Glucocorticoid inhibition of C2C12 proliferation rate and differentiation capacity in relation to mRNA levels of the MRF gene family

The muscle regulatory factors (MRF) gene family regulate muscle fibre development. Several hormones and drugs also affect muscle development. Glucocorticoids are the only drugs reported to have a beneficial effect on muscle degenerative disorders. We investigated the glucocorticoid-related effects on C2C12 myoblast proliferation rate, morphological differentiation, and subsequent mRNA expression patterns of the MRF genes. C2C12 cells were incubated with the glucocorticoids dexamethasone or alpha-methyl-prednisolone. Both glucocorticoids showed comparable effects. Glucocorticoid treatment of C2C12 cells during the proliferative phase reduced the proliferation rate of the cells dose dependently, especially during the third and fourth day of culture, increased MyoD1, myf-5, and MRF4 mRNA levels, and reduced myogenin mRNA level, compared to untreated control cells. Thus, the mRNA level of proliferation-specific MyoD1 and myf-5 expression does not seem to associate with C2C12 myoblast proliferation rate. Glucocorticoid treatment of C2C12 cells during differentiation reduced the differentiation capacity dose dependently, which is accompanied by a dose dependent reduction of myogenin mRNA level, and increased MyoD1, myf-5, and MRF4 mRNA levels compared to untreated control cells. Therefore, we conclude that glucocorticoid treatment reduces differentiation of C2C12 myoblasts probably through reduction of differentiation-specific myogenin mRNA level, while inducing higher mRNA levels of proliferation-associated MRF genes.     

Expression of myogenic factors in denervated chicken breast muscle: isolation of the chicken Myf5 gene.

In this study, we have isolated and characterized the chicken Myf5 gene, and cDNA clones encoding chicken MyoD1 and myogenin. The chicken Myf5 and MRF4 genes are tandemly located on a single genomic DNA fragment, and the chicken Myf5 gene is organized into at least three exons. Using genomic and cDNA probes, we further analyzed the mRNA levels of four myogenic factors during chicken breast muscle development. This analysis revealed that myogenin expression is restricted to in ovo stages in breast muscle, and is not detectable in neonatal and adult stages. On the other hand, Myf5 expression is detectable until day 7 post-hatching, and is not found in adult muscle, whereas high levels of MyoD1 and MRF4 are detectable at all stages. To further understand the roles of innervation on muscle maturation, we analyzed the expression of the four myogenic factors in denervated adult breast muscle. We found that MyoD1, myogenin, and MRF4 are induced at high levels in denervated muscle, whereas no change occurs in the level of Myf5. These studies suggest that innervation controls the relative abundance and type of myogenic factors that are expressed in adult muscle, and that when nerve control is removed, the muscle reverts to a neonatal phenotype, with the enhanced expression of three myogenic factors (MyoD1, myogenin, and MRF4).     

Myogenic gene expression at rest and after a bout of resistance exercise in young (18-30 yr) and old (80-89 yr) women.

The purpose of this study was to investigate mRNA expression of several key skeletal muscle myogenic controllers; myogenic differentiation factor (MyoD), muscle regulatory factor 4 (MRF4), myogenic factor 5 (Myf5), myogenin, myostatin, and myocyte enhancer factor 2 (MEF2) at rest and 4 h after a single bout of resistance exercise (RE) in young and old women. Eight young women (YW; 23 +/- 2 yr, 67 +/- 5 kg) and six old women (OW; 85 +/- 1 yr, 67 +/- 4 kg) performed 3 sets of 10 repetitions of bilateral knee extensions at 70% of one repetition maximum. Muscle biopsies were taken from the vastus lateralis before and 4 h after RE. Using real-time RT PCR, mRNA from the muscle samples was amplified and normalized to GAPDH. At rest, OW expressed higher (P < 0.05) levels of MyoD, MRF4, Myf5, myogenin, and myostatin compared with YW. In response to RE, there was a main time effect (P < 0.05) for the YW and OW combined in the upregulation of MyoD (2.0-fold) and MRF4 (1.4-fold) and in the downregulation of myostatin (2.2-fold). There was a trend (P = 0.08) for time x age interaction in MRF4. These data show that old women express higher myogenic mRNA levels at rest. The higher resting myogenic mRNA levels in old women may reflect an attempt to preserve muscle mass and function. When challenged with RE, old women appear to respond in a similar manner as young women.     

Paradoxical decrease in myf-5 messenger RNA levels during induction of myogenic differentiation by insulin-like growth factors.

