IGF-1 receptor mediates differentiation of primary cultures of mouse skeletal myoblasts

Studies involving immortalized myoblasts suggested that insulin-like growth factors (IGFs) promote differentiation of skeletal muscle, but gene targeting experiments in mice did not provide support for this hypothesis. To address this discrepancy, we examined differentiation of primary cultures of mouse myoblasts. Differentiation was normally unaffected by addition of IGFs to the differentiation medium. However, when we interrupted IGF-mediated signaling, by incubating myoblasts with suramin or with a monoclonal antibody to the IGF-I receptor, differentiation was inhibited. Inhibition was reversed by exogenous IGF-I or IGF-II, but not by insulin. Differentiation was enhanced in myoblasts that were incubated with an inhibitor of the mitogen-activated protein kinase signaling pathway (PD098059) and such cells were responsive to exogenous IGF-I. Our results demonstrate that IGF action contributes to the differentiation of non-immortalized mouse myoblasts and that these cells represent a model system that can be experimentally manipulated to study the molecular events involved in skeletal muscle differentiation.     

Characterisation of the IGF system in a primary adult human skeletal muscle cell model, and comparison of the effects of insulin and IGF-I on protein metabolism

In an attempt to address the complex and clinically challenging question of the causes of muscle wasting in patients with cachexia, we have developed a primary adult human skeletal muscle cell model. The cultured cells were characterised by immunocytochemistry using antibodies to the myofibrillar protein constituents desmin and titin. Myotube formation was confirmed biochemically by a fourfold increase in the activity of the muscle-specific enzyme creatinine kinase, and myoblast withdrawal from the cell cycle, which is essential for terminal differentiation, was associated with progressive retinoblastoma protein dephosphorylation. Having successfully confirmed the phenotype of these adult human muscle cells, we assessed their interaction with the insulin-like growth factor (IGF) system. IGF-I is known to stimulate myoblast survival, proliferation and differentiation in cell lines, and, like insulin, is a potent anabolic agent in the regulation of protein metabolism. We have shown that IGF-I stimulated both replication and differentiation of myoblasts, whilst fibroblast growth factor-2 stimulated replication but inhibited differentiation. Examining the IGF system during the process of terminal differentiation, we found that both myoblasts and myotubes expressed insulin, IGF-I and insulin-IGF-I hybrid receptors, with the levels of all three receptor types increasing on differentiation. The cells also produced a wide range of IGF binding proteins (IGFBPs) including IGFBP-2, IGFBP-4 and abundant IGFBP-3, which has not been shown to be produced by any other skeletal muscle cell line examined to date. Both insulin and IGF-I had anabolic effects on myotube protein metabolism at physiological concentrations. Insulin was more potent than IGF-I: use of the IGF analogue long R(3)IGF-I demonstrated that the effects of exogenous IGF-I on protein metabolism were not affected by the high levels of endogenous IGFBP production. In summary, we have developed and characterised a clinically relevant in vitro model with which to address the aetiology of muscle wasting associated with chronic catabolic conditions, and we anticipate that future work will enable the development of novel, effective therapeutic interventions.     

Akt phosphorylation is not sufficient for insulin-like growth factor-stimulated myogenin expression but must be accompanied by down-regulation of mitogen-activated protein kinase/extracellular signal-regulated kinase phosphorylation

IGF-I has a unique biphasic effect on skeletal muscle differentiation. Initially, IGF-I inhibits expression of myogenin, a skeletal muscle-specific regulatory factor essential for myogenesis. Subsequently, IGF-I switches to stimulating expression of myogenin. The mechanisms that mediate this switch in IGF action are incompletely understood. Several laboratories have demonstrated that the phosphatidylinositol-3-kinase/Akt signaling pathway is essential for myogenic differentiation and have suggested that this pathway mediates IGF-I stimulation of myogenin mRNA expression, an early critical step in the differentiation process. These studies, however, did not address concurrent Akt and MAPK/ERK1/2 phosphorylation, the latter of which is also known to regulate myogenic differentiation. In the present study in rat L6E9 muscle cells, we have manipulated ERK1/2 phosphorylation with either an upstream inhibitor or activator and examined concurrent levels of Akt and ERK1/2 phosphorylation and of myogenin mRNA expression in response to treatment with IGF-I. We find that even in the presence of phosphorylated Akt, it is only when ERK1/2 phosphorylation is inhibited that IGF-I can stimulate myogenin mRNA expression. Thus, although Akt phosphorylation may be necessary, it is not sufficient for induction of myogenic differentiation by IGF-I and must be accompanied by a decrease in ERK1/2 phosphorylation.     

