Genomics analysis and degradation characteristics of lignin by Streptomyces thermocarboxydus strain DF3-3.

Biotechnology for Biofuels and Bioproducts Pub Date : 2022-07-12 DOI:10.1186/s13068-022-02175-1

Fangyun Tan, Jun Cheng, Yu Zhang, Xingfu Jiang, Yueqiu Liu

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引用次数: 8

Abstract

Background: Lignocellulose is an important raw material for biomass-to-energy conversion, and it exhibits a complex but inefficient degradation mechanism. Microbial degradation is promising due to its environmental adaptability and biochemical versatility, but the pathways used by microbes for lignin degradation have not been fully studied. Degradation intermediates and complex metabolic pathways require more study.

Results: A novel actinomycete DF3-3, with the potential for lignin degradation, was screened and isolated. After morphological and molecular identification, DF3-3 was determined to be Streptomyces thermocarboxydus. The degradation of alkali lignin reached 31% within 15 days. Manganese peroxidase and laccase demonstrated their greatest activity levels, 1821.66 UL^-1 and 1265.58 UL^-1, respectively, on the sixth day. The highest lignin peroxidase activity was 480.33 UL^-1 on the fourth day. A total of 19 lignin degradation intermediates were identified by gas chromatography-mass spectrometry (GC-MS), including 9 aromatic compounds. Genome sequencing and annotation identified 107 lignin-degrading enzyme-coding genes containing three core enzymatic systems for lignin depolymerization: laccases, peroxidases and manganese peroxidase. In total, 7 lignin metabolic pathways were predicted.

Conclusions: Streptomyces thermocarboxydus strain DF3-3 has good lignin degradation ability. Degradation products and genomics analyses of DF3-3 show that it has a relatively complete lignin degradation pathway, including the β-ketoadipate pathway and peripheral reactions, gentisate pathway, anthranilate pathway, homogentisic pathway, and catabolic pathway for resorcinol. Two other pathways, the phenylacetate-CoA pathway and the 2,3-dihydroxyphenylpropionic acid pathway, are predicted based on genome data alone. This study provides the basis for future characterization of potential biotransformation enzyme systems for biomass energy conversion.

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热羧酸链霉菌DF3-3菌株木质素降解特性及基因组学分析

背景:木质纤维素是生物质能源转化的重要原料，其降解机制复杂而低效。微生物降解木质素具有良好的环境适应性和生物化学的通用性，但微生物降解木质素的途径尚未得到充分的研究。降解中间体和复杂的代谢途径需要更多的研究。结果:筛选并分离到一株具有木质素降解潜力的新型放线菌DF3-3。经形态学和分子鉴定，确定DF3-3为热羧酸链霉菌。15 d内碱木质素的降解率达到31%。第6天锰过氧化物酶和漆酶活性最高，分别为1821.66 UL-1和1265.58 UL-1。第4天木质素过氧化物酶活性最高，为480.33 UL-1。通过气相色谱-质谱联用技术共鉴定出19种木质素降解中间体，其中芳香族化合物9种。基因组测序和注释鉴定出107个木质素降解酶编码基因，其中包含木质素解聚的三个核心酶系统:漆酶、过氧化物酶和锰过氧化物酶。共预测了7条木质素代谢途径。结论:热羧酸链霉菌菌株DF3-3具有良好的木质素降解能力。降解产物和基因组学分析表明，DF3-3具有相对完整的木质素降解途径，包括β-酮己二酸途径和外周反应、龙豆酸途径、邻苯二酸途径、均质途径和间苯二酚分解代谢途径。另外两种途径，即苯乙酸-辅酶a途径和2,3-二羟基苯丙酸途径，仅基于基因组数据进行了预测。该研究为未来生物质能转化酶系统的表征提供了基础。

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Biotechnology for Biofuels and Bioproducts

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