可编程生物分子开关用于重新布线大肠杆菌中的通量。

Programmable biomolecular switches for rewiring flux in Escherichia coli.

机构信息

State Key Laboratory of Food Science and Technology, Jiangnan University, Wuxi, 214122, China.

Key Laboratory of Industrial Biotechnology, Ministry of Education, Jiangnan University, Wuxi, 214122, China.

出版信息

Nat Commun. 2019 Aug 21;10(1):3751. doi: 10.1038/s41467-019-11793-7.

DOI:10.1038/s41467-019-11793-7

PMID:31434894

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6704175/

Abstract

Synthetic biology aims to develop programmable tools to perform complex functions such as redistributing metabolic flux in industrial microorganisms. However, development of protein-level circuits is limited by availability of designable, orthogonal, and composable tools. Here, with the aid of engineered viral proteases and proteolytic signals, we build two sets of controllable protein units, which can be rationally configured to three tools. Using a protease-based dynamic regulation circuit to fine-tune metabolic flow, we achieve 12.63 g L shikimate titer in minimal medium without inducer. In addition, the carbon catabolite repression is alleviated by protease-based inverter-mediated flux redistribution under multiple carbon sources. By coordinating reaction rate using a protease-based oscillator in E. coli, we achieve D-xylonate productivity of 7.12 g L h with a titer of 199.44 g L. These results highlight the applicability of programmable protein switches to metabolic engineering for valuable chemicals production.

摘要

合成生物学旨在开发可编程工具，以执行复杂功能，例如在工业微生物中重新分配代谢通量。然而，蛋白质水平的电路的开发受到可用的可设计、正交和可组合工具的限制。在这里，借助工程病毒蛋白酶和蛋白水解信号，我们构建了两套可控的蛋白质单元，它们可以被合理地配置为三种工具。利用基于蛋白酶的动态调节回路精细调节代谢流，我们在没有诱导剂的最小培养基中实现了 12.63 g/L 的莽草酸产量。此外，基于蛋白酶的反相器介导的通量再分配缓解了碳分解代谢物的抑制作用，在多种碳源下。通过在大肠杆菌中使用基于蛋白酶的振荡器来协调反应速率，我们实现了 7.12 g/L/h 的 D-木糖酸盐生产力，浓度为 199.44 g/L。这些结果突出了可编程蛋白开关在有价值化学品生产中的代谢工程中的适用性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6e8e/6704175/dbbe66970282/41467_2019_11793_Fig1_HTML.jpg

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可编程生物分子开关用于重新布线大肠杆菌中的通量。

Programmable biomolecular switches for rewiring flux in Escherichia coli.

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