Possible involvement of a cell surface glycoprotein in the differentiation of skeletal myoblasts

From a highly myogenic permanent line of rat skel-myoblasts (L6), we have isolated two classes of single step concanavalin A-resistant mutants. The RI class is about 2-fold and RII about 5-fold more resistant than the parental cells to the lethal action of concanavalin A. In all of the mutants, both the morphological differentiation (i.e. fusion to form myotubes) and biochemical differentiation, measured by the appearance of creatine kinase and acetylcholine receptors, are absent. The biochemical lesion in the RI type of mutants is not known, but RII type of mutants is unable to catalyze transfer of mannose from GDP-mannose into a lipid-linked form. Concanavalin A binding to separated membrane proteins from RII type of mutants on polyacrylamide gels is reduced 80% compared to wild type cells. In the RI type of mutants, however, only one major band, approximately 46,000 daltons, does not bind concanavalin A to the same extent as the wild type cells. In somatic cell hybridizations, RI type of mutants complements the RII type. In the hybrids, fusion as well as creatine kinase and acetylcholine receptors reappear, although not to the same extent as in the wild type cells. The 46,000-dalton band also reappears in the complementing hybrids. Thus, this protein may play some crucial role in myogenesis.     

The role of histone chaperones in osteoblastic differentiation of C2C12 myoblasts

Cellular differentiation is a process in which the cells gain a more specialized shape, metabolism, and function. These cellular changes are accompanied by dynamic changes in gene expression programs. In most cases, DNA methylation, histone modification, and variant histones drive the epigenetic transition that reprograms the gene expression. Histone chaperones, HIRA and Asf1a, have a role for cellular differentiation by deposition of one of variant histones, H3.3, during myogenesis of murine C2C12 cells. In this study, we accessed the roles of histone chaperones and histone H3.3 in osteoblastic conversion of C2C12 myoblasts and compared their roles with those for myogenic differentiation. The unbiased analysis of the expression pattern of histone chaperones and variant histones proposed their uncommon contribution to each pathway. HIRA and Asf1a decreased to ～50% and further diminished during differentiation into osteoblasts, while they were maintained during differentiation into myotubes. HIRA, Asf1a, and H3.3 were indispensable for expression of cell type-specific genes during conversion into osteoblasts or myotubes. RNA interference analysis indicated that histone chaperones and H3.3 were required for early steps of osteoblastic differentiation. Our results suggest that histone chaperones and variant histones might be differentially required for the distinct phases of differentiation pathway.     

Recurrent heat shock impairs the proliferation and differentiation of C2C12 myoblasts

Heat-related illness and injury are becoming a growing safety concern for the farmers, construction workers, miners, firefighters, manufacturing workers, and other outdoor workforces who are exposed to heat stress in their routine lives. A primary response by a cell to an acute heat shock (HS) exposure is the induction of heat-shock proteins (HSPs), which chaperone and facilitate cellular protein folding and remodeling processes. While acute HS is well studied, the effect of repeated bouts of hyperthermia and the sustained production of HSPs in the myoblast-myotube model system of C2C12 cells are poorly characterized. In C2C12 myoblasts, we found that robust HS (43 °C, dose/time) significantly decreased the proliferation by 50% as early as on day 1 and maintained at the same level on days 2 and 3 of HS. This was accompanied by an accumulation of cells at G2 phase with reduced cell number in G1 phase indicating cell cycle arrest. FACS analysis indicates that there was no apparent change in apoptosis (markers) and cell death upon repeated HS. Immunoblot analysis and qPCR demonstrated a significant increase in the baseline expression of HSP25, 70, and 90 (among others) in cells after a single HS (43 °C) for 60 min as a typical HS response. Importantly, the repeated HS for 60 min each on days 2 and 3 maintained the elevated levels of HSPs compared to the control cells. Further, the continuous HS exposure resulted in significant inhibition of the differentiation of C2C12 myocytes to myotubes and only 1/10th of the cells underwent differentiation in HS relative to control. This was associated with significantly higher levels of HSPs and reduced expression of myogenin and Myh2 (P < 0.05), the genes involved in the differentiation process. Finally, the cell migration (scratch) assay indicated that the wound closure was significantly delayed in HS cells relative to the control cells. Overall, these results suggest that a repeated HS may perturb the active process of proliferation, motility, and differentiation processes in an in vitro murine myoblast-myotube model.     

