analysis to determine the structure and biomass of microbial communities in both bulk and rhizosphere soils from tall fescue stands that were either uninfected with E. coenophiala or were infected with the common toxic strain or one of several novel strains of the endophyte. We found that rhizosphere and bulk soils harbored distinct microbial communities. Endophyte presence, regardless of strain, significantly influenced soil fungal communities, but endophyte effects were less pronounced in prokaryotic communities. E. coenophiala presence did not change total fungal biomass but caused a shift in soil and rhizosphere fungal community composition, increasing the relative abundance of taxa within the Glomeromycota phylum and decreasing the relative abundance of genera in the Ascomycota phylum, including Lecanicillium, Volutella, Lipomyces, Pochonia, and Rhizoctonia. Our data suggests that tripartite interactions exist between the shoot endophyte E. coenophiala, tall fescue, and soil fungi that may have important implications for the functioning of soils, such as carbon storage, in fescue-dominated grasslands.

Published

2016

41. Performance of Endophyte Infected Tall Fescue in Europe and North America.

Author

Saikkonen K, Phillips TD, Faeth SH, McCulley RL, Saloniemi I, and Helander M

Subjects

Endophytes isolation & purification, Epichloe isolation & purification, Europe, Festuca growth & development, Finland, Introduced Species, Kentucky, North America, Endophytes physiology, Epichloe physiology, Festuca microbiology, Festuca physiology, Symbiosis

Abstract

Human assisted plant invasions from Europe to North America have been more common than the reverse. We tested endophyte-mediated performance of tall fescue in parallel three year experiments in Europe and the USA using endophyte infected and uninfected wild and cultivated plants. Experimental plants were subjected to nutrient and water treatments. Whereas endophyte infection increased tall fescue performance in general, the effects of endophytes on plant growth and reproduction varied among plant origins under different environmental conditions. Naturally endophyte-free Finnish cultivar 'Retu' performed equally well as 'Kentucky-31' in both geographic locations. All Eurasian origin plants performed well in the US. In Finland, plants established well and both cultivars survived over the first winter. However, winter mortality of 'Kentucky-31' plants was higher, particularly in fertilized soils in the subsequent winters. Our results suggest that tall fescue ecotype 'Kentucky-31' that flourishes in North America is poorly adapted to Northern European conditions.

Published

2016

42. Climate modifies response of non-native and native species richness to nutrient enrichment.

Author

Flores-Moreno H, Reich PB, Lind EM, Sullivan LL, Seabloom EW, Yahdjian L, MacDougall AS, Reichmann LG, Alberti J, Báez S, Bakker JD, Cadotte MW, Caldeira MC, Chaneton EJ, D'Antonio CM, Fay PA, Firn J, Hagenah N, Harpole WS, Iribarne O, Kirkman KP, Knops JM, La Pierre KJ, Laungani R, Leakey AD, McCulley RL, Moore JL, Pascual J, and Borer ET

Subjects

Climate Change, Micronutrients metabolism, Nitrogen metabolism, Phosphorus metabolism, Plant Physiological Phenomena, Potassium metabolism, Biota physiology, Climate, Eutrophication, Grassland, Introduced Species

Abstract

Ecosystem eutrophication often increases domination by non-natives and causes displacement of native taxa. However, variation in environmental conditions may affect the outcome of interactions between native and non-native taxa in environments where nutrient supply is elevated. We examined the interactive effects of eutrophication, climate variability and climate average conditions on the success of native and non-native plant species using experimental nutrient manipulations replicated at 32 grassland sites on four continents. We hypothesized that effects of nutrient addition would be greatest where climate was stable and benign, owing to reduced niche partitioning. We found that the abundance of non-native species increased with nutrient addition independent of climate; however, nutrient addition increased non-native species richness and decreased native species richness, with these effects dampened in warmer or wetter sites. Eutrophication also altered the time scale in which grassland invasion responded to climate, decreasing the importance of long-term climate and increasing that of annual climate. Thus, climatic conditions mediate the responses of native and non-native flora to nutrient enrichment. Our results suggest that the negative effect of nutrient addition on native abundance is decoupled from its effect on richness, and reduces the time scale of the links between climate and compositional change., (© 2016 The Author(s).)

Published

2016

43. Effects of Tall Fescue and Its Fungal Endophyte on the Development and Survival of Tawny-Edged Skippers (Lepidoptera: Hesperiidae).

