Leaf economic strategies drive global variation in phosphorus stimulation of terrestrial plant production

Nan Yang; Constantin M. Zohner; Thomas W. Crowther; Jiguang Feng; Jin Wu; Xinli Chen; Wenxuan Han; Benjamin D. Stocker; Dafeng Hui; Laurent Augusto; Kai Yue; Enqing Hou; Mingkai Jiang; Huili Feng; Zixin Chen; Wenjuan Wu; Aijun Xing; Chengrong Chen; Jordi Sardans; Yiqi Luo; Josep Peñuelas; Hans Lambers; Jingyun Fang; Zhengbing Yan

doi:10.1038/s41467-025-60633-4

Leaf economic strategies drive global variation in phosphorus stimulation of terrestrial plant production

Nan Yang
, Constantin M. Zohner
, Thomas W. Crowther
, Jiguang Feng
, Jin Wu
, Xinli Chen
, Wenxuan Han
, Benjamin D. Stocker
, Dafeng Hui
, Laurent Augusto
, Kai Yue
, Enqing Hou
, Mingkai Jiang
, Huili Feng
, Zixin Chen
, Wenjuan Wu
, Aijun Xing
, Chengrong Chen
, Jordi Sardans
, Yiqi Luo

Josep Peñuelas, Hans Lambers, Jingyun Fang, Zhengbing Yan

CAS - Institute of Botany
China National Botanical Garden
University of Chinese Academy of Sciences
Swiss Federal Institute of Technology Zurich
Inner Mongolia University
Hohai University
The University of Hong Kong
Chinese University of Hong Kong
Zhejiang Agriculture and Forestry University
China Agricultural University
University of Bern
Tennessee State University
INRAE
Fujian Normal University
CAS - South China Institute of Botany
Key Laboratory of National Forestry and Grassland Administration on Plant Conservation and Utilization in Southern China
Zhejiang University
Hainan University
Griffith University Queensland
Global Ecology Unit CREAF-CSIC-UAB
Cornell University
University of Western Australia
Peking University

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

9 Citations (Scopus)

1 Downloads (Pure)

Abstract

Plant biomass and its allocation are fundamental for understanding biospheric matter production. However, the impacts of atmospheric phosphorus (P) deposition on species-specific biomass and its allocation in global terrestrial plants remain unclear. By synthesizing 5548 observations of plant biomass and its allocation related to P addition worldwide, we find that P addition increases plant biomass by an average of 35% globally. This increase varies across plant functional groups, with stronger responses in deciduous (45%), C₃ (36%), and N₂-fixing plants (54%) than in evergreen (28%), C₄ (19%), and non-N₂-fixing plants (31%), respectively. Plants possessing traits indicative of an acquisitive strategy, such as higher nutrient concentrations and specific leaf area, faster photosynthetic rates and shorter leaf lifespan, are particularly responsive to P addition. Furthermore, P addition promotes a greater allocation of biomass to aboveground than belowground organs, resulting in a 5% decrease in root-to-shoot ratio. Our findings provide global-scale quantifications of how P addition regulates biomass accumulation and allocation strategies in terrestrial plants, offering critical insights for predicting the response of terrestrial carbon storage to rising atmospheric P deposition.

Original language	English
Article number	5562
Number of pages	13
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-60633-4
Publication status	Published - Dec 2025
Externally published	Yes

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Yang, N., Zohner, C. M., Crowther, T. W., Feng, J., Wu, J., Chen, X., Han, W., Stocker, B. D., Hui, D., Augusto, L., Yue, K., Hou, E., Jiang, M., Feng, H., Chen, Z., Wu, W., Xing, A., Chen, C., Sardans, J., ... Yan, Z. (2025). Leaf economic strategies drive global variation in phosphorus stimulation of terrestrial plant production. Nature Communications, 16(1), Article 5562. https://doi.org/10.1038/s41467-025-60633-4

@article{ddff4ed848b44bc7932f072e2c95711a,

title = "Leaf economic strategies drive global variation in phosphorus stimulation of terrestrial plant production",

abstract = "Plant biomass and its allocation are fundamental for understanding biospheric matter production. However, the impacts of atmospheric phosphorus (P) deposition on species-specific biomass and its allocation in global terrestrial plants remain unclear. By synthesizing 5548 observations of plant biomass and its allocation related to P addition worldwide, we find that P addition increases plant biomass by an average of 35\% globally. This increase varies across plant functional groups, with stronger responses in deciduous (45\%), C3 (36\%), and N2-fixing plants (54\%) than in evergreen (28\%), C4 (19\%), and non-N2-fixing plants (31\%), respectively. Plants possessing traits indicative of an acquisitive strategy, such as higher nutrient concentrations and specific leaf area, faster photosynthetic rates and shorter leaf lifespan, are particularly responsive to P addition. Furthermore, P addition promotes a greater allocation of biomass to aboveground than belowground organs, resulting in a 5\% decrease in root-to-shoot ratio. Our findings provide global-scale quantifications of how P addition regulates biomass accumulation and allocation strategies in terrestrial plants, offering critical insights for predicting the response of terrestrial carbon storage to rising atmospheric P deposition.",

