大肠杆菌对木质纤维素水解液抑制物的胁迫耐受性

doi:10.13560/j.cnki.biotech.bull.1985.2023-0722

摘要/Abstract

摘要：

木质纤维素类生物质是前景广阔的化石原料替代品，其生物炼制可生产生物能源、生物基化学品和生物材料等多种产品，可降低碳排放，有助于实现“双碳”目标，因此受到越来越多的关注。然而，木质纤维素生物炼制需要经过预处理、微生物发酵和产物纯化等多个步骤，其中，预处理过程产生的多种化合物抑制微生物的细胞生长和发酵性能，是制约生物转化效率的瓶颈之一。大肠杆菌是木质纤维素生物炼制常用的宿主，被广泛应用于多种化合物的生产，研究其对木质纤维素水解液中抑制物的耐受性，对于提高木质纤维素生物炼制效率具有重要意义。本文首先介绍了木质纤维素的主要成分和基本结构，对木质纤维素的预处理方法以及预处理后水解液中的主要抑制物种类进行了简单阐述；随后，总结了木质纤维素水解液中几类主要抑制物呋喃类、羧酸类和酚类对大肠杆菌细胞的毒性，以及大肠杆菌对上述抑制物的胁迫响应机制和基于机制的菌株改造靶点；最后，综述了提高大肠杆菌对上述抑制物的胁迫耐受性的菌株改造策略，包括随机突变、实验室适应性进化和组学辅助的理性设计等，为利用代谢工程构建用于木质纤维素生物炼制的高效大肠杆菌菌株提供参考。

关键词: 木质纤维素水解液抑制物, 胁迫耐受性, 大肠杆菌, 菌株改造, 呋喃类, 羧酸类, 酚类

Abstract:

Lignocellulosic biomass（LCB）is a promising alternative to fossil material, the biofuels, biochemicals and biomaterials are produced via its biorefinery, which may reduce carbon emissions, contributing to achieve the carbon peaking and carbon neutrality goals. Therefore, LCB is receiving more and more attentions. However, there are multiple steps involved in lignocellulosic biorefinery including pretreatment, microbial fermentation and product purification, in which, various compounds generated from pretreatment of LCB inhibit cell growth and fermentation performance of microbes, which is one of the bottlenecks of bioconversion efficiency. Escherichia coli is a commonly used host for lignocellulosic biorefinery and extensively used for the production of many compounds, thus, it is of great importance to study the stress tolerance of E. coli to inhibitors in lignocellulosic hydrolysates for improving lignocellulosic biorefinery efficiency. This paper first introduced the main components and structures of lignocellulose, and briefly elucidated pretreatment methods to lignocellulose as well as main inhibitors in the hydrolysate after pretreatment. Then the paper summarized the toxic effects of main inhibitor furans, carboxylic acids and phenolics in the hydrolysate of lignocellulose on E. coli, as well as the mechanisms of stress tolerance against these inhibitors and the engineering targets for improving strain tolerance based on the mechanisms. Finally, the paper reviewed the strategies for strain engineering to improve the tolerance of E. coli to above motioned inhibitors, including random mutagenesis, adaptive laboratory evolution and omics-assisted rational design,, aiming to provide references for metabolic engineering of efficient E. coli strains for lignocellulosic biorefinery.

Key words: inhibitors in lignocellulosic hydrolysate, stress tolerance, Escherichia coli, strain engineering, furans, carboxylic acids, phenolics

唐瑞琪, 赵心清, 朱笃, 汪涯. 大肠杆菌对木质纤维素水解液抑制物的胁迫耐受性[J]. 生物技术通报, 2023, 39(11): 205-216.

TANG Rui-qi, ZHAO Xin-qing, ZHU Du, WANG Ya. Stress Tolerance of Escherichia coli to Inhibitors in Lignocellulosic Hydrolysates[J]. Biotechnology Bulletin, 2023, 39(11): 205-216.

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基因 Gene	敲除/过表达 Deletion/Overexpression	描述 Description	抑制物 Inhibitor	参考文献 Reference
pgi, encoding glucose-6-phosphate isomerase	Deletion	Shunt glucose to pentose phosphate pathway to increase NADPH production	Furfural, HMF	[31]
pntAB, encoding pyridine nucleotide transhydrogenase	Overexpression	Convert NADP⁺ to NADPH using PntAB to increase NADPH regeneration	Furfural, HMF	[22,29]
yqhD, encoding aldehyde reductase	Deletion	Delete NADPH-dependent YqhD to reduce NADPH consumption	Furfural, HMF	[22,29]
yqhC, encoding transcriptional activator	Deletion	Delete YqhC to downregulate yqhDexpression, reducing NADPH consumption	Furfural	[32]
fucO, encoding propanediol oxidoreductase	Overexpression	Convert furfural using NADH-dependent FucO to reduce NADPH consumption	Furfural	[33]
yghA, encoding oxidoreductase	Overexpression	Convert furfural using NADH-dependent YghA to reduce NADPH consumption	Furfural, HMF	[34]
pncB and nadE, encoding NAD salvage pathway enzymes	Overexpression	Increase NAD（P）H level through the nicotine amide salvage pathway	Furfural	[35]
Heterologous xylBand BaBAD, encoding benzyl alcohol dehydrogenases	Overexpression	Convert furfural using NADH-dependent XylB and BaBAD to reduce NADPH consumption	Furfural	[36]
thyA, encoding thymidylate synthase	Overexpression	Overexpress ThyA to increase dTMP level for DNA repair	Furfural	[37]
potE and puuP, encoding polyamine transporters	Overexpression	Increase cytoplasmic polyamine level to maintain DNA synthesis	Furfural	[38]
lpcA, encoding D-sedoheptulose-7-phosphate isomerase	Overexpression	Overexpress LpcA to increase formation of lipopolysaccharides and NADPH	Furfural	[39]
pssA, encoding phosphatidylserine synthase	Overexpression	Increase phosphatidylethanolamine content to increase membrane integrity	Furfural, HMF	[40]
mdtJI, encoding multidrug resistance efflux pump	Overexpression	Export furfural by efflux pump MdtJI	Furfural, HMF	[41]
groESL, encoding chaperonin	Overexpression	Maintain proper folding of proteins	Furfural	[39]

