Targeted-SMN insufficiency in Skeletal Muscle Stem Cells mediates non-cell autonomous loss of motor neurons at long term
Mecca, J.; Mignot, J.; Gervais, M.; Ozturk, T.; Astord, S.; Berthier, J.; Bauche, S.; Messeant, J.; Biferi, M.-G.; Rouard, H.; Barkats, M.; Relaix, F.; Didier, N.
Show abstract
Spinal Muscular Atrophy (SMA) is due to a deficit in SMN protein encoded by the SMN1 gene. SMN-targeted disease modifying treatments have greatly improved the clinical outcomes of this neuromuscular disease. However, uncertainties remain regarding their long-term efficacy and non-neuronal tissue involvement in disease progression. We found that SMA type II patient muscles display a reduced number of quiescent PAX7+ Muscle Stem Cells (MuSC). In SMA mice, we showed that SMN is an important regulator of myogenic progenitor fate during early postnatal growth. In Pax7 Cre-driven conditional knockout mouse models, we demonstrated that high levels of SMN are required to ensure the maintenance of the quiescent MuSC pool in adult muscle. We further established that depletion of SMN-deficient MuSC yielded neuromuscular junctions remodeling followed by a non-cell autonomous loss of motor neurons in the long term. Overall, our findings demonstrate that MuSC are a crucial therapeutic target for SMA treatment. HIGHLIGHTSO_LISMN regulates myogenic lineage progression and quiescent MuSC pool establishment during postnatal growth C_LIO_LIBoth Smn alleles are necessary for the survival of quiescent MuSC in adult muscle C_LIO_LIDepletion of SMN-deficient MuSC leads to NMJ remodeling and non-cell autonomous loss of MN C_LI
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