鉴定倍半萜合酶 AcTPS1 和在代谢工程酿酒酵母中(-)-反式-金合欢烯 D 的高产。

Identification of the sesquiterpene synthase AcTPS1 and high production of (-)-germacrene D in metabolically engineered Saccharomyces cerevisiae.

机构信息

State Key Laboratory of NBC Protection for Civilian, Beijing, 102205, People's Republic of China.

出版信息

Microb Cell Fact. 2022 May 18;21(1):89. doi: 10.1186/s12934-022-01814-4.

DOI:10.1186/s12934-022-01814-4

PMID:35585553

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9115970/

Abstract

BACKGROUND

The sesquiterpene germacrene D is a highly promising product due to its wide variety of insecticidal activities and ability to serve as a precursor for many other sesquiterpenes. Biosynthesis of high value compounds through genome mining for synthases and metabolic engineering of microbial factories, especially Saccharomyces cerevisiae, has been proven to be an effective strategy. However, there have been no studies on the de novo synthesis of germacrene D from carbon sources in microbes. Hence, the construction of the S. cerevisiae cell factory to achieve high production of germacrene D is highly desirable.

RESULTS

We identified five putative sesquiterpene synthases (AcTPS1 to AcTPS5) from Acremonium chrysogenum and the major product of AcTPS1 characterized by in vivo, in vitro reaction and NMR detection was revealed to be (-)-germacrene D. After systematically comparing twenty-one germacrene D synthases, AcTPS1 was found to generate the highest amount of (-)-germacrene D and was integrated into the terpene precursor-enhancing yeast strain, achieving 376.2 mg/L of (-)-germacrene D. Iterative engineering was performed to improve the production of (-)-germacrene D, including increasing the copy numbers of AcTPS1, tHMG1 and ERG20, and downregulating or knocking out other inhibitory factors (such as erg9, rox1, dpp1). Finally, the optimal strain LSc81 achieved 1.94 g/L (-)-germacrene D in shake-flask fermentation and 7.9 g/L (-)-germacrene D in a 5-L bioreactor, which is the highest reported (-)-germacrene D titer achieved to date.

CONCLUSION

We successfully achieved high production of (-)-germacrene D in S. cerevisiae through terpene synthase mining and metabolic engineering, providing an impressive example of microbial overproduction of high-value compounds.

摘要

背景

倍半萜类化合物大根香叶烯 D 具有广泛的杀虫活性，并且能够作为许多其他倍半萜类化合物的前体，因此极具应用潜力。通过对合成酶进行基因组挖掘和对微生物工厂（尤其是酿酒酵母）进行代谢工程改造，以生产高附加值化合物已被证明是一种有效的策略。然而，目前尚未有关于微生物从头合成大根香叶烯 D 的碳源的研究。因此，构建能够实现大根香叶烯 D 高产的酿酒酵母细胞工厂是非常可取的。

结果

我们从棘孢曲霉中鉴定了五个假定的倍半萜合酶（AcTPS1 到 AcTPS5），通过体内、体外反应和 NMR 检测，确定 AcTPS1 的主要产物为（-）-大根香叶烯 D。在对 21 种大根香叶烯 D 合酶进行系统比较后，发现 AcTPS1 产生（-）-大根香叶烯 D 的量最高，并将其整合到萜烯前体增强酵母菌株中，实现了（-）-大根香叶烯 D 的产量为 376.2mg/L。通过迭代工程来提高（-）-大根香叶烯 D 的产量，包括增加 AcTPS1、tHMG1 和 ERG20 的拷贝数，以及下调或敲除其他抑制因子（如 erg9、rox1、dpp1）。最终，优化后的菌株 LSc81 在摇瓶发酵中达到了 1.94g/L 的（-）-大根香叶烯 D，在 5L 生物反应器中达到了 7.9g/L 的（-）-大根香叶烯 D，这是迄今为止报道的（-）-大根香叶烯 D 产量的最高记录。

结论

我们通过萜烯合酶挖掘和代谢工程成功地在酿酒酵母中实现了（-）-大根香叶烯 D 的高产，为微生物大量生产高价值化合物提供了一个令人印象深刻的范例。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7378/9115970/9c05507dd420/12934_2022_1814_Fig1_HTML.jpg

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鉴定倍半萜合酶 AcTPS1 和在代谢工程酿酒酵母中(-)-反式-金合欢烯 D 的高产。

Identification of the sesquiterpene synthase AcTPS1 and high production of (-)-germacrene D in metabolically engineered Saccharomyces cerevisiae.

机构信息

State Key Laboratory of NBC Protection for Civilian, Beijing, 102205, People's Republic of China.