A periplasmic global regulator, ExoR, for Bacterial invasion of host cells

细菌入侵宿主细胞的周质全局调节因子 ExoR

• 批准号: 7909349
• 负责人: HAI-PING CHENG
• 金额: $ 13.48万
• 依托单位: HERBERT H. LEHMAN COLLEGE
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-09-01 至 2011-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7909349
• 关键词: Ammonia; Antibiotics; Bacteria; Bacterial Infections; Binding; Brucella abortus; Cells; Data; Development; Environment; Figs - dietary; Foundations; Funding; Gene Expression; Genes; Genetic; Glycosaminoglycans; Grant; Hair Cells; Health; Laboratories; Lead; Location; Longitudinal Studies; Membrane; Membrane Proteins; Microbiology; Minority; Modification; Molecular; Molecular Conformation; Multi-Drug Resistance; Peer Review; Periplasmic Proteins; Plant Roots; Post-Translational Modification Site; Post-Translational Protein Processing; Production; Protein Binding Domain; Proteins; Publications; Published Comment; Research; Research Personnel; Research Project Grants; Research Support; Role; Signal Pathway; Signal Transduction; Signal Transduction Pathway; Sinorhizobium meliloti; Site; Solid; Staging; Students; System; Testing; Time; Training; Virulence Factors; Work; base; career; college; design; fighting; graduate student; improved; insight; membrane activity; novel strategies; pathogen; periplasm; protein function; sensor; success

DESCRIPTION (provided by applicant): Bacterial infection is and will continue to be a major health threat, especially with the development of multiple drug resistant pathogens. The success of bacterial infection depends on the ability of bacteria to sense the presence of host cells and produce virulence factors at the right time. Finding a common feature among the diverse array of bacterial sensing sensors can yield effective targets for new antibiotics to fight bacterial infection. In our study of signal transduction required for the invasion of host root hair cells by Sinorhizobium meliloti, we found a bacterial periplasmic protein, ExoR, that appears to regulate the activities of membrane sensors of two-component regulatory systems, which regulate the production of bacterial virulence factors. Our current hypothesis is that ExoR is a global regulator controlling bacterial host cell invasion. ExoR responds to upstream or external signals through the changing of structural conformation or levels of exoR gene expression. The active form of ExoR protein interacts with other membrane sensors such as ExoS and FixL in regulating the expression of genes required for host cell invasion. This hypothesis is developed based on our previous work and the following new findings made in our lab. First, ExoR is a periplasmic protein. Second, ExoR regulates the expression of more than 700 genes. Third, the expression of the exoR gene is regulated by ammonia and the ExoR protein appears to have a site for post-translational modification. Fourth, genetic evidences suggest that ExoR functions directly upstream of the ExoS/Chvl signal transduction pathway. To test the hypothesis, we plan to focus on accomplishing two specific aims. The first is to characterize the signaling mechanism of ExoR by (a) identifying the nodulation stage that requires the function of ExoR; (b) determining the cellular location of ExoR and its glycosaminoglycan modification; and (c) identifying ExoR protein-protein interaction domains. The second is to characterize ExoR-ExoS interactions by (a) characterizing molecular interaction between ExoR and ExoS; (b) identifying regions of ExoR and ExoS that are important for their signaling functions; and (c) determining the global regulatory function of ExoR. This work will provide the first insight for the molecular signaling mechanism of a periplasmic protein and provide a solid base for broad analysis of the global regulatory function of the protein, which will lead to the identification of targets for new classes of antibiotics.

描述（由申请人提供）：细菌感染是并且将继续是主要的健康威胁，尤其是随着多种耐药病原体的发展。细菌感染的成功取决于细菌在适当时间内感知宿主细胞的存在并产生毒力因子的能力。在各种细菌传感传感器阵列中找到共同特征可以为新抗生素抗击细菌感染的有效靶标。在我们对Sinorhizobium Meliloti侵袭宿主根毛细胞所需的信号转导的研究中，我们发现了一种细菌性周质蛋白Exor，它似乎调节了两种分量调节系统的膜传感器的活性，该系统调节了细菌毒力因子的产生。我们目前的假设是，Exor是控制细菌宿主细胞侵袭的全球调节剂。 Exor通过改变结构构象或Exor基因表达水平来响应上游或外部信号。 Exor蛋白的活性形式与其他膜传感器（例如EXOS和FIXL）相互作用，以调节宿主细胞浸润所需的基因表达。该假设是基于我们以前的工作以及我们实验室中提出的以下新发现制定的。首先，exor是一种周质蛋白。其次，Exor调节了700多个基因的表达。第三，Exor基因的表达受氨调节，Exor蛋白似乎具有用于翻译后修饰的部位。第四，遗传证据表明，EXOR功能直接在EXOS/CHVL信号转导途径的上游。 为了检验该假设，我们计划专注于实现两个具体目标。首先是通过（a）识别需要Exor功能的结节阶段来表征Exor的信号传导机理； （b）确定exor的细胞位置及其糖胺聚糖修饰； （c）识别驱虫蛋白 - 蛋白质相互作用结构域。第二个是通过（a）表征exor和exos之间的分子相互作用来表征exor-exos相互作用； （b）识别对其信号功能很重要的exor和exos的区域； （c）确定exor的全局调节功能。这项工作将为周围蛋白质的分子信号传导机制提供第一个见解，并为蛋白质的全球调节功能提供了稳固的基础，这将导致鉴定新的抗生素类别的靶标。