ABSTRACT Clostridium difficile is the most common cause of antibiotic-associated intestinal infections and a significant cause of morbidity and mortality. Infection with C.?difficile requires disruption of the intestinal microbiota, most commonly by antibiotic usage. Therapeutic intervention largely relies on a small number of broad-spectrum antibiotics, which further exacerbate intestinal dysbiosis and leave the patient acutely sensitive to reinfection. Development of novel targeted therapeutic interventions will require a detailed knowledge of essential cellular processes, which represent attractive targets, and species-specific processes, such as bacterial sporulation. Our knowledge of the genetic basis of C.?difficile infection has been hampered by a lack of genetic tools, although recent developments have made some headway in addressing this limitation. Here we describe the development of a method for rapidly generating large numbers of transposon mutants in clinically important strains of C.?difficile . We validated our transposon mutagenesis approach in a model strain of C.?difficile and then generated a comprehensive transposon library in the highly virulent epidemic strain R20291 (027/BI/NAP1) containing more than 70,000 unique mutants. Using transposon-directed insertion site sequencing (TraDIS), we have identified a core set of 404 essential genes, required for growth in vitro . We then applied this technique to the process of sporulation, an absolute requirement for C.?difficile transmission and pathogenesis, identifying 798 genes that are likely to impact spore production. The data generated in this study will form a valuable resource for the community and inform future research on this important human pathogen. IMPORTANCE Clostridium difficile is a common cause of potentially fatal intestinal infections in hospital patients, particularly those who have been treated with antibiotics. Our knowledge of this bacterium has been hampered by a lack of tools for dissecting the organism. We have developed a method to study the function of every gene in the bacterium simultaneously. Using this tool, we have identified a set of 404 genes that are required for growth of the bacteria in the laboratory. C.?difficile also produces a highly resistant spore that can survive in the environment for a long time and is a requirement for transmission of the bacteria between patients. We have applied our genetic tool to identify all of the genes required for production of a spore. All of these genes represent attractive targets for new drugs to treat infection.
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机译:摘要艰难梭菌是抗生素相关的肠道感染的最常见原因,也是发病率和死亡率的重要原因。难辨梭状芽胞杆菌的感染需要破坏肠道菌群,通常是通过使用抗生素来破坏。治疗干预在很大程度上依赖于少数广谱抗生素,这进一步加剧了肠道营养不良,并使患者对再感染极为敏感。新型靶向治疗干预措施的开发将需要基本细胞过程(代表有吸引力的靶标)以及物种特异性过程(例如细菌孢子形成)的详细知识。尽管缺乏新的遗传工具,但我们对艰难梭菌感染的遗传基础的认识受到阻碍,尽管最近的发展在解决这一局限性方面取得了一些进展。在这里,我们描述了一种在临床上重要的艰难梭菌菌株中快速产生大量转座子突变体的方法的开发。我们在艰难梭菌的模型菌株中验证了我们的转座子诱变方法,然后在含有超过70,000个独特突变体的高毒流行株R20291(027 / BI / NAP1)中生成了一个综合的转座子文库。使用转座子定向插入位点测序(TraDIS),我们已经确定了404种必需基因的核心集,这些核心是体外生长所必需的。然后,我们将此技术应用于孢子形成过程,这是艰难梭菌传播和发病机理的绝对要求,确定了可能影响孢子产生的798个基因。这项研究中产生的数据将为社区提供宝贵的资源,并为该重要人类病原体的未来研究提供信息。重要说明艰难梭菌是医院患者尤其是经抗生素治疗的患者潜在致命肠感染的常见原因。我们对这种细菌的了解由于缺乏解剖该生物的工具而受到阻碍。我们已经开发出一种方法来同时研究细菌中每个基因的功能。使用此工具,我们已经确定了实验室中细菌生长所需的404个基因集。艰难梭菌还产生高度抗性的孢子,该孢子可在环境中长期生存,并且是细菌在患者之间传播的要求。我们已经应用了遗传工具来鉴定产生孢子所需的所有基因。所有这些基因代表了治疗感染的新药的诱人靶标。
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