Your search keyword '"Broadbent, A.A.D."' showing total 15 results

1. Drivers of the microbial metabolic quotient across global grasslands

Author

Risch, A.C., Zimmermann, S., Schütz, M., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Knops, J.M.H., Lembrechts, J.J., MacDougall, A.S., McCulley, R.L., Melbourne, B.A., Moore, J.L., Power, S.A., Seabloom, E.W., Silviera, M.L., Virtanen, R., Yahdjian, L., Ochoa-Hueso, R., Risch, A.C., Zimmermann, S., Schütz, M., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Knops, J.M.H., Lembrechts, J.J., MacDougall, A.S., McCulley, R.L., Melbourne, B.A., Moore, J.L., Power, S.A., Seabloom, E.W., Silviera, M.L., Virtanen, R., Yahdjian, L., and Ochoa-Hueso, R.

Abstract

Aim The microbial metabolic quotient (MMQ; mg CO2-C/mg MBC/h), defined as the amount of microbial CO2 respired (MR; mg CO2-C/kg soil/h) per unit of microbial biomass C (MBC; mg C/kg soil), is a key parameter for understanding the microbial regulation of the carbon (C) cycle, including soil C sequestration. Here, we experimentally tested hypotheses about the individual and interactive effects of multiple nutrient addition (nitrogen + phosphorus + potassium + micronutrients) and herbivore exclusion on MR, MBC and MMQ across 23 sites (five continents). Our sites encompassed a wide range of edaphoclimatic conditions; thus, we assessed which edaphoclimatic variables affected MMQ the most and how they interacted with our treatments. Location Australia, Asia, Europe, North/South America. Time period 2015–2016. Major taxa Soil microbes. Methods Soils were collected from plots with established experimental treatments. MR was assessed in a 5-week laboratory incubation without glucose addition, MBC via substrate-induced respiration. MMQ was calculated as MR/MBC and corrected for soil temperatures (MMQsoil). Using linear mixed effects models (LMMs) and structural equation models (SEMs), we analysed how edaphoclimatic characteristics and treatments interactively affected MMQsoil. Results MMQsoil was higher in locations with higher mean annual temperature, lower water holding capacity and lower soil organic C concentration, but did not respond to our treatments across sites as neither MR nor MBC changed. We attributed this relative homeostasis to our treatments to the modulating influence of edaphoclimatic variables. For example, herbivore exclusion, regardless of fertilization, led to greater MMQsoil only at sites with lower soil organic C (< 1.7%). Main conclusions Our results pinpoint the main variables related to MMQsoil across grasslands and emphasize the importance of the local edaphoclimatic conditions in controlling the response of the C cycle to anthropogenic stre

Published

2023

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

Author

Siebert, J., Sünnemann, M., Hautier, Y., Risch, A.C., Bakker, J.D., Biederman, L., Blumenthal, D.M., Borer, E.T., Bugalho, M.N., Broadbent, A.A.D., Caldeira, M.C., Cleland, E., Davies, K.F., Eskelinen, Anu Maria, Hagenah, N., Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Moore, J.L., Power, S.A., Price, J.N., Seabloom, E.W., Standish, R., Stevens, C.J., Zimmermann, S., Eisenhauer, N., Siebert, J., Sünnemann, M., Hautier, Y., Risch, A.C., Bakker, J.D., Biederman, L., Blumenthal, D.M., Borer, E.T., Bugalho, M.N., Broadbent, A.A.D., Caldeira, M.C., Cleland, E., Davies, K.F., Eskelinen, Anu Maria, Hagenah, N., Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Moore, J.L., Power, S.A., Price, J.N., Seabloom, E.W., Standish, R., Stevens, C.J., Zimmermann, S., and Eisenhauer, N.

