Coordination of photosynthetic traits across soil and climate gradients

Andrea C. Westerband; Ian J. Wright; Vincent Maire; Jennifer Paillassa; Iain Colin Prentice; Owen K. Atkin; Keith J. Bloomfield; Lucas A. Cernusak; Ning Dong; Sean M. Gleason; Caio Guilherme Pereira; Hans Lambers; Michelle R. Leishman; Yadvinder Malhi; Rachael H. Nolan

doi:10.1111/gcb.16501

Coordination of photosynthetic traits across soil and climate gradients

Andrea C. Westerband^*, Ian J. Wright, Vincent Maire, Jennifer Paillassa, Iain Colin Prentice, Owen K. Atkin, Keith J. Bloomfield, Lucas A. Cernusak, Ning Dong, Sean M. Gleason, Caio Guilherme Pereira, Hans Lambers, Michelle R. Leishman, Yadvinder Malhi, Rachael H. Nolan

^*Corresponding author for this work

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

15 Citations (Scopus)

Abstract

“Least-cost theory” posits that C₃ plants should balance rates of photosynthetic water loss and carboxylation in relation to the relative acquisition and maintenance costs of resources required for these activities. Here we investigated the dependency of photosynthetic traits on climate and soil properties using a new Australia-wide trait dataset spanning 528 species from 67 sites. We tested the hypotheses that plants on relatively cold or dry sites, or on relatively more fertile sites, would typically operate at greater CO₂ drawdown (lower ratio of leaf internal to ambient CO₂, C_i:C_a) during light-saturated photosynthesis, and at higher leaf N per area (N_area) and higher carboxylation capacity (V_{cmax 25}) for a given rate of stomatal conductance to water vapour, g_sw. These results would be indicative of plants having relatively higher water costs than nutrient costs. In general, our hypotheses were supported. Soil total phosphorus (P) concentration and (more weakly) soil pH exerted positive effects on the N_area–g_sw and V_{cmax 25}–g_sw slopes, and negative effects on C_i:C_a. The P effect strengthened when the effect of climate was removed via partial regression. We observed similar trends with increasing soil cation exchange capacity and clay content, which affect soil nutrient availability, and found that soil properties explained similar amounts of variation in the focal traits as climate did. Although climate typically explained more trait variation than soil did, together they explained up to 52% of variation in the slope relationships and soil properties explained up to 30% of the variation in individual traits. Soils influenced photosynthetic traits as well as their coordination. In particular, the influence of soil P likely reflects the Australia's geologically ancient low-relief landscapes with highly leached soils. Least-cost theory provides a valuable framework for understanding trade-offs between resource costs and use in plants, including limiting soil nutrients.

Original language	English
Pages (from-to)	856-873
Number of pages	18
Journal	Global Change Biology
Volume	29
Issue number	3
DOIs	https://doi.org/10.1111/gcb.16501
Publication status	Published - Feb 2023

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Westerband, A. C., Wright, I. J., Maire, V., Paillassa, J., Prentice, I. C., Atkin, O. K., Bloomfield, K. J., Cernusak, L. A., Dong, N., Gleason, S. M., Guilherme Pereira, C., Lambers, H., Leishman, M. R., Malhi, Y., & Nolan, R. H. (2023). Coordination of photosynthetic traits across soil and climate gradients. Global Change Biology, 29(3), 856-873. https://doi.org/10.1111/gcb.16501

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title = "Coordination of photosynthetic traits across soil and climate gradients",

