Glucocorticoids (GCs) are important regulators of skeletal muscle mass, and prolonged exposure will induce significant muscle atrophy. To better understand the mechanism of skeletal muscle atrophy induced by elevated GC levels, we examined three different models: exogenous synthetic GC treatment [dexamethasone (DEX)], nutritional deprivation, and denervation. Specifically, we tested the direct contribution of the glucocorticoid receptor (GR) in skeletal muscle atrophy by creating a muscle-specific GR-knockout mouse line (MGR(e3)KO) using Cre-lox technology. In MGR(e3)KO mice, we found that the GR is essential for muscle atrophy in response to high-dose DEX treatment. In addition, DEX regulation of multiple genes, including two important atrophy markers, MuRF1 and MAFbx, is eliminated completely in the MGR(e3)KO mice. In a condition where endogenous GCs are elevated, such as nutritional deprivation, induction of MuRF1 and MAFbx was inhibited, but not completely blocked, in MGR(e3)KO mice. In response to sciatic nerve lesion and hindlimb muscle denervation, muscle atrophy and upregulation of MuRF1 and MAFbx occurred to the same extent in both wild-type and MGR(e3)KO mice, indicating that a functional GR is not required to induce atrophy under these conditions. Therefore, we demonstrate conclusively that the GR is an important mediator of skeletal muscle atrophy and associated gene expression in response to exogenous synthetic GCs in vivo and that the MGR(e3)KO mouse is a useful model for studying the role of the GR and its target genes in multiple skeletal muscle atrophy models.
Muscle atrophy can result from inactivity or unloading on one hand or the induction of a catabolic state on the other. Muscle-specific ring finger 1 (MuRF1), a member of the tripartite motif family of E3 ubiquitin ligases, is an essential mediator of multiple conditions inducing muscle atrophy. While most studies have focused on the role of MuRF1 in protein degradation, the protein may have other roles in regulating skeletal muscle mass and metabolism. We therefore systematically evaluated the effect of MuRF1 on gene expression during denervation and dexamethasone-induced atrophy. We find that the lack of MuRF1 leads to few differences in control animals, but there were several significant differences in specific sets of genes upon denervation- and dexamethasone-induced atrophy. For example, during denervation, MuRF1 knockout mice showed delayed repression of metabolic and structural genes and blunted induction of genes associated with the neuromuscular junction. In the latter case, this pattern correlates with blunted HDAC4 and myogenin upregulation. Lack of MuRF1 caused fewer changes in the dexamethasone-induced atrophy program, but certain genes involved in fat metabolism and intracellular signaling were affected. Our results demonstrate a new role for MuRF1 in influencing gene expression in two important models of muscle atrophy.
Glucocorticoids (GCs) are important regulators of skeletal muscle mass and exert their actions primarily via GC receptors (GR) that interact with GC response elements (GREs) near target genes. However, many GR target genes lack clear GREs and there may be nongenomic effects of GCs. In addition, actions of GCs on skeletal muscle mass and function may be exerted outside the myotubes themselves. To investigate skeletal muscle transcriptional responses to GCs leading to atrophy and metabolic changes, we examined the dexamethasone (DEX) induced gene expression in two mouse lines: 1. GR dimerization mutant mice (GRdim) that ubiquitously express GR with an impaired ability to dimerize at certain GREs and 2. muscle specific GR knockout mice (muGRKO). Induction of the muscle atrophy associated MuRF1 gene is blunted in GRdim mice but fully prevented in muGRKO mice; induction of another important atrophy gene, MAFbx, is unaffected in GRdim mice but is also completely blocked in muGRKO mice. In both models, extracellular matrix genes like collagen 1A1 are repressed by DEX, as expected. We hypothesize that the skeletal muscle GR is important for mediating high dose GC induced atrophy, however the deleterious effects of GCs in muscle structure and function may not be muscle cell autonomous. The GRdim and muGRKO mice will be useful models to determine the importance of the GR and its target genes in several muscle atrophy models. This work was funded by NIH RO1 DK75801 and NIH Training Grant 2T32GM007377‐31A1.
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