Abstract

Covering approximately 40% of land surfaces, grasslands provide critical ecosystem services that rely on soil organisms. However, the global determinants of soil biodiversity and functioning remain underexplored. In this study, we investigate the drivers of soil microbial and detritivore activity in grasslands across a wide range of climatic conditions on five continents. We apply standardized treatments of nutrient addition and herbivore reduction, allowing us to disentangle the regional and local drivers of soil organism activity. We use structural equation modeling to assess the direct and indirect effects of local and regional drivers on soil biological activities. Microbial and detritivore activities are positively correlated across global grasslands. These correlations are shaped more by global climatic factors than by local treatments, with annual precipitation and soil water content explaining the majority of the variation. Nutrient addition tends to reduce microbial activity by enhancing plant growth, while herbivore reduction typically increases microbial and detritivore activity through increased soil moisture. Our findings emphasize soil moisture as a key driver of soil biological activity, highlighting the potential impacts of climate change, altered grazing pressure, and eutrophication on nutrient cycling and decomposition within grassland ecosystems.

Published

2023

3. Drivers of the microbial metabolic quotient across global grasslands

Author

Risch, A.C., Zimmermann, S., Schütz, M., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Knops, J.M.H., Lembrechts, J.J., MacDougall, A.S., McCulley, R.L., Melbourne, B.A., Moore, J.L., Power, S.A., Seabloom, E.W., Silviera, M.L., Virtanen, R., Yahdjian, L., Ochoa-Hueso, R., Risch, A.C., Zimmermann, S., Schütz, M., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Knops, J.M.H., Lembrechts, J.J., MacDougall, A.S., McCulley, R.L., Melbourne, B.A., Moore, J.L., Power, S.A., Seabloom, E.W., Silviera, M.L., Virtanen, R., Yahdjian, L., and Ochoa-Hueso, R.

Abstract

Aim The microbial metabolic quotient (MMQ; mg CO2-C/mg MBC/h), defined as the amount of microbial CO2 respired (MR; mg CO2-C/kg soil/h) per unit of microbial biomass C (MBC; mg C/kg soil), is a key parameter for understanding the microbial regulation of the carbon (C) cycle, including soil C sequestration. Here, we experimentally tested hypotheses about the individual and interactive effects of multiple nutrient addition (nitrogen + phosphorus + potassium + micronutrients) and herbivore exclusion on MR, MBC and MMQ across 23 sites (five continents). Our sites encompassed a wide range of edaphoclimatic conditions; thus, we assessed which edaphoclimatic variables affected MMQ the most and how they interacted with our treatments. Location Australia, Asia, Europe, North/South America. Time period 2015–2016. Major taxa Soil microbes. Methods Soils were collected from plots with established experimental treatments. MR was assessed in a 5-week laboratory incubation without glucose addition, MBC via substrate-induced respiration. MMQ was calculated as MR/MBC and corrected for soil temperatures (MMQsoil). Using linear mixed effects models (LMMs) and structural equation models (SEMs), we analysed how edaphoclimatic characteristics and treatments interactively affected MMQsoil. Results MMQsoil was higher in locations with higher mean annual temperature, lower water holding capacity and lower soil organic C concentration, but did not respond to our treatments across sites as neither MR nor MBC changed. We attributed this relative homeostasis to our treatments to the modulating influence of edaphoclimatic variables. For example, herbivore exclusion, regardless of fertilization, led to greater MMQsoil only at sites with lower soil organic C (< 1.7%). Main conclusions Our results pinpoint the main variables related to MMQsoil across grasslands and emphasize the importance of the local edaphoclimatic conditions in controlling the response of the C cycle to

Published

2023

4. Drivers of the microbial metabolic quotient across global grasslands

Author

Risch, A.C., Zimmermann, S., Schütz, M., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Knops, J.M.H., Lembrechts, J.J., MacDougall, A.S., McCulley, R.L., Melbourne, B.A., Moore, J.L., Power, S.A., Seabloom, E.W., Silviera, M.L., Virtanen, R., Yahdjian, L., Ochoa-Hueso, R., Risch, A.C., Zimmermann, S., Schütz, M., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Knops, J.M.H., Lembrechts, J.J., MacDougall, A.S., McCulley, R.L., Melbourne, B.A., Moore, J.L., Power, S.A., Seabloom, E.W., Silviera, M.L., Virtanen, R., Yahdjian, L., and Ochoa-Hueso, R.