abstract = "“Least-cost theory” posits that C3 plants should balance rates of photosynthetic water loss and carboxylation in relation to the relative acquisition and maintenance costs of resources required for these activities. Here we investigated the dependency of photosynthetic traits on climate and soil properties using a new Australia-wide trait dataset spanning 528 species from 67 sites. We tested the hypotheses that plants on relatively cold or dry sites, or on relatively more fertile sites, would typically operate at greater CO2 drawdown (lower ratio of leaf internal to ambient CO2, Ci:Ca) during light-saturated photosynthesis, and at higher leaf N per area (Narea) and higher carboxylation capacity (Vcmax 25) for a given rate of stomatal conductance to water vapour, gsw. These results would be indicative of plants having relatively higher water costs than nutrient costs. In general, our hypotheses were supported. Soil total phosphorus (P) concentration and (more weakly) soil pH exerted positive effects on the Narea–gsw and Vcmax 25–gsw slopes, and negative effects on Ci:Ca. The P effect strengthened when the effect of climate was removed via partial regression. We observed similar trends with increasing soil cation exchange capacity and clay content, which affect soil nutrient availability, and found that soil properties explained similar amounts of variation in the focal traits as climate did. Although climate typically explained more trait variation than soil did, together they explained up to 52% of variation in the slope relationships and soil properties explained up to 30% of the variation in individual traits. Soils influenced photosynthetic traits as well as their coordination. In particular, the influence of soil P likely reflects the Australia's geologically ancient low-relief landscapes with highly leached soils. Least-cost theory provides a valuable framework for understanding trade-offs between resource costs and use in plants, including limiting soil nutrients.",

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author = "Westerband, {Andrea C.} and Wright, {Ian J.} and Vincent Maire and Jennifer Paillassa and Prentice, {Iain Colin} and Atkin, {Owen K.} and Bloomfield, {Keith J.} and Cernusak, {Lucas A.} and Ning Dong and Gleason, {Sean M.} and {Guilherme Pereira}, Caio and Hans Lambers and Leishman, {Michelle R.} and Yadvinder Malhi and Nolan, {Rachael H.}",

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doi = "10.1111/gcb.16501",

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AU - Wright, Ian J.

AU - Maire, Vincent

AU - Paillassa, Jennifer

AU - Prentice, Iain Colin

AU - Atkin, Owen K.

AU - Bloomfield, Keith J.

AU - Cernusak, Lucas A.

AU - Dong, Ning

AU - Gleason, Sean M.

AU - Guilherme Pereira, Caio

AU - Lambers, Hans

AU - Leishman, Michelle R.

AU - Malhi, Yadvinder

AU - Nolan, Rachael H.

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AB - “Least-cost theory” posits that C3 plants should balance rates of photosynthetic water loss and carboxylation in relation to the relative acquisition and maintenance costs of resources required for these activities. Here we investigated the dependency of photosynthetic traits on climate and soil properties using a new Australia-wide trait dataset spanning 528 species from 67 sites. We tested the hypotheses that plants on relatively cold or dry sites, or on relatively more fertile sites, would typically operate at greater CO2 drawdown (lower ratio of leaf internal to ambient CO2, Ci:Ca) during light-saturated photosynthesis, and at higher leaf N per area (Narea) and higher carboxylation capacity (Vcmax 25) for a given rate of stomatal conductance to water vapour, gsw. These results would be indicative of plants having relatively higher water costs than nutrient costs. In general, our hypotheses were supported. Soil total phosphorus (P) concentration and (more weakly) soil pH exerted positive effects on the Narea–gsw and Vcmax 25–gsw slopes, and negative effects on Ci:Ca. The P effect strengthened when the effect of climate was removed via partial regression. We observed similar trends with increasing soil cation exchange capacity and clay content, which affect soil nutrient availability, and found that soil properties explained similar amounts of variation in the focal traits as climate did. Although climate typically explained more trait variation than soil did, together they explained up to 52% of variation in the slope relationships and soil properties explained up to 30% of the variation in individual traits. Soils influenced photosynthetic traits as well as their coordination. In particular, the influence of soil P likely reflects the Australia's geologically ancient low-relief landscapes with highly leached soils. Least-cost theory provides a valuable framework for understanding trade-offs between resource costs and use in plants, including limiting soil nutrients.

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U2 - 10.1111/gcb.16501

DO - 10.1111/gcb.16501

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EP - 873

JO - Global Change Biology

JF - Global Change Biology

IS - 3

ER -

Coordination of photosynthetic traits across soil and climate gradients

Abstract

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