Department of Neuroscience, Clinical Neurophysiology, Uppsala University, Sweden.
Acta Neuropathol. 2012 May;123(5):739-46. doi: 10.1007/s00401-012-0962-z. Epub 2012 Feb 23.
Nemaline myopathy (NM) is the most common congenital myopathy and is caused by mutations in various genes including NEB (nebulin), TPM2 (beta-tropomyosin), TPM3 (gamma-tropomyosin), and ACTA1 (skeletal alpha-actin). 20-25% of NM cases carry ACTA1 defects and these particular mutations usually induce substitutions of single residues in the actin protein. Despite increasing clinical and scientific interest, the contractile consequences of these subtle amino acid substitutions remain obscure. To decipher them, in the present study, we originally recorded and analysed the mechanics as well as the X-ray diffraction patterns of human membrane-permeabilized single muscle fibres with a particular peptide substitution in actin, i.e. p.Phe352Ser. Results unravelled an unexpected cascade of molecular and cellular events. During contraction, p.Phe352Ser greatly enhances the strain of individual cross-bridges. Paradoxically, p.Phe352Ser also slightly lowers the number of cross-bridges by altering the rate of myosin head attachment to actin monomers. Overall, at the cell level, these divergent mechanisms conduct to an improved steady-state force production. Such results provide new surprising scientific insights and crucial information for future therapeutic strategies.
先天性肌病中最常见的是杆状体肌病(Nemaline myopathy,NM),它是由包括 NEB(nebulin)、TPM2(β-原肌球蛋白)、TPM3(γ-原肌球蛋白)和 ACTA1(骨骼肌α-肌动蛋白)在内的多种基因的突变引起的。20-25%的 NM 病例存在 ACTA1 缺陷,这些特定的突变通常会诱导肌动蛋白蛋白中单个残基的取代。尽管临床和科学兴趣日益增加,但这些微妙的氨基酸取代的收缩后果仍然不清楚。为了解决这个问题,在本研究中,我们最初记录和分析了具有肌动蛋白中特定肽取代(即 p.Phe352Ser)的人细胞膜透化单根肌纤维的力学和 X 射线衍射模式。结果揭示了一系列意想不到的分子和细胞事件。在收缩过程中,p.Phe352Ser 极大地增强了单个交联桥的应变。矛盾的是,p.Phe352Ser 通过改变肌球蛋白头部与肌动蛋白单体的附着速度,也略微降低了交联桥的数量。总的来说,在细胞水平上,这些不同的机制导致了稳态力产生的改善。这些结果提供了新的令人惊讶的科学见解和对未来治疗策略的关键信息。
