Abiotic and biotic controls of non-native perennial plant success in drylands

Soroor Rahmanian; Nico Eisenhauer; Yuanyuan Huang; Martin Hejda; Petr Pyšek; Hannes Feilhauer; David J. Eldridge; Nicolas Gross; Yoann Le Bagousse-Pinguet; Hugo Saiz; Manuel Delgado-Baquerizo; Miguel Berdugo; Victoria Ochoa; Beatriz Gozalo; Sergio Asensio; Emilio Guirado; Enrique Valencia; Miguel García-Gómez; Juan J. Gaitán; Betty Mendoza; César Plaza; Paloma Díaz-Martínez; Jaime Martínez-Valderrama; Mehdi Abedi; Negar Ahmadian; Rodrigo J. Ahumada; Fateh Amghar; Thiago Araújo; Antonio I. Arroyo; Farah Ben Salem; Niels Blaum; Enkhjargal Boldbat; Bazartseren Boldgiv; Matthew Bowker; Liesbeth van den Brink; Chongfeng Bu; Rafaella Canessa; Andrea P. Castillo-Monroy; Helena Castro; Patricio Castro-Quezada; Ghassen Chaieb; Roukaya Chibani; Abel A. Conceição; Yvonne C. Davila; Balázs Deák; David A. Donoso; Andrew Dougill; Carlos Iván Espinosa; Alex Fajardo; Mohammad Farzam; Daniela Ferrante; Jorgelina Franzese; Lauchlan H. Fraser; Erika Geiger; Sofia Laura Gonzalez; Elizabeth Gusman Montalván; Robert Hering; Eugene Marais; Rosa Mary Hernández Hernández; Sandra Daniela Hernández-Valdez; Norbert Hölzel; Elisabeth Huber-Sannwald; Oswaldo Jadán; Anke Jentsch; Liana Kindermann; Melanie Köbel; Peter C. le Roux; Cintia V. Leder; Xinhao Li; Pierre Liancourt; Anja Linstädter; Jushan Liu; Michelle A. Louw; Gillian Maggs-Kölling; Thulani P. Makhalanyane; Oumarou Malam Issa; Antonio J. Manzaneda; Pierre Margerie; Raphaël Martin; Mitchel P. McClaran; João Vitor S. Messeder; Juan P. Mora; Gerardo Moreno; Seth M. Munson; Girish R. Nair; Alice Nunes; Gabriel Oliva; Salza Palpurina; Guadalupe Peter; Yolanda Pueyo; Emiliano Quiroga; Sasha C. Reed; Pedro J. Rey; Alexandra Rodríguez; Victor Rolo; Jan C. Ruppert; Ayman Salah; Shlomo Sarig; Brajesh K. Singh; Anthony Swemmer; Alberto L. Teixido; Andrew D. Thomas; Katja Tielbörger; Samantha Travers; Orsolya Valkó; Wanyoike Wamiti; Deli Wang; Lixin Wang; Glenda M. Wardle; Peter Wolff; Laura Yahdjian; Gastón R. Oñatibia; Reza Yari; Eli Zaady; Yuanming Zhang; Xiaobing Zhou; Fernando T. Maestre

doi:10.1038/s41559-025-02971-6

Abiotic and biotic controls of non-native perennial plant success in drylands

Soroor Rahmanian
, Nico Eisenhauer
, Yuanyuan Huang
, Martin Hejda
, Petr Pyšek
, Hannes Feilhauer
, David J. Eldridge
, Nicolas Gross
, Yoann Le Bagousse-Pinguet
, Hugo Saiz
, Manuel Delgado-Baquerizo
, Miguel Berdugo
, Victoria Ochoa
, Beatriz Gozalo
, Sergio Asensio
, Emilio Guirado
, Enrique Valencia
, Miguel García-Gómez
, Juan J. Gaitán
, Betty Mendoza

