通过工程改造β-氧化和碳储存途径在真养产碱杆菌H16中生产脂肪酸

Production of fatty acids in Ralstonia eutropha H16 by engineering β-oxidation and carbon storage.

作者信息

Chen Janice S, Colón Brendan, Dusel Brendon, Ziesack Marika, Way Jeffrey C, Torella Joseph P

机构信息

Wyss Institute for Biologically Inspired Engineering, Harvard Medical School , Boston, MA , United States ; Current affiliation: Department of Molecular and Cell Biology, University of California Berkeley , Berkeley, CA , United States.

Department of Systems Biology, Harvard Medical School , Boston, MA , United States.

出版信息

PeerJ. 2015 Dec 7;3:e1468. doi: 10.7717/peerj.1468. eCollection 2015.

DOI:10.7717/peerj.1468

PMID:26664804

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4675107/

Abstract

Ralstonia eutropha H16 is a facultatively autotrophic hydrogen-oxidizing bacterium capable of producing polyhydroxybutyrate (PHB)-based bioplastics. As PHB's physical properties may be improved by incorporation of medium-chain-length fatty acids (MCFAs), and MCFAs are valuable on their own as fuel and chemical intermediates, we engineered R. eutropha for MCFA production. Expression of UcFatB2, a medium-chain-length-specific acyl-ACP thioesterase, resulted in production of 14 mg/L laurate in wild-type R. eutropha. Total fatty acid production (22 mg/L) could be increased up to 2.5-fold by knocking out PHB synthesis, a major sink for acetyl-CoA, or by knocking out the acyl-CoA ligase fadD3, an entry point for fatty acids into β-oxidation. As ΔfadD3 mutants still consumed laurate, and because the R. eutropha genome is predicted to encode over 50 acyl-CoA ligases, we employed RNA-Seq to identify acyl-CoA ligases upregulated during growth on laurate. Knockouts of the three most highly upregulated acyl-CoA ligases increased fatty acid yield significantly, with one strain (ΔA2794) producing up to 62 mg/L free fatty acid. This study demonstrates that homologous β-oxidation systems can be rationally engineered to enhance fatty acid production, a strategy that may be employed to increase yield for a range of fuels, chemicals, and PHB derivatives in R. eutropha.

摘要

嗜油假单胞菌H16是一种兼性自养型氢氧化细菌，能够生产基于聚羟基丁酸酯（PHB）的生物塑料。由于通过掺入中链长度脂肪酸（MCFA）可以改善PHB的物理性质，并且MCFA自身作为燃料和化学中间体具有价值，我们对嗜油假单胞菌进行了工程改造以生产MCFA。中链长度特异性酰基-ACP硫酯酶UcFatB2的表达导致野生型嗜油假单胞菌中月桂酸的产量达到14 mg/L。通过敲除作为乙酰辅酶A主要消耗途径的PHB合成，或敲除脂肪酸进入β-氧化的入口点酰基辅酶A连接酶fadD3，总脂肪酸产量（22 mg/L）可提高至2.5倍。由于ΔfadD3突变体仍会消耗月桂酸，并且因为预测嗜油假单胞菌基因组编码超过50种酰基辅酶A连接酶，我们采用RNA测序来鉴定在月桂酸生长过程中上调的酰基辅酶A连接酶。敲除上调程度最高的三种酰基辅酶A连接酶可显著提高脂肪酸产量，其中一个菌株（ΔA2794）产生的游离脂肪酸高达62 mg/L。这项研究表明，可以合理设计同源β-氧化系统以提高脂肪酸产量，这一策略可用于提高嗜油假单胞菌中一系列燃料、化学品和PHB衍生物的产量。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d807/4675107/04a1a84eb082/peerj-03-1468-g001.jpg

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通过工程改造β-氧化和碳储存途径在真养产碱杆菌H16中生产脂肪酸

Production of fatty acids in Ralstonia eutropha H16 by engineering β-oxidation and carbon storage.

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