Author

Jokela KJ, Debinski DM, and Mcculley RL

Subjects

Animals, Festuca growth & development, Introduced Species, Iowa, Larva growth & development, Neotyphodium physiology, Poa growth & development, Butterflies growth & development, Endophytes physiology, Epichloe physiology, Festuca microbiology

Abstract

Invasive, exotic grasses are increasing in tallgrass prairie and their dominance may be contributing to the decline of grassland butterflies through alterations in forage quality. Tall fescue (Schedonorus arundinaceus (Schreb.) Dumort.), an exotic grass covering millions of acres in the United States, can host a fungal endophyte, Epichloë coenophiala (Morgan-Jones & Gams). Alkaloids produced by the endophyte are known to be toxic to some foliar-feeding pest insects. Endophyte-infected tall fescue is commonly planted in hayfields, pastures, lawns, and is invading natural areas, but effects of the endophyte on nonpest insects such as butterflies are relatively unknown. Our objective was to investigate the role that tall fescue and its endophyte might play in the decline of grass skippers (Hesperiidae). We examined growth and survival parameters of tawny-edged skippers (Polites themistocles (Latreille)) that were reared on endophyte-infected tall fescue (E+), endophyte-free tall fescue (E-), and Kentucky bluegrass (KBG). KBG was included as a comparison because it is a cool season grass known to be palatable to P. themistocles larvae. Interestingly, results showed that the endophyte did not affect growth and survival of larvae compared to uninfected tall fescue, even though significant amounts of loline alkaloids (average 740 ppm) were measured in endophyte-infected plant material. Larvae feeding on KBG grew faster with greater survival rates than larvae on both tall fescue treatments. These results confirm that tall fescue invasion and dominance may be deteriorating the quality of grassland habitats for native pollinators; however, this effect does not appear to be linked to endophyte infection., (© The Authors 2015. Published by Oxford University Press on behalf of Entomological Society of America. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2016

44. Comment on "Worldwide evidence of a unimodal relationship between productivity and plant species richness".

Author

Tredennick AT, Adler PB, Grace JB, Harpole WS, Borer ET, Seabloom EW, Anderson TM, Bakker JD, Biederman LA, Brown CS, Buckley YM, Chu C, Collins SL, Crawley MJ, Fay PA, Firn J, Gruner DS, Hagenah N, Hautier Y, Hector A, Hillebrand H, Kirkman K, Knops JM, Laungani R, Lind EM, MacDougall AS, McCulley RL, Mitchell CE, Moore JL, Morgan JW, Orrock JL, Peri PL, Prober SM, Risch AC, Schütz M, Speziale KL, Standish RJ, Sullivan LL, Wardle GM, Williams RJ, and Yang LH

Subjects

Biodiversity, Grassland, Plant Development

Abstract

Fraser et al. (Reports, 17 July 2015, p. 302) report a unimodal relationship between productivity and species richness at regional and global scales, which they contrast with the results of Adler et al. (Reports, 23 September 2011, p. 1750). However, both data sets, when analyzed correctly, show clearly and consistently that productivity is a poor predictor of local species richness., (Copyright © 2016, American Association for the Advancement of Science.)

Published

2016

45. Consistent responses of soil microbial communities to elevated nutrient inputs in grasslands across the globe.

Author

Leff JW, Jones SE, Prober SM, Barberán A, Borer ET, Firn JL, Harpole WS, Hobbie SE, Hofmockel KS, Knops JM, McCulley RL, La Pierre K, Risch AC, Seabloom EW, Schütz M, Steenbock C, Stevens CJ, and Fierer N

Subjects

Archaea physiology, Bacterial Physiological Phenomena, Fungi physiology, Nitrogen metabolism, Phosphorus metabolism, Ecosystem, Poaceae physiology, Soil Microbiology

Abstract

Soil microorganisms are critical to ecosystem functioning and the maintenance of soil fertility. However, despite global increases in the inputs of nitrogen (N) and phosphorus (P) to ecosystems due to human activities, we lack a predictive understanding of how microbial communities respond to elevated nutrient inputs across environmental gradients. Here we used high-throughput sequencing of marker genes to elucidate the responses of soil fungal, archaeal, and bacterial communities using an N and P addition experiment replicated at 25 globally distributed grassland sites. We also sequenced metagenomes from a subset of the sites to determine how the functional attributes of bacterial communities change in response to elevated nutrients. Despite strong compositional differences across sites, microbial communities shifted in a consistent manner with N or P additions, and the magnitude of these shifts was related to the magnitude of plant community responses to nutrient inputs. Mycorrhizal fungi and methanogenic archaea decreased in relative abundance with nutrient additions, as did the relative abundances of oligotrophic bacterial taxa. The metagenomic data provided additional evidence for this shift in bacterial life history strategies because nutrient additions decreased the average genome sizes of the bacterial community members and elicited changes in the relative abundances of representative functional genes. Our results suggest that elevated N and P inputs lead to predictable shifts in the taxonomic and functional traits of soil microbial communities, including increases in the relative abundances of faster-growing, copiotrophic bacterial taxa, with these shifts likely to impact belowground ecosystems worldwide.