Administration of insulin to newly hatched chicks improves growth performance via impairment of MyoD gene expression and enhancement of cell proliferation in chicken myoblasts

The insulin/PI3K/Akt signaling pathway is strongly involved in the differentiation of C2C12 cells, as has been demonstrated by the addition of IGFs and insulin to culture media. In this study, we have characterized the role of insulin in chick myoblast proliferation and differentiation in vitro and in vivo, and have revealed novel details of how this exogenous hormone influences myogenic genes during differentiation. Chick myoblast cells cultured in differentiation medium (DMEM containing 2% FBS) supplemented with insulin exhibited a significant decrease in MyoD and myogenin mRNA expression after 12h of culture compared to cells cultured in differentiation media alone. MyoD and myogenin immunoreactive proteins in cells cultured in differentiation medium supplemented with insulin were quite low compared to those in control culture. Supplementation of the differentiation media containing insulin with LY294002 (a PI3K inhibitor) induced myoblast differentiation. A significant increase in MyoD and myogenin mRNA expression was observed in these cells after incubation for 12h, and the level of expression was similar to that of control cells incubated with differentiation media alone. The DNA content and the phosphor-Erk1/2 protein level were increased by the addition of insulin to the differentiation medium. These results suggest that insulin and its signaling pathway play an inhibitory role in chick myoblast differentiation. A high level of Pax7 mRNA was observed in the skeletal muscle of 3-day-old chicks administered insulin or tolbutamide at 1-day-of-age. In addition, body weight at 21 and 50 days-of-age was significantly greater for chickens administered insulin or tolbutamide at 1-day-of-age than for control chickens. These results detail not only species-specific differences in insulin action for myoblasts but also provide novel information that may be used for the improvement of chicken meat production.     

Differentiation-dependent phosphorylation of a 175,000 molecular weight protein in response to insulin and insulin-like growth factor-I in L6 skeletal muscle cells

Insulin and insulin-like growth factor-I (IGF-I) effects on protein phosphorylation were investigated in intact skeletal muscle cells at different stages of differentiation. In undifferentiated L6 myoblasts, stimulation by either insulin or IGF-I, but not IGF-II, led to a 3- to 5-fold increase in phosphorylation of insulin and IGF receptor beta-subunits and the appearance of a 175,000 mol wt (Mr) phosphoprotein (pp175). These effects reached a maximum within 3 min, were maintained for 12 min, and then declined. Dose-response curves for pp175 phosphorylation in response to insulin (ED50 = 2 nM) and IGF-I (ED50 = 0.2 nM) were consistent with occupancy and stimulation of each receptor kinase by its specific hormone. The 175,000 Mr phosphoprotein was not precipitated by antireceptor antibodies, and the phosphoamino acid composition differed markedly from that of insulin and IGF-I receptors, with a 10-fold lower phosphotyrosine/phosphoserine ratio after insulin stimulation. In contrast to insulin and IGF-I receptors, pp175 was not extracted by the nonionic detergent Triton X-100, but required sodium dodecyl sulfate for solubilization. When experiments were carried out with L6 cells after differentiation into skeletal muscle myotubes, hormone-induced phosphorylation of pp175 was almost undetectable. We conclude that pp175 is a phosphoprotein distinct from insulin and IGF-I receptors that is involved in the early phosphorylation events that follow the activation of the insulin and IGF-I receptor kinases. Its disappearance after terminal differentiation of the L6 cells is consistent with a role in hormonal stimulation of cell proliferation.     

Transforming growth factor beta induces myoblast differentiation in the presence of mitogens.

Transforming growth factor beta 1 (TGF-beta 1) added to L6E9 rat skeletal myoblasts in mitogen-rich medium induces a rapid decrease in c-myc expression and delays progression through the G1 phase of the cell cycle. This growth inhibitory response is followed by cell commitment to terminal differentiation with elevated expression of myogenin muscle determination genes, induction of muscle-specific proteins, and formation of multinucleated myotubes. These results suggest that TGF-beta 1 may act as a physiological inducer of myogenic differentiation in mitogen-rich environments, and its otherwise reversible growth inhibitory effect may become permanent if coupled to induction of terminal differentiation.     

