Mechanisms generating ciliary structural diversity in C. elegans

线虫纤毛结构多样性的产生机制

• 批准号: 7922613
• 负责人: Anique Julienne Olivier-Mason
• 金额: $ 2.77万
• 依托单位: BRANDEIS UNIVERSITY
• 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 2012-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7922613
• 关键词: Affect; Afferent Neurons; Animals; Anosmia; Biological Models; Caenorhabditis elegans; Cells; Cilia; Defect; Disease; Ear; Exhibits; Functional disorder; Generations; Genetic; Goals; Hearing; Hearing problem; Homologous Gene; Human; Image; Kinocilium; Labyrinth; Lead; Maintenance; Mammalian Cell; Modeling; Morphology; Mutate; Mutation; Myosin ATPase; Nematoda; Neurons; Process; Proteomics; Regulation; Research; Role; Sensory; Smell Perception; Stereocilium; Structure; Syndrome; Usher Syndrome; Work; base; cell type; hearing impairment; in vivo; mutant; protein transport; public health relevance; research study; response; sensor

DESCRIPTION (provided by applicant): Primary cilia are now believed to be present in all mammalian cell types and act as environmental sensors. Generally, these cilia exhibit relatively simple structures. However, sensory cell types such as the kinocilia in the ear and olfactory sensory cilia exhibit highly specialized cilia structures that are essential for their specialized sensory functions. Although much is now known about how primary cilia are formed, very little is understood about the processes of building and maintaining specialized cilia. Loss of kinocilia or olfactory cilia function result in hearing loss and anosmia. Thus, understanding how these specialized cilia form and function is essential for a complete understanding of how animals smell and hear. C. elegans is an excellent model system in which to study the mechanisms of specialized cilia formation. Several chemosensory neuron types in C. elegans exhibit highly specialized cilia, which are essential for their sensory functions. The goal of this research is to define the genetic mechanisms required for the generation of specialized chemosensory cilia types. Using a proteomics-based approach, an unconventional myosin HUM-4 was identified as a candidate ciliary molecule. Mutations in hum-4 lead to ciliary defects specifically in an olfactory neuron type. Unconventional myosins have previously been implicated in maintenance of both kinocilia and stereocilia structures in the inner ear, and are mutated in hearing disorder syndromes such as Usher syndrome. The goal of this proposal is to investigate the functions of HUM-4 in the generation of specialized olfactory cilia morphology in the C. elegans model system. These cilia structures are essential for neuron-specific chemosensory responses so how sensory neurons are specialized for their unique functions will also be described. The proposed specific aims are: 1. Characterization of the role of the HUM-4 unconventional myosin in the regulation of ciliary morphology. 2. Elucidation of the mechanism by which the HUM-4 unconventional myosin regulates AWB ciliary morphology. PUBLIC HEALTH RELEVANCE: A thorough understanding of these mechanisms is important for a complete understanding of how humans hear and smell. This work will lead to a better understanding of how specialized cilia are formed, and how defects in cilia structure lead to sensory dysfunction.

描述（由申请人提供）：现在认为初级纤毛存在于所有哺乳动物细胞类型中，并充当环境传感器。一般来说，这些纤毛表现出相对简单的结构。然而，感觉细胞类型，如耳中的动纤毛和嗅觉感觉纤毛，表现出高度特化的纤毛结构，这对于它们的特化感觉功能是必不可少的。虽然现在对初级纤毛是如何形成的了解很多，但对建立和维持特化纤毛的过程了解甚少。动纤毛或嗅纤毛功能的丧失导致听力损失和嗅觉丧失。因此，了解这些特殊纤毛的形成和功能对于完全了解动物的嗅觉和听觉至关重要。C.线虫是研究特化纤毛形成机制的极好模型系统。C.秀丽线虫具有高度特化的纤毛，这是它们的感觉功能所必需的。本研究的目的是确定产生专门的化学感受纤毛类型所需的遗传机制。使用基于蛋白质组学的方法，非常规的肌球蛋白HUM-4被确定为候选纤毛分子。hum-4突变导致纤毛缺陷，特别是在嗅觉神经元类型。非常规肌球蛋白先前已涉及内耳中动纤毛和静纤毛结构的维持，并且在听力障碍综合征如Usher综合征中突变。本研究的目的是探讨HUM-4在特化嗅觉纤毛形态发生中的作用。elegans模型系统。这些纤毛结构对于神经元特异性化学感受反应是必不可少的，因此也将描述感觉神经元如何专门用于其独特的功能。建议的具体目标是：1。HUM-4非常规肌球蛋白在纤毛形态调节中作用的表征。2.阐明HUM-4非常规肌球蛋白调节AWB纤毛形态的机制。 公共卫生相关性：彻底了解这些机制对于全面了解人类的听觉和嗅觉非常重要。这项工作将导致更好地了解专业纤毛是如何形成的，以及纤毛结构的缺陷如何导致感觉功能障碍。