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Characterization of the ETEC Virulence Regulator Rns

ETEC 毒力调节剂 Rns 的表征

基本信息

批准号：
7578244
负责人：
GEORGE Patrick MUNSON
金额：
$ 40.48万
依托单位：
UNIVERSITY OF MIAMI SCHOOL OF MEDICINE
依托单位国家：
美国
项目类别：
财政年份：
2005
资助国家：
美国
起止时间：
2005-02-01 至 2011-01-31
项目状态：
已结题

项目摘要

DESCRIPTION (provided by the applicant): Worldwide enterotoxigenic E. coli (ETEC) cause an estimated 210 million episodes of diarrheal disease and 380,000 deaths annually. The impact of this pathogen is greatest among infants and children less than 5 years of age. Adherence of the pathogen to the intestinal mucosa of the host is essential for the establishment of an infection. Attachment is usually achieved by pili which bind specific host receptors. The expression of CS1 and CS2 pili is positively regulated at the level of transcription by Rns a member of the AraC/XylS family. There are two Rns binding sites immediately upstream of the CS1 pilin promoter, within the region expected for a typical prokaryotic activator. Rns also positively autoregulates its own expression, however it does so through a highly unusual arrangement of DNA binding sites. Rns requires two DNA binding sites for the activation of its own promoter Prns. One of these is site 1 which is centered 224.5 bp upstream of the transcription start site (TSS), considerably further upstream than expected. Even more unusual is the location of site 3, which is centered 83.5 bp downstream of the TSS. Only a few prokaryotic activators are known to have binding sites downstream of the -10 hexamer. However we have shown that the virulence regulators VirF from Shigella flexneri, CfaR from ETEC, and AggR from enteroaggregative E. coli are also capable of activating Prns and like Rns, each requires the downstream binding site to do so. To date Rns is the only virulence regulator within this group for which an in vitro system has been developed. Thus our in vitro system, coupled with complimentary genetic analysis, affords us an outstanding opportunity to use Rns as a model system for a group of related regulators. These regulators are essential for the virulence of several pathogenic species of bacteria that collectively kill over 2 million people, predominantly children and infants, every year. A detailed understanding of these homologous regulators may eventually lead to new applications for disease treatment and prevention, such as attenuation of bacterial virulence by targeting the function of conserved virulence regulators. Our proposed studies will also provide new and fundamentally important information about transcription and its regulation because of the unique features of Rns autoregulation. These include activation from a downstream binding site and the potential repression of Prns by nonproductive RNAP open (RPo) complexes. Studies in this proposal will determine the molecular mechanism of Rns positive autoregulation and the biological significance of Rns-independent, nonproductive RPo complexes near Prns.

描述（由申请人提供）：全世界产肠毒素大肠杆菌（ETEC）每年导致约2.1亿例腹泻病和38万例死亡。这种病原体对婴儿和5岁以下儿童的影响最大。病原体附着在宿主的肠黏膜上对于感染的建立是必不可少的。附着通常是通过结合特定宿主受体的毛来实现的。作为AraC/XylS家族成员的Rns在转录水平上正调控CS1和CS2菌毛的表达。在CS1 pilin启动子的上游有两个Rns结合位点，位于典型的原核激活子的预期区域内。Rns也积极地自动调节其自身的表达，然而它是通过一种非常不寻常的DNA结合位点的排列来实现的。Rns需要两个DNA结合位点来激活它自己的启动子prn。其中一个是位于转录起始位点（TSS）上游224.5 bp的1号位点，比预期的要远得多。更不寻常的是3号位点的位置，它位于TSS下游83.5 bp的中心。已知只有少数原核激活剂具有-10六聚体下游的结合位点。然而，我们已经证明来自福氏志贺氏菌的毒力调节因子VirF，来自ETEC的CfaR和来自肠聚集性大肠杆菌的AggR也能够激活Prns，并且像Rns一样，它们都需要下游结合位点才能激活。迄今为止，Rns是这一群体中唯一一个体外系统已开发的毒力调节剂。因此，我们的体外系统，加上互补的遗传分析，为我们提供了一个很好的机会，将Rns作为一组相关调节因子的模型系统。这些调节因子对几种致病性细菌的毒力至关重要，这些细菌每年导致200多万人死亡，主要是儿童和婴儿。对这些同源调节因子的详细了解可能最终导致疾病治疗和预防的新应用，例如通过靶向保守的毒力调节因子的功能来减弱细菌毒力。由于Rns自动调控的独特特征，我们提出的研究也将提供关于转录及其调控的新的重要信息。这些包括来自下游结合位点的激活和非生产性RNAP开放（RPo）复合物对Prns的潜在抑制。本课题的研究将确定Rns正向自动调节的分子机制，以及Prns附近非Rns独立的非生产性RPo复合物的生物学意义。