一种参与克拉维酸生产的双组分调节系统。

A two-component regulatory system involved in clavulanic acid production.

作者信息

Jnawali Hum Nath, Oh Tae-Jin, Liou Kwangkyoung, Park Byoung Chul, Sohng Jae Kyung

机构信息

Institute of Biomolecule Reconstruction (iBR), Department of Pharmaceutical Engineering, SunMoon University.

出版信息

J Antibiot (Tokyo). 2008 Nov;61(11):651-9. doi: 10.1038/ja.2008.92.

DOI:10.1038/ja.2008.92

PMID:19168979

Abstract

A pair of genes encoding the bacterial two-component regulatory system, orf22 and orf23, was found next to the clavulanic acid gene cluster of Streptomyces clavuligerus NRRL3585. Orf23 was deleted for the construction of S. clavuligerus/Deltaorf23. Although growth and morphological analyses showed no differences between S. clavuligerus/Deltaorf23 and wild-type, the production of clavulanic acid in S. clavuligerus/Deltaorf23 was found to be decreased. In addition, the co-overexpression of orf22/orf23 in wild-type resulted in an enhanced 1.49-fold production of clavulanic acid, and the complementation of orf22/orf23 in S. clavuligerus/Deltaorf23 restored clavulanic acid production about 80% as normal levels. These results demonstrate that the orf22/orf23 two-component regulatory system participates as a positive regulator of the biosynthesis of clavulanic acid and increased levels of orf22/orf23 can contribute to enhanced production of clavulanic acid in S. clavuligerus.

摘要

在棒状链霉菌NRRL3585的克拉维酸基因簇旁边发现了一对编码细菌双组分调节系统的基因orf22和orf23。为构建棒状链霉菌/Δorf23而删除了orf23。尽管生长和形态分析表明棒状链霉菌/Δorf23与野生型之间没有差异，但发现棒状链霉菌/Δorf23中克拉维酸的产量有所下降。此外，野生型中orf22/orf23的共过表达导致克拉维酸产量提高了1.49倍，并且棒状链霉菌/Δorf23中orf22/orf23的互补使克拉维酸产量恢复到正常水平的约80%。这些结果表明，orf22/orf23双组分调节系统作为克拉维酸生物合成的正调节因子发挥作用，并且orf22/orf23水平的提高有助于提高棒状链霉菌中克拉维酸的产量。

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一种参与克拉维酸生产的双组分调节系统。

A two-component regulatory system involved in clavulanic acid production.

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