Department of Chemical and Biomolecular Engineering, University of Pennsylvania, Philadelphia, PA, United States.
Department of Applied Physiology and Kinesiology, University of Florida, Gainesville, FL, United States.
Matrix Biol. 2018 Aug;68-69:602-615. doi: 10.1016/j.matbio.2018.01.014. Epub 2018 Feb 2.
The production of force and power are inherent properties of skeletal muscle, and regulated by contractile proteins within muscle fibers. However, skeletal muscle integrity and function also require strong connections between muscle fibers and their extracellular matrix (ECM). A well-organized and pliant ECM is integral to muscle function and the ability for many different cell populations to efficiently migrate through ECM is critical during growth and regeneration. For many neuromuscular diseases, genetic mutations cause disruption of these cytoskeletal-ECM connections, resulting in muscle fragility and chronic injury. Ultimately, these changes shift the balance from myogenic pathways toward fibrogenic pathways, culminating in the loss of muscle fibers and their replacement with fatty-fibrotic matrix. Hence a common pathological hallmark of muscular dystrophy is prominent fibrosis. This review will cover the salient features of muscular dystrophy pathogenesis, highlight the signals and cells that are important for myogenic and fibrogenic actions, and discuss how fibrosis alters the ECM of skeletal muscle, and the consequences of fibrosis in developing therapies.
力量和功率的产生是骨骼肌的固有特性,由肌肉纤维内的收缩蛋白调节。然而,骨骼肌的完整性和功能也需要肌肉纤维与其细胞外基质 (ECM) 之间的牢固连接。一个组织良好且柔韧的 ECM 是肌肉功能的基础,许多不同细胞群体能够有效地穿过 ECM 进行迁移,这在生长和再生过程中至关重要。对于许多神经肌肉疾病,遗传突变会导致细胞骨架-ECM 连接的破坏,导致肌肉脆弱和慢性损伤。最终,这些变化使肌肉生成途径向纤维生成途径转变,导致肌肉纤维的丧失及其被脂肪纤维性基质所取代。因此,肌肉营养不良的一个常见病理标志是明显的纤维化。这篇综述将涵盖肌肉营养不良发病机制的显著特征,强调对肌生成和纤维生成作用很重要的信号和细胞,并讨论纤维化如何改变骨骼肌的 ECM,以及纤维化对开发治疗方法的影响。