Motor Function and Regulation of Myosin VII

肌球蛋白 VII 的运动功能和调节

• 批准号: 6860094
• 负责人: Mitsuo Ikebe
• 金额: $ 30.21万
• 依托单位: UNIV OF MASSACHUSETTS MED SCH WORCESTER
• 依托单位国家: 美国
• 财政年份: 2003
• 资助国家: 美国
• 起止时间: 2003-04-01 至 2008-02-29
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6860094
• 关键词: biological signal transduction; calcium flux; calmodulin; genetic regulation; muscle function; myosins; nanotechnology; phosphorylation; protein engineering; protein structure function; protein transport; recombinant DNA

DESCRIPTION (provided by applicant): Myosin VII, a member of the diverse myosin superfamily, is found distributed in a variety of tissues including retina and inner ear. The most intriguing finding is that myosin VIIa is responsible for three human sensory disorders, Usher syndrome 1B (causing sensorineural deafness and blindness due to retitis pigmentosa), DFNB2 and DFNA11. However, understanding of the mechanism of these diseases suffers from the lack of knowledge of the myosin VIIa function at a molecular level. The goal of the proposed project is to clarify the motor function and regulation of myosin VIIa at a molecular level. First, we will clarify the motor characteristics of myosin VIIa. We will address this objective using two approaches. First, we will analyze each elementary kinetic step of the ATPase cycle that couples with each step of the crossbridge cycle. The analysis determines the duration of the force generating state of myosin VIIa. Second, the characteristic of actin translocating activity of myosin VIIa will be studied by in vitro surface gliding assay with particular emphasis on the use of the single molecule nano-technology. Each step size and the production of successive multiple steps will be determined by use of optical tweezers and nanometry at the single molecule level. The continuous movement of myosin VIIa on actin will be visualized with the recently developed single molecule imaging system. Using these technologies, we will determine whether or not myosin VIIa moves multiple steps before dissociating from actin and the step size. Nothing is known about the regulation mechanism of myosin VIIa. We hypothesize three components to account for the regulation of myosin VIIa. First, the motor activity of myosin VIIa might be modulated by phosphorylation. Our preliminary results have indicated that myosin VIIa is phosphorylated by various protein kinases. Second, Ca binding to the calmodulin light chain directly regulates the motor activity of myosin VIIa. Third, the interaction between the heads of myosin VIIa may play a role in the regulation. The proposed project will clarify the regulatory mechanism of myosin VIIa at a molecular level. Significant numbers of missense mutations of the human sensory disorders are located in the head domain of myosin VIIa, but nothing is known about the effects of these mutations on myosin VIIa function to date. The proposal will clarify functional defects of these mutations at a molecular level. The proposed project will clarify the function and regulation of myosin VIIa, thus providing important information in understanding of the mechanism underlying the human sensory disorders of deafness and blindness.

描述（由申请人提供）：肌球蛋白VII是多种肌球蛋白超家族的成员，分布于包括视网膜和内耳在内的多种组织中。最有趣的发现是，肌球蛋白VIIa与三种人类感觉障碍有关，即Usher综合征1B（由于色素性视网膜炎导致感觉神经性耳聋和失明）、DFNB 2和DFNA 11。然而，了解这些疾病的机制，从缺乏知识的肌球蛋白VIIa功能的分子水平。该项目的目标是在分子水平上阐明肌球蛋白VIIa的运动功能和调节。首先，我们将阐明肌球蛋白VIIa的运动特性。我们将使用两种方法来实现这一目标。首先，我们将分析ATP酶循环的每个基本动力学步骤，这些步骤与过桥循环的每个步骤相耦合。该分析确定肌球蛋白VIIa的力产生状态的持续时间。第二，将通过体外表面滑动实验研究肌球蛋白VIIa的肌动蛋白转位活性的特性，特别强调使用单分子纳米技术。每个步骤的大小和连续多个步骤的产生将通过在单分子水平上使用光镊和纳米测量来确定。肌球蛋白VIIa在肌动蛋白上的连续运动将被最近开发的单分子成像系统可视化。使用这些技术，我们将确定是否或不肌球蛋白VIIa运动多个步骤之前，从肌动蛋白和步长解离。肌球蛋白VIIa的调节机制尚不清楚。我们假设三个组成部分来解释肌球蛋白VIIa的调节。首先，肌球蛋白VIIa的运动活性可能是由磷酸化调节。我们的初步结果表明，肌球蛋白VIIa是磷酸化的各种蛋白激酶。其次，钙结合钙调蛋白轻链直接调节肌球蛋白VIIa的运动活性。第三，肌球蛋白VIIa头部之间的相互作用可能起到调节作用。该项目将在分子水平上阐明肌球蛋白VIIa的调控机制。大量的人类感觉障碍的错义突变位于肌球蛋白VIIa的头部结构域，但迄今为止，这些突变对肌球蛋白VIIa功能的影响尚不清楚。该提案将在分子水平上阐明这些突变的功能缺陷。该项目将阐明肌球蛋白VIIa的功能和调节，从而为理解人类耳聋和失明的感觉障碍的机制提供重要信息。