Bacterial cell wall synthesis, shape and septation

细菌细胞壁的合成、形状和分隔

• 批准号: 6828572
• 负责人: KEVIN D YOUNG
• 金额: $ 42.38万
• 依托单位: UNIVERSITY OF NORTH DAKOTA
• 依托单位国家: 美国
• 财政年份: 2000
• 资助国家: 美国
• 起止时间: 2000-03-01 至 2008-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6828572
• 关键词: Escherichia coli; bacterial genetics; bacterial proteins; binding proteins; cell cycle; cell morphology; cell wall; combinatorial chemistry; gene expression; gene interaction; gene mutation; genetic strain; microorganism culture; mutant; penicillins; peptidoglycan; phenotype; protein structure function

DESCRIPTION (provided by applicant): In addition to protecting bacteria from lysis, the peptidoglycan cell wall plays an important, underappreciated role in several physiological processes. These range from the basic biological functions of creating cellular polarity, influencing differentiation and impeding virus entry, to contributing to host attachment, toxin production and recognition by the innate immune response. Even less well understood are the contributions of bacterial morphology to nutrient accumulation, attachment, motility, chromosome segregation, predation, biofilm formation and virulence. Our long-term goal is to understand the structure, synthesis, regulation and functional implications of peptidoglycan and the enzymes that create and modify it. In particular, we've been searching for the physiological functions of the low molecular weight penicillin binding proteins, a large family of peptidoglycan-modifying enzymes that are present in multiple forms and highly conserved across the bacterial kingdom. These enzymes interact with the bacterial division protein, FtsZ, to create cells of defined and uniform shape via reactions that are either independent of or which precede the now-classic division pathway initiated by FtsZ. Of great import is that newly described phenotypes in multiply-mutated strains allow questions of cell shape and polarity to be approached by genetic techniques not previously available for such studies. We propose to refine and characterize the functioning of this "morphological pathway" by pursuing the following specific aims: 1) characterize the role of FtsZ in generating and localizing inert peptidoglycan; 2) characterize the roles of peptidoglycan hydrolases in cell shape and integrity; 3) define how interacting helical structures propel growth of the wall and envelope; and 4) isolate and characterize suppressor mutants to define the morphological pathway in more detail. These goals will be realized by creating strains deficient in portions of the proposed pathway, by assaying current FtsZ mutants and creating new ones, and by isolating suppressor mutants to define additional components of the pathway.

描述(由申请人提供)：除了保护细菌免受裂解，肽聚糖细胞壁在几个生理过程中发挥着重要的、被低估的作用。从创造细胞极性、影响分化和阻止病毒进入的基本生物学功能，到通过先天免疫反应促进宿主附着、毒素产生和识别的基本生物学功能。细菌形态对营养积累、附着、运动、染色体分离、捕食、生物膜形成和毒力的贡献更不为人所知。我们的长期目标是了解肽聚糖的结构、合成、调节和功能含义，以及产生和修饰它的酶。特别是，我们一直在寻找低分子青霉素结合蛋白的生理功能，这是一大家族的肽聚糖修饰酶，以多种形式存在，在细菌界中高度保守。这些酶与细菌分裂蛋白FtsZ相互作用，通过独立于FtsZ启动的现已经典的分裂途径或在FtsZ启动的分裂途径之前的反应，创建确定和统一形状的细胞。最重要的是，新描述的多重突变菌株的表型允许通过以前不适用于此类研究的遗传技术来解决细胞形状和极性的问题。我们建议通过追求以下特定目标来完善和表征这一“形态途径”的功能：1)表征FtsZ在产生和定位惰性肽聚糖中的作用；2)表征肽聚糖水解酶在细胞形状和完整性中的作用；3)确定相互作用的螺旋结构如何推动壁和包膜的生长；以及4)分离和表征抑制突变体，以更详细地确定形态途径。这些目标将通过创造在所提议的途径的部分中存在缺陷的菌株，通过分析当前的FtsZ突变并创造新的突变，以及通过分离抑制突变来定义该途径的额外成分来实现。