Citation

Price FD, Matyas MN, Gehrke AR, Chen W, Wolin EA, Chen W, Holton KM, Gibbs RM, Lee A, Singu P, Sakakeeny J,Poteracki JM, Goune K, Pfeiffer IT, Boswell SA, Sorger PK, Srivastava M, Pfaff KL, Gussoni E, Buchanan SM, Rubin LL. 2024. Organoid culture promotes dedifferentiation of mouse myoblasts into stem cells capable of complete muscle regeneration. Nature Biotechnology. DOI:https://doi.org/10.1038/s41587-024-02344-7

Abstract

Experimental cell therapies for skeletal muscle conditions have shown little success, primarily because they use committed myogenic progenitors rather than true muscle stem cells, known as satellite cells. Here we present a method to generate in vitro-derived satellite cells (idSCs) from skeletal muscle tissue. When transplanted in small numbers into mouse muscle, mouse idSCs fuse into myofibers, repopulate the satellite cell niche, self-renew, support multiple rounds of muscle regeneration and improve force production on par with freshly isolated satellite cells in damaged skeletal muscle. We compared the epigenomic and transcriptional signatures between idSCs, myoblasts and satellite cells and used these signatures to identify core signaling pathways and genes that confer idSC functionality. Finally, from human muscle biopsies, we successfully generated satellite cell-like cells in vitro. After further development, idSCs may provide a scalable source of cells for the treatment of genetic muscle disorders, trauma-induced muscle damage and age-related muscle weakness.

Related Faculty

Photo of Feodor Price

Feo’s research is translational in nature and geared towards studying how adult skeletal muscle stem cells are involved in regulating muscle regeneration.

Photo of Lee Rubin

Lee Rubin investigates the key molecular mediators of a variety of neurodegenerative diseases, with the ultimate goal of finding effective preclinical therapeutic candidates.

Search Menu