Photosynthetic responses to temperature across the tropics: A meta-analytic approach

Kelsey R. Carter; Molly A. Cavaleri; Owen K. Atkin; Nur H.A. Bahar; Alexander W. Cheesman; Zineb Choury; Kristine Y. Crous; Christopher E. Doughty; Mirindi E. Dusenge; Kim S. Ely; John R. Evans; Jéssica Fonseca Silva; Alida C. Mau; Belinda E. Medlyn; Patrick Meir; Richard J. Norby; Jennifer Read; Sasha C. Reed; Peter B. Reich; Alistair Rogers; Shawn P. Serbin; Martijn Slot; Elsa C. Schwartz; Edgard S. Tribuzy; Johan Uddling; Angelica Vårhammar; Anthony P. Walker; Klaus Winter; Tana E. Wood; Jin Wu

doi:10.1093/aob/mcae206

Photosynthetic responses to temperature across the tropics: A meta-analytic approach

Kelsey R. Carter, Molly A. Cavaleri, Owen K. Atkin, Nur H.A. Bahar, Alexander W. Cheesman, Zineb Choury, Kristine Y. Crous, Christopher E. Doughty, Mirindi E. Dusenge, Kim S. Ely, John R. Evans, Jéssica Fonseca Silva, Alida C. Mau, Belinda E. Medlyn, Patrick Meir, Richard J. Norby, Jennifer Read, Sasha C. Reed, Peter B. Reich, Alistair RogersShawn P. Serbin, Martijn Slot, Elsa C. Schwartz, Edgard S. Tribuzy, Johan Uddling, Angelica Vårhammar, Anthony P. Walker, Klaus Winter, Tana E. Wood, Jin Wu

Ecosystem Processes

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

Abstract

Background and Aims Tropical forests exchange more carbon dioxide (CO2) with the atmosphere than any other terrestrial biome. Yet, uncertainty in the projected carbon balance over the next century is roughly three times greater for the tropics than other for ecosystems. Our limited knowledge of tropical plant physiological responses, including photosynthetic, to climate change is a substantial source of uncertainty in our ability to forecast the global terrestrial carbon sink. Methods We used a meta-analytic approach, focusing on tropical photosynthetic temperature responses, to address this knowledge gap. Our dataset, gleaned from 18 independent studies, included leaf-level light-saturated photosynthetic (Asat) temperature responses from 108 woody species, with additional temperature parameters (35 species) and rates (250 species) of both maximum rates of electron transport (Jmax) and Rubisco carboxylation (Vcmax). We investigated how these parameters responded to mean annual temperature (MAT), temperature variability, aridity and elevation, as well as also how responses differed among successional strategy, leaf habit and light environment. Key Results Optimum temperatures for Asat (ToptA) and Jmax (ToptJ) increased with MAT but not for Vcmax (ToptV). Although photosynthetic rates were higher for 'light' than 'shaded' leaves, light conditions did not generate differences in temperature response parameters. ToptA did not differ with successional strategy, but early successional species had ~4 °C wider thermal niches than mid/late species. Semi-deciduous species had ~1 °C higher ToptA than broadleaf evergreen species. Most global modelling efforts consider all tropical forests as a single 'broadleaf evergreen' functional type, but our data show that tropical species with different leaf habits display distinct temperature responses that should be included in modelling efforts. Conclusions This novel research will inform modelling efforts to quantify tropical ecosystem carbon cycling and provide more accurate representations of how these key ecosystems will respond to altered temperature patterns in the face of climate warming.

Original language	English
Pages (from-to)	1293-1310
Number of pages	18
Journal	Annals of Botany
Volume	135
Issue number	7
DOIs	https://doi.org/10.1093/aob/mcae206
State	Published - Jun 1 2025