Abstract

Aim The microbial metabolic quotient (MMQ; mg CO2-C/mg MBC/h), defined as the amount of microbial CO2 respired (MR; mg CO2-C/kg soil/h) per unit of microbial biomass C (MBC; mg C/kg soil), is a key parameter for understanding the microbial regulation of the carbon (C) cycle, including soil C sequestration. Here, we experimentally tested hypotheses about the individual and interactive effects of multiple nutrient addition (nitrogen + phosphorus + potassium + micronutrients) and herbivore exclusion on MR, MBC and MMQ across 23 sites (five continents). Our sites encompassed a wide range of edaphoclimatic conditions; thus, we assessed which edaphoclimatic variables affected MMQ the most and how they interacted with our treatments. Location Australia, Asia, Europe, North/South America. Time period 2015–2016. Major taxa Soil microbes. Methods Soils were collected from plots with established experimental treatments. MR was assessed in a 5-week laboratory incubation without glucose addition, MBC via substrate-induced respiration. MMQ was calculated as MR/MBC and corrected for soil temperatures (MMQsoil). Using linear mixed effects models (LMMs) and structural equation models (SEMs), we analysed how edaphoclimatic characteristics and treatments interactively affected MMQsoil. Results MMQsoil was higher in locations with higher mean annual temperature, lower water holding capacity and lower soil organic C concentration, but did not respond to our treatments across sites as neither MR nor MBC changed. We attributed this relative homeostasis to our treatments to the modulating influence of edaphoclimatic variables. For example, herbivore exclusion, regardless of fertilization, led to greater MMQsoil only at sites with lower soil organic C (< 1.7%). Main conclusions Our results pinpoint the main variables related to MMQsoil across grasslands and emphasize the importance of the local edaphoclimatic conditions in controlling the response of the C cycle to anthropogenic stre

Published

2023

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

Author

Frey, B., Moser, B., Tytgat, B., Zimmermann, S., Alberti, J., Biederman, L.A., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Hautier, Y., MacDougall, A.S., McCulley, R.L., Moore, J.L., Nepel, M., Power, S.A., Seabloom, E.W., Vázquez, E., Virtanen, R., Yahdjian, L., Risch, A.C., Frey, B., Moser, B., Tytgat, B., Zimmermann, S., Alberti, J., Biederman, L.A., Borer, E.T., Broadbent, A.A.D., Caldeira, M.C., Davies, K.F., Eisenhauer, N., Eskelinen, Anu Maria, Fay, P.A., Hagedorn, F., Hautier, Y., MacDougall, A.S., McCulley, R.L., Moore, J.L., Nepel, M., Power, S.A., Seabloom, E.W., Vázquez, E., Virtanen, R., Yahdjian, L., and Risch, A.C.

Abstract

Anthropogenic nitrogen (N) input is known to alter the soil microbiome, but how N enrichment influences the abundance, alpha-diversity and community structure of N-cycling functional microbial communities in grasslands remains poorly understood. Here, we collected soils from plant communities subjected to up to 9 years of annual N-addition (10 g N m−2 per year using urea as a N-source) and from unfertilized plots (control) in 30 grasslands worldwide spanning a large range of climatic and soil conditions. We focused on three key microbial groups responsible for two essential processes of the global N cycle: N2 fixation (soil diazotrophs) and nitrification (AOA: ammonia-oxidizing archaea and AOB: ammonia-oxidizing bacteria). We targeted soil diazotrophs, AOA and AOB using Illumina MiSeq sequencing and measured the abundance (gene copy numbers) using quantitative PCR. N-addition shifted the structure of the diazotrophic communities, although their alpha-diversity and abundance were not affected. AOA and AOB responded differently to N-addition. The abundance and alpha-diversity of AOB increased, and their community structure shifted with N-addition. In contrast, AOA were not affected by N-addition. AOA abundance outnumbered AOB in control plots under conditions of low N availability, whereas N-addition favoured copiotrophic AOB. Overall, N-addition showed a low impact on soil diazotrophs and AOA while effects for AOB communities were considerable. These results reveal that long-term N-addition has important ecological implications for key microbial groups involved in two critical soil N-cycling processes. Increased AOB abundance and community shifts following N-addition may change soil N-cycling, as larger population sizes may promote higher rates of ammonia oxidation and subsequently increase N loss via gaseous and soil N-leaching. These findings bring us a step closer to predicting the responses and feedbacks of microbial-mediated N-cycling processes

