景天酸代谢连续体的代谢模型揭示了景天酸代谢进化过程中淀粉/糖-苹果酸循环的建立。

Metabolic Modeling of the C-CAM Continuum Revealed the Establishment of a Starch/Sugar-Malate Cycle in CAM Evolution.

作者信息

Tay Ignacius Y Y, Odang Kristoforus Bryant, Cheung C Y Maurice

机构信息

Yale-NUS College, Singapore, Singapore.

出版信息

Front Plant Sci. 2021 Jan 14;11:573197. doi: 10.3389/fpls.2020.573197. eCollection 2020.

DOI:10.3389/fpls.2020.573197

PMID:33584741

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7874232/

Abstract

The evolution of Crassulacean acid metabolism (CAM) is thought to be along a C-CAM continuum including multiple variations of CAM such as CAM cycling and CAM idling. Here, we applied large-scale constraint-based modeling to investigate the metabolism and energetics of plants operating in C, CAM, CAM cycling, and CAM idling. Our modeling results suggested that CAM cycling and CAM idling could be potential evolutionary intermediates in CAM evolution by establishing a starch/sugar-malate cycle. Our model analysis showed that by varying CO exchange during the light period, as a proxy of stomatal conductance, there exists a C-CAM continuum with gradual metabolic changes, supporting the notion that evolution of CAM from C could occur solely through incremental changes in metabolic fluxes. Along the C-CAM continuum, our model predicted changes in metabolic fluxes not only through the starch/sugar-malate cycle that is involved in CAM photosynthetic CO fixation but also other metabolic processes including the mitochondrial electron transport chain and the tricarboxylate acid cycle at night. These predictions could guide engineering efforts in introducing CAM into C crops for improved water use efficiency.

摘要

景天酸代谢（CAM）的进化被认为是沿着一个C - CAM连续体进行的，其中包括CAM的多种变体，如CAM循环和CAM闲置。在此，我们应用大规模基于约束的建模方法，来研究在C途径、CAM途径、CAM循环和CAM闲置状态下运行的植物的代谢和能量学。我们的建模结果表明，CAM循环和CAM闲置可能是CAM进化过程中的潜在进化中间体，通过建立淀粉/糖 - 苹果酸循环实现。我们的模型分析表明，通过改变光周期中的CO₂交换（作为气孔导度的替代指标），存在一个具有逐渐代谢变化的C - CAM连续体，支持了CAM从C途径进化可能仅通过代谢通量的增量变化发生的观点。沿着C - CAM连续体，我们的模型预测了代谢通量的变化，不仅通过参与CAM光合CO₂固定的淀粉/糖 - 苹果酸循环，还包括夜间的其他代谢过程，如线粒体电子传递链和三羧酸循环。这些预测可为将CAM引入C作物以提高水分利用效率的工程努力提供指导。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3095/7874232/6b283b7847c0/fpls-11-573197-g001.jpg

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景天酸代谢连续体的代谢模型揭示了景天酸代谢进化过程中淀粉/糖-苹果酸循环的建立。

Metabolic Modeling of the C-CAM Continuum Revealed the Establishment of a Starch/Sugar-Malate Cycle in CAM Evolution.

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