Structural Dynamics of Stretch Activation in Muscle

肌肉拉伸激活的结构动力学

• 批准号: 8545671
• 负责人: MICHAEL KAY REEDY
• 金额: $ 33.52万
• 依托单位: DUKE UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-09-15 至 2017-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8545671
• 关键词: Actins; Back; Binding; Binding Sites; Biochemical; Calcium; Cardiac; Cattle; Consensus; Contracts; Data; Electron Microscopy; Event; Fiber; Frequencies; Head; Heart; Heart Diseases; Individual; Injury; Insecta; Lead; Left; Length; Link; Mechanics; Mediating; Microfilaments; Modeling; Molecular; Motor; Movement; Muscle; Muscle Fibers; Muscle Proteins; Muscle function; Myocardium; Myopathy; Myosin ATPase; Oryctolagus cuniculus; Output; Phase; Physiological; Physiology; Pilot Projects; Positioning Attribute; Prevention; Process; Production; Property; Protein Isoforms; Proteins; Psoas Muscles; Rattus; Regulation; Research; Resolution; Role; Side; Signal Transduction; Skeletal Muscle; Starling (law); Stretching; Striated Muscles; System; Testing; Thin Filament; Time; Tropomyosin; Troponin; Vanadates; Work; X ray diffraction analysis; X-Ray Diffraction; base; blebbistatin; cell motility; human disease; in vivo; movie; research study; response; sarcopenia; skeletal; theories; troponin-tropomyosin complex; ward

DESCRIPTION (provided by applicant): The long-term objective of this research is to understand the molecular mechanism by which stretching a muscle makes it pull harder. All striated muscles contract via myosin motor proteins that cyclically pull on actin filaments. In a relaxed muscle, myosin is sterically blocked from interacting with actin by the troponin- tropomyosin complex. In a neurogenic contraction, troponin binds released calcium, which relieves the steric blocking by tropomyosin and enables myosin to bind to and pull on actin. By an unknown mechanism, stretching a muscle makes it pull harder, a process known as "length dependent activation" if pre-stretching a relaxed muscle leads to greater force in subsequent contractions, or as "stretch activation" if stretching a partially activated muscle leads to a delayed rise in force. Length dependent activation is an essential feature of cardiac muscle underlying the Frank-Starling Law of the Heart, which allows it to match the input and output volumes beat-to-beat by increasing systolic force after increased diastolic filling. Stretch activation is an essential feature of most insect flight muscles, which allows it to mechanically trigger contraction during flight. All striated muscles, vertebrate or insect, show varying degrees of length dependent activation and stretch activation, but it is currently not known whether these two processes reflect the same underlying phenomenon, nor is the molecular mechanism for either known, despite decades of research. Current data from insect flight muscle suggest that stretch activation is controlled by tropomyosin, similar to neurogenic calcium-activation but mediated by myosin-troponin connections that transmit strain when the muscle is stretched. This project is the first ever systematic comparison of length dependent activation and stretch activation in vertebrate cardiac, slow skeletal, fast skeletal, and insect flight muscles, to determine whether the two modes of activation are different manifestations of a single process for all muscle types. Preliminary data from bovine cardiac muscle and insect flight muscle suggest that length dependent activation and stretch activation are a single process. Troponin-exchange among all four muscle types will determine the type-specific requirements for length dependent activation and stretch activation as judged by the physiological responses, and for myosin-troponin connections as judged by electron microscopy. Real-time X-ray diffraction movies of stretch activation in rabbit psoas muscle will elucidate the molecular mechanisms of stretch activation and length dependent activation in vertebrate striated muscle by revealing the sequence of molecular structural changes, to be compared side by side with insect flight muscle. Understanding the molecular basis of length dependent activation, stretch activation, and the action of myosin-troponin-bridges is necessary for a detailed mechanistic understanding of normal muscle function, which in turn is an essential prerequisite for understanding how these mechanisms are deficient in human disease, including heart disease, muscle myopathies, muscle injuries, and sarcopenia.

描述(申请人提供)：这项研究的长期目标是了解拉伸肌肉使其更用力的分子机制。所有的横纹肌都通过肌球蛋白马达蛋白来收缩，肌球蛋白马达蛋白循环拉动肌动蛋白细丝。在放松的肌肉中，肌钙蛋白-原肌球蛋白复合体在空间上阻止了肌球蛋白与肌动蛋白的相互作用。在神经性收缩中，肌钙蛋白结合释放的钙，这解除了原肌球蛋白的空间阻断，并使肌球蛋白能够结合和拉动肌动蛋白。通过一种未知的机制，拉伸肌肉会使其更用力，如果预先拉伸放松的肌肉会在随后的收缩中产生更大的力量，这一过程被称为“长度依赖激活”，或者如果拉伸部分激活的肌肉导致力量延迟上升，则称为“拉伸激活”。依赖长度的激活是弗兰克-斯塔林心脏定律背后的心肌的一个基本特征，该定律允许心肌在舒张期充盈增加后通过增加收缩力量来匹配每搏的输入和输出容量。伸展活动是大多数昆虫飞行肌肉的基本特征，这使得它能够在飞行过程中机械地触发收缩。所有的横纹肌，脊椎动物或昆虫，都表现出不同程度的 尽管经过几十年的研究，但目前尚不清楚这两个过程是否反映了相同的潜在现象，也不知道两者的分子机制。目前来自昆虫飞行肌肉的数据表明，拉伸激活由原肌球蛋白控制，类似于神经源性钙激活，但由肌球蛋白-肌钙蛋白连接介导，当肌肉拉伸时，肌球蛋白-肌钙蛋白连接传递应变。该项目首次对脊椎动物心脏、慢骨骼、快骨骼和昆虫飞行肌肉的长度依赖激活和拉伸激活进行了系统比较，以确定这两种激活模式是否是所有肌肉类型单一过程的不同表现形式。来自牛心肌和昆虫飞行肌肉的初步数据表明，依赖于长度的激活和拉伸激活是一个单一的过程。所有四种肌肉类型之间的肌钙蛋白交换将决定根据生理反应判断的长度依赖激活和拉伸激活的类型特异性需求，以及根据电子显微镜判断的肌球蛋白-肌钙蛋白连接的类型特异性需求。兔腰大肌拉伸激活的实时X射线衍射片将通过揭示分子结构变化的序列，阐明脊椎动物横纹肌拉伸激活和长度依赖激活的分子机制，并与昆虫飞行肌肉进行对比。了解长度依赖的激活、拉伸激活和肌球蛋白-肌钙蛋白桥的作用的分子基础对于详细了解正常肌肉功能是必要的，而这反过来又是理解这些机制在人类疾病中是如何缺乏的必不可少的先决条件，包括心脏病、肌肉疾病、肌肉损伤和肌纤维减少症。