Department of Neuropathology, NIMHANS, Bangalore 560029, Karnataka, India.
Manipal University, Madhav Nagar, Manipal 576104, Karnataka, India; Institute of Bioinformatics, Whitefield, Bangalore 560066, Karnataka, India.
J Proteomics. 2020 Jan 16;211:103556. doi: 10.1016/j.jprot.2019.103556. Epub 2019 Oct 23.
Analysis of human muscle diseases highlights the role of mitochondrial dysfunction in the skeletal muscle. Our previous work revealed that diverse upstream events correlated with altered mitochondrial proteome in human muscle biopsies. However, several proteins showed relatively unchanged expression suggesting that post-translational modifications, mainly protein phosphorylation could influence their activity and regulate mitochondrial processes. We conducted mitochondrial phosphoprotein profiling, by proteomics approach, of healthy human skeletal muscle (n = 10) and three muscle diseases (n = 10 each): Dysferlinopathy, Polymyositis and Distal Myopathy with Rimmed Vacuoles. Healthy human muscle mitochondrial proteins displayed 253 phosphorylation sites (phosphosites), which contributed to metabolic and redox processes and mitochondrial organization etc. Electron transport chain complexes accounted for 84 phosphosites. Muscle pathologies displayed 33 hyperphosphorylated and 14 hypophorphorylated sites with only 5 common proteins, indicating varied phosphorylation profile across muscle pathologies. Molecular modelling revealed altered local structure in the phosphorylated sites of Voltage-Dependent Anion Channel 1 and complex V subunit ATP5B1. Molecular dynamics simulations in complex I subunits NDUFV1, NDUFS1 and NDUFV2 revealed that phosphorylation induced structural alterations thereby influencing electron transfer and potentially altering enzyme activity. We propose that altered phosphorylation at specific sites could regulate mitochondrial protein function in the skeletal muscle during physiological and pathological processes.
人类肌肉疾病的分析强调了线粒体功能障碍在骨骼肌中的作用。我们之前的工作表明,多种上游事件与人类肌肉活检中线粒体蛋白质组的改变相关。然而,有几种蛋白质的表达相对不变,这表明翻译后修饰(主要是蛋白质磷酸化)可能会影响它们的活性并调节线粒体过程。我们通过蛋白质组学方法对健康人体骨骼肌(n=10)和三种肌肉疾病(每种疾病 n=10)进行了线粒体磷酸化蛋白质组分析:先天性肌营养不良症、多发性肌炎和伴有边缘空泡的远端肌病。健康人肌肉线粒体蛋白质显示出 253 个磷酸化位点(磷酸化位点),这些磷酸化位点有助于代谢和氧化还原过程以及线粒体组织等。电子传递链复合物占 84 个磷酸化位点。肌肉病理显示出 33 个过度磷酸化和 14 个低磷酸化位点,只有 5 个共同蛋白质,表明不同的肌肉疾病具有不同的磷酸化谱。分子建模显示电压依赖性阴离子通道 1 和复合物 V 亚基 ATP5B1 的磷酸化位点的局部结构发生改变。在复合物 I 亚基 NDUFV1、NDUFS1 和 NDUFV2 中进行分子动力学模拟表明,磷酸化诱导结构改变,从而影响电子转移并可能改变酶活性。我们提出,特定位点的磷酸化改变可能会在生理和病理过程中调节骨骼肌中线粒体蛋白质的功能。