基因 Gene	敲除/过表达 Deletion/Overexpression	描述 Description	抑制物 Inhibitor	参考文献 Reference
pgi, encoding glucose-6-phosphate isomerase	Deletion	Shunt glucose to pentose phosphate pathway to increase NADPH production	Furfural, HMF	[31]
pntAB, encoding pyridine nucleotide transhydrogenase	Overexpression	Convert NADP⁺ to NADPH using PntAB to increase NADPH regeneration	Furfural, HMF	[22,29]
yqhD, encoding aldehyde reductase	Deletion	Delete NADPH-dependent YqhD to reduce NADPH consumption	Furfural, HMF	[22,29]
yqhC, encoding transcriptional activator	Deletion	Delete YqhC to downregulate yqhDexpression, reducing NADPH consumption	Furfural	[32]
fucO, encoding propanediol oxidoreductase	Overexpression	Convert furfural using NADH-dependent FucO to reduce NADPH consumption	Furfural	[33]
yghA, encoding oxidoreductase	Overexpression	Convert furfural using NADH-dependent YghA to reduce NADPH consumption	Furfural, HMF	[34]
pncB and nadE, encoding NAD salvage pathway enzymes	Overexpression	Increase NAD（P）H level through the nicotine amide salvage pathway	Furfural	[35]
Heterologous xylBand BaBAD, encoding benzyl alcohol dehydrogenases	Overexpression	Convert furfural using NADH-dependent XylB and BaBAD to reduce NADPH consumption	Furfural	[36]
thyA, encoding thymidylate synthase	Overexpression	Overexpress ThyA to increase dTMP level for DNA repair	Furfural	[37]
potE and puuP, encoding polyamine transporters	Overexpression	Increase cytoplasmic polyamine level to maintain DNA synthesis	Furfural	[38]
lpcA, encoding D-sedoheptulose-7-phosphate isomerase	Overexpression	Overexpress LpcA to increase formation of lipopolysaccharides and NADPH	Furfural	[39]
pssA, encoding phosphatidylserine synthase	Overexpression	Increase phosphatidylethanolamine content to increase membrane integrity	Furfural, HMF	[40]
mdtJI, encoding multidrug resistance efflux pump	Overexpression	Export furfural by efflux pump MdtJI	Furfural, HMF	[41]
groESL, encoding chaperonin	Overexpression	Maintain proper folding of proteins	Furfural	[39]

基因 Gene	描述 Description	胁迫 Stress	参考文献 Reference
dsrA and hfq, encoding small noncoding RNA and chaperone	DsrA increases rpoS mRNA stability and activate RpoS translation, Hfq promotes DsrA annealing to the rpoS5' untranscribed region（UTR）	Low pH	[63]
Heterologous cfaS, encoding cyclopropane fatty acid synthase	Decrease membrane permeability and fluidity	Low pH	[64]
Heterologous cbpA, encoding chaperone	CbpA plays a role in protein and DNA repair	Acetate	[65]
gadE, encoding transcriptional activator	GadE activates acid resistance system	Low pH	[66]
hdeB, encoding periplasmic acid stress chaperone	HdeB prevents periplasmic proteins aggregation at low pH	Low pH	[66]
sodB and katE, encoding superoxide dismutase and catalase	SodB and KatE are ROS scavengers	Low pH	[66]

基因 Gene	描述 Description	胁迫 Stress	参考文献 Reference
dsrA and hfq, encoding small noncoding RNA and chaperone	DsrA increases rpoS mRNA stability and activate RpoS translation, Hfq promotes DsrA annealing to the rpoS5' untranscribed region（UTR）	Low pH	[63]
Heterologous cfaS, encoding cyclopropane fatty acid synthase	Decrease membrane permeability and fluidity	Low pH	[64]
Heterologous cbpA, encoding chaperone	CbpA plays a role in protein and DNA repair	Acetate	[65]
gadE, encoding transcriptional activator	GadE activates acid resistance system	Low pH	[66]
hdeB, encoding periplasmic acid stress chaperone	HdeB prevents periplasmic proteins aggregation at low pH	Low pH	[66]
sodB and katE, encoding superoxide dismutase and catalase	SodB and KatE are ROS scavengers	Low pH	[66]