Funding

This work was supported by United States Geological Survey John Wesley Powell Center Working Center for Analysis and Synthesis. Funding was also provided by United States Department of Energy Office of Science, Biological and Environmental Research Program awards [DE-SC-0012000, DE-SC-0011806, DE-SC-0018942, 89243018S-SC-000014 and 89243018S-SC-000017]. Additional funding and support was provided by USDA Forest Service International Institute of Tropical Forestry (IITF). All research conducted at IITF is supported by the University of Puerto Rico. ORNL is managed by UT-Battelle, LLC, for the Department of Energy under contract DE-AC05-1008 00OR22725. APW, SPS, AR and KSE. were supported by the Next Generation Ecosystem Experiments-Tropics (NGEE Tropics), funded by the United States Department of Energy, Office of Science, Office of Biological and Environmental Research, AR, KSE and SPS were also partially supported by the United States Department of Energy contract No. DE-SC0012704 to Brookhaven National Laboratory, and AR and KSE by the United States Department of Energy Contract No. DE-AC02-05CH11231 to Lawrence Berkeley National Laboratory. KYC gratefully acknowledges the Australian Research Council [DE160101484] supporting data collection on some Australian species. The contribution of PBR was supported by a United States National Science Foundation Biological Integration Institutes grant [DBI-2021898]. Any use of trade, firm or product names is for descriptive purposes only and does not imply endorsement by the United States Government. JW acknowledges the funding support from the National Natural Science Foundation of China [#31922090] and the Innovation and Technology Fund (funding support to State Key Laboratories in Hong Kong of Agrobiotechnology) of the HKSAR, China. This work was supported by United States Geological Survey John Wesley Powell Center Working Center for Analysis and Synthesis. Funding was also provided by United States Department of Energy Office of Science, Biological and Environmental Research Program awards [DE-SC-0012000, DE-SC-0011806, DE-SC-0018942, 89243018S-SC-000014 and 89243018S-SC-000017]. Additional funding and support was provided by USDA Forest Service International Institute of Tropical Forestry (IITF). All research conducted at IITF is supported by the University of Puerto Rico. ORNL is managed by UT-Battelle, LLC, for the Department of Energy under contract DE-AC05-1008 00OR22725. APW, SPS, AR and KSE. were supported by the Next Generation Ecosystem Experiments-Tropics (NGEE Tropics), funded by the United States Department of Energy, Office of Science, Office of Biological and Environmental Research, AR, KSE and SPS were also partially supported by the United States Department of Energy contract No. DE-SC0012704 to Brookhaven National Laboratory, and AR and KSE by the United States Department of Energy Contract No. DE-AC02-05CH11231 to Lawrence Berkeley National Laboratory. KYC gratefully acknowledges the Australian Research Council [DE160101484] collection on some Australian species. The contribution of PBR was supported by a United States National Science Foundation Biological Integration Institutes grant [DBI-2021898]. Any use of trade, firm or product names is for descriptive purposes only and does not imply endorsement by the United States Government. JW acknowledges the funding support from the National Natural Science Foundation of China [#31922090] and the Innovation and Technology Fund (funding support to State Key Laboratories in Hong Kong of Agrobiotechnology) of the HKSAR, China. ACKNOWLEDGEMENTS

Keywords

A-C curves
maximum rate of Rubisco carboxylation (V)
maximum rate of photosynthetic electron transport (J)
meta-analysis
photosynthesis
temperature response
tropics

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10.1093/aob/mcae206

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Carter, K. R., Cavaleri, M. A., Atkin, O. K., Bahar, N. H. A., Cheesman, A. W., Choury, Z., Crous, K. Y., Doughty, C. E., Dusenge, M. E., Ely, K. S., Evans, J. R., Silva, J. F., Mau, A. C., Medlyn, B. E., Meir, P., Norby, R. J., Read, J., Reed, S. C., Reich, P. B., ... Wu, J. (2025). Photosynthetic responses to temperature across the tropics: A meta-analytic approach. Annals of Botany, 135(7), 1293-1310. https://doi.org/10.1093/aob/mcae206

@article{32f4872c42c74f178917b75c87d4d377,

title = "Photosynthetic responses to temperature across the tropics: A meta-analytic approach",

