Interactions among nutrients govern the global grassland biomass–precipitation relationship

Philip A. Fay; Laureano A. Gherardi; Laura Yahdjian; Peter B. Adler; Jonathan D. Bakker; Siddharth Bharath; Elizabeth T. Borer; W. Stanley Harpole; Erika Hersch-Green; Travis E. Huxman; Andrew S. MacDougall; Anita C. Risch; Eric W. Seabloom; Sumanta Bagchi; Isabel C. Barrio; Lori Biederman; Yvonne M. Buckley; Miguel N. Bugalho; Maria C. Caldeira; Jane A. Catford; Qing Qing Chen; Elsa E. Cleland; Scott L. Collins; Pedro Daleo; Christopher R. Dickman; Ian Donohue; Mary E. DuPre; Nico Eisenhauer; Anu Eskelinen; Nicole Hagenah; Yann Hautier; Robert W. Heckman; Ingibjörg S. Jónsdóttir; Johannes M.H. Knops; Ramesh Laungani; Jason P. Martina; Rebecca L. McCulley; John W. Morgan; Harry Olde Venterink; Pablo L. Peri; Sally A. Power; Xavier Raynaud; Zhengwei Ren; Christiane Roscher; Melinda D. Smith; Marie Spohn; Carly J. Stevens; Michelle J. Tedder; Risto Virtanen; Glenda M. Wardle; George R. Wheeler

doi:10.1073/pnas.2410748122

Interactions among nutrients govern the global grassland biomass–precipitation relationship

Philip A. Fay^*
, Laureano A. Gherardi^*
, Laura Yahdjian^*
, Peter B. Adler
, Jonathan D. Bakker
, Siddharth Bharath
, Elizabeth T. Borer
, W. Stanley Harpole
, Erika Hersch-Green
, Travis E. Huxman
, Andrew S. MacDougall
, Anita C. Risch
, Eric W. Seabloom
, Sumanta Bagchi
, Isabel C. Barrio
, Lori Biederman
, Yvonne M. Buckley
, Miguel N. Bugalho
, Maria C. Caldeira
, Jane A. Catford

Qing Qing Chen, Elsa E. Cleland, Scott L. Collins, Pedro Daleo, Christopher R. Dickman, Ian Donohue, Mary E. DuPre, Nico Eisenhauer, Anu Eskelinen, Nicole Hagenah, Yann Hautier, Robert W. Heckman, Ingibjörg S. Jónsdóttir, Johannes M.H. Knops, Ramesh Laungani, Jason P. Martina, Rebecca L. McCulley, John W. Morgan, Harry Olde Venterink, Pablo L. Peri, Sally A. Power, Xavier Raynaud, Zhengwei Ren, Christiane Roscher, Melinda D. Smith, Marie Spohn, Carly J. Stevens, Michelle J. Tedder, Risto Virtanen, Glenda M. Wardle, George R. Wheeler

^*Corresponding author for this work

United States Department of Agriculture
University of California at Berkeley
Universidad de Buenos Aires
Utah State University
University of Washington
University of Minnesota Twin Cities
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Helmholtz Centre for Environmental Research
Martin Luther University Halle-Wittenberg
Michigan Technological University
University of California at Irvine
University of Guelph
Swiss Federal Institute for Forest, Snow and Landscape Research
Indian Institute of Science Bangalore
Agricultural University of Iceland
Iowa State University
Trinity College Dublin
University of Lisbon
King's College London
Australian National University
Senckenberg Gesellschaft für Naturforschung
University of California at San Diego
University of New Mexico
Instituto de Investigaciones Marinas y Costeras
University of Sydney
MPG Ranch
Leipzig University
University of Oulu
University of Pretoria
Utrecht University
University of North Carolina at Chapel Hill
University of Texas at Austin
University of Iceland
Marist College
Texas State University
University of Kentucky
La Trobe University
Vrije Universiteit Brussel
Universidad Nacional de la Patagonia Austral
Western Sydney University
Sorbonne Université
Lanzhou University
Gansu Gannan Grassland Ecosystem National Observation and Research Station
Colorado State University
Swedish University of Agricultural Sciences
Lancaster University
University of KwaZulu-Natal
University of Nebraska-Lincoln

