Endophyte Bacillus subtilis evade plant defense by producing lantibiotic subtilomycin to mask self-produced flagellin

Microbes can enter into healthy plants as endophytes and confer beneficial functions. The entry of commensal microbes into plants involves penetrating plant defense. Most mechanisms about overcoming plant defense are focused on adapted pathogens, while the mechanism involved in beneficial endophyte...

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Published in:Communications biology 2019-10, Vol.2 (1), p.368
Main Authors: Deng, Yun, Chen, Hanqiao, Li, Congzhi, Xu, Jianyi, Qi, Qingdong, Xu, Yuanyuan, Zhu, Yiguang, Zheng, Jinshui, Peng, Donghai, Ruan, Lifang, Sun, Ming
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container_title Communications biology
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creator Deng, Yun
Chen, Hanqiao
Li, Congzhi
Xu, Jianyi
Qi, Qingdong
Xu, Yuanyuan
Zhu, Yiguang
Zheng, Jinshui
Peng, Donghai
Ruan, Lifang
Sun, Ming
description Microbes can enter into healthy plants as endophytes and confer beneficial functions. The entry of commensal microbes into plants involves penetrating plant defense. Most mechanisms about overcoming plant defense are focused on adapted pathogens, while the mechanism involved in beneficial endophyte evades plant defense to achieve harmonious commensalism is unclear. Here, we discover a mechanism that an endophyte bacterium Bacillus subtilis BSn5 reduce to stimulate the plant defensive response by producing lantibiotic subtilomycin to bind self-produced flagellin. Subtilomycin bind with flagellin and affect flg22-induced plant defense, by which means promotes the endophytic colonization in A. thaliana. Subtilomycin also promotes the BSn5 colonization in a distinct plant, Amorphophallus konjac, where the BSn5 was isolated. Our investigation shows more independent subtilomycin/-like producers are isolated from distinct plants. Our work unveils a common strategy that is used for bacterial endophytic colonization.
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title Endophyte Bacillus subtilis evade plant defense by producing lantibiotic subtilomycin to mask self-produced flagellin
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