Published

2022

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

Author

Firn, J., McGree, J.M., Harvey, E., Flores-Moreno, H., Schütz, M., Buckley, Y.M., Borer, E.T., Seabloom, E.W., La Pierre, K.J., MacDougall, A.M., Prober, S.M., Stevens, C.J., Sullivan, L.L., Porter, E., Ladouceur, E., Allen, C., Moromizato, K.H., Morgan, J.W., Harpole, W.S., Hautier, Y., Eisenhauer, N., Wright, J.P., Adler, P.B., Arnillas, C.A., Bakker, J.D., Biederman, L., Broadbent, A.A.D., Brown, C.S., Bugalho, M.N., Caldeira, M.C., Cleland, E.E., Ebeling, A., Fay, P.A., Hagenah, N., Kleinhesselink, A.R., Mitchell, R., Moore, J.L., Nogueira, C., Peri, P.L., Roscher, C., Smith, M.D., Wragg, P.D., Risch, A.C., Firn, J., McGree, J.M., Harvey, E., Flores-Moreno, H., Schütz, M., Buckley, Y.M., Borer, E.T., Seabloom, E.W., La Pierre, K.J., MacDougall, A.M., Prober, S.M., Stevens, C.J., Sullivan, L.L., Porter, E., Ladouceur, E., Allen, C., Moromizato, K.H., Morgan, J.W., Harpole, W.S., Hautier, Y., Eisenhauer, N., Wright, J.P., Adler, P.B., Arnillas, C.A., Bakker, J.D., Biederman, L., Broadbent, A.A.D., Brown, C.S., Bugalho, M.N., Caldeira, M.C., Cleland, E.E., Ebeling, A., Fay, P.A., Hagenah, N., Kleinhesselink, A.R., Mitchell, R., Moore, J.L., Nogueira, C., Peri, P.L., Roscher, C., Smith, M.D., Wragg, P.D., and Risch, A.C.

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

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

Author

Broadbent, A.A.D., Firn, J., McGree, J.M., Borer, E.T., Buckley, Y.M., Harpole, W.S., Komatsu, K.J., MacDougall, A.S., Orwin, K.H., Ostle, N.J., Seabloom, E.W., Bakker, J.D., Biederman, L., Caldeira, M.C., Eisenhauer, N., Hagenah, N., Hautier, Y., Moore, J.L., Nogueira, C., Peri, P.L., Risch, A.C., Roscher, C., Schütz, M., Stevens, C.J., Broadbent, A.A.D., Firn, J., McGree, J.M., Borer, E.T., Buckley, Y.M., Harpole, W.S., Komatsu, K.J., MacDougall, A.S., Orwin, K.H., Ostle, N.J., Seabloom, E.W., Bakker, J.D., Biederman, L., Caldeira, M.C., Eisenhauer, N., Hagenah, N., Hautier, Y., Moore, J.L., Nogueira, C., Peri, P.L., Risch, A.C., Roscher, C., Schütz, M., and Stevens, C.J.

