单一启动子反转可使 Photorhabdus 在致病和共生状态之间切换。
A single promoter inversion switches Photorhabdus between pathogenic and mutualistic states.
机构信息
Department of Microbiology and Molecular Genetics, Michigan State University, East Lansing, MI 48824, USA.
出版信息
Science. 2012 Jul 6;337(6090):88-93. doi: 10.1126/science.1216641.
Abstract
Microbial populations stochastically generate variants with strikingly different properties, such as virulence or avirulence and antibiotic tolerance or sensitivity. Photorhabdus luminescens bacteria have a variable life history in which they alternate between pathogens to a wide variety of insects and mutualists to their specific host nematodes. Here, we show that the P. luminescens pathogenic variant (P form) switches to a smaller-cell variant (M form) to initiate mutualism in host nematode intestines. A stochastic promoter inversion causes the switch between the two distinct forms. M-form cells are much smaller (one-seventh the volume), slower growing, and less bioluminescent than P-form cells; they are also avirulent and produce fewer secondary metabolites. Observations of form switching by individual cells in nematodes revealed that the M form persisted in maternal nematode intestines, were the first cells to colonize infective juvenile (IJ) offspring, and then switched to P form in the IJ intestine, which armed these nematodes for the next cycle of insect infection.
摘要
微生物种群会随机产生具有明显不同特性的变体,例如毒力或无毒力以及抗生素耐受性或敏感性。发光杆菌的细菌在其生活史中具有可变性,它们在多种昆虫的病原体和特定宿主线虫的共生体之间交替。在这里,我们表明,发光杆菌的病原体变体(P 形式)会切换为更小细胞的变体(M 形式),从而在宿主线虫的肠道中启动共生关系。随机启动子反转导致两种不同形式之间的切换。M 形式的细胞小得多(体积为七分之一),生长速度较慢,生物发光能力也较弱,而 P 形式的细胞无毒,产生的次生代谢产物也较少。对单个细胞在线虫中进行形式转换的观察表明,M 形式在母体线虫的肠道中持续存在,是第一个定植感染性幼虫(IJ)后代的细胞,然后在 IJ 肠道中切换为 P 形式,这使这些线虫能够为下一轮昆虫感染做好准备。
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