Triiodothyronine influences quail myoblast proliferation and differentiation*

The influence of triiodothyronine (T3) on avian myoblast proliferation and differentiation was studied in secondary cultures using plating densities of 2500 and 7000 cells/cm². Culture media were depleted of T3 (control myoblasts) and increasing amounts were then added to concentrations of 0.6, 3 and 15 nM T3 (treated myoblasts). Independent of the cell density, T3 induced a dose-related decrease in myoblast proliferation measured by cell number, doubling time and ³H-thymidine incorporation. However, with the lower plating density, this influence was delayed, occurring only after the third day of culture for 0.6 nM T3-treated myoblasts and simultaneous with the onset of myosin heavy chain accumulation. Moreover, when myoblasts were exposed to BrdU for 48 h, the T3 growth inhibitory effect disappeared, thus showing that this effect was clearly linked to differentiation. In addition, we have shown that T3 induced an early fusion of myoblasts: 65% of the maximal value of the fusion index was reached on day 3 in the T3-treated cells in comparison to 25% in the control myoblasts. This hormone also enhanced accumulation of muscle-specific proteins (connectin, acetylcholine receptors, myosin heavy chain), tested by cytoimmunofluorescence, ELISA, binding experiments and Western blot. All these results show that T3 increased myoblast differentiation through a pathway including myoblast withdrawal from the cell cycle. The influence of T3 could partly explain its previously reported positive effect on the number of muscle fibers.     

Changes in mitochondrial activity during avian myoblast differentiation: Influence of triiodothyronine or v-erbA expression

Numerous data suggest that mitochondrial activity is involved in the regulation of cell growth and differentiation. Therefore, we have studied the changes in mitochondrial activity in avian myoblast cultures (QM7 line) undergoing differentiation or in BrdU-treated, differentiation-deficient cells. As we have previously shown that triiodothyronine and v-erb A expression stimulate myogenic differentiation, we have also observed their influence upon mitochondrial activity. Comparison of control and BrdU-treated myoblasts indicated that precocious differentiation events were associated with a stimulation of citrate synthase and cytochrome oxidase activities. They also induced a transient decrease in mitochondrial membrane potential assessed by rhodamine 123 uptake. In control myoblasts, a general stimulation of mitochondrial activity was recorded at cell confluence, prior to terminal differentiation. These events did not occur in BrdU-treated myoblasts, thus indicating that they were tightly linked to myoblast commitment. Whereas no significant triiodothyronine influence could be detected upon mitochondrial activity, we observed that v-erb A expression significantly depresses the mitochondrial membrane potential in control myoblasts. This action was not observed in BrdU-treated myoblasts, thus suggesting that it involves an indirect pathway linked to differentiation. Moreover, the oncoprotein abrogated the decrease in E2-PDH subunit level observed at cell confluence. These data underline that changes in mitochondrial activity occurred prior to myoblast terminal differentiation and could be involved in the processes regulating myogenesis. In addition, they provide the first evidence that the v-erb A oncoprotein influences mitochondrial activity. © 1996 Wiley-Liss, Inc.     

Paracrine control of myoblast proliferation and differentiation by fibroblasts

Double-muscling (DM) is a hereditary (apparently single-gene) skeletal muscle hyperplasia which occurs in beef cattle. In order to investigate the cellular basis of this phenotype, cell cultures from developing muscle tissue of normal and DM fetal calves were studied. In cultures composed of both myogenic cells and nonmyogenic, fibroblast-like cells, DM myoblasts exhibited a prolonged proliferative phase. This resulted in delayed, but increased production of fused myotubes in the DM cultures. "Conditioned" media experiments indicated that the fibroblast-like cells in the cultures produced soluble myoblast growth factor activity. Both normal and DM fibroblast-like cells produced the growth factor activity, but the mutant fibroblast-like cells produced a greater level of such activity. The conditioned media failed to increase proliferation of bovine muscle fibroblasts and did not stimulate quiescent Swiss 3T3 cells to divide, indicating that the myoblast trophic activity is distinct from bFGF or PDGF. Also, the myotrophic activity present in the conditioned media acted in an additive fashion with saturating doses of bFGF and of IGF-1, suggesting that the activity is not due to either of these known myogenic growth factors. Both normal and DM fibroblast-like cells produced myoblast trophic activity when the cells were proliferating, but did not produce myotrophic activity when the fibroblasts were mitotically quiescent. These findings indicate that the proliferative state of the connective tissue cells in muscle may have a controlling influence on myoblast proliferation and differentiation during development.     

