Key Facilitator Proteins that Mediate Sarcolemma Membrane Repair have Potential as Therapeutics for Muscle Disease and Injury

Abstract

A common aspect of many diseases and traumatic injuries affecting skeletal muscle is the necrotic death of muscle fibers. Necrotic death of muscle fibers involves the breakdown of the sarcolemmal membrane that can be exacerbated by increased fragility of the membrane or by compromised endogenous sarcolemmal membrane repair processes. Increasing the efficacy of these repair mechanisms could act as a therapeutic approach for several muscular diseases and injuries. Limb‐girdle muscular dystrophy 2B (LGMD2B), a subtype of LGMD, is an autosomal recessive neuromuscular disorder caused by mutations in the DYSF gene that encodes dysferlin, a protein that is vital in membrane repair. The dysferlin protein has been previously shown to facilitate membrane repair in skeletal muscle and knockout mice for dysferlin develop progressive muscular dystrophy. When dysferlin is absent or inactivated through mutation, membrane damage that cannot be repaired accumulates until muscle fibers undergo necrosis that eventually overwhelms the regenerative capacity of the muscle. This causes skeletal muscle deterioration in LGMD2B patients, particularly in the pelvic and shoulder girdle muscles. There is currently no cure for LGMD2B and treatments that stimulate the membrane repair process in muscle fibers have been greatly overlooked and underutilized as a potential therapeutic approach. This project investigates a novel membrane repair signaling cascade in skeletal cells by utilizing SC79, an Akt activator, to increase membrane repair capacity in skeletal muscle. We hypothesize that activation of the phosphoinositide‐3 kinase (PI3K)/Akt1 signaling axis regulates membrane repair in cultured muscle cells and mouse tissue. Based on our data, we find that SC79 injection leads to decreased sarcolemmal membrane injury during treadmill exercises where injection of SC79 decreases the entry of Evans blue dye into muscle fibers. We determined that various doses of SC79 can increase membrane repair in cultured muscle cells and Bla/J dysferlin deficient mice. In these studies, multi‐photon infrared laser microscopy was used to damage the cell membrane of myoblasts, transdifferentiated from skin fibroblasts isolated from LGMD2B patients, in the presence of FM4‐64 dye, a lipophilic dye that fluoresces when it enters the cells and binds to the phospholipids of the cell membrane and intracellular organelles. The extent of localized FM4‐64 dye fluorescence provides a measurement of how well the membrane is repaired. We found SC79 could increase membrane repair in these human patient myoblasts in a dose dependent fashion. This assay was also used on isolated complete muscles from the Bla/J dysferlin deficient mice, where SC79 also increased membrane repair responses. We conclude that activation of the PI3K/Akt1 signaling axis increases membrane repair in dysferlin deficient skeletal muscle. This project explores a novel signaling cascade controlling membrane repair that could be leveraged to develop new therapies for muscle disease and injury.