César Plaza, Paloma Díaz-Martínez, Jaime Martínez-Valderrama, Mehdi Abedi, Negar Ahmadian, Rodrigo J. Ahumada, Fateh Amghar, Thiago Araújo, Antonio I. Arroyo, Farah Ben Salem, Niels Blaum, Enkhjargal Boldbat, Bazartseren Boldgiv, Matthew Bowker, Liesbeth van den Brink, Chongfeng Bu, Rafaella Canessa, Andrea P. Castillo-Monroy, Helena Castro, Patricio Castro-Quezada, Ghassen Chaieb, Roukaya Chibani, Abel A. Conceição, Yvonne C. Davila, Balázs Deák, David A. Donoso, Andrew Dougill, Carlos Iván Espinosa, Alex Fajardo, Mohammad Farzam, Daniela Ferrante, Jorgelina Franzese, Lauchlan H. Fraser, Erika Geiger, Sofia Laura Gonzalez, Elizabeth Gusman Montalván, Robert Hering, Eugene Marais, Rosa Mary Hernández Hernández, Sandra Daniela Hernández-Valdez, Norbert Hölzel, Elisabeth Huber-Sannwald, Oswaldo Jadán, Anke Jentsch, Liana Kindermann, Melanie Köbel, Peter C. le Roux, Cintia V. Leder, Xinhao Li, Pierre Liancourt, Anja Linstädter, Jushan Liu, Michelle A. Louw, Gillian Maggs-Kölling, Thulani P. Makhalanyane, Oumarou Malam Issa, Antonio J. Manzaneda, Pierre Margerie, Raphaël Martin, Mitchel P. McClaran, João Vitor S. Messeder, Juan P. Mora, Gerardo Moreno, Seth M. Munson, Girish R. Nair, Alice Nunes, Gabriel Oliva, Salza Palpurina, Guadalupe Peter, Yolanda Pueyo, Emiliano Quiroga, Sasha C. Reed, Pedro J. Rey, Alexandra Rodríguez, Victor Rolo, Jan C. Ruppert, Ayman Salah, Shlomo Sarig, Brajesh K. Singh, Anthony Swemmer, Alberto L. Teixido, Andrew D. Thomas, Katja Tielbörger, Samantha Travers, Orsolya Valkó, Wanyoike Wamiti, Deli Wang, Lixin Wang, Glenda M. Wardle, Peter Wolff, Laura Yahdjian, Gastón R. Oñatibia, Reza Yari, Eli Zaady, Yuanming Zhang, Xiaobing Zhou, Fernando T. Maestre

German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Leipzig University
Czech Academy of Sciences
Charles University
University of New South Wales
Université Clermont Auvergne
Avignon Université
University of Zaragoza
CSIC - Institute of Natural Resources and Agrobiology of Seville
Complutense University
University of Jaén
University of Alicante
King Abdullah University of Science and Technology
Technical University of Madrid
Universidad Nacional de Luján
Universidad Rey Juan Carlos
CSIC - Biological Mission of Galicia
Universidad Autónoma de Madrid
CSIC - Estación Experimental de Zonas Áridas (EEZA)
Tarbiat Modarres University
Instituto Nacional de Tecnología Agropecuaria
M'Hamed Bougara University of Boumerdes
Instituto Federal de Educação, Ciência e Tecnologia da Bahia
CSIC
University of Gabes
University of Potsdam
National University of Mongolia
Northern Arizona University
University of Tübingen
Universidad de Concepción
Northwest Agriculture and Forestry University
CAS - Institute of Soil and Water Conservation
Martin Luther University Halle-Wittenberg
University of Marburg
Universidad de las Américas - Ecuador
University of Coimbra
Thompson Rivers University
Institut des Régions Arides
Universidade Estadual de Feira de Santana
University of Technology Sydney
Centre for Ecological Research
University of York
Universidad Técnica Particular de Loja
Universidad de Talca
Instituto de Ecología y Biodiversidad
Ministerio de Planificación, Chile
Ferdowsi University of Mashhad
Curtin University
Universidad Nacional de la Patagonia Austral
Instituto de Investigaciones en Biodiversidad y Medioambiente, Bariloche
United States Geological Survey
Gobabeb Namib Research Institute
Universidad Nacional Experimental Simón Rodríguez (UNESR)
Instituto Potosino de Investigacion Cientifica y Tecnologica
University of Münster
University of Bayreuth
University of Lisbon
University of Pretoria
Consejo Nacional de Investigaciones Científicas y Técnicas
Universidad Nacional de Río Negro
State Museum of Natural History Stuttgart
Northeast Normal University
North West University
Stellenbosch University
Sorbonne Université
ECODIV
University of Arizona
Virginia Polytechnic Institute and State University
University of Extremadura
Bulgarian Academy of Sciences
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The Ministry of Innovation
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South African Environmental Observation Network
Aberystwyth University
National Museums of Kenya
University of Indianapolis
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Universidad de Buenos Aires
Animal Science Research Institute, Iran
CAS - Xinjiang Institute of Ecology and Geography

