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合成多物种微生物群落揭示了次生代谢物的变化,并促进了隐匿天然产物的发现。

Synthetic multispecies microbial communities reveals shifts in secondary metabolism and facilitates cryptic natural product discovery.

机构信息

Ocean College, Zhejiang University, Hangzhou 310058, China.

Department of Applied Chemistry, Zhejiang Gongshang University, Hangzhou 310058, China.

出版信息

Environ Microbiol. 2017 Sep;19(9):3606-3618. doi: 10.1111/1462-2920.13858. Epub 2017 Aug 14.

Abstract

Chemically mediated interactions have been hypothesized to be essential for ecosystem functioning as co-occurring organisms can influence the performance of each other by metabolic means. Here, we present a co-culture device that allows co-culturing of microorganisms that are physically separated but can exchange chemical signals and metabolites. This setup was adopted to perform investigations on the secondary metabolisms of both a fungal-bacterial community and an actinomycetic-actinomycetic community. This study employed a metabolomics approach integrating LC-MS profiling, multivariate data analysis and molecular networking techniques. LC-MS measurements revealed a pronounced influence of such chemical communication on the metabolic profiles of synthetic co-culture communities with a group of molecules being induced or upregulated in co-cultures. A novel antibiotic exhibiting antibiotic properties against Klebsiella pneumoniae was unveiled in the fungal-bacterial community. Besides, a further survey of the fungal-bacterial cross-talk indicated that the production of co-culture-induced diphenyl ethers by fungi might result from the fungal response against the secretion of surfactins by bacteria in the cross-talk. This study demonstrated that the presented co-culture device and the metabolomic routine would facilitate the investigation on chemically mediated interactions in nature as well as cryptic natural products discovery.

摘要

化学介导的相互作用被假设对于生态系统功能至关重要,因为共存的生物体可以通过代谢手段相互影响对方的表现。在这里,我们提出了一种共培养装置,允许将物理上分离但可以交换化学信号和代谢物的微生物进行共培养。该装置用于研究真菌-细菌群落和放线菌-放线菌群落的次生代谢物。本研究采用代谢组学方法,整合了 LC-MS 分析、多变量数据分析和分子网络技术。LC-MS 测量结果表明,这种化学通讯对合成共培养群落的代谢谱有明显影响,共培养中诱导或上调了一组分子。在真菌-细菌群落中发现了一种具有抗肺炎克雷伯菌活性的新型抗生素。此外,进一步调查真菌-细菌的交叉对话表明,真菌产生共培养诱导的二苯醚可能是真菌对交叉对话中细菌分泌表面活性剂的反应所致。本研究表明,所提出的共培养装置和代谢组学常规将有助于研究自然环境中的化学介导相互作用以及隐匿天然产物的发现。

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