细菌群体感应元件构建和工程应用

周爱林; 刘奕; 巴方; 钟超

doi:10.12211/2096-8280.2020-066

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细菌群体感应元件构建和工程应用

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- 细菌群体感应元件构建和工程应用
- Construction and engineering application of bacterial quorum sensing elements
- 合成生物学 2021年2卷第2期页码：234-246
- 作者机构：
  
  1.上海科技大学物质科学与技术学院，上海 201210
  2.上海科技大学生命科学与技术学院，上海 201210
  3.中国科学院深圳先进技术研究院，深圳合成生物学创新研究院，中国科学院定量工程生物学重点实验室，广东　深圳 518055
  4.中国科学院深圳先进技术研究院，深圳合成生物学创新研究院，材料合成生物学中心，广东　深圳 518055
- 作者简介：
  
  [ "周爱林（1999—），女，主要研究方向为合成生物学的研究。E-mail：zhoual@shanghaitech.edu.cn" ]
  [ "钟超（1979—）,男，博士，研究员。主要研究方向为利用合成生物学技术发展新材料和生物纳米技术，包括基于蛋白的水下黏合胶水和细菌生物被膜活体功能材料。E-mail：chao.zhong@siat.ac.cn" ]
- 基金信息：
  
  中国国家自然科学基金(U1932204);国家重点研发计划(2018YFA0902804);上海市科学技术委员会(17JC1403900)
- DOI：10.12211/2096-8280.2020-066
  中图分类号： Q819
- 收稿：2020-06-05，
  
  修回：2021-02-19，
  
  纸质出版：2021-04-30
- 稿件说明：
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周爱林, 刘奕, 巴方, 钟超. 细菌群体感应元件构建和工程应用[J]. 合成生物学, 2021, 2(2): 234-246

ZHOU Ailin, LIU Yi, BA Fang, ZHONG Chao. Construction and engineering application of bacterial quorum sensing elements[J]. Synthetic Biology Journal, 2021, 2(2): 234-246
周爱林, 刘奕, 巴方, 钟超. 细菌群体感应元件构建和工程应用[J]. 合成生物学, 2021, 2(2): 234-246 DOI： 10.12211/2096-8280.2020-066.

ZHOU Ailin, LIU Yi, BA Fang, ZHONG Chao. Construction and engineering application of bacterial quorum sensing elements[J]. Synthetic Biology Journal, 2021, 2(2): 234-246 DOI： 10.12211/2096-8280.2020-066.

摘要

群体感应现象指的是微生物通过独特的交流方式使不同菌个体间的行为同步，从而展现群体性行为。当前在微生物群体感应系统方面的研究，除了促进或抑制天然群体感应方面的基础研究外，研究人员逐渐开始将群体感应系统引入到合成生物学的工程应用研究，并且将其广泛运用在医学、工业、环境等应用领域。本文主要总结了细菌群体感应元件在构建过程中的常用策略与方法，并探讨了基于群体感应基因元件改造的工程菌在动态代谢调节、周期性振荡呈现、异种菌种间关系的构建等方面的应用。群体感应元件的研究主要包括新群体感应元件的开发和针对已有群体感应元件的优化。通过模拟、优化群体感应元件并将其模块化，研究人员构建了丰富的群体感应基因元件库，使群体感应能被灵活应用于不同场景。另外，通过在细菌中引入群体感应基因回路，可以将单个细菌内部的各类反馈回路较好地拓展到整个细菌群体中，而这种多细胞体系的构建，使得更多复杂的功能得以实现，如通过群体感应实现动态代谢调节从而提高发酵效率，或实现群体周期性振荡以释放肿瘤杀伤药物等。此外，环境中异种微生物的关系也可以通过外源引入群体感应来进行调控，这为微生物的共培养提供了新工具，更为复杂的合成生物学系统的建立提供了新思路。随着机器学习等计算机领域的发展，未来可以更多借助计算机来设计复杂群体感应回路，并对外源群体感应引入后的效果做出更精准的预测。

Abstract

Quorum sensing refers to the specific communication among bacteria which could synchronize individual behaviors to collective benefits. This mechanism relies on the production

detection

and response to extracellular signaling molecules called autoinducers. Based on the understanding of scientific fundamentals underlying the activation and inhibition of natural quorum sensing systems

researchers attempt to introduce quorum sensing into engineering applications as modules or gene parts through synthetic biology

and employ it in fields such as medicine

industry and environment. In this review

strategies and methods used in the construction of quorum sensing system are briefly discussed

and the promising applications of engineered bacteria with quorum sensing for dynamic metabolic reflux

oscillation

and microbial consortia are also highlighted. The construction of quorum sensing elements requires the grasp of its essence

which involves the development of new elements and the optimization of existing ones. By simulating natural quorum sensing systems

and optimizing and modularizing quorum sensing elements

researchers construct libraries for quorum sensing elements

making them possible to employ quorum sensing under different circumstances. Moreover

by introducing quorum sensing

various feedback loops initially possessed by a single bacterium could be extended to the whole population. With the construction of such multicellular quorum sensing systems

more complex functions could be initiated

such as dynamic regulation of metabolic flux for boosting fermentation efficiency

robust production of drugs by collective oscillation and so on. In addition

microbial consortia containing could be manipulated by introducing exogenous quorum sensing systems

providing new tools for microbial co-culture and new ideas for the construction of biological systems with higher complexity. In the future

machine learning will be applied for designing complex quorum sensing circuits and accurately predicting the behavior of exogenous quorum sensing systems in certain microbial population.

关键词

Keywords

references

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