Using the inner membrane of Escherichia coli as a scaffold to anchor enzymes for metabolic flux enhancement

IF 3.9 4区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Engineering in Life Sciences Pub Date : 2023-01-10 DOI:10.1002/elsc.202200034

You Wang, Yushu Wang, Yuqi Wu, Yang Suo, Huaqing Guo, Yineng Yu, Ruonan Yin, Rui Xi, Jiajie Wu, Nan Hua, Yuehan Zhang, Shaobo Zhang, Zhenming Jin, Lin He, Gang Ma

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Abstract

Clustering enzymes in the same metabolic pathway is a natural strategy to enhance productivity. Synthetic protein, RNA and DNA scaffolds have been designed to artificially cluster multiple enzymes in the cell, which require complex construction processes and possess limited slots for target enzymes. We utilized the Escherichia coli inner cell membrane as a native scaffold to cluster four fatty acid synthases (FAS) and achieved to improve the efficiency of fatty acid synthesis in vivo. The construction strategy is as simple as fusing target enzymes to the N-terminus or C-terminus of the membrane anchor protein (Lgt), and the number of anchored enzymes is not restricted. This novel device not only presents a similar efficiency in clustering multiple enzymes to that of other artificial scaffolds but also promotes the product secretion, driving the entire metabolic flux forward and further increasing the gross yield compared with that in a cytoplasmic scaffold system.

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利用大肠杆菌内膜作为支架锚定酶增强代谢通量

将酶聚集在同一代谢途径中是提高生产力的自然策略。合成蛋白质、RNA和DNA支架已被设计用于在细胞中人工聚集多种酶，这些酶需要复杂的构建过程，并且具有有限的靶酶槽。我们利用大肠杆菌内细胞膜作为天然支架对四种脂肪酸合成酶（FAS）进行聚类，从而提高了体内脂肪酸合成的效率。构建策略就像将靶酶融合到膜锚定蛋白（Lgt）的N末端或C末端一样简单，并且锚定酶的数量不受限制。与细胞质支架系统相比，这种新型装置不仅在聚集多种酶方面表现出与其他人工支架类似的效率，而且还能促进产物分泌，推动整个代谢通量向前发展，并进一步提高总产量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Engineering in Life Sciences 工程技术-生物工程与应用微生物

CiteScore

6.40

自引率

3.70%

发文量

审稿时长

3 months

期刊介绍： Engineering in Life Sciences (ELS) focuses on engineering principles and innovations in life sciences and biotechnology. Life sciences and biotechnology covered in ELS encompass the use of biomolecules (e.g. proteins/enzymes), cells (microbial, plant and mammalian origins) and biomaterials for biosynthesis, biotransformation, cell-based treatment and bio-based solutions in industrial and pharmaceutical biotechnologies as well as in biomedicine. ELS especially aims to promote interdisciplinary collaborations among biologists, biotechnologists and engineers for quantitative understanding and holistic engineering (design-built-test) of biological parts and processes in the different application areas.