Investigating the Molecular Basis of Mechanotransduction Channel Gating

研究力转导通道门控的分子基础

• 批准号: 7677051
• 负责人: Amy Lynn Eastwood
• 金额: $ 4.52万
• 依托单位: STANFORD UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-07-01 至 2012-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7677051
• 关键词: ASIC channel; Alanine; Amino Acids; Animal Model; Animals; Aspartate; Blood Pressure; Brain; Caenorhabditis elegans; Caenorhabditis elegans Proteins; Cells; Data; Environment; Epithelial; Equilibrium; Esthesia; Extracellular Protein; Family; Future; Glycine; Goals; Hearing; Human; Intervention; Investigation; Ion Channel; Kidney; Laboratories; Lead; Link; Literature; Mammals; Maps; Mechanics; Mechanoreceptors; Methodology; Methods; Molecular; Mutate; Mutation; Nematoda; Nerve Degeneration; Neurons; Patch-Clamp Techniques; Pathway interactions; Pattern; Phenotype; Process; Proteins; Publishing; Receptor Cell; Regulation; Renal function; Role; Signal Transduction; Site; Skin; Sodium Channel; Sodium Chloride; Stimulus; Stretching; Structure; Surface; Techniques; Testing; Touch sensation; Translating; Water; Work; base; carboxyl group; in vivo; insight; molecular scale; mutant; novel; pressure; prevent; protein activation; receptor; response; success

DESCRIPTION (provided by candidate): On the cellular and molecular level, exactly how humans sense touch is poorly understood. Even a slight breeze exerts enough pressure against the skin to start a rapid signaling cascade that immediately transmits the sensation to the brain. This process of translating mechanical stimuli into neuronal signals is called mechanosensation, and it is critical for the sense of touch, hearing, balance, kidney regulation, and more. Integral components of mechanosensation are proteins embedded within the surface of a cell called ion channels that open upon tension or stretch. In mammals epithelial sodium channels (ENaCs) and acid- sensing ion channels (ASICs) are linked to mechanosensation, but little is known about how they function in this process. C. elegans is a model organism often used for studying mechanosensation. The two C. elegans proteins that are the focus of this proposal, MEC-4 and MEC-10, constitute the channel that senses gentle touch and are in the same super family as ENaCs and ASICs. Thus, information gained from studying MEC-4 and MEC-10 in their native environment will be relevant to mammalian touch sensation. Many of the residues that line the pore of the channels in this super family are highly conserved, and they have long been implicated in channel function. In this proposal highly conserved residues found in the pore of the channel formed by MEC-4 and MEC-10 will be mutated in order to determine how specific changes alter channel function in vivo using the slit-worm whole-cell patch clamp technique. Determining the roles of these residues will enhance the understanding of channel gating at the molecular protein level. First, mutations with known phenotypes will be studied. Then, the many pore-lining glycines will be investigated to probe the importance of the GxxxG helix-packing motif in the gating pathway of the channel. This work will be the first thorough in vivo electrophysiological investigation of this important region. Mechanosensitive protein channels are involved in many vital processes such as interpreting the sensations of touch and hearing, regulating kidney function, controling blood pressure, and balancing the ratio of salt and water across cells. Understanding how these channels function could open the door to interventions that prevent or slow the decline of the important human functions that they control.

描述（由候选人提供）：在细胞和分子水平上，人们对人类如何感知触摸的确切了解甚少。即使是轻微的微风也会对皮肤产生足够的压力，从而启动快速的信号级联，立即将这种感觉传递到大脑。这种将机械刺激转化为神经元信号的过程称为机械感觉，它对触觉，听觉，平衡，肾脏调节等至关重要。机械感觉的组成部分是嵌入细胞表面的蛋白质，称为离子通道，在张力或拉伸时打开。在哺乳动物中，上皮钠通道（ENaCs）和酸敏感离子通道（ASIC）与机械感觉有关，但对它们在此过程中的功能知之甚少。C.线虫是一种常用于研究机械感觉的模式生物。两个C。作为该提议的焦点的秀丽线虫蛋白质MEC-4和MEC-10构成了感知温柔触摸的通道，并且与ENaCs和ASIC属于同一超家族。因此，在其自然环境中研究MEC-4和MEC-10获得的信息将与哺乳动物的触觉相关。在这个超家族中，排列在通道孔中的许多残基是高度保守的，并且它们长期以来与通道功能有关。在该提议中，将突变由MEC-4和MEC-10形成的通道孔中发现的高度保守的残基，以使用狭缝蠕虫全细胞膜片钳技术确定特定变化如何改变体内通道功能。确定这些残基的作用，将提高在分子蛋白质水平上的通道门控的理解。首先，将研究具有已知表型的突变。然后，许多孔内衬甘氨酸将被调查，以探测GxxxG螺旋包装基序的通道的门控途径中的重要性。这项工作将是第一次彻底的在体内电生理调查这一重要区域。机械敏感蛋白质通道参与许多重要过程，例如解释触觉和听觉，调节肾功能，控制血压以及平衡细胞内盐和水的比例。了解这些通道的功能可以为预防或减缓它们所控制的重要人体功能的衰退打开干预之门。