Lydick Victoria N, Mass Shir, Pepin Robert, Podicheti Ram, Klempic Emra, Rusch Douglas B, Ushijima Blake, Brown Laura C, Salomon Dor, van Kessel Julia C
Department of Biology, Indiana University, Bloomington, Indiana, USA.
Department of Clinical Microbiology and Immunology, School of Medicine, Faculty of Medical and Health Sciences, Tel Aviv University, Tel Aviv, Israel.
Appl Environ Microbiol. 2025 Feb 19;91(2):e0114324. doi: 10.1128/aem.01143-24. Epub 2025 Jan 15.
The bacterial pathogen causes disease in coral species worldwide. The mechanisms of coral colonization, coral microbiome interactions, and virulence factor production are understudied. In other model species, virulence factors like biofilm formation, toxin secretion, and protease production are controlled through a density-dependent communication system called quorum sensing (QS). Comparative genomics indicated that genomes share high sequence identity for most of the QS signaling and regulatory components identified in other species. Here, we identify an active QS signaling pathway in two strains with distinct infection etiologies: type strain BAA-450 and coral isolate OCN008. In , the inter-species AI-2 autoinducer signaling pathway in both strains controls expression of the master QS transcription factor and LuxR/HapR homolog VcpR to regulate >300 genes, including protease production, biofilm formation, and two conserved type VI secretion systems (T6SSs). Activation of T6SS1 by QS results in the secretion of effectors and enables interbacterial competition and killing of prey bacteria. We conclude that the QS system in is functional and controls the expression of genes involved in relevant bacterial behaviors typically associated with host infection.IMPORTANCE infects many marine organisms, including multiple species of corals, and is a primary causative agent of tissue loss diseases and bacterial-induced bleaching. Here, we investigated a common cell-cell communication mechanism called quorum sensing, which is known to be intimately connected to virulence in other species. Our genetic and chemical studies of quorum sensing uncovered an active pathway that directly regulates the following key virulence factors: proteases, biofilms, and secretion systems. These findings connect bacterial signaling in communities to the infection of corals, which may lead to novel treatments and earlier diagnoses of coral diseases in reefs.
这种细菌病原体在全球范围内的珊瑚物种中引发疾病。关于其在珊瑚上定殖的机制、与珊瑚微生物群的相互作用以及毒力因子的产生,目前研究较少。在其他模式物种中,诸如生物膜形成、毒素分泌和蛋白酶产生等毒力因子是通过一种名为群体感应(QS)的密度依赖性通讯系统来控制的。比较基因组学表明,对于在其他物种中鉴定出的大多数QS信号传导和调控成分,该细菌的基因组具有高度的序列同一性。在此,我们在具有不同感染病因的两种菌株中鉴定出一条活跃的QS信号通路:模式菌株BAA - 450和珊瑚分离株OCN008。在该细菌中,两种菌株的种间AI - 2自诱导物信号通路控制着主要QS转录因子以及LuxR/HapR同源物VcpR的表达,以调控300多个基因,包括蛋白酶产生、生物膜形成以及两个保守的VI型分泌系统(T6SSs)。QS对T6SS1的激活导致效应物的分泌,并实现细菌间的竞争以及对猎物细菌的杀伤。我们得出结论,该细菌中的QS系统具有功能,并控制着与通常与宿主感染相关的细菌行为有关的基因表达。重要性:该细菌感染许多海洋生物,包括多种珊瑚,并且是组织损失疾病和细菌诱导的白化的主要病原体。在此,我们研究了一种名为群体感应的常见细胞间通讯机制,已知该机制在其他物种中与毒力密切相关。我们对该细菌群体感应的遗传和化学研究发现了一条直接调控以下关键毒力因子的活跃通路:蛋白酶、生物膜和分泌系统。这些发现将群落中的细菌信号传导与珊瑚感染联系起来,这可能会带来珊瑚礁珊瑚疾病的新治疗方法和早期诊断。