Having previously demonstrated that the insulin-like growth factors (IGFs) induce expression of the myogenin gene, we have now extended our investigation of the induction of myogenesis by the IGFs to a second member of the MyoD family, myf-5. This is the only myogenesis gene other than myogenin expressed early in the differentiation of L6 myoblasts, so its regulation was of particular interest because of our observations on myogenin. In contrast to myogenin, myf-5 mRNA was detectable in proliferating myoblasts, but the steady state levels of myf-5 mRNA fell strikingly for 48 h after the cells were switched to low serum medium containing IGF-II in both murine cell lines and myoblasts cultured from human muscle. In spite of this decrease, translation of myf-5 mRNA appeared essential during the early stages of stimulation of myogenesis by the IGFs; an antisense oligodeoxynucleotide complementary to the first five codons of myf-5 blocked the increase in myogenin mRNA and inhibited morphological (cell fusion) and biochemical (creatine kinase elevation) aspects of myogenesis. We conclude that expression of myf-5 is essential for the initial induction of myogenin by the IGFs, but that subsequent elevation of myogenin expression is independent of myf-5, possibly resulting from autoinduction of the myogenin gene. The functional significance of the dramatic decrease in myf-5 mRNA levels during differentiation is not obvious.     

The expression of myogenic regulatory factors and muscle growth factors in the masticatory muscles of dystrophin-deficient (MDX) mice

The activities of myogenic regulatory factors (MRF) and muscle growth factors increase in muscle that is undergoing regeneration, and may correspond to some specific changes. Little is known about the role of MRFs in masticatory muscles in mdx mice (the model of Duchenne muscular dystrophy) and particularly about their mRNA expression during the process of muscle regeneration. Using Taqman RT-PCR, we examined the mRNA expression of the MRFs myogenin and MyoD1 (myogenic differentiation 1), and of the muscle growth factors myostatin, IGF1 (insulin-like growth factor) and MGF (mechanogrowth factor) in the masseter, temporal and tongue masticatory muscles of mdx mice (n = 6 to 10 per group). The myogenin mRNA expression in the mdx masseter and temporal muscle was found to have increased (P < 0.05), whereas the myostatin mRNA expressions in the mdx masseter (P < 0.005) and tongue (P < 0.05) were found to have diminished compared to those for the controls. The IGF and MGF mRNA amounts in the mdx mice remained unchanged. Inside the mdx animal group, gender-related differences in the mRNA expressions were also found. A higher mRNA expression of myogenin and MyoD1 in the mdx massterer and temporal muscles was found in females in comparison to males, and the level of myostatin was higher in the masseter and tongue muscle (P < 0.001 for all comparisons). Similar gender-related differences were also found within the control groups. This study reveals the intermuscular differences in the mRNA expression pattern of myogenin and myostatin in mdx mice. The existence of these differences implies that dystrophinopathy affects the skeletal muscles differentially. The finding of gender-related differences in the mRNA expression of the examined factors may indicate the importance of hormonal influences on muscle regeneration.     

Insulin-like growth factor-I stimulates terminal myogenic differentiation by induction of myogenin gene expression.

Stimulation of myogenic differentiation by the insulin-like growth factors (IGFs) has been established for many years, but our attempts to elucidate the mechanism of that stimulation have been successful only in eliminating some likely possibilities. The recent discovery of a family of muscle determination genes has opened a new approach to this question, allowing specific focus on those genes that might play central roles in controlling myogenesis. We now report that IGF-I stimulates terminal myogenic differentiation in L6A1 cells by inducing a large increase in expression of the myogenin gene. This conclusion is supported by the following observations. 1) Myogenin mRNA is elevated by IGF-I, with a concentration dependency that parallels the stimulation of differentiation, including a decrease in stimulation at higher concentrations. 2) The time course of elevation of myogenin mRNA is consistent with its acting as an intermediate in the signalling pathway between occupancy of the IGF-I receptor and induction of expression of muscle-specific genes. 3) Inhibitors of myogenesis also inhibit elevation of myogenin mRNA in response to IGF-I. 4) An antisense oligonucleotide to the N-terminus of myogenin prevents the stimulation of differentiation by IGF-I and IGF-II, but has no effect on other actions of IGF-I on myoblasts. MyoD has been reported not to be expressed in L6 cells, and the expression of myf-5 and herculin/myf-6/MRF4 is reportedly low or undetectable. Thus, the stimulation of differentiation by IGF-I can be attributed largely, if not entirely, to increased expression of the myogenin gene. However, the relatively long time period between addition of the IGFs and elevation of myogenin mRNA as well as the inhibition of this process by several inhibitors indicate that increased myogenin mRNA levels are not a simple direct result of occupation of the IGF-I receptor.     