Notch signaling imposes two distinct blocks in the differentiation of C2C12 myoblasts

Notch signal transduction regulates expression of downstream genes through the activation of the DNA-binding protein Su(H)/CBF1. In Drosophila most of Notch signaling requires Su(H); however, some Notch-dependent processes occur in the absence of Su(H) suggesting that Notch signaling does not always involve activation of this factor. Using constitutively active forms of Notch lacking CBF1-interacting sequences we identified a Notch signaling pathway that inhibits myogenic differentiation of C2C12 myoblasts in the absence of CBF1 activation. Here we show that ligand-induced Notch signaling suppresses myogenesis in C2C12 myoblasts that express a dominant negative form of CBF1, providing additional evidence for CBF1-independent Notch signal transduction. Surprisingly mutant forms of Notch deficient in CBF1 activation are unable to antagonize MyoD activity, despite the fact that they inhibit myogenesis. Moreover, Notch-induced antagonism of MyoD requires CBF1 suggesting that the CBF1-dependent pathway mediates a cell-type-specific block in the myogenic program. However, Notch signaling in the absence of CBF1 activation blocks both myogenesis and osteogenesis, indicative of a general block in cellular differentiation. Taken together our data provide evidence for two distinct Notch signaling pathways that function to block differentiation at separate steps during the process of myogenesis in C2C12 myoblasts.     

Possible involvement of protein kinase C in proliferation and differentiation of osteoblast-like cells

In cloned osteoblast-like cells, MC3T3-E1, 12-O-tetradecanoylphorbol-13-acetate (TPA), a protein kinase C activating phorbol ester, and 1-oleoyl-2-acetylglycerol (OAG), a specific activator for protein kinase C, stimulated DNA synthesis in a dose-dependent manner. Both TPA and OAG acted synergistically with insulin-like growth factor I to stimulate DNA synthesis. TPA as well as OAG suppressed the increase in alkaline phosphatase activity of MC3T3-E1 cells induced by parathyroid hormone. These results suggest that protein kinase C is involved in the process which directs osteoblast-like cells toward proliferation.     

Synergistic action of static stretching and BMP-2 stimulation in the osteoblast differentiation of C2C12 myoblasts

Static stretching is a major type of mechanical stimuli utilized during distraction osteogenesis (DO), a general surgical method for the lengthening of bone. The molecular signals that drive the regenerative process in DO include a variety of cytokines. Among these, bone morphogenic protein (BMP, -2 and -4) has been reported to exhibit strongly enhanced expression following the application of mechanical strain during the distraction phase. We hypothesize that mechanical stretching enhances osteoblast differentiation in DO by means of interaction with BMP-2 induced cytokine stimulation. C2C12 pluripotential myoblasts were exposed to stretching load and the resulting cell proliferation and osteoblast differentiation were then examined. The application of static stretching force resulted in significant cell proliferation at day 3, although with variable intensity according to the magnitude of stretching. A combined treatment of stretching load with BMP-2 stimulation significantly increased alkaline phosphatase (ALP) activity and up-regulated the gene expression of osteogenic markers (ALP, type I collagen, osteopontin, osteocalcin, cbfa1, osterix and dlx5). Results obtained with the combined treatment yielded more activity than just the BMP-2 treatment or stretching alone. These results reveal that specific levels of static stretching force increase cell proliferation and effectively stimulate the osteoblast differentiation of C2C12 cells in conjunction with BMP-2 stimulation, thus indicating a synergistic interaction between mechanical strain and cytokine signaling.     

Mirk/Dyrk1B mediates survival during the differentiation of C2C12 myoblasts

The kinase Mirk/dyrk1B is essential for the differentiation of C2C12 myoblasts. Mirk reinforces the G0/G1 arrest state in which differentiation occurs by directly phosphorylating and stabilizing p27(Kip1) and destabilizing cyclin D1. We now demonstrate that Mirk is anti-apoptotic in myoblasts. Knockdown of endogenous Mirk by RNA interference activated caspase 3 and decreased myoblast survival by 75%, whereas transient overexpression of Mirk increased cell survival. Mirk exerts its anti-apoptotic effects during muscle differentiation at least in part through effects on the cell cycle inhibitor and pro-survival molecule p21(Cip1). Overexpression and RNA interference experiments demonstrated that Mirk phosphorylates p21 within its nuclear localization domain at Ser-153 causing a portion of the typically nuclear p21 to localize in the cytoplasm. Phosphomimetic GFP-p21-S153D was pancellular in both cycling C2C12 myoblasts and NIH3T3 cells. Endogenous Mirk in myotubes and overexpressed Mirk in NIH3T3 cells were able to cause the pancellular localization of wild-type GFP-p21 but not the nonphosphorylatable mutant GFP-p21-S153A. Translocation to the cytoplasm enables p21 to block apoptosis through inhibitory interaction with pro-apoptotic molecules. Phosphomimetic p21-S153D was more effective than wild-type p21 in blocking the activation of caspase 3. Transient expression of p21-S153D also increased myoblast viability in colony forming assays, whereas the p21-S153A mutant had no effect. This Mirk-dependent change in p21 intracellular localization is a natural part of myoblast differentiation. Endogenous p21 localized exclusively to the nuclei of proliferating myoblasts but was also found in the cytoplasm of post-mitotic multinucleated myotubes and adult human skeletal myofibers.     

