THE STRUCTURE AND FUNCTION OF CYTOPLASMIC DYNEIN

细胞质动力蛋白的结构和功能

• 批准号: 7957812
• 负责人: Thomas S Hays
• 金额: $ 0.33万
• 依托单位: UNIVERSITY OF WASHINGTON
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-09-01 至 2010-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7957812
• 关键词: Address; Affinity; Axonal Transport; Binding; Biology; Cell Differentiation process; Chromosome Segregation; Collaborations; Complex; Computer Retrieval of Information on Scientific Projects Database; Congenital Abnormality; Development; Dynein ATPase; Functional disorder; Funding; Fungal Genome; Grant; Growth; Individual; Institution; Intracellular Transport; Light; Location; Mass Spectrum Analysis; Mediating; Medical; Microtubules; Molecular Genetics; Molecular Motors; Motor; Mutagenesis; Mutate; Neurodegenerative Disorders; Organelles; Phenotype; Phosphorylation Site; Post-Translational Protein Processing; Process; Protein Isoforms; Proteins; Research; Research Activity; Research Institute; Research Personnel; Resources; Signal Pathway; Source; Structure; Syndrome; Testing; Tissues; To specify; Transgenes; Transport Process; United States National Institutes of Health; Work; mutant; polypeptide; protein function

This subproject is one of many research subprojects utilizing the resources provided by a Center grant funded by NIH/NCRR. The subproject and investigator (PI) may have received primary funding from another NIH source, and thus could be represented in other CRISP entries. The institution listed is for the Center, which is not necessarily the institution for the investigator. Molecular motor proteins function in a multitude of intracellular transport processes that include the organization of organelles and their transport, chromosome segregation, axonal transport, and signaling pathways. Motor dependent processes are critical for the growth, proliferation, and differentiation of cells and tissues. How motor function is regulated in a developmental context, and the relationship of motor dysfunction to numerous medical problems including neurodegenerative disease, congenital chromosomal syndromes, and birth defects is a current focus of research activity. Our work is focused on the microtubule motor cytoplasmic dynein, and the important and unanswered question regarding how this single motor isoform accomplishes multiple tasks. How is dynein targeted to specific cargoes and/or cellular locations and structures? Our aims will address three non-exclusive mechanisms that potentially contribute to dynein targeting. (1) First, cytoplasmic dynein contains multiple subunits. The individual subunits or subunit domains could specify where, and to what, dynein is attached. To test this hypothesis we will ask whether domains within the light intermediate and the intermediate chain polypeptides confer specific functions. Mutagenesis and molecular genetic approaches will be used to disrupt domain function and the mutant phenotypes will be characterized. (2) Second, the posttranslational modification of dynein subunits might control whether subunits are competent to bind a cargo with high affinity. Collaboration with Dr. John Yates (Scripps Research Institute) will define the sites of phosphorylation on subunits within the dynein complex using a mass spectrometry approach. Subsequently, the phosphorylation sites identified will be mutated to mimic the phosphorylated or unphosphorylated state of the respective subunit. The phenotypes produced by transgenes that express the mutant subunits will be analyzed to reveal the functional significance of dynein phosphoregulation. (3) In a third mechanism, specific binding partners or "effector" proteins might mediate the targeting of the dynien motor to specific cargoes or locations. We will pursue the functional analysis of candidate interacting proteins identified in the previous period and will continue with secondary tests on other interacting loci.

这个子项目是许多研究子项目中的一个 由NIH/NCRR资助的中心赠款提供的资源。子项目和 研究者（PI）可能从另一个NIH来源获得了主要资金， 因此可以在其他CRISP条目中表示。所列机构为 研究中心，而研究中心不一定是研究者所在的机构。 分子马达蛋白在许多细胞内运输过程中发挥作用，包括细胞器的组织及其运输、染色体分离、轴突运输和信号传导途径。 运动依赖性过程对于细胞和组织的生长、增殖和分化至关重要。如何在发育的背景下调节运动功能，以及运动功能障碍与许多医学问题的关系，包括神经退行性疾病，先天性染色体综合征和出生缺陷是当前研究活动的焦点。 我们的工作集中在微管运动细胞质动力蛋白，以及关于这个单一的运动亚型如何完成多个任务的重要和未回答的问题。 动力蛋白如何靶向特定的货物和/或细胞位置和结构？ 我们的目标将解决三个非排他性的机制，可能有助于动力蛋白的目标。 (1)首先，细胞质动力蛋白含有多个亚基。 单个亚基或亚基结构域可以指定动力蛋白附着在哪里和什么上。 为了检验这一假设，我们将询问轻链中间体和中间链多肽内的结构域是否赋予特定的功能。 将使用诱变和分子遗传学方法来破坏结构域功能，并对突变体表型进行表征。 (2)其次，动力蛋白亚基的翻译后修饰可能控制亚基是否能够以高亲和力结合货物。 与John Yates博士（Scripps研究所）的合作将使用质谱法来确定动力蛋白复合物中亚基上的磷酸化位点。随后，鉴定的磷酸化位点将被突变以模拟相应亚基的磷酸化或非磷酸化状态。 将分析由表达突变亚基的转基因产生的表型，以揭示动力蛋白磷酸调节的功能意义。 (3)在第三种机制中，特异性结合伴侣或“效应”蛋白可能介导动力马达靶向特定的货物或位置。 我们将继续对前一阶段确定的候选相互作用蛋白进行功能分析，并将继续对其他相互作用位点进行二次测试。