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致病变异体肌球蛋白导致的先天性肌病通过不同的生理机制引起细肌丝功能障碍。

Congenital myopathy-causing tropomyosin mutations induce thin filament dysfunction via distinct physiological mechanisms.

机构信息

Department of Neuroscience, Uppsala University, Uppsala, Sweden.

出版信息

Hum Mol Genet. 2012 Oct 15;21(20):4473-85. doi: 10.1093/hmg/dds289. Epub 2012 Jul 13.

DOI:10.1093/hmg/dds289
PMID:22798622
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3459469/
Abstract

In humans, congenital myopathy-linked tropomyosin mutations lead to skeletal muscle dysfunction, but the cellular and molecular mechanisms underlying such dysfunction remain obscure. Recent studies have suggested a unifying mechanism by which tropomyosin mutations partially inhibit thin filament activation and prevent proper formation and cycling of myosin cross-bridges, inducing force deficits at the fiber and whole-muscle levels. Here, we aimed to verify this mechanism using single membrane-permeabilized fibers from patients with three tropomyosin mutations (TPM2-null, TPM3-R167H and TPM2-E181K) and measuring a broad range of parameters. Interestingly, we identified two divergent, mutation-specific pathophysiological mechanisms. (i) The TPM2-null and TPM3-R167H mutations both decreased cooperative thin filament activation in combination with reductions in the myosin cross-bridge number and force production. The TPM3-R167H mutation also induced a concomitant reduction in thin filament length. (ii) In contrast, the TPM2-E181K mutation increased thin filament activation, cross-bridge binding and force generation. In the former mechanism, modulating thin filament activation by administering troponin activators (CK-1909178 and EMD 57033) to single membrane-permeabilized fibers carrying tropomyosin mutations rescued the thin filament activation defect associated with the pathophysiology. Therefore, administration of troponin activators may constitute a promising therapeutic approach in the future.

摘要

在人类中,先天性肌病相关原肌球蛋白突变导致骨骼肌功能障碍,但这种功能障碍的细胞和分子机制仍不清楚。最近的研究表明,有一种统一的机制,即原肌球蛋白突变部分抑制细肌丝激活,并阻止肌球蛋白横桥的正确形成和循环,从而在纤维和整个肌肉水平上引起力量缺陷。在这里,我们旨在使用来自三种原肌球蛋白突变(TPM2-缺失、TPM3-R167H 和 TPM2-E181K)的单个膜透化纤维来验证该机制,并测量广泛的参数。有趣的是,我们确定了两种具有不同突变特异性的病理生理机制。(i)TPM2-缺失和 TPM3-R167H 突变均降低了协同性细肌丝激活,同时降低了肌球蛋白横桥数量和力的产生。TPM3-R167H 突变还诱导了细肌丝长度的相应减少。(ii)相比之下,TPM2-E181K 突变增加了细肌丝激活、横桥结合和力的产生。在前一种机制中,通过向携带原肌球蛋白突变的单个膜透化纤维施用肌钙蛋白激活剂(CK-1909178 和 EMD 57033)来调节细肌丝激活,可挽救与病理生理学相关的细肌丝激活缺陷。因此,肌钙蛋白激活剂的给药可能是未来有希望的治疗方法。

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Hum Mol Genet. 2011 May 15;20(10):2015-25. doi: 10.1093/hmg/ddr084. Epub 2011 Feb 28.
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The Nebulin family: an actin support group.肌联蛋白家族:肌动蛋白的支援小组。
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