Unconventional roles for membrane traffic proteins in response to muscle membrane stress.

Abstract In skeletal muscle fibers, ubiquitous membrane trafficking pathways responsible for transporting newly synthesized proteins, recycling cell surface receptors, and organizing membrane compartmentation have adapted to the high needs of an extremely specialized cell under constant mechanical stress. Membrane remodeling proteins involved in ubiquitous mechanisms such as clathrin-mediated endocytosis, caveolae formation, and membrane fusion have evolved to produce new pathways with sometimes completely different functions such as adhesion and mechanoprotection. In this review, I discuss recent advances in understanding the specialized features of skeletal muscle clathrin-coated plaques, caveolae, and dysferlin-mediated membrane repair. A special emphasis is given on recent findings suggesting that membrane trafficking pathways have evolved to participate into the mechanisms responsible for sarcolemma resistance to mechanical stress and discuss how defects in these pathways result in muscle disease.