RpoS activates formation of Salmonella Typhi biofilms and drives persistence in the gall bladder.

Stuti K Desai, Yiyang Zhou, Rahul Dilawari, Andrew L Routh, Vsevolod Popov, Linda J Kenney
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Abstract

The development of strategies for targeting the asymptomatic carriage of Salmonella Typhi in chronic typhoid patients has suffered owing to our basic lack of understanding of the molecular mechanisms that enable the formation of S. Typhi biofilms. Traditionally, studies have relied on cholesterol-attached biofilms formed by a closely related serovar, Typhimurium, to mimic multicellular Typhi communities formed on human gallstones. In long-term infections, S. Typhi adopts the biofilm lifestyle to persist in vivo and survive in the carrier state, ultimately leading to the spread of infections via the fecal-oral route of transmission. In the present work, we studied S. Typhi biofilms directly, applied targeted as well as genome-wide genetic approaches to uncover unique biofilm components that do not conform to the CsgD-dependent pathway established in S. Typhimurium. We undertook a genome-wide Tn5 mutation screen in H58, a clinically relevant multidrug resistance strain of S. Typhi, in gallstone-mimicking conditions. We generated New Generation Sequencing libraries based on the ClickSeq technology to identify the key regulators, IraP and RpoS, and the matrix components Sth fimbriae, Vi capsule and lipopolysaccharide. We discovered that the starvation sigma factor, RpoS, was required for the transcriptional activation of matrix-encoding genes in vitro, and for S. Typhi colonization in persistent infections in vivo, using a heterologous fish larval model. An rpoS null mutant failed to colonize the gall bladder in chronic zebrafish infections. Overall, our work uncovered a novel RpoS-driven, CsgD-independent paradigm for the formation of cholesterol-attached Typhi biofilms, and emphasized the role(s) of stress signaling pathways for adaptation in chronic infections. Our identification of the biofilm regulators in S. Typhi paves the way for the development of drugs against typhoid carriage, which will ultimately control the increased incidence of gall bladder cancer in typhoid carriers.

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在斑马鱼模型中,RpoS激活伤寒沙门氏菌生物膜并驱动持久性。
针对慢性伤寒患者无症状携带伤寒沙门菌的策略的发展受到影响,因为我们基本缺乏对形成伤寒沙门菌生物膜的分子机制的理解。传统上,研究依赖于由一种密切相关的血清型鼠伤寒菌形成的胆固醇附着生物膜来模拟在人类胆结石上形成的多细胞鼠伤寒菌群。在长期感染中,伤寒沙门氏菌采用生物膜生活方式在体内持续存在,以载体状态生存,最终导致感染通过粪-口传播途径传播。在目前的工作中,我们直接研究了伤寒沙门氏菌的生物膜,应用靶向和全基因组遗传方法来发现独特的生物膜成分,这些成分不符合在伤寒沙门氏菌中建立的csgd依赖途径。我们在模拟胆结石条件下对伤寒沙门氏菌进行全基因组Tn5突变筛选,并基于ClickSeq技术生成New Generation Sequencing文库,鉴定关键调控因子IraP和RpoS,基质成分为Sth菌膜、Vi胶囊和脂多糖。我们发现饥饿sigma因子,RpoS,是体外基质编码基因转录激活所必需的,并且是使用异种鱼幼虫模型在体内持续感染的伤寒沙门氏菌定殖所必需的。总的来说,我们的工作建立了一种新的rpos驱动的范式,用于形成胆固醇附着的伤寒生物膜,并强调了应激信号通路在慢性感染中的适应作用。
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