Regulation of formins and cell polarity in yeast

酵母中福尔明和细胞极性的调节

• 批准号: 7572883
• 负责人: Bruce L Goode
• 金额: $ 25.11万
• 依托单位: BRANDEIS UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-03-01 至 2012-02-29
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7572883
• 关键词: Actins; Address; Affect; Animal Model; Animals; Architecture; Back; Binding; Biochemical; Biochemistry; Biological; Cell Adhesion; Cell Extracts; Cell Polarity; Cell division; Cell physiology; Cells; Cellular biology; Complex; Congenital Abnormality; Cues; Cytokinesis; Cytoskeleton; Data; Disease; Electron Microscopy; Endocytosis; Event; Exhibits; Filament; Genes; Genetic; Goals; Half-Life; Homologous Gene; Human; Inhibitory Concentration 50; Length; Life; Ligands; Malignant Neoplasms; Mammals; Mass Spectrum Analysis; Mediating; Microfilaments; Modeling; Molecular; Morphogenesis; Mothers; Mutation; Myosin ATPase; Neck; Neurodegenerative Disorders; Organelles; Organism; Pattern; Physiological; Physiology; Plants; Play; Population; Positioning Attribute; Problem Solving; Protein Family; Proteins; Recycling; Regulation; Relative (related person); Role; Saccharomyces cerevisiae; Saccharomycetales; Secretory Vesicles; Structure; System; Tertiary Protein Structure; Testing; Tissues; Transcript; Visual; Work; Yeasts; base; cell growth; cell motility; cellular imaging; fungus; in vivo; insight; interdisciplinary approach; novel; particle; polarized cell; protein structure; response; rho GTP-Binding Proteins

DESCRIPTION (provided by applicant): Our long-term goal is to gain a highly mechanistic understanding of how the actin cytoskeleton directs cell polarity and cell morphogenesis. All living cells have internal and external structures tailored to and critical for their distinctive physiological functions. Further, cell architecture can be changed rapidly in response to various cues. The mechanisms underlying these events remain poorly understood and represent a major challenge for cell biologists to define. Recently, a conserved family of proteins called formins has emerged as crucial regulators of actin assembly and remodeling in cells, often functioning directly downstream of Rho GTPases. Formins are large multi-domain proteins that play essential roles in cell polarity, cell division, cell migration, endocytosis, and cell adhesion in a wide range of organisms. Formins directly nucleate actin assembly by a novel mechanism and remain processively attached to the growing end of the filament, protecting the end from capping proteins while guiding insertion of new actin subunits. While the last five years have seen rapid progress in elucidating formin protein structure, mechanism and function, comparatively little is known about how formin activities are regulated spatially and temporally in cells. In this proposal, we will address this question using the budding yeast Saccharomyces cerevisiae as a model organism. Whereas mammals have 15 different formin genes, S. cerevisiae has only two (Bni1 and Bnr1), and hence offers a simplified model to dissect formin regulation. Yeast also allows us to take a multidisciplinary approach, combining genetics, biochemistry, and live cell imaging. Bni1 and Bnr1 have distinct localization and dynamics, and assemble two distinct sets of actin cables. These cables serve as polarized tracks required for targeted secretion and polarized cell growth. We will determine how one of these formins (Bnr1) is regulated in vivo, which will provide key mechanistic insights into the molecular basis of cell polarity and cell morphogenesis. The Specific Aims of the proposal are: (1) How is Bnr1 anchored at the bud neck, activated/released from an autoinhibited state, and then retrieved from actin filament ends for new rounds of actin assembly? (2) How are the activities and cellular functions of a novel Bnr1-regulator (Bud14) controlled by its in vivo binding partners (Kel1 and Kel2)? Defining the molecular basis of these events is critical not only for understanding normal human cell biology and physiology, but also for determining how mutations in the genes encoding morphogenetic determinants give rise to disease states including cancer, birth defects, and neurodegenerative disorders.

描述（由申请人提供）：我们的长期目标是获得对肌动蛋白细胞骨架如何指导细胞极性和细胞形态发生的高度机械理解。所有活细胞都有适合其独特生理功能的内部和外部结构。此外，细胞结构可以根据各种线索迅速改变。这些事件背后的机制仍然知之甚少，对细胞生物学家来说，这是一个重大的挑战。最近，一个被称为formmins的保守蛋白家族已经成为细胞中肌动蛋白组装和重塑的关键调节因子，通常直接在Rho GTPases的下游起作用。Formins是一种大的多结构域蛋白，在细胞极性、细胞分裂、细胞迁移、内吞作用和细胞粘附中发挥重要作用。形成蛋白通过一种新的机制直接形成肌动蛋白组装的核，并继续附着在丝的生长端，保护丝的末端不受封顶蛋白的影响，同时指导新的肌动蛋白亚基的插入。虽然近五年来在阐明双胍蛋白结构、机制和功能方面取得了快速进展，但对细胞中双胍活性如何在空间和时间上受到调节的了解相对较少。在本提案中，我们将使用出芽酵母酿酒酵母作为模式生物来解决这个问题。哺乳动物有15种不同的双胍基因，而酿酒酵母只有两种（Bni1和Bnr1），因此提供了一个简化的模型来解剖双胍调控。酵母也允许我们采取多学科的方法，结合遗传学，生物化学和活细胞成像。Bni1和Bnr1具有不同的定位和动态，并组装两组不同的肌动蛋白电缆。这些电缆作为定向分泌和极化细胞生长所需的极化轨道。我们将确定其中一种形成蛋白（Bnr1）在体内是如何被调节的，这将为细胞极性和细胞形态发生的分子基础提供关键的机制见解。该提案的具体目的是：(1)Bnr1如何锚定在芽颈，从自抑制状态激活/释放，然后从肌动蛋白丝端重新获得新一轮肌动蛋白组装？(2)一种新的bnr1调节因子（Bud14）的活性和细胞功能如何受到其体内结合伙伴（Kel1和Kel2）的控制？确定这些事件的分子基础不仅对于理解正常的人类细胞生物学和生理学至关重要，而且对于确定编码形态发生决定因素的基因突变如何引起包括癌症、出生缺陷和神经退行性疾病在内的疾病状态至关重要。