abstract = "Background and Aims Tropical forests exchange more carbon dioxide (CO2) with the atmosphere than any other terrestrial biome. Yet, uncertainty in the projected carbon balance over the next century is roughly three times greater for the tropics than other for ecosystems. Our limited knowledge of tropical plant physiological responses, including photosynthetic, to climate change is a substantial source of uncertainty in our ability to forecast the global terrestrial carbon sink. Methods We used a meta-analytic approach, focusing on tropical photosynthetic temperature responses, to address this knowledge gap. Our dataset, gleaned from 18 independent studies, included leaf-level light-saturated photosynthetic (Asat) temperature responses from 108 woody species, with additional temperature parameters (35 species) and rates (250 species) of both maximum rates of electron transport (Jmax) and Rubisco carboxylation (Vcmax). We investigated how these parameters responded to mean annual temperature (MAT), temperature variability, aridity and elevation, as well as also how responses differed among successional strategy, leaf habit and light environment. Key Results Optimum temperatures for Asat (ToptA) and Jmax (ToptJ) increased with MAT but not for Vcmax (ToptV). Although photosynthetic rates were higher for 'light' than 'shaded' leaves, light conditions did not generate differences in temperature response parameters. ToptA did not differ with successional strategy, but early successional species had \textasciitilde{}4 °C wider thermal niches than mid/late species. Semi-deciduous species had \textasciitilde{}1 °C higher ToptA than broadleaf evergreen species. Most global modelling efforts consider all tropical forests as a single 'broadleaf evergreen' functional type, but our data show that tropical species with different leaf habits display distinct temperature responses that should be included in modelling efforts. Conclusions This novel research will inform modelling efforts to quantify tropical ecosystem carbon cycling and provide more accurate representations of how these key ecosystems will respond to altered temperature patterns in the face of climate warming.",

keywords = "A-C curves, maximum rate of Rubisco carboxylation (V), maximum rate of photosynthetic electron transport (J), meta-analysis, photosynthesis, temperature response, tropics",

author = "Carter, \{Kelsey R.\} and Cavaleri, \{Molly A.\} and Atkin, \{Owen K.\} and Bahar, \{Nur H.A.\} and Cheesman, \{Alexander W.\} and Zineb Choury and Crous, \{Kristine Y.\} and Doughty, \{Christopher E.\} and Dusenge, \{Mirindi E.\} and Ely, \{Kim S.\} and Evans, \{John R.\} and Silva, \{J{\'e}ssica Fonseca\} and Mau, \{Alida C.\} and Medlyn, \{Belinda E.\} and Patrick Meir and Norby, \{Richard J.\} and Jennifer Read and Reed, \{Sasha C.\} and Reich, \{Peter B.\} and Alistair Rogers and Serbin, \{Shawn P.\} and Martijn Slot and Schwartz, \{Elsa C.\} and Tribuzy, \{Edgard S.\} and Johan Uddling and Angelica V{\aa}rhammar and Walker, \{Anthony P.\} and Klaus Winter and Wood, \{Tana E.\} and Jin Wu",

year = "2025",

month = jun,

day = "1",

doi = "10.1093/aob/mcae206",

language = "English",

volume = "135",

pages = "1293--1310",

journal = "Annals of Botany",

issn = "0305-7364",

publisher = "Oxford University Press",

number = "7",

}

Carter, KR, Cavaleri, MA, Atkin, OK, Bahar, NHA, Cheesman, AW, Choury, Z, Crous, KY, Doughty, CE, Dusenge, ME, Ely, KS, Evans, JR, Silva, JF, Mau, AC, Medlyn, BE, Meir, P, Norby, RJ, Read, J, Reed, SC, Reich, PB, Rogers, A, Serbin, SP, Slot, M, Schwartz, EC, Tribuzy, ES, Uddling, J, Vårhammar, A, Walker, AP, Winter, K, Wood, TE & Wu, J 2025, 'Photosynthetic responses to temperature across the tropics: A meta-analytic approach', Annals of Botany, vol. 135, no. 7, pp. 1293-1310. https://doi.org/10.1093/aob/mcae206

TY - JOUR

T1 - Photosynthetic responses to temperature across the tropics

T2 - A meta-analytic approach

AU - Carter, Kelsey R.

AU - Cavaleri, Molly A.

AU - Atkin, Owen K.

AU - Bahar, Nur H.A.

AU - Cheesman, Alexander W.

AU - Choury, Zineb

AU - Crous, Kristine Y.

AU - Doughty, Christopher E.

AU - Dusenge, Mirindi E.

AU - Ely, Kim S.

AU - Evans, John R.

AU - Silva, Jéssica Fonseca

AU - Mau, Alida C.

AU - Medlyn, Belinda E.

AU - Meir, Patrick

AU - Norby, Richard J.

AU - Read, Jennifer

AU - Reed, Sasha C.

AU - Reich, Peter B.

AU - Rogers, Alistair

AU - Serbin, Shawn P.

AU - Slot, Martijn

AU - Schwartz, Elsa C.

AU - Tribuzy, Edgard S.

AU - Uddling, Johan

AU - Vårhammar, Angelica

AU - Walker, Anthony P.