Conditional conversion of ES cells to skeletal muscle by an exogenous MyoD1 gene.

A variety of differentiated cell types can be converted to skeletal muscle cells following transfection with the myogenic regulatory gene MyoD1. To determine whether multipotent embryonic stem (ES) cells respond similarly, cultures of two ES cell lines were electroporated with a MyoD1 cDNA driven by the beta-actin promoter. All transfected clones, carrying a single copy of the exogenous gene, expressed high levels of MyoD1 mRNA. Surprisingly, although maintained in mitogen-rich medium, this ectopic expression was associated with a transactivation of the endogenous myogenin and myosin light chain 2 gene but not the endogenous MyoD1, MRF4, Myf5, the skeletal muscle actin, or the myosin heavy chain genes. Preferential myogenesis and the appearance of contracting skeletal muscle fibers were observed only when the transfected cells were allowed to differentiate in vitro, via embryoid bodies, in low-mitogen-containing medium. Myogenesis was associated with the activation of MRF4 and Myf5 genes and resulted in a significant increase in the level of myogenin mRNA. Not all cells were converted to skeletal muscle cells, indicating that only a subset of stem cells can respond to MyoD1. Moreover, the continued expression of the introduced gene was not required for myogenesis. These results show that ES cells can respond to MyoD1, but environmental factors control the expression of its myogenic differentiation function, that MyoD1 functions in ES cells even under environmental conditions that favor differentiation is not dominant (incomplete penetrance), that MyoD1 expression is required for the establishment of the myogenic program but not for its maintenance, and that the exogenous MyoD1 gene can trans-activate the endogenous myogenin and MLC2 genes in undifferentiated ES cells.     

Testosterone protects against dexamethasone-induced muscle atrophy, protein degradation and MAFbx upregulation

Administration of glucocorticoids in pharmacological amounts results in muscle atrophy due, in part, to accelerated degradation of muscle proteins by the ubiquitin-proteasome pathway. The ubiquitin ligase MAFbx is upregulated during muscle loss including that caused by glucocorticoids and has been implicated in accelerated muscle protein catabolism during such loss. Testosterone has been found to reverse glucocorticoid-induced muscle loss due to prolonged glucocorticoid administration. Here, we tested the possibility that testosterone would block muscle loss, upregulation of MAFbx, and protein catabolism when begun at the time of glucocorticoid administration. Coadministration of testosterone to male rats blocked dexamethasone-induced reduction in gastrocnemius muscle mass and upregulation of MAFbx mRNA levels. Administration of testosterone together with dexamethasone also prevented glucocorticoid-induced upregulation of MAFbx mRNA levels and protein catabolism in C2C12 myotube expressing the androgen receptor. Half-life of MAFbx was not altered by testosterone, dexamethasone or the combination. Testosterone blocked dexamethasone-induced increases in activity of the human MAFbx promotor. The findings indicate that administration testosterone prevents glucocorticoid-induced muscle atrophy and suggest that this results, in part at least, from reductions in muscle protein catabolism and expression of MAFbx.     

Myostatin and MyoD family expression in skeletal muscle of IGF-1 knockout mice

Insulin-like growth factor-1 (IGF-1) is a positive regulator in proliferation and differentiation of skeletal muscle cells, while myostatin (MSTN) is a member of transforming growth factor beta superfamily that acts as a negative regulator of skeletal muscle mass. The present study was performed to detail whether a correlation exists between MSTN and IGF-1 in skeletal muscle of IGF-1 knockout mice (IGF-1(-/-)) and their wild type (WT; i.e., IGF-1(+/+)) littermates. The body weight of IGF-1(-/-) animals was 32% that of WT littermates. The fiber cross-sectional areas (CSA) and number of fibers in M. rectus femoris of IGF-1(-/-) animals were 49 and 59% those of WT animals, respectively. Thus, muscle hypoplasia of IGF-1(-/-) undoubtedly was confirmed. Myostatin mRNA levels and protein levels were similar between M. gastrocnemius of IGF-1(-/-) and WT animals. Myostatin immunoreactivity was similarly localized in muscle fibers of both IGF-1(-/-) and WT M. rectus femoris. The mRNA levels of MyoD family (Myf5, MyoD, MRF4, myogenin) were differentially expressed in IGF-1(-/-)M. gastrocnemius, in which the mRNA expression of MRF4 and myogenin was significantly lower, whereas there were no changes in the mRNA expression of Myf5 and MyoD. These findings first describe that myostatin expression is not influenced by intrinsic failure of IGF-1, although MRF4 and myogenin are downregulated.