Research output: Contribution to journal › Article › peer-review

8 Citations (Scopus)

Abstract

Ecosystems are experiencing changing global patterns of mean annual precipitation (MAP) and enrichment with multiple nutrients that potentially colimit plant biomass production. In grasslands, mean aboveground plant biomass is closely related to MAP, but how this relationship changes after enrichment with multiple nutrients remains unclear. We hypothesized the global biomass–MAP relationship becomes steeper with an increasing number of added nutrients, with increases in steepness corresponding to the form of interaction among added nutrients and with increased mediation by changes in plant community diversity. We measured aboveground plant biomass production and species diversity in 71 grasslands on six continents representing the global span of grassland MAP, diversity, management, and soils. We fertilized all sites with nitrogen, phosphorus, and potassium with micronutrients in all combinations to identify which nutrients limited biomass at each site. As hypothesized, fertilizing with one, two, or three nutrients progressively steepened the global biomass–MAP relationship. The magnitude of the increase in steepness corresponded to whether sites were not limited by nitrogen or phosphorus, were limited by either one, or were colimited by both in additive, or synergistic forms. Unexpectedly, we found only weak evidence for mediation of biomass–MAP relationships by plant community diversity because relationships of species richness, evenness, and beta diversity to MAP and to biomass were weak or opposing. Site-level properties including baseline biomass production, soils, and management explained little variation in biomass–MAP relationships. These findings reveal multiple nutrient colimitation as a defining feature of the global grassland biomass–MAP relationship.

Original language	English
Article number	e2410748122
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	122
Issue number	15
DOIs	https://doi.org/10.1073/pnas.2410748122
Publication status	Published - 15 Apr 2025

Keywords

diversity
grasslands
precipitation
primary productivity

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10.1073/pnas.2410748122

Cite this

Fay, P. A., Gherardi, L. A., Yahdjian, L., Adler, P. B., Bakker, J. D., Bharath, S., Borer, E. T., Harpole, W. S., Hersch-Green, E., Huxman, T. E., MacDougall, A. S., Risch, A. C., Seabloom, E. W., Bagchi, S., Barrio, I. C., Biederman, L., Buckley, Y. M., Bugalho, M. N., Caldeira, M. C., ... Wheeler, G. R. (2025). Interactions among nutrients govern the global grassland biomass–precipitation relationship. Proceedings of the National Academy of Sciences of the United States of America, 122(15), Article e2410748122. https://doi.org/10.1073/pnas.2410748122

@article{179438c988b843cd8e3d744c95e8a107,

title = "Interactions among nutrients govern the global grassland biomass–precipitation relationship",

abstract = "Ecosystems are experiencing changing global patterns of mean annual precipitation (MAP) and enrichment with multiple nutrients that potentially colimit plant biomass production. In grasslands, mean aboveground plant biomass is closely related to MAP, but how this relationship changes after enrichment with multiple nutrients remains unclear. We hypothesized the global biomass–MAP relationship becomes steeper with an increasing number of added nutrients, with increases in steepness corresponding to the form of interaction among added nutrients and with increased mediation by changes in plant community diversity. We measured aboveground plant biomass production and species diversity in 71 grasslands on six continents representing the global span of grassland MAP, diversity, management, and soils. We fertilized all sites with nitrogen, phosphorus, and potassium with micronutrients in all combinations to identify which nutrients limited biomass at each site. As hypothesized, fertilizing with one, two, or three nutrients progressively steepened the global biomass–MAP relationship. The magnitude of the increase in steepness corresponded to whether sites were not limited by nitrogen or phosphorus, were limited by either one, or were colimited by both in additive, or synergistic forms. Unexpectedly, we found only weak evidence for mediation of biomass–MAP relationships by plant community diversity because relationships of species richness, evenness, and beta diversity to MAP and to biomass were weak or opposing. Site-level properties including baseline biomass production, soils, and management explained little variation in biomass–MAP relationships. These findings reveal multiple nutrient colimitation as a defining feature of the global grassland biomass–MAP relationship.",