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

Abstract

Drivers of non-native plant success in drylands are poorly understood. Here we identify functional differences between dryland native and non-native perennial plants and assess how biotic, abiotic and anthropogenic factors shape the success of the latter. On the basis of plant community and functional trait data from 98 sites across 25 countries, we report a total of 41 non-native plant species at 31 sites. Non-natives tend towards faster growth strategies than natives. Non-native plant richness is higher at sites with greater grazing pressure and under environmental conditions associated with higher soil fertility, decomposition and fungal richness—conditions that tend to occur in less arid regions—and lower where native plant and herbivore richness are greater. Non-native plant cover correlates positively with grazing pressure and negatively with native plant richness. Taken together, our results suggest that non-native plant success in drylands is facilitated when high grazing pressure coincides with elevated resource availability. Such context-dependence of non-native plant success and linkages with native plant and herbivore diversity highlight the need for managing grazing and conserving biodiversity across the world’s drylands.

Original language	English
Pages (from-to)	523-535
Number of pages	13
Journal	nature ecology & evolution
Volume	10
Issue number	3
DOIs	https://doi.org/10.1038/s41559-025-02971-6 https://doi.org/10.1038/s41559-025-02971-6
State	Published - Mar 2026

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This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 15 Life on Land

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Rahmanian, S., Eisenhauer, N., Huang, Y., Hejda, M., Pyšek, P., Feilhauer, H., Eldridge, D. J., Gross, N., Le Bagousse-Pinguet, Y., Saiz, H., Delgado-Baquerizo, M., Berdugo, M., Ochoa, V., Gozalo, B., Asensio, S., Guirado, E., Valencia, E., García-Gómez, M., Gaitán, J. J., ... Maestre, F. T. (2026). Abiotic and biotic controls of non-native perennial plant success in drylands. nature ecology & evolution, 10(3), 523-535. https://doi.org/10.1038/s41559-025-02971-6, https://doi.org/10.1038/s41559-025-02971-6

@article{751f79283fa94011a30f9ecfe83b4714,

title = "Abiotic and biotic controls of non-native perennial plant success in drylands",

abstract = "Drivers of non-native plant success in drylands are poorly understood. Here we identify functional differences between dryland native and non-native perennial plants and assess how biotic, abiotic and anthropogenic factors shape the success of the latter. On the basis of plant community and functional trait data from 98 sites across 25 countries, we report a total of 41 non-native plant species at 31 sites. Non-natives tend towards faster growth strategies than natives. Non-native plant richness is higher at sites with greater grazing pressure and under environmental conditions associated with higher soil fertility, decomposition and fungal richness—conditions that tend to occur in less arid regions—and lower where native plant and herbivore richness are greater. Non-native plant cover correlates positively with grazing pressure and negatively with native plant richness. Taken together, our results suggest that non-native plant success in drylands is facilitated when high grazing pressure coincides with elevated resource availability. Such context-dependence of non-native plant success and linkages with native plant and herbivore diversity highlight the need for managing grazing and conserving biodiversity across the world{\textquoteright}s drylands.",

