Matrisome proteomics reveals novel mediators of muscle remodeling with aerobic exercise training

Q1 Medicine
Pattarawan Pattamaprapanont , Eileen M. Cooney , Tara L. MacDonald , Joao A. Paulo , Hui Pan , Jonathan M. Dreyfuss , Sarah J. Lessard
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Abstract

Skeletal muscle has a unique ability to remodel in response to stimuli such as contraction and aerobic exercise training. Phenotypic changes in muscle that occur with training such as a switch to a more oxidative fiber type, and increased capillary density contribute to the well-known health benefits of aerobic exercise. The muscle matrisome likely plays an important role in muscle remodeling with exercise. However, due to technical limitations in studying muscle ECM proteins, which are highly insoluble, little is known about the muscle matrisome and how it contributes to muscle remodeling. Here, we utilized two-fraction methodology to extract muscle proteins, combined with multiplexed tandem mass tag proteomic technology to identify 161 unique ECM proteins in mouse skeletal muscle. In addition, we demonstrate that aerobic exercise training induces remodeling of a significant proportion of the muscle matrisome. We performed follow-up experiments to validate exercise-regulated ECM targets in a separate cohort of mice using Western blotting and immunofluorescence imaging. Our data demonstrate that changes in several key ECM targets are strongly associated with muscle remodeling processes such as increased capillary density in mice. We also identify LOXL1 as a novel muscle ECM target associated with aerobic capacity in humans. In addition, publically available data and databases were used for in silico modeling to determine the likely cellular sources of exercise-induced ECM remodeling targets and identify ECM interaction networks. This work greatly enhances our understanding of ECM content and function in skeletal muscle and demonstrates an important role for ECM remodeling in the adaptive response to exercise. The raw MS data have been deposited to the ProteomeXchange with identifier PXD053003.

Matrisome 蛋白组学揭示了有氧运动训练肌肉重塑的新介质
骨骼肌对收缩和有氧运动训练等刺激具有独特的重塑能力。随着训练的进行,肌肉的表型会发生变化,如转变为氧化性更强的纤维类型,以及毛细血管密度增加,这些都是众所周知的有氧运动对健康的益处。肌肉矩阵组可能在肌肉随运动而重塑的过程中发挥了重要作用。然而,由于研究肌肉 ECM 蛋白的技术限制,人们对肌肉 matrisome 及其如何促进肌肉重塑知之甚少。在这里,我们利用双馏分方法提取肌肉蛋白质,结合多重串联质量标签蛋白质组学技术,鉴定出小鼠骨骼肌中 161 种独特的 ECM 蛋白。此外,我们还证明有氧运动训练会诱导相当一部分肌肉矩阵组的重塑。我们进行了后续实验,利用 Western 印迹和免疫荧光成像技术在另一批小鼠中验证了运动调节的 ECM 目标。我们的数据表明,几个关键 ECM 靶点的变化与小鼠肌肉重塑过程(如毛细血管密度增加)密切相关。我们还发现 LOXL1 是与人类有氧能力相关的新型肌肉 ECM 靶点。此外,我们还利用公开数据和数据库进行了硅学建模,以确定运动诱导的 ECM 重塑靶点的可能细胞来源,并识别 ECM 相互作用网络。这项工作极大地增强了我们对骨骼肌中 ECM 含量和功能的了解,并证明了 ECM 重塑在运动适应性反应中的重要作用。原始 MS 数据已存入 ProteomeXchange,标识符为 PXD053003。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Matrix Biology Plus
Matrix Biology Plus Medicine-Histology
CiteScore
9.00
自引率
0.00%
发文量
25
审稿时长
105 days
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