Coordinate expression of insulin-like growth factor II and its receptor during muscle differentiation.

The role of polypeptide growth factors in promoting muscle differentiation is uncharacterized. We have used a fusing skeletal muscle cell line, C2, to examine the endogenous expression of one peptide, insulin-like growth factor II (IGF-II), and its receptor during differentiation. The synthesis of IGF-II is low during proliferation of myoblasts; IGF-II mRNA can be detected only through use of a highly sensitive solution-hybridization assay. Competition binding studies reveal that the IGF-II receptor is similarly nonabundant in myoblasts. During differentiation IGF-II mRNA rises rapidly. A nearly 4-fold increase is seen within 16 hr of onset of the differentiation process, and levels are 25 times higher than those in myoblasts by 96 hr, when myotubes have formed and muscle-specific alpha-actin mRNAs are synthesized. IGF-II accumulates in conditioned culture medium with similar kinetics. The expression of IGF-II receptors on the cell surface increases almost 6-fold 24 hr after the onset of differentiation and remains high. These studies suggest that IGF-II and its receptor are coordinately regulated during myogenic differentiation in C2 cells and that IGF-II may be an autocrine factor for skeletal muscle.     

Insulin-like growth factor I (IGF-I) is a more potent regulator of gene expression than insulin in primary human myoblasts and myotubes

Conventionally, insulin is believed to induce a metabolic response, and IGF-I a mitogenic/differentiation response in vivo. However, several studies indicate that the roles of insulin and IGF-I may not be that easy to separate. In this study, insulin and IGF-I specificity in terms of gene regulation was investigated in primary human skeletal muscle cells before and after differentiation. Cell cultures were treated with 100 nM insulin, IGF-I or nothing for 4 h, and gene expression was subsequently determined using the Affymetrix microarray platform. Insulin and IGF-I receptor levels were determined by qRT-PCR and by radioligand binding assays. In primary myoblasts, insulin did not have any significant effect on gene expression, whereas IGF-I regulated 229 genes. In primary myotubes, insulin regulated 105 genes, whereas IGF-I regulated 697 genes. Additionally, 99 genes were found to be differentially regulated by insulin and IGF-I in a direct comparison. The majority of these genes were specifically regulated by IGF-I, 16 genes were regulated by both ligands, and no genes were regulated by only insulin. The microarray results correlated with low levels of insulin receptors compared to IGF-I receptors as determined by radioligand binding assays. In the myotubes, we did not identify any ligand specificity in terms of functional categories. The major difference between the two ligands was their respective potencies in gene regulation, which was higher for IGF-I than for insulin. This was true for genes involved in both mitogenic and metabolic regulations. The data suggest that IGF-I is a more important metabolic regulator in skeletal muscle than previously estimated.     

Role of insulin-like growth factors and myogenin in the altered program of proliferation and differentiation in the NFB4 mutant muscle cell line.

In the present study we used the mutant muscle cell line NFB4 to study the balance between proliferation and myogenic differentiation. We show that removal of serum, which induced the parental C2C12 cells to withdraw from the cell cycle and differentiate, had little effect on NFB4 cells. Gene products characteristic of the proliferation state, such as c-Jun, continued to accumulate in the mutant cells in low serum, whereas those involved in differentiation, like myogenin, insulin-like growth factor II (IGF-II), and IGF-binding protein 5 (IGFBP-5) were undetectable. Moreover, NFB4 cells displayed a unique pattern of tyrosine phosphorylated proteins, especially in low serum, suggesting that the signal transduction pathway(s) that controls differentiation is not properly regulated in these cells. Treatment of NFB4 cells with exogenous IGF-I or IGF-II at concentrations shown to promote myogenic differentiation in wild-type cells resulted in activation of myogenin but not MyoD gene expression, secretion of IG-FBP-5, changes in tyrosine phosphorylation, and enhanced myogenic differentiation. Similarly, transfection of myogenin expression constructs also enhanced differentiation and resulted in activation of IGF-II expression, showing that myogenin and IGF-II cross-activate each other's expression. However, in both cases, the expression of Jun mRNA remained elevated, suggesting that IGFs and myogenin cannot overcome all aspects of the block to differentiation in NFB4 cells.