THE ROLE OF CELL SHAPE AND CELL WALL IN HELICOBACTER PYLORI PATHOGENESIS

细胞形状和细胞壁在幽门螺杆菌发病机制中的作用

• 批准号: 7843536
• 负责人: Nina Salama
• 金额: $ 25.62万
• 依托单位: FRED HUTCHINSON CANCER RESEARCH CENTER
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-05-15 至 2011-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7843536
• 关键词: Acidity; Affect; Agar; Animals; Applications Grants; Bacteria; Biochemical; Biochemical Genetics; Campylobacter jejuni; Cell Line; Cell Shape; Cell Wall; Cell Wall Alteration; Cellular Stress; Cellular biology; Chemotaxis; Clinical; Coculture Techniques; Complement; Complex; Cytoskeleton; Defect; Detection; Disease; Elements; Enzymes; Epithelial; Epithelial Cells; Exposure to; Face; Frequencies; Gastritis; Genes; Genetic Epistasis; Goals; Helicobacter; Helicobacter pylori; Human; Immune system; Immunoprecipitation; Infection; Inflammatory; Intestines; Investigation; Learning; Libraries; Life; Link; Liver diseases; Measures; Mediating; Metabolism; Modification; Molecular; Mucous body substance; Mus; Names; Organism; Osmolar Concentration; Outcome; Pathogenesis; Pathway interactions; Peptic Ulcer; Peptidoglycan; Phenotype; Proteins; Role; Shapes; Signal Transduction; Stomach; Stress; Structure; Swimming; Testing; Tropism; Vibrio cholerae; Virulence; Visual; Work; antimicrobial peptide; cellular imaging; cytokine; gene discovery; genetic analysis; insight; malignant stomach neoplasm; microbial; mutant; novel; pathogen; protein function; public health relevance; research study; retinal rods; theories

DESCRIPTION (provided by applicant): Evident in its name, Helicobacter pylori is a helical bacterium that colonizes the human stomach causing clinical outcomes ranging from mild gastritis to peptic ulcer and gastric cancer. Descriptions of H. pylori virulence include a widely accepted hypothesis that the bacterium's spiral shape enhances its ability to swim through the viscous epithelial mucus layer and successfully colonize the stomach. This theory, however, has never been tested and the molecular determinants of H. pylori's shape remain unknown. Using a visual screen of a transposon mutant library, we identified clones displaying two classes of altered cell shape: straight rod and curved vibrioid. Genetic analyses revealed three chromosomal loci, one with at least three genes all affecting cell shape. Biochemical analyses indicate that some of these proteins modify the cell wall peptidoglycan (PG) structure. All mutants tested show slight, but reproducible defects in halo formation in soft agar suggesting compromised swimming or chemotaxis. One vibrioid and two rod-shaped mutants were tested for their ability to colonize the mouse stomach and all showed an altered phenotype compared to wild type or complemented strains. Interestingly the rod-shaped mutants colonized better than their spiral counter parts while the vibrioid mutant showed lower colonization. Thus the identified spiral shape-determining genes influence stomach colonization, but how and why remains to be elucidated. We have two goals with the current grant proposal. The goal of Aim 1 is to understand how the gene products identified in our loss of spirality screen alter cell shape. What is the role of the cell wall? Do the gene products identified within or between shape classes interact? Do they interact with known PG biosynthetic and degrading enzymes or with bacterial cytoskeletal elements? The goal of Aim 2 is to understand how these proteins function during stomach colonization. Are the colonization phenotypes due to altered swimming as previously hypothesized, or is chemotaxis altered? Are the identified cell wall modifications important for the bacteria's ability to survive stresses encountered in the stomach such as fluctuations in osmolarity, acidity and exposure to antimicrobial peptides? Do the cell wall alterations influence PG signaling and/or detection by the host immune system? We believe this work will yield significant advancements in both cell biology and pathogenesis. An outstanding question in microbial cell biology is how and why spiral shape is maintained. The discovery that some of these proteins modify PG is also significant from both cell biology and pathogenesis perspectives. H. pylori's PG activates a major pro-inflammatory pathway via the intracellular pathogen recognition molecule Nod1. Recognition of specific PG components by epithelial cells has been shown to be important for both symbiotic and pathogenic interactions of bacteria and their host. Altogether the experimental aims will probe how and why H. pylori maintains its spiral shape and its role in pathogenesis. PUBLIC HEALTH RELEVANCE: Evident in its name, Helicobacter pylori is a helical bacterium that colonizes the human stomach causing clinical outcomes that range from mild gastritis to peptic ulcer and gastric cancer. We discovered genes that promote spiral shape by this bacterium can alter its cell wall. Study of how these cell wall modifications promote spiral shape and bacterial survival in its unique niche will help us better understand how this bacteria causes disease and discover new ways to inhibit infection.

