Global photosynthetic capacity is optimized to the environment

Nicholas G. Smith; Trevor F. Keenan; I. Colin Prentice; Han Wang; Ian J. Wright; Ulo Niinemets; Kristine Y. Crous; Thomas F. Domingues; Rosella Guerrieri; F. Yoko Ishida; Jens Kattge; Eric L. Kruger; Vincent Maire; Alistair Rogers; Shawn P. Serbin; Lasse Tarvainen; Henrique F. Togashi; Philip A. Townsend; Meng Wang; Lasantha K. Weerasinghe; Shuang-Xi Zhou

doi:10.1111/ele.13210

Global photosynthetic capacity is optimized to the environment

Nicholas G. Smith, Trevor F. Keenan, I. Colin Prentice, Han Wang, Ian J. Wright, Ulo Niinemets, Kristine Y. Crous, Thomas F. Domingues, Rosella Guerrieri, F. Yoko Ishida, Jens Kattge, Eric L. Kruger, Vincent Maire, Alistair Rogers, Shawn P. Serbin, Lasse Tarvainen, Henrique F. Togashi, Philip A. Townsend, Meng Wang, Lasantha K. WeerasingheShuang-Xi Zhou

Western Sydney University

Macquarie University

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

182 Citations (Scopus)

Abstract

Earth system models (ESMs) use photosynthetic capacity, indexed by the maximum Rubisco carboxylation rate (Vcmax), to simulate carbon assimilation and typically rely on empirical estimates, including an assumed dependence on leaf nitrogen determined from soil fertility. In contrast, new theory, based on biochemical coordination and co-optimization of carboxylation and water costs for photosynthesis, suggests that optimal Vcmax can be predicted from climate alone, irrespective of soil fertility. Here, we develop this theory and find it captures 64% of observed variability in a global, field-measured Vcmax dataset for C3 plants. Soil fertility indices explained substantially less variation (32%). These results indicate that environmentally regulated biophysical constraints and light availability are the first-order drivers of global photosynthetic capacity. Through acclimation and adaptation, plants efficiently utilize resources at the leaf level, thus maximizing potential resource use for growth and reproduction. Our theory offers a robust strategy for dynamically predicting photosynthetic capacity in ESMs.

Original language	English
Pages (from-to)	506-517
Number of pages	12
Journal	Ecology Letters
Volume	22
Issue number	3
DOIs	https://doi.org/10.1111/ele.13210
Publication status	Published - 2019

Open Access - Access Right Statement

© 2019 The Authors. Ecology Letters published by CNRS and John Wiley & Sons Ltd This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

Keywords

acclimatization
carbon cycle (biogeochemistry)
carbon dioxide
climatic changes
leaf water balance
photosynthesis

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10.1111/ele.13210

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Smith, N. G., Keenan, T. F., Prentice, I. C., Wang, H., Wright, I. J., Niinemets, U., Crous, K. Y., Domingues, T. F., Guerrieri, R., Ishida, F. Y., Kattge, J., Kruger, E. L., Maire, V., Rogers, A., Serbin, S. P., Tarvainen, L., Togashi, H. F., Townsend, P. A., Wang, M., ... Zhou, S.-X. (2019). Global photosynthetic capacity is optimized to the environment. Ecology Letters, 22(3), 506-517. https://doi.org/10.1111/ele.13210

@article{3ec84ef57424409b8a2e090252a5fa76,

title = "Global photosynthetic capacity is optimized to the environment",

abstract = "Earth system models (ESMs) use photosynthetic capacity, indexed by the maximum Rubisco carboxylation rate (Vcmax), to simulate carbon assimilation and typically rely on empirical estimates, including an assumed dependence on leaf nitrogen determined from soil fertility. In contrast, new theory, based on biochemical coordination and co-optimization of carboxylation and water costs for photosynthesis, suggests that optimal Vcmax can be predicted from climate alone, irrespective of soil fertility. Here, we develop this theory and find it captures 64% of observed variability in a global, field-measured Vcmax dataset for C3 plants. Soil fertility indices explained substantially less variation (32%). These results indicate that environmentally regulated biophysical constraints and light availability are the first-order drivers of global photosynthetic capacity. Through acclimation and adaptation, plants efficiently utilize resources at the leaf level, thus maximizing potential resource use for growth and reproduction. Our theory offers a robust strategy for dynamically predicting photosynthetic capacity in ESMs.",

keywords = "acclimatization, carbon cycle (biogeochemistry), carbon dioxide, climatic changes, leaf water balance, photosynthesis",

