Advances in synthetic biology for photosynthetic carbon assimilation

SHENG Yangyang; XU Xiumei; ZHANG Qiaohong; ZHANG Lixin

doi:10.12211/2096-8280.2022-019

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Advances in synthetic biology for photosynthetic carbon assimilation

Invited Review | 更新时间：2025-03-20

- Advances in synthetic biology for photosynthetic carbon assimilation
- Synthetic Biology Journal Vol. 3, Issue 5, Pages: 870-883(2022)
- 作者机构：
  
  河南大学生命科学学院，省部共建作物逆境适应与改良国家重点实验室，河南开封 475004
- 作者简介：
- 基金信息：
- DOI：10.12211/2096-8280.2022-019
  CLC： Q81
- Received：02 April 2022，
  
  Revised：2022-06-29，
  
  Published：31 October 2022
- 稿件说明：
移动端阅览
盛阳阳，徐秀美，张巧红，张立新. 光合作用碳同化的合成生物学研究进展［J］. 合成生物学， 2022， 3（5）： 870-883

SHENG Yangyang， XU Xiumei， ZHANG Qiaohong， ZHANG Lixin. Advances in synthetic biology for photosynthetic carbon assimilation［J］. Synthetic Biology Journal， 2022， 3（5）： 870-883
盛阳阳，徐秀美，张巧红，张立新. 光合作用碳同化的合成生物学研究进展［J］. 合成生物学， 2022， 3（5）： 870-883 DOI： 10.12211/2096-8280.2022-019.

SHENG Yangyang， XU Xiumei， ZHANG Qiaohong， ZHANG Lixin. Advances in synthetic biology for photosynthetic carbon assimilation［J］. Synthetic Biology Journal， 2022， 3（5）： 870-883 DOI： 10.12211/2096-8280.2022-019.

摘要

随着人口增多及耕地面积的减少，人类对粮食的需求日益增加，因此保障足够的粮食供给尤为重要。光合作用通过光反应和碳同化把无机物转换成有机物，是地球上最重要的化学反应。90%以上的植物干物质来源于光合作用固碳反应，光合作用同化的有机物是作物产量形成的物质基础，因此提高作物光能利用效率是提高作物产量的重要途径。近年来，合成生物学在能源、材料、健康和环境等多领域的快速发展，为提高植物光合效率提供了新的机遇。本文着重讨论了合成生物学在提高光合作用碳同化效率方面的研究进展，主要集中在提高Rubisco酶的羧化活性、引进CO

浓缩机制、降低光呼吸等方面；最后，对新型光合固碳回路进行探讨，通过合成生物学对光合作用碳同化模块进行设计、改造、优化和重组，必将有效提高碳同化效率，最终提高作物产量。

Abstract

With the increase of population and the decrease of cultivated land

human demand for food is increasing. Therefore

it is particularly important to ensure adequate food supply. Photosynthesis is the most important chemical reaction on the earth

which converts inorganic matter into organic matter through light reaction and carbon assimilation. More than 90% of plant dry matter comes from the carbon fixation reaction of photosynthesis. The assimilated organic matter of photosynthesis is the material basis for the formation of crop yield. Therefore

improving the efficiency of crop light energy utilization is an important way to improve crop yield. In recent years

the rapid development of synthetic biology in the fields of energy

materials

health and environment has provided new opportunities for improving plant photosynthetic efficiency. This paper highlights the research progress of synthetic biology in improving the carbon assimilation efficiency of photosynthesis

mainly focusing on: (1) Improving the carboxylation activity of Rubisco enzymes

including identifying Rubisco enzymes with high carboxylation activity

optimizing gene expression regulatory sequences on Rubisco

and co-expressing Rubisco chaperone proteins; (2) Introducing CO

concentrating mechanisms

including C

photosynthetic enzymes

cyanobacterial transporter proteins

and cyanobacterial carboxysomes; (3) Reducing photorespiration through the introduction of four photorespiratory branches: chloroplast glycerate bypass

peroxisomal glycerate bypass

chloroplast glycolate

oxidation bypass

and 3-hydroxypropionate bypass

and the exploration of new branches of photorespiration; Finally

the new photosynthetic carbon fixation circuit is discussed. The design

transformation

optimization and reorganization of photosynthetic carbon assimilation module through synthetic biology will effectively improve the efficiency of carbon assimilation and ultimately improve crop yield.

关键词

Keywords

references

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