Abstract

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

Published

2020

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

Author

Broadbent, A.A.D., Firn, J., McGree, J.M., Borer, E.T., Buckley, Y.M., Harpole, W.S., Komatsu, K.J., MacDougall, A.S., Orwin, K.H., Ostle, N.J., Seabloom, E.W., Bakker, J.D., Biederman, L., Caldeira, M.C., Eisenhauer, N., Hagenah, N., Hautier, Y., Moore, J.L., Nogueira, C., Peri, P.L., Risch, A.C., Roscher, C., Schütz, M., Stevens, C.J., Broadbent, A.A.D., Firn, J., McGree, J.M., Borer, E.T., Buckley, Y.M., Harpole, W.S., Komatsu, K.J., MacDougall, A.S., Orwin, K.H., Ostle, N.J., Seabloom, E.W., Bakker, J.D., Biederman, L., Caldeira, M.C., Eisenhauer, N., Hagenah, N., Hautier, Y., Moore, J.L., Nogueira, C., Peri, P.L., Risch, A.C., Roscher, C., Schütz, M., and Stevens, C.J.

Abstract

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

Published

2020

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

Author

Risch, A.C., Zimmermann, S., Moser, B., Schütz, M., Hagedorn, F., Firn, J., Fay, P.A., Adler, P.B., Biederman, L.A., Blair, J.M., Borer, E.T., Broadbent, A.A.D., Brown, C.S., Cadotte, M.W., Caldeira, M.C., Davies, K.F., di Virgilio, A., Eisenhauer, N., Eskelinen, Anu Maria, Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Melbourne, B.A., Moore, J.L., Power, S.A., Prober, S.M., Seabloom, E.W., Siebert, J., Silveira, M.L., Speziale, K.L., Stevens, C.J., Tognetti, P.M., Virtanen, R., Yahdjian, L., Ochoa‐Hueso, R., Risch, A.C., Zimmermann, S., Moser, B., Schütz, M., Hagedorn, F., Firn, J., Fay, P.A., Adler, P.B., Biederman, L.A., Blair, J.M., Borer, E.T., Broadbent, A.A.D., Brown, C.S., Cadotte, M.W., Caldeira, M.C., Davies, K.F., di Virgilio, A., Eisenhauer, N., Eskelinen, Anu Maria, Knops, J.M.H., MacDougall, A.S., McCulley, R.L., Melbourne, B.A., Moore, J.L., Power, S.A., Prober, S.M., Seabloom, E.W., Siebert, J., Silveira, M.L., Speziale, K.L., Stevens, C.J., Tognetti, P.M., Virtanen, R., Yahdjian, L., and Ochoa‐Hueso, R.

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 Nmin), i.e., 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 Nmin 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 Nmin. Herbivore removal in the absence of fertilization did not alter potential and realized soil net Nmin. However, fertilization alone and in combination with herbivore removal consistently increased potential soil net Nmin. Realized soil net Nmin, in contrast, significantly decreased in fertilized plots where herbivores were removed. Treatment effects on potential and realized soil net Nmin were contingent on site‐specific soil and climatic properties. Fertilization effects on potential soil net Nmin were larger at sites with higher mean annual precipitation (MAP) and temperature of the wettest quarter (T.q.wet). Reciprocally, realized soil net Nmin 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 Nmin across global grasslands under realistic field conditions. This is important context‐dependent knowledge for grassland management worldwide.

Published

2020

10. Dominant native and non‐native graminoids differ in key leaf traits irrespective of nutrient availability

Author

Broadbent, A.A.D., Firn, J., McGree, J.M., Borer, E.T., Buckley, Y.M., Harpole, William Stanley, Komatsu, K.J., MacDougall, A.S., Orwin, K.H., Ostle, N.J., Seabloom, E.W., Bakker, J.D., Biederman, L., Caldeira, M.C., Eisenhauer, N., Hagenah, N., Hautier, Y., Moore, J.L., Nogueira, C., Peri, P.L., Risch, A.C., Roscher, Christiane, Schütz, M., Stevens, C.J., Broadbent, A.A.D., Firn, J., McGree, J.M., Borer, E.T., Buckley, Y.M., Harpole, William Stanley, Komatsu, K.J., MacDougall, A.S., Orwin, K.H., Ostle, N.J., Seabloom, E.W., Bakker, J.D., Biederman, L., Caldeira, M.C., Eisenhauer, N., Hagenah, N., Hautier, Y., Moore, J.L., Nogueira, C., Peri, P.L., Risch, A.C., Roscher, Christiane, Schütz, M., and Stevens, C.J.

