雷帕霉素通过酵母全细胞生物转化提高了 2-苯乙醇的产量。

Rapamycin enhanced the production of 2-phenylethanol during whole-cell bioconversion by yeast.

机构信息

Key Laboratory of Fermentation Engineering (Ministry of Education), National "111" Center for Cellular Regulation and Molecular Pharmaceutics, Hubei Provincial Cooperative Innovation Center of Industrial Fermentation, College of Bioengineering, Hubei University of Technology, Wuhan, 430068, People's Republic of China.

ABI Group, College of Marine Science and Technology, Zhejiang Ocean University, Zhoushan, Zhejiang, China.

出版信息

Appl Microbiol Biotechnol. 2022 Oct;106(19-20):6471-6481. doi: 10.1007/s00253-022-12169-6. Epub 2022 Sep 13.

DOI:10.1007/s00253-022-12169-6

PMID:36098787

Abstract

2-Phenylethanol (2-PE), a higher alcohol with a rose-like odor, has been widely utilized in food, perfume, and beverages. Saccharomyces cerevisiae is one of the most promising microorganisms for the biosynthesis of natural 2-PE. However, the growth of S. cerevisiae is generally inhibited by 2-PE, which makes its production in yeast cell factories challenging. Here, the whole-cell bioconversion was used to avert growth inhibition, leading to an increase in the concentration and productivity of 2-PE. Moreover, rapamycin (Rap) addition further improved the efficiency of 2-PE synthesis. The concentration of 2-PE (2.20 g/L) was 1.68-fold higher than that in the absence of Rap during the whole-cell bioconversion by S. cerevisiae BY4741. RT-qPCR results showed that Rap addition increased the transcription of ARO9, ARO10, ADH2, GAP1, ARO80, GLN3, and GDH2. When the GLN3 was knocked out, the transcriptional levels of the genes were dramatically decreased, and the concentration of 2-PE significantly decreased to 0.21 g/L. The results indicated that Rap enhanced the flux of the Ehrlich pathway, and Gln3 exerted a central role in the regulation of Rap. Furthermore, commercial yeast (S. cerevisiae FY202001) was selected to verify the applicability of Rap. In the presence of Rap, 3.67 g/L 2-PE was obtained by whole-cell bioconversion in flask, which was increased by 9% than that in the absence of Rap. Finally, the 2-PE titer reached 4.93 g/L by whole-cell bioconversion in a 5 L bioreactor, with a yield of 84 mol% from L-phenylalanine and a productivity of 0.103 g/L h, which was far higher than that of the currently reported in S. cerevisiae. These findings provided a new idea for the efficient synthesis of 2-PE. KEY POINTS: • Whole-cell bioconversion was used to produce 2-PE. • The regulation of the Ehrlich pathway by Rap provides a theoretical basis for developing an effective yeast cell factory to produce 2-PE. • The 2-PE productivity of 0.103 g/L h is far higher than that of the currently reported in S. cerevisiae .

摘要

2-苯乙醇（2-PE）是一种带有玫瑰香味的高级醇，广泛应用于食品、香水和饮料中。酿酒酵母是生物合成天然 2-PE 的最有前途的微生物之一。然而，2-PE 通常会抑制酵母的生长，这使得在酵母细胞工厂中生产 2-PE 具有挑战性。在这里，采用全细胞生物转化来避免生长抑制，从而提高 2-PE 的浓度和生产力。此外，添加雷帕霉素（Rap）进一步提高了 2-PE 合成的效率。在酿酒酵母 BY4741 的全细胞生物转化过程中，添加 Rap 可使 2-PE 的浓度（2.20 g/L）提高 1.68 倍，高于没有 Rap 的情况。RT-qPCR 结果表明，添加 Rap 增加了 ARO9、ARO10、ADH2、GAP1、ARO80、GLN3 和 GDH2 的转录水平。当敲除 GLN3 时，基因的转录水平显著降低，2-PE 的浓度显著降低至 0.21 g/L。结果表明，Rap 增强了 Ehrlich 途径的通量，Gln3 在 Rap 的调控中发挥核心作用。此外，还选择了商业酵母（S. cerevisiae FY202001）来验证 Rap 的适用性。在 Rap 的存在下，通过摇瓶中的全细胞生物转化获得 3.67 g/L 的 2-PE，比没有 Rap 时提高了 9%。最后，通过 5 L 生物反应器中的全细胞生物转化，2-PE 的浓度达到 4.93 g/L，L-苯丙氨酸的得率为 84 mol%，产率为 0.103 g/L·h，远高于目前在酿酒酵母中报道的值。这些发现为 2-PE 的高效合成提供了新的思路。关键点：• 采用全细胞生物转化生产 2-PE。• Rap 对 Ehrlich 途径的调控为开发有效的酵母细胞工厂生产 2-PE 提供了理论依据。• 0.103 g/L·h 的 2-PE 生产率远高于目前在酿酒酵母中报道的值。

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雷帕霉素通过酵母全细胞生物转化提高了 2-苯乙醇的产量。

Rapamycin enhanced the production of 2-phenylethanol during whole-cell bioconversion by yeast.

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