The dominant-negative mitochondrial calcium uniporter subunit MCUb drives macrophage polarization during skeletal muscle regeneration.

Damaged skeletal muscle can regenerate because of the coordinated action of immune cells with muscle stem cells, called satellite cells. Proinflammatory macrophages infiltrate skeletal muscle soon after injury to sustain the proliferation of satellite cells. These macrophages later acquire the anti-inflammatory phenotype and promote the differentiation and fusion of satellite cells. Here, we showed that MCUb, the dominant-negative subunit of the mitochondrial calcium uniporter (MCU) complex, promotes muscle regeneration by controlling macrophage responses. Macrophages lacking MCUb lost the ability to efficiently acquire the anti-inflammatory profile, and mice with MCUb-deficient macrophages showed delayed regeneration through exhaustion of the satellite cell pool. MCUb ablation altered macrophage metabolism by promoting glycolysis and the accumulation of TCA cycle intermediates, which was accompanied by the stabilization of HIF-1α, the master transcriptional regulator of the macrophage proinflammatory program. Together, these data demonstrate that MCUb abundance is tightly controlled in macrophages to enable satellite cell functional differentiation and recovery of tissue homeostasis after damage.

Heparan Sulfate Mimetics Accelerate Postinjury Skeletal Muscle Regeneration.

Although skeletal muscle is capable of complete recovery after an injury, specific situations require support or acceleration of this process, such as in the elderly and athletes, respectively. Skeletal muscle regeneration is due to muscle stem cells (MuSCs) that undergo adult myogenesis, a process sustained by MuSC environment. Although recognized as important, extracellular matrix (ECM) has been overlooked in this process. Matrix-based therapy aims at improving ECM remodeling to support tissue repair. In this context, we investigated the properties of a single injection of the clinical grade glycosaminoglycan mimetics RGTA® (ReGeneraTing Agents) on skeletal muscle regeneration in a context compatible with a clinical application, that is, 3 days after the injury. Our results show that RGTA-treated muscles showed an increase of the number of myonuclei in regenerating myofibers and an increase of the capillarization of the new myofibers. In vitro experiments showed that RGTA directly acts on MuSCs by stimulating their fusion into myotubes and on endothelial cells by stimulating the formation and maturation of vessels in a 3D culture setup. These results indicate that a single administration of RGTA in regenerating muscle stimulated both myogenesis and angiogenesis, thus accelerating skeletal muscle regeneration. Impact Statement Although highly powerful in normal condition, postinjury skeletal muscle regeneration is less efficient in some situations, such as obese, elderly, or resting people. In other context, such as high-performance sport, skeletal muscle regeneration must be shortened but in a way ensuring a full functional recovery. In this context, our results show that a single injection of the clinical grade glycosaminoglycan mimetics RGTA® (ReGeneraTing Agents), in a context compatible with a clinical application, that is, 3 days after the injury, is beneficial for skeletal muscle regeneration, through the stimulation of both myogenesis and angiogenesis.