Published

2015

46. Compositional differences in simulated root exudates elicit a limited functional and compositional response in soil microbial communities.

Author

Strickland MS, McCulley RL, Nelson JA, and Bradford MA

Abstract

Inputs of low molecular weight carbon (LMW-C) to soil - primarily via root exudates- are expected to be a major driver of microbial activity and source of stable soil organic carbon. It is expected that variation in the type and composition of LMW-C entering soil will influence microbial community composition and function. If this is the case then short-term changes in LMW-C inputs may alter processes regulated by these communities. To determine if change in the composition of LMW-C inputs influences microbial community function and composition, we conducted a 90 day microcosm experiment whereby soils sourced from three different land covers (meadows, deciduous forests, and white pine stands) were amended, at low concentrations, with one of eight simulated root exudate treatments. Treatments included no addition of LMW-C, and the full factorial combination of glucose, glycine, and oxalic acid. After 90 days, we conducted a functional response assay and determined microbial composition via phospholipid fatty acid analysis. Whereas we noted a statistically significant effect of exudate treatments, this only accounted for ∼3% of the variation observed in function. In comparison, land cover and site explained ∼46 and ∼41% of the variation, respectively. This suggests that exudate composition has little influence on function compared to site/land cover specific factors. Supporting the finding that exudate effects were minor, we found that an absence of LMW-C elicited the greatest difference in function compared to those treatments receiving any LMW-C. Additionally, exudate treatments did not alter microbial community composition and observable differences were instead due to land cover. These results confirm the strong effects of land cover/site legacies on soil microbial communities. In contrast, short-term changes in exudate composition, at meaningful concentrations, may have little impact on microbial function and composition.

Published

2015

47. Plant species' origin predicts dominance and response to nutrient enrichment and herbivores in global grasslands.

Author

Seabloom EW, Borer ET, Buckley YM, Cleland EE, Davies KF, Firn J, Harpole WS, Hautier Y, Lind EM, MacDougall AS, Orrock JL, Prober SM, Adler PB, Anderson TM, Bakker JD, Biederman LA, Blumenthal DM, Brown CS, Brudvig LA, Cadotte M, Chu C, Cottingham KL, Crawley MJ, Damschen EI, Dantonio CM, DeCrappeo NM, Du G, Fay PA, Frater P, Gruner DS, Hagenah N, Hector A, Hillebrand H, Hofmockel KS, Humphries HC, Jin VL, Kay A, Kirkman KP, Klein JA, Knops JM, La Pierre KJ, Ladwig L, Lambrinos JG, Li Q, Li W, Marushia R, McCulley RL, Melbourne BA, Mitchell CE, Moore JL, Morgan J, Mortensen B, O'Halloran LR, Pyke DA, Risch AC, Sankaran M, Schuetz M, Simonsen A, Smith MD, Stevens CJ, Sullivan L, Wolkovich E, Wragg PD, Wright J, and Yang L

Subjects

Animals, Eutrophication, Nitrogen, Phosphorus, Vertebrates, Biodiversity, Ecosystem, Food, Grassland, Herbivory, Introduced Species, Plants, Soil chemistry

Abstract

Exotic species dominate many communities; however the functional significance of species' biogeographic origin remains highly contentious. This debate is fuelled in part by the lack of globally replicated, systematic data assessing the relationship between species provenance, function and response to perturbations. We examined the abundance of native and exotic plant species at 64 grasslands in 13 countries, and at a subset of the sites we experimentally tested native and exotic species responses to two fundamental drivers of invasion, mineral nutrient supplies and vertebrate herbivory. Exotic species are six times more likely to dominate communities than native species. Furthermore, while experimental nutrient addition increases the cover and richness of exotic species, nutrients decrease native diversity and cover. Native and exotic species also differ in their response to vertebrate consumer exclusion. These results suggest that species origin has functional significance, and that eutrophication will lead to increased exotic dominance in grasslands.