Macrophage migration inhibitory factor in the regulation of myoblast proliferation and differentiation

Obesity is documented to be a state of chronic mild inflammation associated with increased macrophage infiltration into adipose tissue and liver and skeletal muscle. As a pleiotropic inflammatory mediator, macrophage migration inhibitory factor (MIF) is associated with metabolic disease, so MIF may signal molecular links between adipocytes and myocytes. MIF expression was modified during myoblast differentiation, but the role of MIF during this process is unclear. C2C12 cells were transfected with MIF to investigate their role during differentiation. MIF expression attenuated C2C12 differentiation. It did not change proliferation, but downregulated cyclin D1 and CDK4, causing cell accumulation in the G1 phase. p21 protein was increased significantly and MyoD, MyoG, and p21 mRNA also increased significantly in the C2C12 cells treated with ISO-1, suggesting that inhibition of MIF promotes differentiation. MIF inhibits the myoblast differentiation by affecting the cell cycle progression, but does not affect proliferation.     

Skeletal muscle Kv7 (KCNQ) channels in myoblast differentiation and proliferation

Voltage-dependent K⁺ channels (Kv) are involved in myocyte proliferation and differentiation by triggering changes in membrane potential and regulating cell volume. Since Kv7 channels may participate in these events, the purpose of this study was to investigate whether skeletal muscle Kv7.1 and Kv7.5 were involved during proliferation and myogenesis. Here we report that, while myotube formation did not regulate Kv7 channels, Kv7.5 was up-regulated during cell cycle progression. Although, Kv7.1 mRNA also increased during the G₁-phase, pharmacological evidence mainly involves Kv7.5 in myoblast growth. Our results indicate that the cell cycle-dependent expression of Kv7.5 is involved in skeletal muscle cell proliferation.     

Zinc and the initiation of myoblast differentiation

Previous studies have indicated that a lack of available zinc inhibited myoblast differentiation as shown by a failure of the cells to fuse and low expression of creatine kinase mRNA and activity. However, the nature of the requirement for zinc and its relationship to the events leading to differentiation have been unclear. The current studies with C₂C₁₂ cells indicated that the muscle-specific enhancer present in the 5′-flanking region of the creatine kinase gene contributed to the zinc sensitivity of this enzyme. Because this enhancer can be activated by expression of the myogenic factors MyoD and myogenin, their sensitivity to zinc was investigated. The concentrations of both MyoD and, particularly, myogenin mRNA, were decreased by zinc deficiency. In vitro translation experiments suggested that these changes closely corresponded with alterations in their rates of synthesis. Further experiments failed to indicate a major effect of zinc on the stabilities of these mRNAs. Because an induction of myogenin mRNA is one of the earliest known events in myoblast differentiation, its particular sensitivity to lack of zinc suggests that zinc may be required before or during the initiation of myoblast differentiation.     

Ontogeny of the v-erbA oncoprotein from the thyroid hormone receptor: an alteration in the DNA binding domain plays a role crucial for v-erbA function.

The avian erythroblastosis virus v-erbA oncogene is imprecisely derived from a cellular gene (c-erbA) encoding a thyroid hormone receptor: the v-erbA protein has sustained both small terminal deletions and internal amino acid sequence changes relative to c-erbA. We report here that one of these missense differences between v- and c-erbA proteins, located in a zinc finger DNA binding domain, has dramatic effects on the biological activities of the encoded protein. Back mutation of the viral coding sequence to resemble c-erbA at this site severely impairs erythroid transformation and produces subtle changes in DNA binding by the encoded protein, suggesting that differences in DNA binding by the viral and cellular proteins may be involved in the activation of v-erbA as an oncogene.     

Pregnancy-associated plasma protein-A regulates myoblast proliferation and differentiation through an insulin-like growth factor-dependent mechanism

Pregnancy-associated plasma protein-A (PAPP-A), a member of the metalloproteinase superfamily, is an important regulator of mammalian growth and development. However, the role of PAPP-A and its mechanism of action in various cellular processes remain unknown. In this study, we have investigated the role of PAPP-A in skeletal myogenesis using C2C12 myoblasts. Recombinant PAPP-A was purified from the conditioned medium of HT1080 cells overexpressing PAPP-A. Treatment of C2C12 myoblasts with PAPP-A increased their proliferation in a dose- and time-dependent manner. Addition of exogenous PAPP-A also increased the myotube formation and the activity of creatine kinase in C2C12 cultures. Transient overexpression of the full-length PAPP-A-(1-1547), but not truncated protease-inactive N-terminal PAPP-A-(1-920) or C-terminal PAPP-A-(1100-1547), significantly enhanced the proliferation of C2C12 myoblasts. In vitro and in situ experiments demonstrated that PAPP-A cleaves insulin-like growth factor-binding protein (IGFBP)-2, but not IGFBP-3, in the conditioned medium of C2C12 myoblasts. Overexpression of PAPP-A led to degradation of the IGFBP-2 produced by C2C12 myoblasts and increased free IGF-I concentrations without affecting total IGF-I concentrations. Addition of protease-resistant IGFBP-4 completely abolished the PAPP-A-induced proliferation of C2C12 myoblasts. Our results demonstrate that 1) PAPP-A increases the proliferation and differentiation of myoblasts, 2) the stimulatory effect of PAPP-A on myogenesis is governed by its proteolytic activity, and 3) PAPP-A promotes skeletal myogenesis by increasing the amount of free IGFs via specific degradation of IGFBP-2 produced by myoblasts.     

