红霉素生物合成的前体供应：基于丙酰化修饰的丙酸同化途径工程

Precursor Supply for Erythromycin Biosynthesis: Engineering of Propionate Assimilation Pathway Based on Propionylation Modification.

作者信息

You Di, Wang Miao-Miao, Yin Bin-Cheng, Ye Bang-Ce

机构信息

Laboratory of Biosystems and Microanalysis, State Key Laboratory of Bioreactor Engineering , East China University of Science and Technology , Shanghai 200237 , China.

Institute of Engineering Biology and Health, Collaborative Innovation Center of Yangtze River Delta Region Green Pharmaceuticals, College of Pharmaceutical Sciences , Zhejiang University of Technology , Hangzhou 310014 , Zhejiang , China.

出版信息

ACS Synth Biol. 2019 Feb 15;8(2):371-380. doi: 10.1021/acssynbio.8b00396. Epub 2019 Feb 4.

DOI:10.1021/acssynbio.8b00396

PMID:30657660

Abstract

Erythromycin is necessary in medical treatment and known to be biosynthesized with propionyl-CoA as direct precursor. Oversupply of propionyl-CoA induced hyperpropionylation, which was demonstrated as harmful for erythromycin synthesis in Saccharopolyspora erythraea. Herein, we identified three propionyl-CoA synthetases regulated by propionylation, and one propionyl-CoA synthetase SACE_1780 revealed resistance to propionylation. A practical strategy for raising the precursor (propionyl-CoA) supply bypassing the feedback inhibition caused by propionylation was developed through two approaches: deletion of the propionyltransferase AcuA, and SACE_1780 overexpression. The constructed Δ acuA strain presented a 10% increase in erythromycin yield; SACE_1780 overexpression strain produced 33% higher erythromycin yield than the wildtype strain NRRL2338 and 22% higher erythromycin yield than the industrial high yield Ab strain. These findings uncover the role of protein acylation in precursor supply for antibiotics biosynthesis and provide efficient post-translational modification-metabolic engineering strategy (named as PTM-ME) in synthetic biology for improvement of secondary metabolites.

摘要

红霉素在医学治疗中不可或缺，已知其以丙酰辅酶A作为直接前体进行生物合成。丙酰辅酶A的过量供应会导致高丙酰化，这对红色糖多孢菌中红霉素的合成有害。在此，我们鉴定了三种受丙酰化调节的丙酰辅酶A合成酶，其中一种丙酰辅酶A合成酶SACE_1780对丙酰化具有抗性。通过两种方法开发了一种提高前体（丙酰辅酶A）供应的实用策略，以绕过丙酰化引起的反馈抑制：删除丙酰转移酶AcuA和过表达SACE_1780。构建的ΔacuA菌株的红霉素产量提高了10%；SACE_1780过表达菌株的红霉素产量比野生型菌株NRRL2338高33%，比工业高产Ab菌株高22%。这些发现揭示了蛋白质酰化在抗生素生物合成前体供应中的作用，并为合成生物学中改善次级代谢产物提供了有效的翻译后修饰-代谢工程策略（称为PTM-ME）。

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Precursor Supply for Erythromycin Biosynthesis: Engineering of Propionate Assimilation Pathway Based on Propionylation Modification.红霉素生物合成的前体供应：基于丙酰化修饰的丙酸同化途径工程

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红霉素生物合成的前体供应：基于丙酰化修饰的丙酸同化途径工程

Precursor Supply for Erythromycin Biosynthesis: Engineering of Propionate Assimilation Pathway Based on Propionylation Modification.

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