新金黄色分枝杆菌甾醇侧链降解以产生类固醇合成子的操纵子的研究。

Yun-Qiu Zhao, Yong-Jun Liu, Lu Song, Dingyan Yu, Kun Liu, Ke Liu, Bei Gao, Xin-Yi Tao, Liang-Bin Xiong, Feng-Qing Wang, Dong-Zhi Wei
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引用次数: 0

摘要

背景:利用工程分枝杆菌将廉价的植物甾醇转化为有价值的类固醇合成子是工业上生产类固醇激素的基本途径。因此,C-19和C-22类固醇是两种主要的商业合成子,也是C17侧链降解植物甾醇的产物。在固醇的转化过程中,C-19和C-22甾体通常同时产生,尽管其中一种可能是主要产物,另一种可能是次要副产物。这是用于工业应用的工程分枝杆菌的一个主要缺点,这可能是由于在降解甾醇C17侧链时雄烯-4-烯-3,17-二酮(AD)和22-羟基-23,24-双去甲酚-4-烯-3-酮(HBC)亚途径共存。由于HBC子通路的关键机制尚未明确,上述缺点至今尚未解决。结果:通过比较基因组分析,从新金分枝杆菌基因组中挖掘出了推测的HBC亚通路的关键基因。有趣的是,一个醛缩酶编码基因atf1被鉴定为负责HBC亚通路的第一反应,它作为一个保守的操纵子与duf35型基因chsH4、还原酶基因chsE6和转录调控基因kstR3一起存在于基因组中。随后,atf1和chsH4被确定为参与HBC亚通路的关键基因。因此,提出了一种更新的策略,通过同时修饰AD和HBC亚通路来开发工程C-19或C-22类固醇产生菌株。以4-HBC和9-OHAD产菌的培养为例,改进后的4-HBC产菌的生产滴度为20.7 g/L,摩尔产率为92.5%,副产物减少56.4%;改进后的9-OHAD产菌的生产滴度为19.87 g/L,摩尔产率为94.6%,副产物减少43.7%。结论:这些菌株的优异表现表明,参与HBC亚途径的一级操纵子提高了工业菌株将植物甾醇转化为类固醇合成子的能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Unravelling and engineering an operon involved in the side-chain degradation of sterols in Mycolicibacterium neoaurum for the production of steroid synthons.

Unravelling and engineering an operon involved in the side-chain degradation of sterols in Mycolicibacterium neoaurum for the production of steroid synthons.

Unravelling and engineering an operon involved in the side-chain degradation of sterols in Mycolicibacterium neoaurum for the production of steroid synthons.

Unravelling and engineering an operon involved in the side-chain degradation of sterols in Mycolicibacterium neoaurum for the production of steroid synthons.

Background: Harnessing engineered Mycolicibacteria to convert cheap phytosterols into valuable steroid synthons is a basic way in the industry for the production of steroid hormones. Thus, C-19 and C-22 steroids are the two main types of commercial synthons and the products of C17 side chain degradation of phytosterols. During the conversion process of sterols, C-19 and C-22 steroids are often produced together, although one may be the main product and the other a minor byproduct. This is a major drawback of the engineered Mycolicibacteria for industrial application, which could be attributed to the co-existence of androstene-4-ene-3,17-dione (AD) and 22-hydroxy-23,24-bisnorchol-4-ene-3-one (HBC) sub-pathways in the degradation of the sterol C17 side chain. Since the key mechanism underlying the HBC sub-pathway has not yet been clarified, the above shortcoming has not been resolved so far.

Results: The key gene involved in the putative HBC sub-pathway was excavated from the genome of M. neoaurum by comparative genomic analysis. Interestingly, an aldolase- encoding gene, atf1, was identified to be responsible for the first reaction of the HBC sub-pathway, and it exists as a conserved operon along with a DUF35-type gene chsH4, a reductase gene chsE6, and a transcriptional regulation gene kstR3 in the genome. Subsequently, atf1 and chsH4 were identified as the key genes involved in the HBC sub-pathway. Therefore, an updated strategy was proposed to develop engineered C-19 or C-22 steroid-producing strains by simultaneously modifying the AD and HBC sub-pathways. Taking the development of 4-HBC and 9-OHAD-producing strains as examples, the improved 4-HBC-producing strain achieved a 20.7 g/L production titer with a 92.5% molar yield and a 56.4% reduction in byproducts, and the improved 9-OHAD producing strain achieved a 19.87 g/L production titer with a 94.6% molar yield and a 43.7% reduction in byproduct production.

Conclusions: The excellent performances of these strains demonstrated that the primary operon involved in the HBC sub-pathway improves the industrial strains in the conversion of phytosterols to steroid synthons.

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