BMP10 positively regulates myogenic differentiation in C2C12 myoblasts via the Smad 1/5/8 signaling pathway

Molecular and Cellular Biochemistry - BMP10 plays an essential role in regulating cardiac growth, chamber maturation, and maintaining normal expressions of several key cardiogenic factors; however,...     

Stretch activation of GTP-binding proteins in C2C12 myoblasts

Mechanical stimulation has been proposed as a fundamental determinant of muscle physiology. The mechanotransduction of strain and strain rate in C2C12 myoblasts were investigated utilizing a radiolabeled GTP analogue to detect stretch-induced GTP-binding protein activation. Cyclic uniaxial strains of 10% and 20% at a strain rate of 20% s(-1) rapidly (within 1 min) activated a 25-kDa GTPase (183 +/- 17% and 186 +/- 19%, respectively), while 2% strain failed to elicit a response (109 +/- 11%) relative to controls. One, five, and sixty cycles of 10% strain elicited 187 +/- 20%, 183 +/- 17%, and 276 +/- 38% increases in activation. A single 10% stretch at 20% s(-1), but not 0.3% s(-1), resulted in activation. Insulin activated the same 25-kDa band in a dose-dependent manner. Western blot analysis revealed a panel of GTP-binding proteins in C2C12 myoblasts, and tentatively identified the 25-kDa GTPase as rab5. In separate experiments, a 40-kDa protein tentatively identified as Galpha(i) was activated (240 +/- 16%) by 10% strain at 1 Hz for 15 min. These results demonstrate the rapid activation of GTP-binding proteins by mechanical strain in myoblasts in both a strain magnitude- and strain rate-dependent manner.     

Possible involvement of microfilaments in protein kinase C translocation

We investigated the role of microfilaments in stimulus-induced translocation of protein kinase C (PKC) in polymorphonuclear leukocytes (PMNs) from C57BL/6 mice. Cytochalasin B and dihydrocytochalasin B almost completely inhibited PKC translocation induced by either TPA or Ca2+ ionophore after pretreatment of cells for 30 min. In addition, ML-9, a potent inhibitor of Ca2+/calmodulin-dependent myosin light chain kinase which regulate microfilament contraction, and a calmodulin antagonist W-7, also inhibited PKC translocation. These findings suggest the possibility that microfilaments are involved in the translocation of PKC.     

Expression of bone morphogenetic protein-2 via adenoviral vector in C2C12 myoblasts induces differentiation into the osteoblast lineage.

To examine the effectiveness of a gene transfer of bone morphogenetic protein (BMP)-2 into C2C12 myoblasts, we constructed a human BMP-2-expressing replication-deficient adenoviral vector, AxCAOBMP-2. C2C12 cells were infected in vitro with either this viral vector or an Escherichia coli LacZ gene-expressing control adenovirus vector. An efficient gene transfer to the C2C12 cells was confirmed with the LacZ gene-expressing vector by X-gal staining. Abundant BMP-2 expression in C2C12 cells infected with this viral vector was confirmed by immunofluorescence and Western blot analysis. C2C12 cells transferred with the BMP-2 gene by this vector produced alkaline phosphatase in the cells and also produced and secreted osteocalcin in the culture medium, demonstrating that a gene transfer of BMP-2 into C2C12 cells in vitro could convert these cells from myoblast to osteoblast lineage.     

Overexpression of Kelch domain containing-2 (mKlhdc2) inhibits differentiation and directed migration of C2C12 myoblasts

Targeted migration of muscle precursor cells to the anlagen of limb muscles is a complex process, which is only partially understood. We have used Lbx1 mutant mice, which are unable to establish correct migration paths of muscle precursor cells into the limbs to identify new genes involved in the accurate placement of myogenic cells in developing muscles. We found that mKlhdc2 (Kelch domain containing-2), a novel member of the family of Kelch domain containing proteins, is significantly downregulated in Lbx1 homozygous mutant embryos. Functional characterization of mKlhdc2 by targeted overexpression in 10T1/2 fibroblasts and C2C12 muscle cells rendered these cells unable to respond to chemoattractants such as HGF. Furthermore, C2C12 myoblasts overexpressing mKlhdc2 display altered cellular morphology and are unable to differentiate into mature myotubes. Our results suggest that a tightly controlled expression of mKlhdc2 is essential for a faithful execution of the myogenic differentiation and migration program.     

The effect of protease inhibitors, leupeptin and E64d, on differentiation of C2C12 myoblasts in tissue culture.

Intracellular calcium levels play an important role in myofibril disintegration and regeneration of muscle fibers. Earlier studies have shown that the calcium activated protease, calpain, is involved in the removal of Z-discs from myofibrils of striated muscle and the tripeptide-aldehyde, leupeptin, which is an inhibitor of calpain, inhibits this activity. In the present communication, we demonstrate that leupeptin and another calpain inhibitor, E64d, inhibit the fusion of mouse skeletal muscle C2C12 myoblasts to form multinucleated myotubes in tissue culture.