author = "Nan Yang and Zohner, \{Constantin M.\} and Crowther, \{Thomas W.\} and Jiguang Feng and Jin Wu and Xinli Chen and Wenxuan Han and Stocker, \{Benjamin D.\} and Dafeng Hui and Laurent Augusto and Kai Yue and Enqing Hou and Mingkai Jiang and Huili Feng and Zixin Chen and Wenjuan Wu and Aijun Xing and Chengrong Chen and Jordi Sardans and Yiqi Luo and Josep Pe{\~n}uelas and Hans Lambers and Jingyun Fang and Zhengbing Yan",

year = "2025",

month = dec,

doi = "10.1038/s41467-025-60633-4",

language = "English",

volume = "16",

journal = "Nature Communications",

issn = "2041-1723",

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number = "1",

}

Yang, N, Zohner, CM, Crowther, TW, Feng, J, Wu, J, Chen, X, Han, W, Stocker, BD, Hui, D, Augusto, L, Yue, K, Hou, E, Jiang, M, Feng, H, Chen, Z, Wu, W, Xing, A, Chen, C, Sardans, J, Luo, Y, Peñuelas, J, Lambers, H, Fang, J & Yan, Z 2025, 'Leaf economic strategies drive global variation in phosphorus stimulation of terrestrial plant production', Nature Communications, vol. 16, no. 1, 5562. https://doi.org/10.1038/s41467-025-60633-4

TY - JOUR

T1 - Leaf economic strategies drive global variation in phosphorus stimulation of terrestrial plant production

AU - Yang, Nan

AU - Zohner, Constantin M.

AU - Crowther, Thomas W.

AU - Feng, Jiguang

AU - Wu, Jin

AU - Chen, Xinli

AU - Han, Wenxuan

AU - Stocker, Benjamin D.

AU - Hui, Dafeng

AU - Augusto, Laurent

AU - Yue, Kai

AU - Hou, Enqing

AU - Jiang, Mingkai

AU - Feng, Huili

AU - Chen, Zixin

AU - Wu, Wenjuan

AU - Xing, Aijun

AU - Chen, Chengrong

AU - Sardans, Jordi

AU - Luo, Yiqi

AU - Peñuelas, Josep

AU - Lambers, Hans

AU - Fang, Jingyun

AU - Yan, Zhengbing

PY - 2025/12

Y1 - 2025/12

N2 - Plant biomass and its allocation are fundamental for understanding biospheric matter production. However, the impacts of atmospheric phosphorus (P) deposition on species-specific biomass and its allocation in global terrestrial plants remain unclear. By synthesizing 5548 observations of plant biomass and its allocation related to P addition worldwide, we find that P addition increases plant biomass by an average of 35% globally. This increase varies across plant functional groups, with stronger responses in deciduous (45%), C3 (36%), and N2-fixing plants (54%) than in evergreen (28%), C4 (19%), and non-N2-fixing plants (31%), respectively. Plants possessing traits indicative of an acquisitive strategy, such as higher nutrient concentrations and specific leaf area, faster photosynthetic rates and shorter leaf lifespan, are particularly responsive to P addition. Furthermore, P addition promotes a greater allocation of biomass to aboveground than belowground organs, resulting in a 5% decrease in root-to-shoot ratio. Our findings provide global-scale quantifications of how P addition regulates biomass accumulation and allocation strategies in terrestrial plants, offering critical insights for predicting the response of terrestrial carbon storage to rising atmospheric P deposition.

AB - Plant biomass and its allocation are fundamental for understanding biospheric matter production. However, the impacts of atmospheric phosphorus (P) deposition on species-specific biomass and its allocation in global terrestrial plants remain unclear. By synthesizing 5548 observations of plant biomass and its allocation related to P addition worldwide, we find that P addition increases plant biomass by an average of 35% globally. This increase varies across plant functional groups, with stronger responses in deciduous (45%), C3 (36%), and N2-fixing plants (54%) than in evergreen (28%), C4 (19%), and non-N2-fixing plants (31%), respectively. Plants possessing traits indicative of an acquisitive strategy, such as higher nutrient concentrations and specific leaf area, faster photosynthetic rates and shorter leaf lifespan, are particularly responsive to P addition. Furthermore, P addition promotes a greater allocation of biomass to aboveground than belowground organs, resulting in a 5% decrease in root-to-shoot ratio. Our findings provide global-scale quantifications of how P addition regulates biomass accumulation and allocation strategies in terrestrial plants, offering critical insights for predicting the response of terrestrial carbon storage to rising atmospheric P deposition.

UR - https://www.scopus.com/pages/publications/105009622000

U2 - 10.1038/s41467-025-60633-4

DO - 10.1038/s41467-025-60633-4

M3 - Article

AN - SCOPUS:105009622000

SN - 2041-1723

VL - 16

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 5562

ER -

Leaf economic strategies drive global variation in phosphorus stimulation of terrestrial plant production

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