Systematic Structural Biology of Dynein

动力蛋白的系统结构生物学

• 批准号: 6520554
• 负责人: Stephen M King
• 金额: $ 24.65万
• 依托单位: UNIVERSITY OF CONNECTICUT SCH OF MED/DNT
• 依托单位国家: 美国
• 财政年份: 2001
• 资助国家: 美国
• 起止时间: 2001-07-01 至 2005-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6520554
• 关键词: dynein ATPase; nuclear magnetic resonance spectroscopy; protein structure function; structural biology

Dyneins are microtubule-based molecular motors involved in a wide variety of essential cellular functions including retrograde vesicular trafficking, ciliary/flagellar motility and cell division. These enzymes are highly complex containing up to thirteen different polypeptide components with a total mass of almost 2 MDa. In order to achieve a molecular understanding of mechanism, it will be essential to obtain high resolution structural information for all components of the dynein complex. However, the complexity and size of the dynein particle combined with the inherent flexibility of several domains has made obtaining high resolution structural information for the entire enzyme unfeasible. This application proposes a systematic approach to dynein structural biology by obtaining information for individual proteins or subdomains using multidimensional NMR techniques. These structures will then be used to build ever more complete models of the dynein motor and will enable structure-based hypotheses concerning function to be made. The specific aims for this submission center on analysis of dynein light chains and include: 1) molecular dynamics and refinement of the solution structure of LC1 which is associated with the dynein motor domain; 2) structural analysis of mutant forms of LC1 to allow interpretation of mutant phenotypes at the structural level; 3) completion of the NMR assignments and calculation of the solution structure for the Tctex1 light chain; 4) NMR structure analysis of thioredoxin-related and Ca2+-binding light chains; 5) preparation of other dynein domains for structure analysis following a systematic search for appropriate solution conditions. These studies will provide structure-based insight into the mechanisms of dynein regulation and will provide the necessary background for further structural analysis of this massive molecular motor.

动力蛋白是基于微管的分子马达，参与多种基本细胞功能，包括逆行囊泡运输、纤毛/鞭毛运动和细胞分裂。这些酶是高度复杂的，含有多达13种不同的多肽成分，总质量几乎为2mda。为了实现对机制的分子理解，获得动力蛋白复合物所有组分的高分辨率结构信息将是必不可少的。然而，动力蛋白颗粒的复杂性和大小以及几个结构域的固有灵活性使得获得整个酶的高分辨率结构信息变得不可行。该应用程序提出了一个系统的方法，以动力蛋白结构生物学通过获取信息的单个蛋白质或子域使用多维核磁共振技术。然后，这些结构将被用于构建更完整的动力马达模型，并将使基于结构的关于功能的假设成为可能。本次提交的具体目标集中在动力蛋白轻链的分析，包括：1)与动力蛋白运动域相关的LC1的分子动力学和溶液结构的细化；2)对LC1的突变形式进行结构分析，以便在结构水平上解释突变表型；3)完成Tctex1轻链的核磁共振赋值和溶液结构计算；4)硫氧还蛋白相关和Ca2+结合轻链的核磁共振结构分析；5)在系统地寻找合适的溶液条件后，制备用于结构分析的其他动力蛋白结构域。这些研究将为动力蛋白调控机制提供基于结构的见解，并将为进一步分析这种巨大的分子马达提供必要的背景。