keywords = "diversity, grasslands, precipitation, primary productivity",

author = "Fay, \{Philip A.\} and Gherardi, \{Laureano A.\} and Laura Yahdjian and Adler, \{Peter B.\} and Bakker, \{Jonathan D.\} and Siddharth Bharath and Borer, \{Elizabeth T.\} and Harpole, \{W. Stanley\} and Erika Hersch-Green and Huxman, \{Travis E.\} and MacDougall, \{Andrew S.\} and Risch, \{Anita C.\} and Seabloom, \{Eric W.\} and Sumanta Bagchi and Barrio, \{Isabel C.\} and Lori Biederman and Buckley, \{Yvonne M.\} and Bugalho, \{Miguel N.\} and Caldeira, \{Maria C.\} and Catford, \{Jane A.\} and Chen, \{Qing Qing\} and Cleland, \{Elsa E.\} and Collins, \{Scott L.\} and Pedro Daleo and Dickman, \{Christopher R.\} and Ian Donohue and DuPre, \{Mary E.\} and Nico Eisenhauer and Anu Eskelinen and Nicole Hagenah and Yann Hautier and Heckman, \{Robert W.\} and J{\'o}nsd{\'o}ttir, \{Ingibj{\"o}rg S.\} and Knops, \{Johannes M.H.\} and Ramesh Laungani and Martina, \{Jason P.\} and McCulley, \{Rebecca L.\} and Morgan, \{John W.\} and Venterink, \{Harry Olde\} and Peri, \{Pablo L.\} and Power, \{Sally A.\} and Xavier Raynaud and Zhengwei Ren and Christiane Roscher and Smith, \{Melinda D.\} and Marie Spohn and Stevens, \{Carly J.\} and Tedder, \{Michelle J.\} and Risto Virtanen and Wardle, \{Glenda M.\} and Wheeler, \{George R.\}",

note = "Publisher Copyright: Copyright {\textcopyright} 2025 the Author(s).",

year = "2025",

month = apr,

day = "15",

doi = "10.1073/pnas.2410748122",

language = "English",

volume = "122",

journal = "Proceedings of the National Academy of Sciences of the United States of America",

issn = "0027-8424",

number = "15",

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Fay, PA, Gherardi, LA, Yahdjian, L, Adler, PB, Bakker, JD, Bharath, S, Borer, ET, Harpole, WS, Hersch-Green, E, Huxman, TE, MacDougall, AS, Risch, AC, Seabloom, EW, Bagchi, S, Barrio, IC, Biederman, L, Buckley, YM, Bugalho, MN, Caldeira, MC, Catford, JA, Chen, QQ, Cleland, EE, Collins, SL, Daleo, P, Dickman, CR, Donohue, I, DuPre, ME, Eisenhauer, N, Eskelinen, A, Hagenah, N, Hautier, Y, Heckman, RW, Jónsdóttir, IS, Knops, JMH, Laungani, R, Martina, JP, McCulley, RL, Morgan, JW, Venterink, HO, Peri, PL, Power, SA, Raynaud, X, Ren, Z, Roscher, C, Smith, MD, Spohn, M, Stevens, CJ, Tedder, MJ, Virtanen, R, Wardle, GM & Wheeler, GR 2025, 'Interactions among nutrients govern the global grassland biomass–precipitation relationship', Proceedings of the National Academy of Sciences of the United States of America, vol. 122, no. 15, e2410748122. https://doi.org/10.1073/pnas.2410748122

TY - JOUR

T1 - Interactions among nutrients govern the global grassland biomass–precipitation relationship

AU - Fay, Philip A.

AU - Gherardi, Laureano A.

AU - Yahdjian, Laura

AU - Adler, Peter B.

AU - Bakker, Jonathan D.

AU - Bharath, Siddharth

AU - Borer, Elizabeth T.

AU - Harpole, W. Stanley

AU - Hersch-Green, Erika

AU - Huxman, Travis E.

AU - MacDougall, Andrew S.

AU - Risch, Anita C.

AU - Seabloom, Eric W.

AU - Bagchi, Sumanta

AU - Barrio, Isabel C.

AU - Biederman, Lori

AU - Buckley, Yvonne M.

AU - Bugalho, Miguel N.

AU - Caldeira, Maria C.

AU - Catford, Jane A.

AU - Chen, Qing Qing

AU - Cleland, Elsa E.

AU - Collins, Scott L.

AU - Daleo, Pedro

AU - Dickman, Christopher R.

AU - Donohue, Ian

AU - DuPre, Mary E.