Abstract

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

Published

2020

11. Soil net nitrogen mineralisation across global grasslands

Author

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

Abstract

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

Published

2019

12. Leaf nutrients, not specific leaf area, are consistent indicators of elevated nutrient inputs

Author

Firn, J., McGree, J.M., Harvey, E., Flores-Moreno, H., Schütz, M., Buckley, Y.M., Borer, E.T., Seabloom, E.W., La Pierre, K.J., MacDougall, A.M., Prober, S.M., Stevens, C.J., Sullivan, L.L., Porter, E., Ladouceur, E., Allen, C., Moromizato, K.H., Morgan, J.W., Harpole, W.S., Hautier, Y., Eisenhauer, N., Wright, J.P., Adler, P.B., Arnillas, C.A., Bakker, J.D., Biederman, L., Broadbent, A.A.D., Brown, C.S., Bugalho, M.N., Caldeira, M.C., Cleland, E.E., Ebeling, A., Fay, P.A., Hagenah, N., Kleinhesselink, A.R., Mitchell, R., Moore, J.L., Nogueira, C., Peri, P.L., Roscher, C., Smith, M.D., Wragg, P.D., Risch, A.C., Firn, J., McGree, J.M., Harvey, E., Flores-Moreno, H., Schütz, M., Buckley, Y.M., Borer, E.T., Seabloom, E.W., La Pierre, K.J., MacDougall, A.M., Prober, S.M., Stevens, C.J., Sullivan, L.L., Porter, E., Ladouceur, E., Allen, C., Moromizato, K.H., Morgan, J.W., Harpole, W.S., Hautier, Y., Eisenhauer, N., Wright, J.P., Adler, P.B., Arnillas, C.A., Bakker, J.D., Biederman, L., Broadbent, A.A.D., Brown, C.S., Bugalho, M.N., Caldeira, M.C., Cleland, E.E., Ebeling, A., Fay, P.A., Hagenah, N., Kleinhesselink, A.R., Mitchell, R., Moore, J.L., Nogueira, C., Peri, P.L., Roscher, C., Smith, M.D., Wragg, P.D., and Risch, A.C.

Abstract

Leaf traits are frequently measured in ecology to provide a ‘common currency’ for predicting how anthropogenic pressures impact ecosystem function. Here, we test whether leaf traits consistently respond to experimental treatments across 27 globally distributed grassland sites across 4 continents. We find that specific leaf area (leaf area per unit mass)—a commonly measured morphological trait inferring shifts between plant growth strategies—did not respond to up to four years of soil nutrient additions. Leaf nitrogen, phosphorus and potassium concentrations increased in response to the addition of each respective soil nutrient. We found few significant changes in leaf traits when vertebrate herbivores were excluded in the short-term. Leaf nitrogen and potassium concentrations were positively correlated with species turnover, suggesting that interspecific trait variation was a significant predictor of leaf nitrogen and potassium, but not of leaf phosphorus concentration. Climatic conditions and pretreatment soil nutrient levels also accounted for significant amounts of variation in the leaf traits measured. Overall, we find that leaf morphological traits, such as specific leaf area, are not appropriate indicators of plant response to anthropogenic perturbations in grasslands.

