微藻光驱固碳合成技术的发展现状与未来展望

崔金玉; 张爱娣; 栾国栋; 吕雪峰

doi:10.12211/2096-8280.2022-005

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微藻光驱固碳合成技术的发展现状与未来展望

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- 微藻光驱固碳合成技术的发展现状与未来展望
  封面论文
- Engineering microalgae for photosynthetic biosynthesis： progress and prospect
- 合成生物学 2022年3卷第5期页码：884-900
- 作者机构：
  
  1.中国科学院青岛生物能源与过程研究所，中国科学院生物燃料重点实验室，山东青岛 266101
  2.山东能源研究院，山东青岛 266101
  3.青岛新能源山东省实验室，山东青岛 266101
  4.中南林业科技大学，生命科学与技术学院，湖南长沙 410004
- 作者简介：
  
  [ "崔金玉（1989—），女，博士，博士后。主要从事光合蓝细菌代谢工程相关研究，包括利用合成生物学和系统生物学等策略开发高附加产值化学品和优化底盘菌株抗逆性能。E-mail：cuijinyu@qibebt.ac.cn" ]
  [ "吕雪峰（1974—），男，博士，研究员，博士生导师。主要从事合成生物学与绿色生物制造领域的研究，在光驱固碳产能蓝细菌的人工设计与构建及真菌天然产物药物等方面取得系列学术成果。 E-mail：lvxf@qibebt.ac.cn" ]
- 基金信息：
  
  国家重点研发计划(2021YFA0909700);中国博士后科学基金第70批面上项目(2021M703320)
- DOI：10.12211/2096-8280.2022-005
  中图分类号： Q815
- 收稿：2022-01-19，
  
  修回：2022-03-31，
  
  纸质出版：2022-10-31
- 稿件说明：
移动端阅览
崔金玉，张爱娣，栾国栋，吕雪峰. 微藻光驱固碳合成技术的发展现状与未来展望［J］. 合成生物学， 2022， 3（5）： 884-900

CUI Jinyu， ZHANG Aidi， LUAN Guodong， LYU Xuefeng. Engineering microalgae for photosynthetic biosynthesis： progress and prospect［J］. Synthetic Biology Journal， 2022， 3（5）： 884-900
崔金玉，张爱娣，栾国栋，吕雪峰. 微藻光驱固碳合成技术的发展现状与未来展望［J］. 合成生物学， 2022， 3（5）： 884-900 DOI： 10.12211/2096-8280.2022-005.

CUI Jinyu， ZHANG Aidi， LUAN Guodong， LYU Xuefeng. Engineering microalgae for photosynthetic biosynthesis： progress and prospect［J］. Synthetic Biology Journal， 2022， 3（5）： 884-900 DOI： 10.12211/2096-8280.2022-005.

摘要

发展CO

的高效资源化利用技术可同时缓解迫切的环境和能源压力，是实现“双碳”目标的重要途径。微藻是重要的光合固碳微生物，是生物圈初级生产力的主要来源，也是研究光合作用的重要模式体系。近年来，微藻又被视为极具潜力的新型微生物光合平台，具有将太阳能和CO

直接转化为各种生物基产品的潜力，该生产模式被称为光驱固碳合成技术，可以同时起到固碳减排和绿色合成的效果，是有望助力“双碳”战略目标实现的新型生物制造技术路线。微藻光驱固碳合成技术本质上是通过微藻光合代谢网络重塑实现CO

的资源化利用，对该方面本文系统总结了“拆盲盒”“挤海绵”“动刀子”3种基本开发模式的研究进展、重要突破和代表性应用示范。而微藻

光合代谢网络的深度重塑，又有效扩展了基于微藻光驱固碳合成过程的技术应用场景，在这一方面，本文着重总结微藻生物技术与生物医学、生物光伏、生物航天技术等新型应用场景和技术领域的交叉融合。最后，还针对微藻光驱固碳合成技术在应用中面临的挑战，提出应该重点从合成生物学工具箱开发、高效光合平台开发、规模化培养防污染和防逃逸策略开发等几个环节进行攻关，以加强微藻光驱固碳合成过程的可控制性和可应用性。

Abstract

The development of highly efficient CO

utilization technologies can alleviate the urgent pressure on the environment and energy

playing a vital role in achieving the goal of “carbon peak and neutrality”. Microalgae are an important group of photoautotrophic microorganisms

providing the main source of primary productivity in the biosphere

and also serving as important model organisms for photosynthesis research. In recent years

microalgae have also been considered as promising chassis for photosynthetic biosynthesis

directly converting solar energy and carbon dioxide into various bio-based products. This technological route is called photosynthetic biomanufacturing

which possesses the advantages of simultaneous carbon fixation and clean production. This review focuses on the perspectives of development models and application scenarios

and suggests trends related to the further development of photosynthetic biomanufacturing. Regarding the efforts to harness and utilize photosynthetic carbon flow in microalgae cells

we summarized and compared three widely adopted strategies

including novel species screening

environmental perturbations

and genetic engineering. The research progress

significant breakthrough

and representative application demonstration of development models were systematically summarized. In the future

the combination of promising chassis cells with desired industrial properties

systematic metabolic engineering to remodel the native metabolism

and specific environmental treatments to maximize synthesis capacities could be expected to generate next-generation advanced microalgae cell factories. The optimized microalgae cell factories with desired photosynthesis and biosynthesis properties could be expected to pl

ay important roles in the areas of biomedical therapy

biophotovoltaics

and bioastronautics through interdisciplinary technology cooperation and integrations. Microalgal synthetic biology is also expect to focus on solving emerging problems rising from new application scenarios and larger application scales

including the development and optimization of the synthetic biology toolboxes

engineering chassis cells toward more efficient photosynthesis

the development of anti-biocontamination and biosafety strategies for large-scale cultivation. Taken together

this review provides useful and updated information to facilitate the development of photosynthetic biosynthesis route with carbon fixation and clean production

providing certain feasible solutions for the "carbon peak and neutrality".

关键词

Keywords

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