Published

2015

48. Grassland productivity limited by multiple nutrients.

Author

Fay PA, Prober SM, Harpole WS, Knops JM, Bakker JD, Borer ET, Lind EM, MacDougall AS, Seabloom EW, Wragg PD, Adler PB, Blumenthal DM, Buckley YM, Chu C, Cleland EE, Collins SL, Davies KF, Du G, Feng X, Firn J, Gruner DS, Hagenah N, Hautier Y, Heckman RW, Jin VL, Kirkman KP, Klein J, Ladwig LM, Li Q, McCulley RL, Melbourne BA, Mitchell CE, Moore JL, Morgan JW, Risch AC, Schütz M, Stevens CJ, Wedin DA, and Yang LH

Abstract

Terrestrial ecosystem productivity is widely accepted to be nutrient limited(1). Although nitrogen (N) is deemed a key determinant of aboveground net primary production (ANPP)(2,3), the prevalence of co-limitation by N and phosphorus (P) is increasingly recognized(4-8). However, the extent to which terrestrial productivity is co-limited by nutrients other than N and P has remained unclear. Here, we report results from a standardized factorial nutrient addition experiment, in which we added N, P and potassium (K) combined with a selection of micronutrients (K+μ), alone or in concert, to 42 grassland sites spanning five continents, and monitored ANPP. Nutrient availability limited productivity at 31 of the 42 grassland sites. And pairwise combinations of N, P, and K+μ co-limited ANPP at 29 of the sites. Nitrogen limitation peaked in cool, high latitude sites. Our findings highlight the importance of less studied nutrients, such as K and micronutrients, for grassland productivity, and point to significant variations in the type and degree of nutrient limitation. We suggest that multiple-nutrient constraints must be considered when assessing the ecosystem-scale consequences of nutrient enrichment.

Published

2015

49. Tall fescue cultivar and fungal endophyte combinations influence plant growth and root exudate composition.

Author

Guo J, McCulley RL, and McNear DH Jr

Abstract

Tall fescue [Lolium arundinaceum (Schreb.)] is a cool-season perennial grass used in pastures throughout the Southeastern United States. The grass can harbor a shoot-specific fungal endophyte (Epichloë coenophiala) thought to provide the plant with enhanced resistance to biotic and abiotic stresses. Because alkaloids produced by the common variety of the endophyte cause severe animal health issues, focus has been on replacing the common-toxic strain with novel varieties that do not produce the mammal-toxic alkaloids but maintain abiotic and biotic stress tolerance benefits. Little attention has been given to the influence of the plant-fungal symbiosis on rhizosphere processes. Therefore, our objective was to study the influence of this relationship on plant biomass production and root exudate composition in tall fescue cultivars PDF and 97TF1, which were either not infected with the endophyte (E-), infected with the common toxic endophyte (CTE+) strain or with one of two novel endophytes (AR542E+, AR584E+). Plants were grown sterile for 3 weeks after which plant biomass, total organic carbon, total phenolic content and detailed chemical composition of root exudates were determined. Plant biomass production and exudate phenolic and organic carbon content were influenced by endophyte status, tall fescue cultivar, and their interaction. GC-TOF MS identified 132 compounds, including lipids, carbohydrates and carboxylic acids. Cluster analysis showed that the interaction between endophyte and cultivar resulted in unique exudate profiles. This is the first detailed study to assess how endophyte infection, notably with novel endophytes, and tall fescue cultivar interact to influence root exudate composition. Our results illustrate that tall fescue cultivar and endophyte status can influence plant growth and root exudate composition, which may help explain the observed influence of this symbiosis on rhizosphere biogeochemical processes.

Published

2015

50. Plant diversity predicts beta but not alpha diversity of soil microbes across grasslands worldwide.

Author

Prober SM, Leff JW, Bates ST, Borer ET, Firn J, Harpole WS, Lind EM, Seabloom EW, Adler PB, Bakker JD, Cleland EE, DeCrappeo NM, DeLorenze E, Hagenah N, Hautier Y, Hofmockel KS, Kirkman KP, Knops JM, La Pierre KJ, MacDougall AS, McCulley RL, Mitchell CE, Risch AC, Schuetz M, Stevens CJ, Williams RJ, and Fierer N

Subjects

Archaea classification, Bacteria genetics, Biota, Fungi genetics, Linear Models, Biodiversity, Grassland, Plants, Soil Microbiology

Abstract

Aboveground-belowground interactions exert critical controls on the composition and function of terrestrial ecosystems, yet the fundamental relationships between plant diversity and soil microbial diversity remain elusive. Theory predicts predominantly positive associations but tests within single sites have shown variable relationships, and associations between plant and microbial diversity across broad spatial scales remain largely unexplored. We compared the diversity of plant, bacterial, archaeal and fungal communities in one hundred and forty-five 1 m(2) plots across 25 temperate grassland sites from four continents. Across sites, the plant alpha diversity patterns were poorly related to those observed for any soil microbial group. However, plant beta diversity (compositional dissimilarity between sites) was significantly correlated with the beta diversity of bacterial and fungal communities, even after controlling for environmental factors. Thus, across a global range of temperate grasslands, plant diversity can predict patterns in the composition of soil microbial communities, but not patterns in alpha diversity., (© 2014 John Wiley & Sons Ltd/CNRS.)

Published

2015