Bioactive lipid mediator class switching regulates myogenic cell progression and muscle regeneration.

The muscle stem cell niche is well-described as influencing myogenic cell fate decision; however, the intrinsic mechanisms driving muscle stem cell progression during myogenesis are not yet fully elucidated. Here, we demonstrate that bioactive lipid class switching, an auto-regulatory mechanism originally described during the inflammatory process, is conserved during myogenesis. During the transition from proliferation to differentiation, myogenic cells shift from pro-inflammatory to pro-resolution pathways, a process partially mediated by 15Δ-PGJ(2) that promotes the expression of the prostaglandin inactivation enzyme 15-hydroxyprostaglandin dehydrogenase. Using pharmacological inhibitors and knockout models of the pro-resolution enzyme 15-lipoxygenase, we show that blocking the bioactive lipid class switching impairs myoblast differentiation in vitro and muscle regeneration in vivo. Administration of the pro-resolving mediator Protectin-D1 restores myogenesis, enhances muscle regeneration post-injury and improves muscle phenotype in a dystrophic mouse model. Overall, these findings provide a better comprehension of the mechanisms regulating myogenic progression, which opens new therapeutic avenues for muscle regeneration and dystrophies.