Published

2019

13. Leaf nutrients, not specific leaf area, are consistent indicators of elevated nutrient inputs

Author

Firn, J., McGree, J.M., Harvey, E., Flores-Moreno, H., Schütz, M., Buckley, Y.M., Borer, E.T., Seabloom, E.W., La Pierre, K.J., MacDougall, A.M., Prober, S.M., Stevens, C.J., Sullivan, L.L., Porter, E., Ladouceur, E., Allen, C., Moromizato, K.H., Morgan, J.W., Harpole, W.S., Hautier, Y., Eisenhauer, N., Wright, J.P., Adler, P.B., Arnillas, C.A., Bakker, J.D., Biederman, L., Broadbent, A.A.D., Brown, C.S., Bugalho, M.N., Caldeira, M.C., Cleland, E.E., Ebeling, A., Fay, P.A., Hagenah, N., Kleinhesselink, A.R., Mitchell, R., Moore, J.L., Nogueira, C., Peri, P.L., Roscher, C., Smith, M.D., Wragg, P.D., Risch, A.C., Firn, J., McGree, J.M., Harvey, E., Flores-Moreno, H., Schütz, M., Buckley, Y.M., Borer, E.T., Seabloom, E.W., La Pierre, K.J., MacDougall, A.M., Prober, S.M., Stevens, C.J., Sullivan, L.L., Porter, E., Ladouceur, E., Allen, C., Moromizato, K.H., Morgan, J.W., Harpole, W.S., Hautier, Y., Eisenhauer, N., Wright, J.P., Adler, P.B., Arnillas, C.A., Bakker, J.D., Biederman, L., Broadbent, A.A.D., Brown, C.S., Bugalho, M.N., Caldeira, M.C., Cleland, E.E., Ebeling, A., Fay, P.A., Hagenah, N., Kleinhesselink, A.R., Mitchell, R., Moore, J.L., Nogueira, C., Peri, P.L., Roscher, C., Smith, M.D., Wragg, P.D., and Risch, A.C.

Abstract

Leaf traits are frequently measured in ecology to provide a ‘common currency’ for predicting how anthropogenic pressures impact ecosystem function. Here, we test whether leaf traits consistently respond to experimental treatments across 27 globally distributed grassland sites across 4 continents. We find that specific leaf area (leaf area per unit mass)—a commonly measured morphological trait inferring shifts between plant growth strategies—did not respond to up to four years of soil nutrient additions. Leaf nitrogen, phosphorus and potassium concentrations increased in response to the addition of each respective soil nutrient. We found few significant changes in leaf traits when vertebrate herbivores were excluded in the short-term. Leaf nitrogen and potassium concentrations were positively correlated with species turnover, suggesting that interspecific trait variation was a significant predictor of leaf nitrogen and potassium, but not of leaf phosphorus concentration. Climatic conditions and pretreatment soil nutrient levels also accounted for significant amounts of variation in the leaf traits measured. Overall, we find that leaf morphological traits, such as specific leaf area, are not appropriate indicators of plant response to anthropogenic perturbations in grasslands.

Published

2019

14. Soil net nitrogen mineralisation across global grasslands

Author

Risch, A.C., Zimmermann, S., Ochoa-Hueso, R., Schütz, M., Frey, B., Firn, J.L., Fay, P.A., Hagedorn, F., Borer, E.T., Seabloom, E.W., Harpole, William Stanley, Knops, J.M.H., McCulley, R.L., Broadbent, A.A.D., Stevens, C.J., Silveira, M.L., Adler, P.B., Báez, S., Biederman, L.A., Blair, J.M., Brown, C.S., Caldeira, M.C., Collins, S.L., Daleo, P., di Virgilio, A., Ebeling, A., Eisenhauer, N., Esch, E., Eskelinen, Anu Maria, Hagenah, N., Hautier, Y., Kirkman, K.P., MacDougall, A.S., Moore, J.L., Power, S.A., Prober, S.M., Roscher, Christiane, Sankaran, M., Siebert, J., Speziale, K.L., Tognetti, P.M., Virtanen, Risto, Yahdjian, L., Moser, B., Risch, A.C., Zimmermann, S., Ochoa-Hueso, R., Schütz, M., Frey, B., Firn, J.L., Fay, P.A., Hagedorn, F., Borer, E.T., Seabloom, E.W., Harpole, William Stanley, Knops, J.M.H., McCulley, R.L., Broadbent, A.A.D., Stevens, C.J., Silveira, M.L., Adler, P.B., Báez, S., Biederman, L.A., Blair, J.M., Brown, C.S., Caldeira, M.C., Collins, S.L., Daleo, P., di Virgilio, A., Ebeling, A., Eisenhauer, N., Esch, E., Eskelinen, Anu Maria, Hagenah, N., Hautier, Y., Kirkman, K.P., MacDougall, A.S., Moore, J.L., Power, S.A., Prober, S.M., Roscher, Christiane, Sankaran, M., Siebert, J., Speziale, K.L., Tognetti, P.M., Virtanen, Risto, Yahdjian, L., and Moser, B.