author = "Soroor Rahmanian and Nico Eisenhauer and Yuanyuan Huang and Martin Hejda and Petr Py{\v s}ek and Hannes Feilhauer and Eldridge, \{David J.\} and Nicolas Gross and \{Le Bagousse-Pinguet\}, Yoann and Hugo Saiz and Manuel Delgado-Baquerizo and Miguel Berdugo and Victoria Ochoa and Beatriz Gozalo and Sergio Asensio and Emilio Guirado and Enrique Valencia and Miguel Garc{\'i}a-G{\'o}mez and Gait{\'a}n, \{Juan J.\} and Betty Mendoza and C{\'e}sar Plaza and Paloma D{\'i}az-Mart{\'i}nez and Jaime Mart{\'i}nez-Valderrama and Mehdi Abedi and Negar Ahmadian and Ahumada, \{Rodrigo J.\} and Fateh Amghar and Thiago Ara{\'u}jo and Arroyo, \{Antonio I.\} and \{Ben Salem\}, Farah and Niels Blaum and Enkhjargal Boldbat and Bazartseren Boldgiv and Matthew Bowker and \{van den Brink\}, Liesbeth and Chongfeng Bu and Rafaella Canessa and Castillo-Monroy, \{Andrea P.\} and Helena Castro and Patricio Castro-Quezada and Ghassen Chaieb and Roukaya Chibani and Concei{\c c}{\~a}o, \{Abel A.\} and Davila, \{Yvonne C.\} and Bal{\'a}zs De{\'a}k and Donoso, \{David A.\} and Andrew Dougill and Espinosa, \{Carlos Iv{\'a}n\} and Alex Fajardo and Mohammad Farzam and Daniela Ferrante and Jorgelina Franzese and Fraser, \{Lauchlan H.\} and Erika Geiger and Gonzalez, \{Sofia Laura\} and Montalv{\'a}n, \{Elizabeth Gusman\} and Robert Hering and Eugene Marais and \{Hern{\'a}ndez Hern{\'a}ndez\}, \{Rosa Mary\} and Hern{\'a}ndez-Valdez, \{Sandra Daniela\} and Norbert H{\"o}lzel and Elisabeth Huber-Sannwald and Oswaldo Jad{\'a}n and Anke Jentsch and Liana Kindermann and Melanie K{\"o}bel and \{le Roux\}, \{Peter C.\} and Leder, \{Cintia V.\} and Xinhao Li and Pierre Liancourt and Anja Linst{\"a}dter and Jushan Liu and Louw, \{Michelle A.\} and Gillian Maggs-K{\"o}lling and Makhalanyane, \{Thulani P.\} and Issa, \{Oumarou Malam\} and Manzaneda, \{Antonio J.\} and Pierre Margerie and Rapha{\"e}l Martin and McClaran, \{Mitchel P.\} and Messeder, \{Jo{\~a}o Vitor S.\} and Mora, \{Juan P.\} and Gerardo Moreno and Munson, \{Seth M.\} and Nair, \{Girish R.\} and Alice Nunes and Gabriel Oliva and Salza Palpurina and Guadalupe Peter and Yolanda Pueyo and Emiliano Quiroga and Reed, \{Sasha C.\} and Rey, \{Pedro J.\} and Alexandra Rodr{\'i}guez and Victor Rolo and Ruppert, \{Jan C.\} and Ayman Salah and Shlomo Sarig and Singh, \{Brajesh K.\} and Anthony Swemmer and Teixido, \{Alberto L.\} and Thomas, \{Andrew D.\} and Katja Tielb{\"o}rger and Samantha Travers and Orsolya Valk{\'o} and Wanyoike Wamiti and Deli Wang and Lixin Wang and Wardle, \{Glenda M.\} and Peter Wolff and Laura Yahdjian and O{\~n}atibia, \{Gast{\'o}n R.\} and Reza Yari and Eli Zaady and Yuanming Zhang and Xiaobing Zhou and Maestre, \{Fernando T.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2026.",