AU - Winter, Klaus

AU - Wood, Tana E.

AU - Wu, Jin

PY - 2025/6/1

Y1 - 2025/6/1

N2 - Background and Aims Tropical forests exchange more carbon dioxide (CO2) with the atmosphere than any other terrestrial biome. Yet, uncertainty in the projected carbon balance over the next century is roughly three times greater for the tropics than other for ecosystems. Our limited knowledge of tropical plant physiological responses, including photosynthetic, to climate change is a substantial source of uncertainty in our ability to forecast the global terrestrial carbon sink. Methods We used a meta-analytic approach, focusing on tropical photosynthetic temperature responses, to address this knowledge gap. Our dataset, gleaned from 18 independent studies, included leaf-level light-saturated photosynthetic (Asat) temperature responses from 108 woody species, with additional temperature parameters (35 species) and rates (250 species) of both maximum rates of electron transport (Jmax) and Rubisco carboxylation (Vcmax). We investigated how these parameters responded to mean annual temperature (MAT), temperature variability, aridity and elevation, as well as also how responses differed among successional strategy, leaf habit and light environment. Key Results Optimum temperatures for Asat (ToptA) and Jmax (ToptJ) increased with MAT but not for Vcmax (ToptV). Although photosynthetic rates were higher for 'light' than 'shaded' leaves, light conditions did not generate differences in temperature response parameters. ToptA did not differ with successional strategy, but early successional species had ~4 °C wider thermal niches than mid/late species. Semi-deciduous species had ~1 °C higher ToptA than broadleaf evergreen species. Most global modelling efforts consider all tropical forests as a single 'broadleaf evergreen' functional type, but our data show that tropical species with different leaf habits display distinct temperature responses that should be included in modelling efforts. Conclusions This novel research will inform modelling efforts to quantify tropical ecosystem carbon cycling and provide more accurate representations of how these key ecosystems will respond to altered temperature patterns in the face of climate warming.

AB - Background and Aims Tropical forests exchange more carbon dioxide (CO2) with the atmosphere than any other terrestrial biome. Yet, uncertainty in the projected carbon balance over the next century is roughly three times greater for the tropics than other for ecosystems. Our limited knowledge of tropical plant physiological responses, including photosynthetic, to climate change is a substantial source of uncertainty in our ability to forecast the global terrestrial carbon sink. Methods We used a meta-analytic approach, focusing on tropical photosynthetic temperature responses, to address this knowledge gap. Our dataset, gleaned from 18 independent studies, included leaf-level light-saturated photosynthetic (Asat) temperature responses from 108 woody species, with additional temperature parameters (35 species) and rates (250 species) of both maximum rates of electron transport (Jmax) and Rubisco carboxylation (Vcmax). We investigated how these parameters responded to mean annual temperature (MAT), temperature variability, aridity and elevation, as well as also how responses differed among successional strategy, leaf habit and light environment. Key Results Optimum temperatures for Asat (ToptA) and Jmax (ToptJ) increased with MAT but not for Vcmax (ToptV). Although photosynthetic rates were higher for 'light' than 'shaded' leaves, light conditions did not generate differences in temperature response parameters. ToptA did not differ with successional strategy, but early successional species had ~4 °C wider thermal niches than mid/late species. Semi-deciduous species had ~1 °C higher ToptA than broadleaf evergreen species. Most global modelling efforts consider all tropical forests as a single 'broadleaf evergreen' functional type, but our data show that tropical species with different leaf habits display distinct temperature responses that should be included in modelling efforts. Conclusions This novel research will inform modelling efforts to quantify tropical ecosystem carbon cycling and provide more accurate representations of how these key ecosystems will respond to altered temperature patterns in the face of climate warming.

KW - A-C curves

KW - maximum rate of Rubisco carboxylation (V)

KW - maximum rate of photosynthetic electron transport (J)

KW - meta-analysis

KW - photosynthesis

KW - temperature response

KW - tropics

UR - https://www.scopus.com/pages/publications/105013292377

U2 - 10.1093/aob/mcae206

DO - 10.1093/aob/mcae206

M3 - Article

C2 - 39663400

AN - SCOPUS:105013292377

SN - 0305-7364

VL - 135

SP - 1293

EP - 1310

JO - Annals of Botany

JF - Annals of Botany

IS - 7

ER -

Photosynthetic responses to temperature across the tropics: A meta-analytic approach

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