Abstract

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

Published

2019

15. Leaf nutrients, not specific leaf area, are consistent indicators of elevated nutrient inputs

Author

Firn, J., McGree, J.M., Harvey, E., Flores-Moreno, H., Schütz, M., Buckley, Y.M., Borer, E.T., Seabloom, E.W., La Pierre, K.J., MacDougall, A.M., Prober, S.M., Stevens, C.J., Sullivan, L.L., Porter, E., Ladouceur, Emma, Allen, C., Moromizato, K.H., Morgan, J.W., Harpole, William Stanley, Hautier, Y., Eisenhauer, N., Wright, J.P., Adler, P.B., Arnillas, C.A., Bakker, J.D., Biederman, L., Broadbent, A.A.D., Brown, C.S., Bugalho, M.N., Caldeira, M.C., Cleland, E.E., Ebeling, A., Fay, P.A., Hagenah, N., Kleinhesselink, A.R., Mitchell, R., Moore, J.L., Nogueira, C., Peri, P.L., Roscher, Christiane, Smith, M.D., Wragg, P.D., Risch, A.C., Firn, J., McGree, J.M., Harvey, E., Flores-Moreno, H., Schütz, M., Buckley, Y.M., Borer, E.T., Seabloom, E.W., La Pierre, K.J., MacDougall, A.M., Prober, S.M., Stevens, C.J., Sullivan, L.L., Porter, E., Ladouceur, Emma, Allen, C., Moromizato, K.H., Morgan, J.W., Harpole, William Stanley, Hautier, Y., Eisenhauer, N., Wright, J.P., Adler, P.B., Arnillas, C.A., Bakker, J.D., Biederman, L., Broadbent, A.A.D., Brown, C.S., Bugalho, M.N., Caldeira, M.C., Cleland, E.E., Ebeling, A., Fay, P.A., Hagenah, N., Kleinhesselink, A.R., Mitchell, R., Moore, J.L., Nogueira, C., Peri, P.L., Roscher, Christiane, Smith, M.D., Wragg, P.D., and Risch, A.C.

Abstract

Leaf traits are frequently measured in ecology to provide a ‘common currency’ for predicting how anthropogenic pressures impact ecosystem function. Here, we test whether leaf traits consistently respond to experimental treatments across 27 globally distributed grassland sites across 4 continents. We find that specific leaf area (leaf area per unit mass)—a commonly measured morphological trait inferring shifts between plant growth strategies—did not respond to up to four years of soil nutrient additions. Leaf nitrogen, phosphorus and potassium concentrations increased in response to the addition of each respective soil nutrient. We found few significant changes in leaf traits when vertebrate herbivores were excluded in the short-term. Leaf nitrogen and potassium concentrations were positively correlated with species turnover, suggesting that interspecific trait variation was a significant predictor of leaf nitrogen and potassium, but not of leaf phosphorus concentration. Climatic conditions and pretreatment soil nutrient levels also accounted for significant amounts of variation in the leaf traits measured. Overall, we find that leaf morphological traits, such as specific leaf area, are not appropriate indicators of plant response to anthropogenic perturbations in grasslands.

Published

2019