Leaf water content contributes to global leaf trait relationships

Zhiqiang Wang; Heng Huang; Han Wang; Josep Penuelas; Jordi Sardans; Ulo Niinemets; Karl J. Niklas; Yan Li; Jiangbo Xie; Ian J. Wright

doi:10.1038/s41467-022-32784-1

Leaf water content contributes to global leaf trait relationships

Zhiqiang Wang, Heng Huang, Han Wang, Josep Penuelas, Jordi Sardans, Ulo Niinemets, Karl J. Niklas, Yan Li, Jiangbo Xie, Ian J. Wright

Western Sydney University

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

45 Citations (Scopus)

Abstract

Leaf functional traits are important indicators of plant growth and ecosystem dynamics. Despite a wealth of knowledge about leaf trait relationships, a mechanistic understanding of how biotic and abiotic factors quantitatively influence leaf trait variation and scaling is still incomplete. We propose that leaf water content (LWC) inherently affects other leaf traits, although its role has been largely neglected. Here, we present a modification of a previously validated model based on metabolic theory and use an extensive global leaf trait dataset to test it. Analyses show that mass-based photosynthetic capacity and specific leaf area increase nonlinearly with LWC, as predicted by the model. When the effects of temperature and LWC are controlled, the numerical values for the leaf area-mass scaling exponents converge onto 1.0 across plant functional groups, ecosystem types, and latitudinal zones. The data also indicate that leaf water mass is a better predictor of whole-leaf photosynthesis and leaf area than whole-leaf nitrogen and phosphorus masses. Our findings highlight a comprehensive theory that can quantitatively predict some global patterns from the leaf economics spectrum.

Original language	English
Article number	5525
Number of pages	9
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-32784-1
Publication status	Published - 2022

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@article{7878827650684a1984e9ed222f4499ff,

title = "Leaf water content contributes to global leaf trait relationships",

abstract = "Leaf functional traits are important indicators of plant growth and ecosystem dynamics. Despite a wealth of knowledge about leaf trait relationships, a mechanistic understanding of how biotic and abiotic factors quantitatively influence leaf trait variation and scaling is still incomplete. We propose that leaf water content (LWC) inherently affects other leaf traits, although its role has been largely neglected. Here, we present a modification of a previously validated model based on metabolic theory and use an extensive global leaf trait dataset to test it. Analyses show that mass-based photosynthetic capacity and specific leaf area increase nonlinearly with LWC, as predicted by the model. When the effects of temperature and LWC are controlled, the numerical values for the leaf area-mass scaling exponents converge onto 1.0 across plant functional groups, ecosystem types, and latitudinal zones. The data also indicate that leaf water mass is a better predictor of whole-leaf photosynthesis and leaf area than whole-leaf nitrogen and phosphorus masses. Our findings highlight a comprehensive theory that can quantitatively predict some global patterns from the leaf economics spectrum.",

author = "Zhiqiang Wang and Heng Huang and Han Wang and Josep Penuelas and Jordi Sardans and Ulo Niinemets and Niklas, {Karl J.} and Yan Li and Jiangbo Xie and Wright, {Ian J.}",

year = "2022",

doi = "10.1038/s41467-022-32784-1",

language = "English",

volume = "13",

journal = "Nature Communications",

issn = "2041-1723",

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TY - JOUR

T1 - Leaf water content contributes to global leaf trait relationships

AU - Wang, Zhiqiang

AU - Huang, Heng

AU - Wang, Han

AU - Penuelas, Josep

AU - Sardans, Jordi

AU - Niinemets, Ulo

AU - Niklas, Karl J.

AU - Li, Yan

AU - Xie, Jiangbo

AU - Wright, Ian J.

PY - 2022

Y1 - 2022

N2 - Leaf functional traits are important indicators of plant growth and ecosystem dynamics. Despite a wealth of knowledge about leaf trait relationships, a mechanistic understanding of how biotic and abiotic factors quantitatively influence leaf trait variation and scaling is still incomplete. We propose that leaf water content (LWC) inherently affects other leaf traits, although its role has been largely neglected. Here, we present a modification of a previously validated model based on metabolic theory and use an extensive global leaf trait dataset to test it. Analyses show that mass-based photosynthetic capacity and specific leaf area increase nonlinearly with LWC, as predicted by the model. When the effects of temperature and LWC are controlled, the numerical values for the leaf area-mass scaling exponents converge onto 1.0 across plant functional groups, ecosystem types, and latitudinal zones. The data also indicate that leaf water mass is a better predictor of whole-leaf photosynthesis and leaf area than whole-leaf nitrogen and phosphorus masses. Our findings highlight a comprehensive theory that can quantitatively predict some global patterns from the leaf economics spectrum.

AB - Leaf functional traits are important indicators of plant growth and ecosystem dynamics. Despite a wealth of knowledge about leaf trait relationships, a mechanistic understanding of how biotic and abiotic factors quantitatively influence leaf trait variation and scaling is still incomplete. We propose that leaf water content (LWC) inherently affects other leaf traits, although its role has been largely neglected. Here, we present a modification of a previously validated model based on metabolic theory and use an extensive global leaf trait dataset to test it. Analyses show that mass-based photosynthetic capacity and specific leaf area increase nonlinearly with LWC, as predicted by the model. When the effects of temperature and LWC are controlled, the numerical values for the leaf area-mass scaling exponents converge onto 1.0 across plant functional groups, ecosystem types, and latitudinal zones. The data also indicate that leaf water mass is a better predictor of whole-leaf photosynthesis and leaf area than whole-leaf nitrogen and phosphorus masses. Our findings highlight a comprehensive theory that can quantitatively predict some global patterns from the leaf economics spectrum.

UR - https://hdl.handle.net/1959.7/uws:70431

U2 - 10.1038/s41467-022-32784-1

DO - 10.1038/s41467-022-32784-1

M3 - Article

SN - 2041-1723

VL - 13

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 5525

ER -

Leaf water content contributes to global leaf trait relationships

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