Metabolic engineering for the biosynthesis of bis-indolylquinone terrequinone A in Escherichia coli from L-tryptophan and prenol.

Lijuan Wang, Yongdong Deng, Rihe Peng, Jianjie Gao, Zhenjun Li, Wenhui Zhang, Jing Xu, Bo Wang, Yu Wang, Hongjuan Han, Xiaoyan Fu, Yongsheng Tian, Quanhong Yao
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Abstract

Background: Terrequinone A is a bis-indolylquinone natural product with antitumor activity. Due to its unique asymmetric quinone core structure and multiple functional groups, biosynthesis is more efficient and environmentally friendly than traditional chemical synthesis. Currently, most bis-indolylquinones are obtained by direct extraction from fungi or by chemical synthesis. By focusing on the biosynthesis of terrequinone A, we hope to explore the way to synthesize bis-indolylquinones de novo using Escherichia coli as a cell factory.

Results: In this study, a terrequinone A synthesis pathway containing the tdiA-tdiE genes was constructed into Escherichia coli and activated by a phosphopantetheinyl transferase gene sfp, enabling the strain to synthesize 1.54 mg/L of terrequinone A. Subsequently, a two-step isopentenol utilization pathway was introduced to enhance the supply of endogenous dimethylallyl diphosphate (DMAPP) in E. coli, increasing the level of terrequinone A to 20.1 mg/L. By adjusting the L-tryptophan (L-Trp)/prenol ratio, the major product could be changed from ochrindole D to terrequinone A, and the content of terrequinone A reached the highest 106.3 mg/L under the optimized culture conditions. Metabolic analysis of L-Trp indicated that the conversion of large amounts of L-Trp to indole was an important factor preventing the further improvement of terrequinone A yield.

Conclusions: A comprehensive approach was adopted and terrequinone A was successfully synthesized from low-cost L-Trp and prenol in E. coli. This study provides a metabolic engineering strategy for the efficient synthesis of terrequinone A and other similar bis-indolylquinones with asymmetric quinone cores. In addition, this is the first report on the de novo biosyhthesis of terrequinone A in an engineered strain.

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Abstract Image

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l -色氨酸和丙烯醇在大肠杆菌中合成双吲哚醌terrequinone A的代谢工程。
背景:Terrequinone A是一种具有抗肿瘤活性的双吲哚醌类天然产物。由于其独特的不对称醌核心结构和多个官能团,生物合成比传统的化学合成更高效、更环保。目前,大多数双吲哚醌是通过直接从真菌中提取或化学合成得到的。以terrequinone A的生物合成为重点,我们希望探索利用大肠杆菌作为细胞工厂重新合成双吲哚醌的方法。结果:本研究在大肠杆菌中构建了含有tdiA-tdiE基因的terrequinone a合成途径,并通过磷酸化前甲酰基转移酶基因sfp激活,使菌株合成了1.54 mg/L的terrequinone a。随后,通过引入两步异戊烯醇利用途径,增加了大肠杆菌内源性二甲基丙烯基二磷酸(dimethylallyl diphosphate, DMAPP)的供应,使terrequinone a的水平提高到20.1 mg/L。通过调节L-色氨酸(L- trp)/丙烯醇的比例,可使主要产物由氯吲哚D转变为terrequinone A,在优化的培养条件下,terrequinone A的含量最高,达到106.3 mg/L。l -色氨酸代谢分析表明,大量l -色氨酸转化为吲哚是阻碍terrequinone A产量进一步提高的重要因素。结论:采用综合方法,以低成本的l -色氨酸和丙烯醇为原料,在大肠杆菌中成功合成了terrequinone A。本研究为高效合成terrequinone a和其他具有不对称醌核的双吲哚醌类化合物提供了一种代谢工程策略。此外,这是在工程菌株中重新合成terrequinone A的第一篇报道。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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