Engineering an Escherichia coli strain for enhanced production of flavonoids derived from pinocembrin.

IF 4.3 2区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Erik K R Hanko, Christopher J Robinson, Sahara Bhanot, Adrian J Jervis, Nigel S Scrutton
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引用次数: 0

Abstract

Background: Flavonoids are a structurally diverse group of secondary metabolites, predominantly produced by plants, which include a range of compounds with pharmacological importance. Pinocembrin is a key branch point intermediate in the biosynthesis of a wide range of flavonoid subclasses. However, replicating the biosynthesis of these structurally diverse molecules in heterologous microbial cell factories has encountered challenges, in particular the modest pinocembrin titres achieved to date. In this study, we combined genome engineering and enzyme candidate screening to significantly enhance the production of pinocembrin and its derivatives, including chrysin, pinostrobin, pinobanksin, and galangin, in Escherichia coli.

Results: By implementing a combination of established strain engineering strategies aimed at enhancing the supply of the building blocks phenylalanine and malonyl-CoA, we constructed an E. coli chassis capable of accumulating 353 ± 19 mg/L pinocembrin from glycerol, without the need for precursor supplementation or the fatty acid biosynthesis inhibitor cerulenin. This chassis was subsequently employed for the production of chrysin, pinostrobin, pinobanksin, and galangin. Through an enzyme candidate screening process involving eight type-1 and five type-2 flavone synthases (FNS), we identified Petroselinum crispum FNSI as the top candidate, producing 82 ± 5 mg/L chrysin. Similarly, from a panel of five flavonoid 7-O-methyltransferases (7-OMT), we found pinocembrin 7-OMT from Eucalyptus nitida to yield 153 ± 10 mg/L pinostrobin. To produce pinobanksin, we screened seven enzyme candidates exhibiting flavanone 3-hydroxylase (F3H) or F3H/flavonol synthase (FLS) activity, with the bifunctional F3H/FLS enzyme from Glycine max being the top performer, achieving a pinobanksin titre of 12.6 ± 1.8 mg/L. Lastly, by utilising a combinatorial library of plasmids encoding G. max F3H and Citrus unshiu FLS, we obtained a maximum galangin titre of 18.2 ± 5.3 mg/L.

Conclusion: Through the integration of microbial chassis engineering and screening of enzyme candidates, we considerably increased the production levels of microbially synthesised pinocembrin, chrysin, pinostrobin, pinobanksin, and galangin. With the introduction of additional chassis modifications geared towards improving cofactor supply and regeneration, as well as alleviating potential toxic effects of intermediates and end products, we anticipate further enhancements in the yields of these pinocembrin derivatives, potentially enabling greater diversification in microbial hosts.

改造大肠埃希氏菌株,提高提取自松果菊酯的黄酮类化合物的产量。
背景:类黄酮是一类结构多样的次级代谢产物,主要由植物产生,其中包括一系列具有重要药理作用的化合物。在多种类黄酮亚类的生物合成过程中,卵磷脂是一个关键的分支点中间体。然而,在异源微生物细胞工厂中复制这些结构多样的分子的生物合成却遇到了挑战,特别是迄今为止所获得的皮诺雪琳滴度并不高。在这项研究中,我们将基因组工程和候选酶筛选结合起来,显著提高了大肠杆菌生产松果菊素及其衍生物的能力,包括蛹虫草素、松果菊素、松果菊苷和高良姜苷:结果:通过实施旨在提高苯丙氨酸和丙二酰-CoA组成成分供应的既定菌株工程策略组合,我们构建了一个大肠杆菌底盘,该底盘能够从甘油中积累 353 ± 19 mg/L 的松果菊酯,而无需补充前体或脂肪酸生物合成抑制剂脑磷脂。该底盘随后被用于生产菊黄素、松果菊素、松果菊素和高良姜素。通过涉及 8 种 1 型和 5 种 2 型黄酮合成酶(FNS)的候选酶筛选过程,我们确定了脆柄石楠 FNSI 为最佳候选酶,可产生 82 ± 5 mg/L 菊黄素。同样,在五种类黄酮 7-O-甲基转移酶(7-OMT)的研究小组中,我们发现硝基桉树(Eucalyptus nitida)的松柏素 7-OMT 产生 153 ± 10 mg/L 松柏素。为了生产蒎烷素,我们筛选了七种具有黄酮 3- 羟化酶(F3H)或 F3H/黄酮醇合成酶(FLS)活性的候选酶,其中来自 Glycine max 的双功能 F3H/FLS 酶表现最佳,其蒎烷素滴度为 12.6 ± 1.8 mg/L。最后,通过利用编码 G. max F3H 和 Citrus unshiu FLS 的质粒组合文库,我们获得了 18.2 ± 5.3 mg/L 的最高高良姜素滴定度:通过整合微生物底盘工程和候选酶的筛选,我们大大提高了微生物合成的松果菊素、菊脂素、松果菊素、松果菊苷和高良姜苷的生产水平。随着更多底盘改造的引入,以改善辅助因子的供应和再生,以及减轻中间产物和最终产品的潜在毒性影响,我们预计这些松果菊酯衍生物的产量将进一步提高,并有可能使微生物宿主更加多样化。
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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来源期刊
Microbial Cell Factories
Microbial Cell Factories 工程技术-生物工程与应用微生物
CiteScore
9.30
自引率
4.70%
发文量
235
审稿时长
2.3 months
期刊介绍: Microbial Cell Factories is an open access peer-reviewed journal that covers any topic related to the development, use and investigation of microbial cells as producers of recombinant proteins and natural products, or as catalyzers of biological transformations of industrial interest. Microbial Cell Factories is the world leading, primary research journal fully focusing on Applied Microbiology. The journal is divided into the following editorial sections: -Metabolic engineering -Synthetic biology -Whole-cell biocatalysis -Microbial regulations -Recombinant protein production/bioprocessing -Production of natural compounds -Systems biology of cell factories -Microbial production processes -Cell-free systems
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