Mahmud A K M Firoj, Nilsson Kristina, Fahlgren Anna, Navais Roberto, Choudhury Rajdeep, Avican Kemal, Fällman Maria
Department of Molecular Biology, Laboratory for Molecular Infection Medicine Sweden (MIMS), Umeå Centre for Microbial Research (UCMR), Umeå University, Umeå, Sweden.
Department of Molecular Biology, Laboratory for Molecular Infection Medicine Sweden (MIMS), Umeå Centre for Microbial Research (UCMR), Umeå University, Umeå, Sweden
mSystems. 2020 Nov 10;5(6):e01006-20. doi: 10.1128/mSystems.01006-20.
RpoN, an alternative sigma factor commonly known as σ, is implicated in persistent stages of infections in which genes associated with this regulator are upregulated. We here combined phenotypic and genomic assays to provide insight into its role and function in this pathogen. RpoN was found essential for virulence in mice, and functional assays showed that it controls biofilm formation and motility. Mapping genome-wide associations of RpoN using chromatin immunoprecipitation coupled with next-generation sequencing identified an RpoN binding motif located at 103 inter- and intragenic sites on both sense and antisense strands. Deletion of had a large impact on gene expression, including downregulation of genes encoding proteins involved in flagellar assembly, chemotaxis, and quorum sensing. There were also clear indications of cross talk with other sigma factors, together with indirect effects due to altered expression of other regulators. Matching differential gene expression with locations of the binding sites implicated around 130 genes or operons potentially activated or repressed by RpoN. Mutagenesis of selected intergenic binding sites confirmed both positive and negative regulatory effects of RpoN binding. Corresponding mutations of intragenic sense sites had less impact on associated gene expression. Surprisingly, mutating intragenic sites on the antisense strand commonly reduced expression of genes carried by the corresponding sense strand. The alternative sigma factor RpoN (σ), which is widely distributed in eubacteria, has been implicated in controlling gene expression of importance for numerous functions including virulence. Proper responses to host environments are crucial for bacteria to establish infection, and regulatory mechanisms involved are therefore of high interest for development of future therapeutics. Little is known about the function of RpoN in the intestinal pathogen , and we therefore investigated its regulatory role in this pathogen. This regulator was indeed found to be critical for establishment of infection in mice, likely involving its requirement for motility and biofilm formation. The RpoN regulon involved both activating and suppressive effects on gene expression which could be confirmed with mutagenesis of identified binding sites. This is the first study of its kind of RpoN in , revealing complex regulation of gene expression involving both productive and silent effects of its binding to DNA, providing important information about RpoN regulation in enterobacteria.
RpoN是一种通常被称为σ的替代西格玛因子,与感染的持续阶段有关,在这些阶段中,与该调节因子相关的基因会上调。我们在此结合表型和基因组分析,以深入了解其在这种病原体中的作用和功能。发现RpoN对小鼠的毒力至关重要,功能分析表明它控制生物膜形成和运动性。使用染色质免疫沉淀结合下一代测序对RpoN进行全基因组关联图谱分析,确定了一个位于有义链和反义链上103个基因间和基因内位点的RpoN结合基序。缺失对基因表达有很大影响,包括下调编码参与鞭毛组装、趋化性和群体感应的蛋白质的基因。也有与其他西格玛因子相互作用的明确迹象,以及由于其他调节因子表达改变而产生的间接影响。将差异基因表达与结合位点的位置相匹配,表明约130个基因或操纵子可能被RpoN激活或抑制。对选定基因间结合位点的诱变证实了RpoN结合的正负调节作用。基因内有义位点的相应突变对相关基因表达的影响较小。令人惊讶的是,反义链上基因内位点的突变通常会降低相应有义链携带基因的表达。替代西格玛因子RpoN(σ)广泛分布于真细菌中,与控制包括毒力在内的多种功能重要的基因表达有关。对宿主环境的适当反应对细菌建立感染至关重要,因此所涉及的调节机制对未来治疗方法的开发具有高度意义。关于RpoN在肠道病原体中的功能知之甚少,因此我们研究了它在这种病原体中的调节作用。确实发现该调节因子对小鼠感染的建立至关重要,可能涉及其对运动性和生物膜形成的需求。RpoN调控子对基因表达既有激活作用也有抑制作用,这可以通过对已鉴定结合位点的诱变来证实。这是首次在该病原体中对RpoN进行此类研究,揭示了基因表达的复杂调控,包括其与DNA结合的有效和沉默效应,为肠杆菌中的RpoN调节提供了重要信息。
