理解和工程化初级植物代谢的进展。

Progress in understanding and engineering primary plant metabolism.

机构信息

Max Planck Institute of Molecular Plant Physiology, Am Muehlenberg 1, 14474 Potsdam-Golm, Germany.

出版信息

Curr Opin Biotechnol. 2013 Apr;24(2):229-38. doi: 10.1016/j.copbio.2012.11.002. Epub 2012 Dec 4.

DOI:10.1016/j.copbio.2012.11.002

PMID:23219183

Abstract

The maximum yield of crop plants depends on the efficiency of conversion of sunlight into biomass. This review summarises recent models that estimate energy conversion efficiency for successive steps in photosynthesis and metabolism. Photorespiration was identified as a major reason for energy loss during photosynthesis and strategies to modify or suppress photorespiration are presented. Energy loss during the conversion of photosynthate to biomass is also large but cannot be modelled as precisely due to incomplete knowledge about pathways and turnover and maintenance costs. Recent research on pathways involved in metabolite transport and interconversion in different organs, and recent insights into energy requirements linked to the production, maintenance and turnover of the apparatus for cellular growth and repair processes are discussed.

摘要

作物的最大产量取决于将阳光转化为生物量的效率。本综述总结了最近的模型，这些模型估计光合作用和代谢过程中连续步骤的能量转换效率。已确定光呼吸是光合作用过程中能量损失的主要原因，并提出了修饰或抑制光呼吸的策略。将光合产物转化为生物量的过程中也会损失大量能量，但由于对途径和周转率以及维持成本的了解不完整，因此无法精确建模。本文讨论了最近关于不同器官中代谢物运输和相互转化途径的研究，以及与细胞生长和修复过程的设备的产生、维持和周转率相关的能量需求的最新见解。

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理解和工程化初级植物代谢的进展。

Progress in understanding and engineering primary plant metabolism.

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