肌球蛋白杆结构改变所致肌病缺陷的结构基础。
Structural basis for myopathic defects engendered by alterations in the myosin rod.
机构信息
Department of Biology and the Molecular Biology Institute, San Diego State University, San Diego, CA 92182, USA.
出版信息
J Mol Biol. 2011 Dec 9;414(4):477-84. doi: 10.1016/j.jmb.2011.10.019. Epub 2011 Oct 20.
Abstract
While mutations in the myosin subfragment 1 motor domain can directly disrupt the generation and transmission of force along myofibrils and lead to myopathy, the mechanism whereby mutations in the myosin rod influences mechanical function is less clear. Here, we used a combination of various imaging techniques and molecular dynamics simulations to test the hypothesis that perturbations in the myosin rod can disturb normal sarcomeric uniformity and, like motor domain lesions, would influence force production and propagation. We show that disrupting the rod can alter its nanomechanical properties and, in vivo, can drive asymmetric myofilament and sarcomere formation. Our imaging results indicate that myosin rod mutations likely disturb production and/or propagation of contractile force. This provides a unifying theory where common pathological cascades accompany both myosin motor and specific rod domain mutations. Finally, we suggest that sarcomeric inhomogeneity, caused by asymmetric thick filaments, could be a useful index of myopathic dysfunction.
摘要
虽然肌球蛋白亚基 1 马达结构域的突变可以直接破坏肌原纤维中力的产生和传递,导致肌病,但肌球蛋白杆部突变影响机械功能的机制尚不清楚。在这里,我们使用了各种成像技术和分子动力学模拟的组合来测试以下假设:肌球蛋白杆部的扰动会破坏正常的肌节均匀性,并且与马达结构域的损伤一样,会影响力的产生和传播。我们发现,破坏杆部可以改变其纳米力学特性,并且在体内可以驱动不对称的肌丝和肌节形成。我们的成像结果表明,肌球蛋白杆部突变可能会干扰收缩力的产生和/或传播。这提供了一个统一的理论,其中共同的病理级联伴随着肌球蛋白马达和特定杆部结构域的突变。最后,我们认为由不对称的粗丝引起的肌节不均匀性可能是肌病功能障碍的一个有用指标。
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