Modeling Light Response of Electron Transport Rate and Its Allocation for Ribulose Biphosphate Carboxylation and Oxygenation.

Shuang-Xi Zhou,Zi-Piao Ye,Hong-Lang Duan,Hua-Jing Kang,Ting An,Xiao-Long Yang,Fu-Biao Wang

doi:10.3389/fpls.2020.581851

Abstract

Accurately describing the light response curve of electron transport rate (J–I curve) and allocation of electron flow for ribulose biphosphate (RuBP) carboxylation (J C–I curve) and that for oxygenation (J O–I curve) is fundamental for modeling of light relations of electron flow at the whole-plant and ecosystem scales. The non-rectangular hyperbolic model (hereafter, NH model) has been widely used to characterize light response of net photosynthesis rate (A n; A n–I curve) and J–I curve. However, NH model has been reported to overestimate the maximum A n (A nmax) and the maximum J (J max), largely due to its asymptotic function. Meanwhile, few efforts have been delivered for describing J C–I and J O–I curves. The long-standing challenge on describing A n–I and J–I curves have been resolved by a recently developed A n–I and J–I models (hereafter, Ye model), which adopt a nonasymptotic function. To test whether Ye model can resolve the challenge of NH model in reproducing J–I, J C–I and J O–I curves over light-limited, light-saturated, and photoinhibitory I levels, we compared the performances of Ye model and NH model against measurements on two C3 crops (Triticum aestivum L. and Glycine max L.) grown in field. The results showed that NH model significantly overestimated the A nmax and J max for both species, which can be accurately obtained by Ye model. Furthermore, NH model significantly overestimated the maximum electron flow for carboxylation (J C-max) but not the maximum electron flow for oxygenation (J O-max) for both species, disclosing the reason underlying the long-standing problem of NH model—overestimation of J max and A nmax.

Highlights

Light intensity (I) is one of the most important environmental drivers affecting electron flow and its allocation for carboxylation versus oxygenation of ribulose biphosphate (RuBP)
Anmax and Jmax values returned by Ye model were in very close agreement with the observations for both species (Table 1)
Assessed with an observation-modeling intercomparison approach, the results in this study highlight the robustness of Ye model in accurately reproducing An–I, J–I, JC–I, and JO–I curves and returning key quantities defining the curves, in particular: Anmax, Jmax, JC-max, and JO-max

Summary

Introduction

Light intensity (I) is one of the most important environmental drivers affecting electron flow and its allocation for carboxylation versus oxygenation of ribulose biphosphate (RuBP). Significant difference between observed Anmax values and that estimated by NH model for various species has been widely reported (e.g., Chen et al, 2011; dos Santos et al, 2013; Lobo et al, 2014; Ogawa, 2015; Sun et al, 2015; Quiroz et al, 2017; Poirier-Pocovi et al, 2018; Ye et al, 2020) This long-standing challenge has been resolved by an An–I model, which adopts a nonasymptotic function and can accurately reproduce An–I curve over light-limited, lightsaturated and photoinhibitory I levels (Ye et al, 2013) (hereafter, Ye model)

Objectives

Methods

Results

Discussion

Conclusion