Department of Microbiology and Immunology, Wake Forest School of Medicine, Winston-Salem, North Carolina, USA.
Department of Microbiology, New York University, New York, New York, USA.
mBio. 2019 Jun 18;10(3):e01032-19. doi: 10.1128/mBio.01032-19.
Host-to-host transmission is a necessary but poorly understood aspect of microbial pathogenesis. Herein, we screened a genomic library of mutants of the leading respiratory pathogen generated by mariner transposon mutagenesis (Tn-Seq) to identify genes contributing to its exit or shedding from the upper respiratory tract (URT), the limiting step in the organism's transmission in an infant mouse model. Our analysis focused on genes affecting the bacterial surface that directly impact interactions with the host. Among the multiple factors identified was the locus, which adds d-alanine onto lipoteichoic acids (LTA) and thereby increases Toll-like receptor 2-mediated inflammation and resistance to antimicrobial peptides. The more robust proinflammatory response in the presence of d-alanylation promotes secretions that facilitate pneumococcal shedding and allows for transmission. Expression of the locus is controlled by the CiaRH system, which senses cell wall stress in response to antimicrobial activity, including in response to lysozyme, the most abundant antimicrobial along the URT mucosa. Accordingly, in a host, there was no longer an effect of the locus on pneumococcal shedding. Thus, our findings demonstrate how a pathogen senses the URT milieu and then modifies its surface characteristics to take advantage of the host response for transit to another host. (the pneumococcus) is a common cause of respiratory tract and invasive infection. The overall effectiveness of immunization with the organism's capsular polysaccharide depends on its ability to block colonization of the upper respiratory tract and thereby prevent host-to-host transmission. Because of the limited coverage of current pneumococcal vaccines, we carried out an unbiased transposon mutagenesis screen to identify pneumococcal factors other than its capsular polysaccharide that affect transmission. One such candidate was expressed by the locus, previously shown to add d-alanine onto the pneumococcal lipoteichoic acid present on the bacterial cell surface. This modification protects against host antimicrobials and augments host inflammatory responses. The latter increases secretions and bacterial shedding from the upper respiratory tract to allow for transmission. Thus, this study provides insight into a mechanism employed by the pneumococcus to successfully transit from one host to another.
宿主间传播是微生物发病机制中一个必要但了解甚少的方面。在此,我们通过转座子突变(Tn-Seq)筛选了主要呼吸道病原体的突变基因文库,以鉴定导致其从上呼吸道(URT)排出或脱落的基因,这是该病原体在婴儿小鼠模型中传播的限制步骤。我们的分析重点是影响细菌表面的基因,这些基因直接影响与宿主的相互作用。在确定的多个因素中,是 基因座,它将 D-丙氨酸添加到脂磷壁酸(LTA)中,从而增加 Toll 样受体 2 介导的炎症和对抗生素肽的抵抗力。在 D-丙氨酸化存在的情况下,更强的促炎反应促进了有助于肺炎球菌脱落和传播的分泌物的产生。该基因座的表达受 CiaRH 系统控制,该系统响应包括溶菌酶在内的抗微生物活性(URT 黏膜上最丰富的抗菌剂)感知细胞壁应激。因此,在 宿主中, 基因座对肺炎球菌脱落的影响不再存在。因此,我们的研究结果表明,病原体如何感知 URT 环境,然后修饰其表面特性,以利用宿主反应进行转移到另一个宿主。(肺炎球菌)是呼吸道和侵袭性感染的常见原因。用该生物体荚膜多糖进行免疫接种的总体效果取决于其阻止上呼吸道定植的能力,从而防止宿主间传播。由于目前肺炎球菌疫苗的覆盖范围有限,我们进行了一项无偏转座子突变筛选,以确定除其荚膜多糖之外影响传播的肺炎球菌因素。候选物之一由 基因座表达,该基因座先前被证明可将 D-丙氨酸添加到细菌细胞表面存在的肺炎球菌脂磷壁酸上。这种修饰可防止宿主的抗微生物作用,并增强宿主的炎症反应。后者增加了从上呼吸道的分泌物和细菌脱落,从而允许传播。因此,这项研究提供了对肺炎球菌从一个宿主成功过渡到另一个宿主所采用的机制的深入了解。