描述（由申请人提供）：顾名思义，幽门螺杆菌是一种螺旋状细菌，定植于人体胃中，导致从轻度胃炎到消化性溃疡和胃癌的临床结局。描述H。幽门螺旋杆菌的毒力包括一个被广泛接受的假设，即细菌的螺旋形状增强了其游过粘性上皮粘液层并成功地在胃中定植的能力。然而，这一理论从未被验证过，H的分子决定因素。pylori的形状仍然未知。使用转座子突变库的视觉屏幕，我们确定了显示两类改变的细胞形状的克隆：直杆和弯曲的弧菌。遗传分析显示了三个染色体位点，其中一个至少有三个基因都影响细胞形状。生化分析表明，这些蛋白质中的一些修改细胞壁肽聚糖（PG）的结构。所有测试的突变体显示轻微的，但可重复的缺陷，在软琼脂中的晕形成，这表明受损的游泳或趋化性。测试了一种弧菌和两种杆状突变体在小鼠胃中定殖的能力，与野生型或互补菌株相比，所有突变体均显示出改变的表型。有趣的是，杆状突变体的定殖比其螺旋对应部分更好，而类弧菌突变体显示出较低的定殖。因此，已确定的螺旋形状决定基因影响胃定植，但如何以及为什么仍有待阐明。我们有两个目标与目前的赠款提案。目标1的目的是了解在我们的螺旋缺失筛选中鉴定的基因产物如何改变细胞形状。细胞壁的作用是什么？在形状类别内或形状类别之间鉴定的基因产物是否相互作用？它们是否与已知的PG生物合成和降解酶或细菌细胞骨架元件相互作用？目标2的目标是了解这些蛋白质在胃定植期间的功能。定植表型是否如先前假设的那样是由于游泳改变，还是趋化性改变？确定的细胞壁修饰对于细菌在胃中遇到的压力（如渗透压、酸度和暴露于抗菌肽的波动）中生存的能力是否重要？细胞壁的改变是否会影响PG信号传导和/或宿主免疫系统的检测？我们相信这项工作将在细胞生物学和发病机制方面取得重大进展。微生物细胞生物学中的一个突出问题是如何以及为什么保持螺旋形状。这些蛋白质中的一些修饰PG的发现从细胞生物学和发病机理的角度来看也是重要的。H.幽门螺杆菌的PG通过细胞内病原体识别分子Nod 1激活主要的促炎途径。上皮细胞对特定PG组分的识别已被证明对于细菌及其宿主的共生和致病相互作用都是重要的。总之，实验的目的将探讨如何和为什么H。pylori保持其螺旋形状及其在发病机制中的作用。公共卫生相关性：幽门螺杆菌（Helicobacter pylori）是一种螺旋状细菌，在人类胃中定植，导致从轻度胃炎到消化性溃疡和胃癌的临床结果。我们发现这种细菌的螺旋形基因可以改变它的细胞壁。研究这些细胞壁修饰如何促进螺旋形状和细菌在其独特的生态位中存活，将有助于我们更好地了解这种细菌如何引起疾病，并发现抑制感染的新方法。