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Chaperone Mining of the Chlamydia Type Three Secretion System

衣原体三型分泌系统的伴侣挖掘

基本信息

批准号：
7242501
负责人：
ELLENA Marie PETERSON
金额：
$ 35.91万
依托单位：
UNIVERSITY OF CALIFORNIA-IRVINE
依托单位国家：
美国
项目类别：
财政年份：
2006
资助国家：
美国
起止时间：
2006-07-01 至 2011-06-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7242501
关键词：
Appearance Attenuated Bacteria Bacterial Typing Binding Biological Assay Cells Characteristics Chlamydia Chlamydia Infections Chlamydia trachomatis Chromosome Mapping Chromosomes Class Cloning Complex Cytosol DNA-Directed RNA Polymerase Development Electrons Elements Event Gene Expression Gene Structure Genes Genetic Genetic Transcription Genomics Goals Gram-Negative Bacteria Growth Harvest Immunoelectron Microscopy Immunologics Infection prevention Invaded Lead Libraries Light Location Maps Methods Microscopic Mining Molecular Chaperones Nature Pathogenicity Island Plasmids Play Prevention Principal Investigator Property Protein Secretion Proteins Public Health Recombinant Proteins Regulation Regulatory Element Relative (related person)Reporting Research Personnel Reverse Transcriptase Polymerase Chain Reaction Role Sexually Transmitted Diseases Signal Transduction Staging Structural Genes System Testing Time Transcriptional Regulation Virulence Work Yersinia base design genetic regulatory protein pathogen prevent programs promoter protein function tool transcription factor yeast two hybrid system

项目摘要

DESCRIPTION (provided by applicant): Chlamydia trachomatis is a leading cause of sexually transmitted diseases. Understanding how this pathogen invades and replicates in host cells is fundamental to our efforts to design effective therapies that can aid in the prevention of Chlamydia infections. It has recently been shown that Chlamydia possesses genes for a type three secretion (TTS) system. In other bacteria TTS systems are a powerful virulence component shared by pathogens that allow them to subvert and invade the host. TTS systems are composed of several proteins that interact in a highly regulated manner. Chlamydia does not have a classic genetic system with which to study this complex system, thereby making this a challenging task. However, a common element to all TTS systems are the TTS chaperones which serve as a lynchpin interacting with other TTS key elements, namely, structural, effectors and regulatory proteins. We plan to exploit TTS chaperones in order to identify and characterize other key chlamydial TTS proteins. Once identified the role these proteins play, i.e. effectors, translocon or transcriptional regulator, will be established. Specifically in Aim 1 we will use TTS chaperones as bait in pull down assays and in a bacterial two-hybrid system, using targeted and genomic-wide cloning. To further characterize the proteins identified, in Aim 2 we will establish the temporal relationship of the proteins to the Chlamydia developmental cycle. Proteins will be characterized as to time of appearance and location throughout the developmental cycle, using RT-PCR, light and immuno-electron microscopy. We will also establish if proteins identified have a characteristic property of a TTS effector molecule by determining if they can be secreted by a heterologous TTS system. In other pathogens, proteins interacting with TTS chaperones have been shown to play a role in transcriptional regulation of TTS. However, nothing is known of the regulation of the Chlamydia TTS so we will first have to establish the transcriptional organization in order to determine whether the proteins identified have a role in the transcriptional regulation of the Chlamydia TTS. This will be accomplished in Aim 3 by: mapping promoters and determining the form of RNA polymerase responsible for transcription; identifying transcriptional regulators by binding to predicted regulatory elements; finally, testing the proteins identified in Aim 1 for their potential to function as a transcriptional regulator. Accomplishing these goals will aid in finding and putting the pieces of the TTS puzzle together to determine how this system functions in Chlamydia. Preventing and controlling Chlamydia infections is of great public health concern. Having an understanding of the critical elements of the Chlamydia TTS system should lead to the development of strategies to subvert the TTS system with the ultimate goal of attenuating or preventing infections with this pathogen.

描述（由申请人提供）：沙眼衣原体是性传播疾病的主要原因。了解这种病原体如何在宿主细胞中入侵和复制，对于我们设计有效的治疗方法以帮助预防衣原体感染至关重要。最近的研究表明，衣原体具有三型分泌（TTS）系统的基因。在其他细菌中，TTS系统是病原体共享的强大毒力成分，使它们能够破坏和入侵宿主。TTS系统由几种以高度调节的方式相互作用的蛋白质组成。衣原体没有一个经典的遗传系统来研究这个复杂的系统，因此这是一个具有挑战性的任务。然而，所有TTS系统的共同元件是TTS分子伴侣，其充当与其他TTS关键元件（即，结构蛋白、效应蛋白和调节蛋白）相互作用的关键。我们计划利用TTS分子伴侣，以确定和表征其他关键衣原体TTS蛋白。一旦确定了这些蛋白质所起的作用，即效应子、转座子或转录调节子，将被确定。具体而言，在目标1中，我们将使用TTS分子伴侣作为诱饵，在下拉测定和细菌双杂交系统中，使用靶向和全基因组克隆。为了进一步表征所鉴定的蛋白质，在目标2中，我们将建立蛋白质与衣原体发育周期的时间关系。将使用RT-PCR、光学和免疫电子显微镜对蛋白质在整个发育周期中的出现时间和位置进行表征。我们还将通过确定所鉴定的蛋白质是否可以由异源TTS系统分泌来确定它们是否具有TTS效应分子的特征性质。在其他病原体中，与TTS分子伴侣相互作用的蛋白质已被证明在TTS的转录调控中发挥作用。然而，没有什么是已知的衣原体TTS的调节，所以我们将首先必须建立转录组织，以确定是否确定的蛋白质在衣原体TTS的转录调节中的作用。这将在目标3中通过以下方式实现：定位启动子并确定负责转录的RNA聚合酶的形式;通过与预测的调控元件结合来鉴定转录调控因子;最后，测试目标1中鉴定的蛋白质作为转录调控因子的潜力。实现这些目标将有助于找到并将TTS拼图的碎片放在一起，以确定该系统如何在衣原体中发挥作用。预防和控制衣原体感染是一个重大的公共卫生问题。了解衣原体TTS系统的关键要素应导致制定策略来颠覆TTS系统，最终目标是减轻或预防这种病原体的感染。