On the need to incorporate sensitivity to CO2 transfer conductance into the Farquhar–von Caemmerer–Berry leaf photosynthesis model
G. J. Ethier,Nigel J. Livingston +1 more
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An alternative A‐C i curve fitting method is presented that accounts for g i through a non-rectangular hyperbola version of the model of Farquhar et al .Abstract:
Virtually all current estimates of the maximum carboxylation rate ( V cmax ) of ribulose-1,5-bisphosphate carboxylase/ oxygenase (Rubisco) and the maximum electron transport rate ( J max ) for C 3 species implicitly assume an infinite CO 2 transfer conductance ( g i ). And yet, most measurements in perennial plant species or in ageing or stressed leaves show that g i imposes a significant limitation on photosynthesis. Herein, we demonstrate that many current parameterizations of the photosynthesis model of Farquhar, von Caemmerer & Berry ( Planta 149, 78‐90, 1980) based on the leaf intercellular CO 2 concentration ( C i ) are incorrect for leaves where g i limits photosynthesis. We show how conventional A‐C i curve (net CO 2 assimilation rate of a leaf ‐ A n ‐ as a function of C i ) fitting methods which rely on a rectangular hyperbola model under the assumption of infinite g i can significantly underestimate V cmax for such leaves. Alternative parameterizations of the conventional method based on a single, apparent Michaelis‐Menten constant for CO 2 evaluated at C i [ K m (CO 2 ) i ] used for all C 3 plants are also not acceptable since the relationship between V cmax and g i is not conserved among species. We present an alternative A‐C i curve fitting method that accounts for g i through a non-rectangular hyperbola version of the model of Farquhar et al . (1980). Simulated and real examples are used to demonstrate how this new approach eliminates the errors of the conventional A‐C i curve fitting method and provides V cmax estimates that are virtually insensitive to g i . Finally, we show how the new A‐C i curve fitting method can be used to estimate the value of the kinetic constants of Rubisco in vivo is presentedread more
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References
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Journal ArticleDOI
A Biochemical Model of Photosynthetic CO 2 Assimilation in Leaves of C 3 Species
TL;DR: Various aspects of the biochemistry of photosynthetic carbon assimilation in C3 plants are integrated into a form compatible with studies of gas exchange in leaves.
Journal ArticleDOI
Some relationships between the biochemistry of photosynthesis and the gas exchange of leaves.
TL;DR: It was found that the response of the rate of CO2 Assimilation to irradiance, partial pressure of O2, p(O2), and temperature was different at low and high intercellular p(CO2), suggesting that CO2 assimilation rate is governed by different processes at lowand high inter cellular p (CO2).
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Cellular mechanisms for heavy metal detoxification and tolerance
TL;DR: A broad overview of the evidence for an involvement of each mechanism in heavy metal detoxification and tolerance is provided.
Journal ArticleDOI
Physiological and environmental regulation of stomatal conductance, photosynthesis and transpiration: a model that includes a laminar boundary layer
TL;DR: In this article, a system of models for the simulation of gas and energy exchange of a leaf of a C3 plant in free air is presented, where the physiological processes are simulated by sub-models that: (a) give net photosynthesis (An) as a function of environmental and leaf parameters and stomatal conductance (gs); (b) give g, as well as the concentration of CO2 and H2O in air at the leaf surface and the current rate of photosynthesis of the leaf.
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Modeling the Exchanges of Energy, Water, and Carbon Between Continents and the Atmosphere
Piers J. Sellers,Robert E. Dickinson,David A. Randall,Alan K. Betts,Forrest G. Hall,Joseph A. Berry,G. J. Collatz,A. S. Denning,Harold A. Mooney,Carlos A. Nobre,N. Sato,Christopher B. Field,Ann Henderson-Sellers +12 more
TL;DR: Modern schemes incorporate biogeochemical and ecological knowledge and, when coupled with advanced climate and ocean models, will be capable of modeling the biological and physical responses of the Earth system to global change, for example, increasing atmospheric carbon dioxide.