链霉菌 Chattanoogensis 的 γ-丁内酯调控系统连接营养利用、代谢和发育。

Gamma-butyrolactone regulatory system of Streptomyces chattanoogensis links nutrient utilization, metabolism, and development.

机构信息

Zhejiang University, College of Life Sciences, Hangzhou, 310058 Zhejiang, People's Republic of China.

出版信息

Appl Environ Microbiol. 2011 Dec;77(23):8415-26. doi: 10.1128/AEM.05898-11. Epub 2011 Sep 23.

DOI:10.1128/AEM.05898-11

PMID:21948843

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3233056/

Abstract

Gamma-butyrolactones (GBLs) produced by several Streptomyces species have been shown to serve as quorum-sensing signaling molecules for activating antibiotic production. The GBL system of Streptomyces chattanoogensis L10, a producer of antifungal agent natamycin, consists of three genes: scgA, scgX, and scgR. Both scgA and scgX contribute to GBL production, while scgR encodes a GBL receptor. ΔscgA and ΔscgX mutants of S. chattanoogensis behaved identically: they had a growth defect in submerged cultures and delayed or abolished the morphological differentiation and secondary metabolites production on solid medium. ScgR could bind to the promoter region of scgA and repress its transcription. Moreover, scgA seems also to be controlled by a GBL-mediated negative-feedback system. Hence, it is apparent that GBL biosynthesis is tightly controlled to ensure the correct timing for metabolic switch. An additional direct ScgR-target gene gbdA was identified by genomic SELEX and transcriptional analysis. Comparative proteomic analysis between L10 and its ΔscgA mutant revealed that the GBL system affects the expression of more than 50 proteins, including enzymes involved in carbon uptake system, primary metabolism, and stress response, we thus conclude that scgR-scgA-scgX constitute a novel GBL regulatory system involved in nutrient utilization, triggering adaptive responses, and finally dictating the switch from primary to secondary metabolism.

摘要

几种链霉菌产生的γ-丁内酯 (GBL) 已被证明可作为群体感应信号分子，激活抗生素的产生。产抗真菌剂纳他霉素的链霉菌 Chattanoogensis L10 的 GBL 系统由三个基因组成：scgA、scgX 和 scgR。scgA 和 scgX 都有助于 GBL 的产生，而 scgR 则编码 GBL 受体。 Chattanoogensis 的 scgA 和 scgX 缺失突变体表现出相同的行为：它们在液体培养物中生长缺陷，并且在固体培养基上延迟或取消形态分化和次级代谢产物的产生。ScgR 可以结合到 scgA 的启动子区域并抑制其转录。此外，scgA 似乎也受到 GBL 介导的负反馈系统的控制。因此，GBL 生物合成受到严格控制，以确保代谢转换的正确时机。通过基因组 SELEX 和转录分析鉴定了一个额外的直接 ScgR 靶标基因 gbdA。L10 与其 ΔscgA 突变体之间的比较蛋白质组学分析表明，GBL 系统影响超过 50 种蛋白质的表达，包括参与碳摄取系统、初级代谢和应激反应的酶，我们因此得出结论，scgR-scgA-scgX 构成了一个新的 GBL 调控系统，涉及营养物质利用、触发适应性反应，最终决定从初级代谢到次级代谢的转变。

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