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The Role of Glucocorticoid Signaling in Adult Muscle Stem Cell and Myogenic DifferentiationRajgara, Rashida 16 June 2023 (has links)
Glucocorticoids are the most widely prescribed medications due primarily to their anti-inflammatory and immunosuppressive actions, however, their use is not without side effects. Among these, glucocorticoids cause profound muscle atrophy, yet paradoxically are used as the first line of treatment for muscle wasting disorders such as Duchenne Muscular Dystrophy (DMD) and inflammatory myopathies. In DMD patients, glucocorticoid treatment can improve muscle strength during the first 6 months of treatment and can delay loss of muscle function by up to three years. While recent advancements have been made to understand the effect of glucocorticoids (GCs) on the myofiber, the impact of GCs on skeletal muscle stem cells (MuSCs), the adult stem cells responsible for muscle regeneration, and their role in myogenic differentiation, are relatively unknown. To study the role of glucocorticoid signalling during muscle repair, I developed a conditional null mouse (GRMuSC-/-) model in which glucocorticoid receptor (GR) expression is knocked out specifically in MuSCs (GRMuSC-/-). One-week following acute muscle injury, WT and GRMuSC-/- mice both underwent robust repair assessed by myofiber cross-sectional area (CSA) analysis. However, the GR-/- MuSCs failed to return to quiescence following repair resulting in a significant increase in average myofiber CSA at 28- and 42- days post-injury, as compared to controls. Loss of the GR led to a significant increase in the percentage of PAX7+Ki67+ cycling cells in GRMuSC-/- mice (as compared to controls) at 42 days post injury. In the uninjured contralateral limb, I observed significantly fewer MuSCs in GRMuSC-/- mice with a concomitant increase in fibers with centrally located nuclei, indicating that these PAX7+ MuSCs progressed to differentiation in the absence of direct injury. In an uninjured model, two weeks following loss of GR expression there was an increase in the percentage of BrdU+ and Ki67+ cycling cells in resting GRMuSC-/- tibialis anterior muscles as compared to WT, suggesting that the GR acts to maintain MuSC quiescence. Consistent with this, immunostaining of single EDL myofiber fibers at T2h post-dissociation revealed that loss of GR in MuSCs lead to precocious activation and subsequent proliferation of MuSCs as compared to controls. Bulk RNA-sequencing from in situ fixed MuSCs in resting muscle revealed that the gene signature of GR-/- MuSCs was consistent with cells that have exited from the quiescent state and are activated for differentiation. Despite precocious activation, GR-/- myoblasts differentiate and fuse normally, however the myotubes produced had abnormal morphology and aberrant myonuclear placement in regenerated muscle fibers in vivo.
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