Regulatory mechanism of novel host-relevant biofilm formation protein in non-Cholera Vibrio species

非霍乱弧菌中新型宿主相关生物膜形成蛋白的调节机制

基本信息

批准号：
10505474
负责人：
Morgan Eilise Milton
金额：
$ 15.68万
依托单位：
EAST CAROLINA UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2023
资助国家：
美国
起止时间：
2023-08-02 至 2025-07-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10505474
关键词：
Address Bacillus subtilis Bacteria Bacterial Infections Binding Biochemical Biophysics Communities Complex Data Disease Drug resistance Environment Extracellular Matrix Food Poisoning Food Safety Funding Future Gene Expression Genetic Genetic Transcription Goals Health Homologous Gene Human Infection K22 Award Knowledge Microbial Biofilms Molecular Outcome Pathogenesis Pathway interactions Phosphorylation Play Polysaccharides Positioning Attribute Process Production Protein Family Proteins Public Health Publications Regulation Regulatory Pathway Research Research Personnel Resources Role Sigma Factor Signal Pathway Structure Subgroup Surface Symbiosis System Techniques Tertiary Protein Structure Therapeutic Intervention United States Vibrio Vibrio Infections Vibrio fischeri Vibrio parahaemolyticus Vibrio vulnificus Virulence Work Wound Infection antagonist bacterial community bacterial resistance experimental study genetic analysis genetic approach genetic regulatory protein host-associated biofilms human pathogen innovation insight model organism novel nucleoside triphosphatase protein complex protein protein interaction protein structure response sulfate transporter

项目摘要

PROJECT SUMMARY/ABSTRACT Non-cholera Vibrio (NCV) species represent a notable and increasing threat to human health and food safety. The biofilms formed by Vibrio species are robust and highly relevant to host infection. Biofilms are tightly regulated communities of matrix-associated bacteria and are a major component of bacterial pathogenesis including drug resistance. Since an estimated 75% of bacterial infections involve biofilms, it is crucial to better understand how biofilms are formed. In this application, I propose to elucidate the molecular mechanism of an unusual regulatory protein necessary for controlling NCV biofilm formation. This protein is conserved in NCVs and controls the production of symbiosis polysaccharide (Syp), a component of the biofilm matrix involved in host infection. Based on preliminary findings, this protein has an atypical mode of action compared to well characterized homologs. My fundamental hypothesis is that this NCV biofilm regulator protein uses a novel mechanism to control biofilm formation and will challenge our current understanding of this family of proteins. My hypothesis will be addressed through two specific aims: 1) probing the protein’s function using biochemical and structural characterization studies, and 2) uncovering its position in the regulatory network by identifying binding partners. The proposed research is innovative because it focuses on a system that is crucial for biofilm formation, and to date, the system has only been investigated using cellular and genetic approaches. The structure-function approach proposed here will provide essential information needed to fill our knowledge gaps. The project is significant because it will provide a deeper understanding of the regulation of host-associated biofilms from the rising threat of NCV infection. Ultimately, the work proposed will answer key questions related to the molecular mechanisms of a protein within a critical and conserved pathway that regulates host-relevant biofilms. Support from this K22 award will facilitate my transition to an independent investigator by providing me with resources to generate data and publications that will strengthen my competitiveness for future funding.

项目概要/摘要非霍乱弧菌 (NCV) 物种对人类健康和食品安全构成显着且日益严重的威胁。弧菌形成的生物膜非常坚固并且与宿主感染高度相关。基质相关细菌的受调节群落，是细菌发病机制的主要组成部分由于估计 75% 的细菌感染涉及生物膜，因此更好地解决这一问题至关重要。了解生物膜是如何形成的在本申请中，我建议阐明生物膜的分子机制。控制 NCV 生物膜形成所需的不寻常调节蛋白该蛋白在 NCV 中保守。并控制共生多糖 (Syp) 的产生，共生多糖是参与生物膜基质的成分根据初步发现，与正常情况相比，该蛋白质具有非典型的作用模式。我的基本假设是，这种 NCV 生物膜调节蛋白使用了一种新颖的同源物。控制生物膜形成的机制，并将挑战我们目前对该蛋白质家族的理解。我的假设将通过两个具体目标来实现：1）利用生化手段探测蛋白质的功能和结构表征研究，以及 2）通过识别来揭示其在监管网络中的地位拟议的研究具有创新性，因为它重点关注对生物膜至关重要的系统。迄今为止，仅使用细胞和遗传方法对该系统进行了研究。这里提出的结构功能方法将提供填补我们知识空白所需的基本信息。该项目意义重大，因为它将提供对与宿主相关的监管的更深入的了解最终，拟议的工作将回答相关的关键问题。调节宿主相关的关键和保守途径中蛋白质的分子机制 K22 奖项的支持将有助于我向独立研究者过渡。拥有生成数据和出版物的资源，这将增强我未来融资的竞争力。