year = "2026",

month = mar,

doi = "10.1038/s41559-025-02971-6",

language = "Ingl{\'e}s",

volume = "10",

pages = "523--535",

journal = "nature ecology \& evolution",

issn = "2397-334X",

publisher = "Springer Nature",

number = "3",

}

Rahmanian, S, Eisenhauer, N, Huang, Y, Hejda, M, Pyšek, P, Feilhauer, H, Eldridge, DJ, Gross, N, Le Bagousse-Pinguet, Y, Saiz, H, Delgado-Baquerizo, M, Berdugo, M, Ochoa, V, Gozalo, B, Asensio, S, Guirado, E, Valencia, E, García-Gómez, M, Gaitán, JJ, Mendoza, B, Plaza, C, Díaz-Martínez, P, Martínez-Valderrama, J, Abedi, M, Ahmadian, N, Ahumada, RJ, Amghar, F, Araújo, T, Arroyo, AI, Ben Salem, F, Blaum, N, Boldbat, E, Boldgiv, B, Bowker, M, van den Brink, L, Bu, C, Canessa, R, Castillo-Monroy, AP, Castro, H, Castro-Quezada, P, Chaieb, G, Chibani, R, Conceição, AA, Davila, YC, Deák, B, Donoso, DA, Dougill, A, Espinosa, CI, Fajardo, A, Farzam, M, Ferrante, D, Franzese, J, Fraser, LH, Geiger, E, Gonzalez, SL, Montalván, EG, Hering, R, Marais, E, Hernández Hernández, RM, Hernández-Valdez, SD, Hölzel, N, Huber-Sannwald, E, Jadán, O, Jentsch, A, Kindermann, L, Köbel, M, le Roux, PC, Leder, CV, Li, X, Liancourt, P, Linstädter, A, Liu, J, Louw, MA, Maggs-Kölling, G, Makhalanyane, TP, Issa, OM, Manzaneda, AJ, Margerie, P, Martin, R, McClaran, MP, Messeder, JVS, Mora, JP, Moreno, G, Munson, SM, Nair, GR, Nunes, A, Oliva, G, Palpurina, S, Peter, G, Pueyo, Y, Quiroga, E, Reed, SC, Rey, PJ, Rodríguez, A, Rolo, V, Ruppert, JC, Salah, A, Sarig, S, Singh, BK, Swemmer, A, Teixido, AL, Thomas, AD, Tielbörger, K, Travers, S, Valkó, O, Wamiti, W, Wang, D, Wang, L, Wardle, GM, Wolff, P, Yahdjian, L, Oñatibia, GR, Yari, R, Zaady, E, Zhang, Y, Zhou, X & Maestre, FT 2026, 'Abiotic and biotic controls of non-native perennial plant success in drylands', nature ecology & evolution, vol. 10, no. 3, pp. 523-535. https://doi.org/10.1038/s41559-025-02971-6, https://doi.org/10.1038/s41559-025-02971-6

TY - JOUR

T1 - Abiotic and biotic controls of non-native perennial plant success in drylands

AU - Rahmanian, Soroor

AU - Eisenhauer, Nico

AU - Huang, Yuanyuan

AU - Hejda, Martin

AU - Pyšek, Petr

AU - Feilhauer, Hannes

AU - Eldridge, David J.

AU - Gross, Nicolas

AU - Le Bagousse-Pinguet, Yoann

AU - Saiz, Hugo

AU - Delgado-Baquerizo, Manuel

AU - Berdugo, Miguel

AU - Ochoa, Victoria

AU - Gozalo, Beatriz

AU - Asensio, Sergio

AU - Guirado, Emilio

AU - Valencia, Enrique

AU - García-Gómez, Miguel

AU - Gaitán, Juan J.

AU - Mendoza, Betty

AU - Plaza, César

AU - Díaz-Martínez, Paloma

AU - Martínez-Valderrama, Jaime

AU - Abedi, Mehdi

AU - Ahmadian, Negar

AU - Ahumada, Rodrigo J.

AU - Amghar, Fateh

AU - Araújo, Thiago

AU - Arroyo, Antonio I.

AU - Ben Salem, Farah

AU - Blaum, Niels

AU - Boldbat, Enkhjargal

AU - Boldgiv, Bazartseren

AU - Bowker, Matthew

AU - van den Brink, Liesbeth

AU - Bu, Chongfeng

AU - Canessa, Rafaella

AU - Castillo-Monroy, Andrea P.

AU - Castro, Helena

AU - Castro-Quezada, Patricio

AU - Chaieb, Ghassen

AU - Chibani, Roukaya

AU - Conceição, Abel A.

AU - Davila, Yvonne C.

AU - Deák, Balázs

AU - Donoso, David A.

AU - Dougill, Andrew

AU - Espinosa, Carlos Iván

AU - Fajardo, Alex

AU - Farzam, Mohammad

AU - Ferrante, Daniela

AU - Franzese, Jorgelina

AU - Fraser, Lauchlan H.

AU - Geiger, Erika

AU - Gonzalez, Sofia Laura

AU - Montalván, Elizabeth Gusman

AU - Hering, Robert

AU - Marais, Eugene

AU - Hernández Hernández, Rosa Mary

AU - Hernández-Valdez, Sandra Daniela

AU - Hölzel, Norbert

AU - Huber-Sannwald, Elisabeth

AU - Jadán, Oswaldo

AU - Jentsch, Anke

AU - Kindermann, Liana

AU - Köbel, Melanie

AU - le Roux, Peter C.

