Australian Institute for Microbiology and Infection, University of Technology Sydney, Ultimo, Australia.
Institut Cochin, INSERM U1016, Université de Paris, Paris, France.
mSystems. 2024 Oct 22;9(10):e0038724. doi: 10.1128/msystems.00387-24. Epub 2024 Sep 17.
Uropathogenic (UPEC) requires an adaptable physiology to survive the wide range of environments experienced in the host, including gut and urinary tract surfaces. To identify UPEC genes required during intracellular infection, we developed a transposon-directed insertion-site sequencing approach for cellular infection models and searched for genes in a library of ~20,000 UTI89 transposon-insertion mutants that are specifically required at the distinct stages of infection of cultured bladder epithelial cells. Some of the bacterial functional requirements apparent in host bladder cell growth overlapped with those for M9-glycerol, notably nutrient utilization, polysaccharide and macromolecule precursor biosynthesis, and cell envelope stress tolerance. Two genes implicated in the intracellular bladder cell infection stage were confirmed through independent gene deletion studies: (sialic acid capsule biosynthesis) and (histidine biosynthesis). Distinct sets of UPEC genes were also implicated in bacterial dispersal, where UPEC erupts from bladder cells in highly filamentous or motile forms upon exposure to human urine, and during recovery from infection in a rich medium. We confirm that the gene linked to septal peptidoglycan remodeling is required during UPEC dispersal from human bladder cells and may help stabilize cell division or the cell wall during envelope stress created by host cells. Our findings support a view that the host intracellular environment and infection cycle are multi-nutrient limited and create stress that demands an array of biosynthetic, cell envelope integrity, and biofilm-related functions of UPEC.
Urinary tract infections (UTIs) are one of the most frequent infections worldwide. Uropathogenic (UPEC), which accounts for ~80% of UTIs, must rapidly adapt to highly variable host environments, such as the gut, bladder sub-surface, and urine. In this study, we searched for UPEC genes required for bacterial growth and survival throughout the cellular infection cycle. Genes required for synthesis of biomolecules and cell envelope integrity appeared to be important, and other genes were also implicated in bacterial dispersal and recovery from infection of cultured bladder cells. With further studies of individual gene function, their potential as therapeutic targets may be realized. This study expands knowledge of the UTI cycle and establishes an approach to genome-wide functional analyses of stage-resolved microbial infections.
尿路致病性 (UPEC) 需要适应生理机能以在宿主内经历的广泛环境中存活,包括肠道和泌尿道表面。为了鉴定细胞内感染期间所需的 UPEC 基因,我们针对细胞感染模型开发了转座子定向插入位点测序方法,并在 UTI89 转座子插入突变体文库中搜索特定于培养的膀胱上皮细胞感染阶段的不同阶段所需的基因。在宿主膀胱细胞生长中明显的一些细菌功能要求与 M9-甘油的要求重叠,特别是营养物质利用、多糖和大分子前体生物合成以及细胞包膜应激耐受。通过独立的基因缺失研究证实了两个与细胞内膀胱细胞感染阶段相关的细菌功能要求:(唾液酸胶囊生物合成)和 (组氨酸生物合成)。在细菌扩散阶段,UPEC 也涉及到不同的 UPEC 基因,其中 UPEC 在暴露于人尿时从膀胱细胞中爆发成高度丝状或运动形式,并且在富含培养基中从感染中恢复时也是如此。我们证实与隔膜肽聚糖重塑相关的 基因在 UPEC 从人膀胱细胞中扩散时是必需的,并且可能有助于在宿主细胞产生的包膜应激下稳定细胞分裂或细胞壁。我们的发现支持了这样一种观点,即宿主细胞内环境和感染周期是多种营养物质限制的,并产生了对 UPEC 的各种生物合成、细胞包膜完整性和生物膜相关功能的需求。
尿路感染(UTI)是全球最常见的感染之一。尿路致病性 (UPEC)占 UTI 的约 80%,必须快速适应高度可变的宿主环境,如肠道、膀胱下表面和尿液。在这项研究中,我们搜索了 UPEC 基因,这些基因在整个细胞感染周期中都需要用于细菌的生长和存活。合成生物分子和细胞包膜完整性所需的基因似乎很重要,其他基因也与细菌扩散和从培养的膀胱细胞感染中恢复有关。随着对单个基因功能的进一步研究,它们作为治疗靶点的潜力可能会实现。本研究扩展了 UTI 周期的知识,并建立了一种针对分阶段微生物感染的全基因组功能分析方法。
