捕食性细菌定殖浮萍微生物组并改变其结构的潜力：使用专性捕食菌，Bacteriovorax sp. HI3 的模型研究。

Potential of Predatory Bacteria to Colonize the Duckweed Microbiome and Change Its Structure: A Model Study Using the Obligate Predatory Bacterium, Bacteriovorax sp. HI3.

机构信息

Division of Sustainable Energy and Environmental Engineering, Osaka University.

出版信息

Microbes Environ. 2023;38(3). doi: 10.1264/jsme2.ME23040.

DOI:10.1264/jsme2.ME23040

PMID:37690850

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10522839/

Abstract

Modifying the duckweed microbiome is a major challenge for enhancing the effectiveness of duckweed-based wastewater treatment and biomass production technologies. We herein examined the potential of the exogenous introduction of predatory bacteria to change the duckweed microbiome. Bacteriovorax sp. HI3, a model predatory bacterium, colonized the core of the Lemna microbiome, and its predatory behavior changed the microbiome structure, which correlated with colonization density. These results reveal that bacterial predatory interactions may be important drivers that shape the duckweed microbiome, suggesting their potential usefulness in modifying the microbiome.

摘要

改变浮萍微生物组是提高浮萍为基础的废水处理和生物质生产技术效果的主要挑战。在此，我们研究了外源引入捕食菌改变浮萍微生物组的潜力。捕食菌 Bacteriovorax sp. HI3 定植在浮萍微生物组核心，其捕食行为改变了微生物组结构，这与定植密度相关。这些结果揭示了细菌捕食相互作用可能是塑造浮萍微生物组的重要驱动力，表明它们在修饰微生物组方面具有潜在的用处。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c1d7/10522839/c8c5a9bf0cc5/38_23040-g001.jpg

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捕食性细菌定殖浮萍微生物组并改变其结构的潜力：使用专性捕食菌，Bacteriovorax sp. HI3 的模型研究。

Potential of Predatory Bacteria to Colonize the Duckweed Microbiome and Change Its Structure: A Model Study Using the Obligate Predatory Bacterium, Bacteriovorax sp. HI3.

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