Bacterial cell wall synthesis, shape and septation

细菌细胞壁的合成、形状和分隔

• 批准号: 7934807
• 负责人: KEVIN D YOUNG
• 金额: $ 5万
• 依托单位: UNIV OF ARKANSAS FOR MED SCIS
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-09-30 至 2011-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7934807
• 关键词: Address; Animals; Antibiotic Resistance; Antibiotic Therapy; Antibiotics; Area; Bacteria; Bacterial Physiology; Biological Process; Cell Cycle; Cell Shape; Cell Wall; Cell division; Cell division phases; Cells; Characteristics; Chemicals; Cytolysis; Cytoplasmic Protein; Effectiveness; Enzymes; Escherichia coli; Goals; Grant; Growth; Human; Hydrolase; Immune response; Lead; Light; Membrane; Microbial Biofilms; Molds; Molecular; Morphology; Mutation; N-Acetylmuramoyl-L-alanine Amidase; Nature; Nutrient; Organism; Osmotic Pressure; Pathogenesis; Pathway interactions; Peptidoglycan; Periplasmic Proteins; Phenotype; Play; Process; Proteins; Reaction; Regulation; Role; Shapes; Structure; Surface; Toxin; Vertebral column; Virulence; cell motility; constriction; microorganism; periplasm; public health relevance; segregation; tool

DESCRIPTION (provided by applicant): The bacterial cell wall plays a fundamental role in several critical biological processes, including protecting microorganisms against lysis by osmotic pressure and contributing to subcellular organization and overall morphology. Fragments of peptidoglycan, the structural backbone of the wall, function as toxins toward humans and animals and are targeted by the innate immune response in these higher organisms. In addition, by imparting to bacteria their different shapes, the wall creates polarities, influences bacterial differentiation, and contributes directly or indirectly to nutrient accumulation, attachment to surfaces, motility, chromosomal segregation, predator avoidance, biofilm formation, and pathogenesis. Thus, this field addresses concerns that are both basic and practical: basic, in considering how cells are constructed; and practical, because these characteristics contribute to bacterial virulence and determine the effectiveness of antibiotic therapy. The long-term goal of this project is to understand the structure, synthesis, regulation and functional implications of peptidoglycan and the enzymes that create and modify it. More specifically, we wish to know how cells differentiate their walls into structural and functional domains, how they process the wall during cell division, and how they mold it to produce cells of different shapes. Recent discoveries demonstrate that the premier cell division protein, FtsZ, does far more than its acknowledged role in initiating and directing cell division. First, division relies on the activities of peptidoglycan-modifying enzymes, and this relationship, when disturbed, can lead to cell dissolution. Second, it is now apparent that FtsZ directs cell wall synthesis throughout the cell cycle: diffusely into the sidewalls as bacteria elongate; in a concentrated narrow band at the cell center prior to the initiation of septation; and during the constriction phase of cell division. We propose to extend and refine our understanding of these aspects of bacterial physiology by pursuing the following specific aims: 1) examining more closely the mechanisms that drive FtsZ-dependent peptidoglycan synthesis, 2) characterizing new phenotypes associated with FtsZ, and 3) determining the structure of the cell wall. These goals will be realized by defining the proteins that, along with FtsZ, are responsible for the different types of peptidoglycan synthesis, by isolating and characterizing mutations in pathways that intersect with FtsZ and cell wall synthesis, and by creating new tools to examine the chemical nature of the wall. Understanding the processes underlying cellular integrity, cell shape and division will shed light on the genesis, structure and topological regulation of peptidoglycan synthesis and on prokaryotic morphology in general. PUBLIC HEALTH RELEVANCE: A rigid cell wall is essential for bacterial survival, and a large number of our most important antibiotics inhibit the proteins that create this protective structure. Because antibiotic resistance is increasing, it has become especially urgent to understand completely how the bacterial wall is made, the activities of the proteins that make it, and what its final structure looks like. This project will approach this goal by discovering ways in which proteins interact to synthesize the cell wall and by creating new tools for visualizing its molecular composition.

描述（由申请人提供）：细菌细胞壁在几个关键生物过程中起着重要作用，包括保护微生物免受渗透压裂解，并有助于亚细胞组织和整体形态。肽聚糖的片段，壁的结构骨架，作为毒素对人类和动物起作用，并在这些高等生物体中被先天免疫反应靶向。此外，通过赋予细菌不同的形状，壁产生极性，影响细菌分化，并直接或间接地有助于营养积累，附着于表面，运动性，染色体分离，捕食者回避，生物膜形成和发病机制。因此，该领域解决了基本和实用的问题：基本的，考虑细胞是如何构建的;实用的，因为这些特征有助于细菌的毒力并决定抗生素治疗的有效性。本项目的长期目标是了解肽聚糖的结构、合成、调节和功能意义以及产生和修饰肽聚糖的酶。更具体地说，我们希望了解细胞如何将其壁分化为结构和功能域，细胞在细胞分裂过程中如何处理壁，以及如何塑造壁以产生不同形状的细胞。最近的发现表明，首要的细胞分裂蛋白，FtsZ，远远超过其公认的作用，在启动和指导细胞分裂。首先，分裂依赖于肽聚糖修饰酶的活性，当这种关系受到干扰时，会导致细胞溶解。其次，现在很明显，FtsZ指导细胞壁合成整个细胞周期：扩散到侧壁作为细菌伸长;在一个集中的窄带在细胞中心开始分隔之前;和在收缩期的细胞分裂。我们建议通过追求以下具体目标来扩展和完善我们对细菌生理学这些方面的理解：1）更密切地研究驱动FtsZ依赖性肽聚糖合成的机制，2）表征与FtsZ相关的新表型，3）确定细胞壁的结构。这些目标将通过定义蛋白质，沿着FtsZ，负责不同类型的肽聚糖合成，通过分离和表征与FtsZ和细胞壁合成交叉的途径中的突变，以及通过创建新的工具来检查壁的化学性质来实现。了解细胞完整性，细胞形状和分裂的过程将揭示肽聚糖合成的起源，结构和拓扑调控以及原核生物的形态学。公共卫生关系：坚硬的细胞壁对细菌的生存至关重要，我们最重要的抗生素中有大量抑制产生这种保护结构的蛋白质。由于抗生素耐药性正在增加，因此完全了解细菌壁是如何形成的，制造它的蛋白质的活动以及它的最终结构是什么样子变得尤为迫切。该项目将通过发现蛋白质相互作用以合成细胞壁的方式以及通过创建可视化其分子组成的新工具来实现这一目标。