author = "Smith, {Nicholas G.} and Keenan, {Trevor F.} and Prentice, {I. Colin} and Han Wang and Wright, {Ian J.} and Ulo Niinemets and Crous, {Kristine Y.} and Domingues, {Thomas F.} and Rosella Guerrieri and Ishida, {F. Yoko} and Jens Kattge and Kruger, {Eric L.} and Vincent Maire and Alistair Rogers and Serbin, {Shawn P.} and Lasse Tarvainen and Togashi, {Henrique F.} and Townsend, {Philip A.} and Meng Wang and Weerasinghe, {Lasantha K.} and Shuang-Xi Zhou",

year = "2019",

doi = "10.1111/ele.13210",

language = "English",

volume = "22",

pages = "506--517",

journal = "Ecology Letters",

issn = "1461-023X",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "3",

}

Smith, NG, Keenan, TF, Prentice, IC, Wang, H, Wright, IJ, Niinemets, U, Crous, KY, Domingues, TF, Guerrieri, R, Ishida, FY, Kattge, J, Kruger, EL, Maire, V, Rogers, A, Serbin, SP, Tarvainen, L, Togashi, HF, Townsend, PA, Wang, M, Weerasinghe, LK & Zhou, S-X 2019, 'Global photosynthetic capacity is optimized to the environment', Ecology Letters, vol. 22, no. 3, pp. 506-517. https://doi.org/10.1111/ele.13210

TY - JOUR

T1 - Global photosynthetic capacity is optimized to the environment

AU - Smith, Nicholas G.

AU - Keenan, Trevor F.

AU - Prentice, I. Colin

AU - Wang, Han

AU - Wright, Ian J.

AU - Niinemets, Ulo

AU - Crous, Kristine Y.

AU - Domingues, Thomas F.

AU - Guerrieri, Rosella

AU - Ishida, F. Yoko

AU - Kattge, Jens

AU - Kruger, Eric L.

AU - Maire, Vincent

AU - Rogers, Alistair

AU - Serbin, Shawn P.

AU - Tarvainen, Lasse

AU - Togashi, Henrique F.

AU - Townsend, Philip A.

AU - Wang, Meng

AU - Weerasinghe, Lasantha K.

AU - Zhou, Shuang-Xi

PY - 2019

Y1 - 2019

N2 - Earth system models (ESMs) use photosynthetic capacity, indexed by the maximum Rubisco carboxylation rate (Vcmax), to simulate carbon assimilation and typically rely on empirical estimates, including an assumed dependence on leaf nitrogen determined from soil fertility. In contrast, new theory, based on biochemical coordination and co-optimization of carboxylation and water costs for photosynthesis, suggests that optimal Vcmax can be predicted from climate alone, irrespective of soil fertility. Here, we develop this theory and find it captures 64% of observed variability in a global, field-measured Vcmax dataset for C3 plants. Soil fertility indices explained substantially less variation (32%). These results indicate that environmentally regulated biophysical constraints and light availability are the first-order drivers of global photosynthetic capacity. Through acclimation and adaptation, plants efficiently utilize resources at the leaf level, thus maximizing potential resource use for growth and reproduction. Our theory offers a robust strategy for dynamically predicting photosynthetic capacity in ESMs.

AB - Earth system models (ESMs) use photosynthetic capacity, indexed by the maximum Rubisco carboxylation rate (Vcmax), to simulate carbon assimilation and typically rely on empirical estimates, including an assumed dependence on leaf nitrogen determined from soil fertility. In contrast, new theory, based on biochemical coordination and co-optimization of carboxylation and water costs for photosynthesis, suggests that optimal Vcmax can be predicted from climate alone, irrespective of soil fertility. Here, we develop this theory and find it captures 64% of observed variability in a global, field-measured Vcmax dataset for C3 plants. Soil fertility indices explained substantially less variation (32%). These results indicate that environmentally regulated biophysical constraints and light availability are the first-order drivers of global photosynthetic capacity. Through acclimation and adaptation, plants efficiently utilize resources at the leaf level, thus maximizing potential resource use for growth and reproduction. Our theory offers a robust strategy for dynamically predicting photosynthetic capacity in ESMs.

KW - acclimatization

KW - carbon cycle (biogeochemistry)

KW - carbon dioxide

KW - climatic changes

KW - leaf water balance

KW - photosynthesis

UR - http://hdl.handle.net/1959.7/uws:50716

U2 - 10.1111/ele.13210

DO - 10.1111/ele.13210

M3 - Article

C2 - 30609108

SN - 1461-023X

VL - 22

SP - 506

EP - 517

JO - Ecology Letters

JF - Ecology Letters

IS - 3

ER -

Global photosynthetic capacity is optimized to the environment

Abstract

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Keywords

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