Mitochondrial-dependent regulation of myoblast proliferation

The aim of the present study was to determine whether mitochondrial activity could regulate myoblast proliferation. We demonstrate that an increase in mitochondrial activity of L6E9 myoblasts can be easily obtained by simply raising extracellular pyruvate concentration in the culture dish. Under this condition, L6E9 myoblasts underwent a rapid growth arrest in G1 + S phases concomitant to a marked cellular hypertrophy. No sign of myoblast fusion was evident. This was accompanied by the down-regulation of proliferating cell nuclear antigen expression and an increase in p21 expression. Mitochondrial biogenesis was also stimulated, as indicated by a twofold increase in mitochondrial content. These cells exhibited a large increase in the production of reactive oxygen species that could contribute to the observed phenotypic alterations. However, exposure of pyruvate-treated cells to antioxidants did not reverse growth arrest. Similarly, exposure of control cells to oxidants did not induce growth arrest. Our observations suggest that mitochondrial activity appears to play a central role in regulating myoblast proliferation. They also argue strongly in favor of a retrograde communication establishing a mitochondrial control of nuclear gene expression that could be modulated by mitochondrial activity.     

The HECT-domain ubiquitin ligase Huwe1 controls neural differentiation and proliferation by destabilizing the N-Myc oncoprotein

Development of the nervous system requires that timely withdrawal from the cell cycle be coupled with initiation of differentiation. Ubiquitin-mediated degradation of the N-Myc oncoprotein in neural stem/progenitor cells is thought to trigger the arrest of proliferation and begin differentiation. Here we report that the HECT-domain ubiquitin ligase Huwe1 ubiquitinates the N-Myc oncoprotein through Lys 48-mediated linkages and targets it for destruction by the proteasome. This process is physiologically implemented by embryonic stem (ES) cells differentiating along the neuronal lineage and in the mouse brain during development. Genetic and RNA interference-mediated inactivation of the Huwe1 gene impedes N-Myc degradation, prevents exit from the cell cycle by opposing the expression of Cdk inhibitors and blocks differentiation through persistent inhibition of early and late markers of neuronal differentiation. Silencing of N-myc in cells lacking Huwe1 restores neural differentiation of ES cells and rescues cell-cycle exit and differentiation of the mouse cortex, demonstrating that Huwe1 restrains proliferation and enables neuronal differentiation by mediating the degradation of N-Myc. These findings indicate that Huwe1 links destruction of N-Myc to the quiescent state that complements differentiation in the neural tissue.     

miR-22 regulates C2C12 myoblast proliferation and differentiation by targeting TGFBR1

Recently, miR-22 was found to be differentially expressed in different skeletal muscle growth period, indicated that it might have function in skeletal muscle myogenesis. In this study, we found that the expression of miR-22 was the most in skeletal muscle and was gradually up-regulated during mouse myoblast cell (C2C12 myoblast cell line) differentiation. Overexpression of miR-22 repressed C2C12 myoblast proliferation and promoted myoblast differentiation into myotubes, whereas inhibition of miR-22 showed the opposite results. During myogenesis, we predicted and verified transforming growth factor beta receptor 1 (TGFBR1), a key receptor of the TGF-β/Smad signaling pathway, was a target gene of miR-22. Then, we found miR-22 could regulate the expression of TGFBR1 and down-regulate the Smad3 signaling pathway. Knockdown of TGFBR1 by siRNA suppressed the proliferation of C2C12 cells but induced its differentiation. Conversely, overexpression of TGFBR1 significantly promoted proliferation but inhibited differentiation of the myoblast. Additionally, when C2C12 cells were treated with different concentrations of transforming growth factor beta 1 (TGF-β1), the level of miR-22 in C2C12 cells was reduced. The TGFBR1 protein level was significantly elevated in C2C12 cells treated with TGF-β1. Moreover, miR-22 was able to inhibit TGF-β1-induced TGFBR1 expression in C2C12 cells. Altogether, we demonstrated that TGF-β1 inhibited miR-22 expression in C2C12 cells and miR-22 regulated C2C12 cell myogenesis by targeting TGFBR1.