AU - Eisenhauer, Nico

AU - Eskelinen, Anu

AU - Hagenah, Nicole

AU - Hautier, Yann

AU - Heckman, Robert W.

AU - Jónsdóttir, Ingibjörg S.

AU - Knops, Johannes M.H.

AU - Laungani, Ramesh

AU - Martina, Jason P.

AU - McCulley, Rebecca L.

AU - Morgan, John W.

AU - Venterink, Harry Olde

AU - Peri, Pablo L.

AU - Power, Sally A.

AU - Raynaud, Xavier

AU - Ren, Zhengwei

AU - Roscher, Christiane

AU - Smith, Melinda D.

AU - Spohn, Marie

AU - Stevens, Carly J.

AU - Tedder, Michelle J.

AU - Virtanen, Risto

AU - Wardle, Glenda M.

AU - Wheeler, George R.

PY - 2025/4/15

Y1 - 2025/4/15

N2 - Ecosystems are experiencing changing global patterns of mean annual precipitation (MAP) and enrichment with multiple nutrients that potentially colimit plant biomass production. In grasslands, mean aboveground plant biomass is closely related to MAP, but how this relationship changes after enrichment with multiple nutrients remains unclear. We hypothesized the global biomass–MAP relationship becomes steeper with an increasing number of added nutrients, with increases in steepness corresponding to the form of interaction among added nutrients and with increased mediation by changes in plant community diversity. We measured aboveground plant biomass production and species diversity in 71 grasslands on six continents representing the global span of grassland MAP, diversity, management, and soils. We fertilized all sites with nitrogen, phosphorus, and potassium with micronutrients in all combinations to identify which nutrients limited biomass at each site. As hypothesized, fertilizing with one, two, or three nutrients progressively steepened the global biomass–MAP relationship. The magnitude of the increase in steepness corresponded to whether sites were not limited by nitrogen or phosphorus, were limited by either one, or were colimited by both in additive, or synergistic forms. Unexpectedly, we found only weak evidence for mediation of biomass–MAP relationships by plant community diversity because relationships of species richness, evenness, and beta diversity to MAP and to biomass were weak or opposing. Site-level properties including baseline biomass production, soils, and management explained little variation in biomass–MAP relationships. These findings reveal multiple nutrient colimitation as a defining feature of the global grassland biomass–MAP relationship.

AB - Ecosystems are experiencing changing global patterns of mean annual precipitation (MAP) and enrichment with multiple nutrients that potentially colimit plant biomass production. In grasslands, mean aboveground plant biomass is closely related to MAP, but how this relationship changes after enrichment with multiple nutrients remains unclear. We hypothesized the global biomass–MAP relationship becomes steeper with an increasing number of added nutrients, with increases in steepness corresponding to the form of interaction among added nutrients and with increased mediation by changes in plant community diversity. We measured aboveground plant biomass production and species diversity in 71 grasslands on six continents representing the global span of grassland MAP, diversity, management, and soils. We fertilized all sites with nitrogen, phosphorus, and potassium with micronutrients in all combinations to identify which nutrients limited biomass at each site. As hypothesized, fertilizing with one, two, or three nutrients progressively steepened the global biomass–MAP relationship. The magnitude of the increase in steepness corresponded to whether sites were not limited by nitrogen or phosphorus, were limited by either one, or were colimited by both in additive, or synergistic forms. Unexpectedly, we found only weak evidence for mediation of biomass–MAP relationships by plant community diversity because relationships of species richness, evenness, and beta diversity to MAP and to biomass were weak or opposing. Site-level properties including baseline biomass production, soils, and management explained little variation in biomass–MAP relationships. These findings reveal multiple nutrient colimitation as a defining feature of the global grassland biomass–MAP relationship.

KW - diversity

KW - grasslands

KW - precipitation

KW - primary productivity

UR - https://www.scopus.com/pages/publications/105002807954

U2 - 10.1073/pnas.2410748122

DO - 10.1073/pnas.2410748122

M3 - Article

C2 - 40215280

AN - SCOPUS:105002807954

SN - 0027-8424

VL - 122

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 15

M1 - e2410748122

ER -

Interactions among nutrients govern the global grassland biomass–precipitation relationship

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Keywords

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