AU - Leder, Cintia V.

AU - Li, Xinhao

AU - Liancourt, Pierre

AU - Linstädter, Anja

AU - Liu, Jushan

AU - Louw, Michelle A.

AU - Maggs-Kölling, Gillian

AU - Makhalanyane, Thulani P.

AU - Issa, Oumarou Malam

AU - Manzaneda, Antonio J.

AU - Margerie, Pierre

AU - Martin, Raphaël

AU - McClaran, Mitchel P.

AU - Messeder, João Vitor S.

AU - Mora, Juan P.

AU - Moreno, Gerardo

AU - Munson, Seth M.

AU - Nair, Girish R.

AU - Nunes, Alice

AU - Oliva, Gabriel

AU - Palpurina, Salza

AU - Peter, Guadalupe

AU - Pueyo, Yolanda

AU - Quiroga, Emiliano

AU - Reed, Sasha C.

AU - Rey, Pedro J.

AU - Rodríguez, Alexandra

AU - Rolo, Victor

AU - Ruppert, Jan C.

AU - Salah, Ayman

AU - Sarig, Shlomo

AU - Singh, Brajesh K.

AU - Swemmer, Anthony

AU - Teixido, Alberto L.

AU - Thomas, Andrew D.

AU - Tielbörger, Katja

AU - Travers, Samantha

AU - Valkó, Orsolya

AU - Wamiti, Wanyoike

AU - Wang, Deli

AU - Wang, Lixin

AU - Wardle, Glenda M.

AU - Wolff, Peter

AU - Yahdjian, Laura

AU - Oñatibia, Gastón R.

AU - Yari, Reza

AU - Zaady, Eli

AU - Zhang, Yuanming

AU - Zhou, Xiaobing

AU - Maestre, Fernando T.

PY - 2026/3

Y1 - 2026/3

N2 - Drivers of non-native plant success in drylands are poorly understood. Here we identify functional differences between dryland native and non-native perennial plants and assess how biotic, abiotic and anthropogenic factors shape the success of the latter. On the basis of plant community and functional trait data from 98 sites across 25 countries, we report a total of 41 non-native plant species at 31 sites. Non-natives tend towards faster growth strategies than natives. Non-native plant richness is higher at sites with greater grazing pressure and under environmental conditions associated with higher soil fertility, decomposition and fungal richness—conditions that tend to occur in less arid regions—and lower where native plant and herbivore richness are greater. Non-native plant cover correlates positively with grazing pressure and negatively with native plant richness. Taken together, our results suggest that non-native plant success in drylands is facilitated when high grazing pressure coincides with elevated resource availability. Such context-dependence of non-native plant success and linkages with native plant and herbivore diversity highlight the need for managing grazing and conserving biodiversity across the world’s drylands.

AB - Drivers of non-native plant success in drylands are poorly understood. Here we identify functional differences between dryland native and non-native perennial plants and assess how biotic, abiotic and anthropogenic factors shape the success of the latter. On the basis of plant community and functional trait data from 98 sites across 25 countries, we report a total of 41 non-native plant species at 31 sites. Non-natives tend towards faster growth strategies than natives. Non-native plant richness is higher at sites with greater grazing pressure and under environmental conditions associated with higher soil fertility, decomposition and fungal richness—conditions that tend to occur in less arid regions—and lower where native plant and herbivore richness are greater. Non-native plant cover correlates positively with grazing pressure and negatively with native plant richness. Taken together, our results suggest that non-native plant success in drylands is facilitated when high grazing pressure coincides with elevated resource availability. Such context-dependence of non-native plant success and linkages with native plant and herbivore diversity highlight the need for managing grazing and conserving biodiversity across the world’s drylands.

UR - https://www.scopus.com/pages/publications/105029687415

U2 - 10.1038/s41559-025-02971-6

DO - 10.1038/s41559-025-02971-6

M3 - Artículo

AN - SCOPUS:105029687415

SN - 2397-334X

VL - 10

SP - 523

EP - 535

JO - nature ecology & evolution

JF - nature ecology & evolution

IS - 3

ER -

Abiotic and biotic controls of non-native perennial plant success in drylands

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