Expression of acetylcholine receptor alpha-subunit mRNA during differentiation of the BC3H1 muscle cell line

The accumulation of translatable acetylcholine receptor alpha-subunit mRNA was examined in the BC3H1 muscle cell line in response to serum and cell growth. Relative amounts of alpha-subunit mRNA were quantitated during differentiation by cell-free translation and immunoprecipitation with an alpha-subunit-specific monoclonal antibody. Logarithmically growing cells do not possess cell surface acetylcholine receptors; however, a significant amount of alpha-subunit mRNA is detectable in cells under these conditions. Furthermore, alpha-subunit is synthesized in growing undifferentiated cells at a rate similar to that of differentiated cultures. Following growth arrest of BC3H1 cells, surface receptors are induced to levels greater than 100-fold above that of growing cells. The relative level of translatable alpha-subunit mRNA in differentiated cells, however, is only approximately 4-fold greater than in growing cultures. Induction of alpha-subunit mRNA appears to be reversible since reinitiation of growth in quiescent differentiated BC3H1 cells results in a reduction in relative abundance of this mRNA species to levels comparable to that of undifferentiated cells and the concomitant loss of surface receptors. These results indicate that receptor expression during differentiation is regulated both post-translationally and at the level of receptor subunit mRNA accumulation.     

Membrane glycoproteins are involved in the differentiation of the BC3H1 muscle cell line

The nonfusing muscle cell line BC3H1 expresses a family of muscle-specific proteins when the fetal bovine serum (FBS) concentration is reduced from 20 to 1%. We have used a series of glycosylation inhibitors to assess the role played by glycoproteins in the initiation of differentiation in this cell line. Tunicamycin (TNM) and 2-deoxy-D-glucose, added to cells when the FBS concentration was reduced, blocked creatine phosphokinase (CPK) induction by 70-95%. These effects were dose dependent and reversible. TNM and 2-deoxy-D-glucose also reversed CPK induction in differentiated cells. Leupeptin and N-acetylglucosamine did not reverse these effects. 1-Deoxynojirimycin, 1-deoxymannojirimycin, and swainsonine have no effect on induced CPK expression, whereas castanospermine, a glucosidase I inhibitor, blocked its induction completely. As attempts to use conditioned medium from cells grown in 1 or 20% FBS have no effect on this differentiation process we conclude that high mannose structures, but not complex form glycoproteins, bound to the surface of BC3H1 cells play a role in transducing signals for differentiation and are probable mediators of cell/cell contact.     

Control by fibroblast growth factor of differentiation in the BC3H1 muscle cell line

The regulation of creatine phosphokinase (CPK) expression by polypeptide growth factors has been examined in the clonal mouse muscle BC3H1 cell line. After arrest of cell growth by exposure to low concentrations of serum, BC3H1 cells accumulate high levels of muscle-specific proteins including CPK. The induction of this enzyme is reversible in the presence of high concentrations of fetal calf serum, which cause quiescent, differentiated cells to reenter the cell cycle. Under these conditions, the rate of CPK synthesis is drastically reduced. We show in the present communication that either pituitary-derived fibroblast growth factor (FGF) or brain-derived FGF are as effective as serum in repressing the synthesis of CPK when added to quiescent, differentiated cells. The decrease in the rate of synthesis of CPK occurs within 22 h after the addition of pituitary FGF to the cells. Pituitary FGF had very little effect, if any, on the rate CPK degradation. The overall rate of protein synthesis and the pattern of synthesis of the major polypeptides made by these cells was not altered by the addition of FGF. Although pituitary FGF was mitogenic for BC3H1 cells, the rate of cell growth was not absolutely correlated with the extent of repression of CPK. Brain-derived FGF fully repressed CPK induction under conditions where it showed no significant mitogenic activity. These results show that the expression of a muscle-specific protein, CPK, can be controlled by a single defined polypeptide growth factor in fully differentiated cultures, and that initiation of cell division is not required for their regulation to take place.     

Regulation of differentiation of the BC3H1 muscle cell line through cAMP-dependent and -independent pathways

Serum mitogens, fibroblast growth factor (FGF), and type beta transforming growth factor (TGF-beta) suppress differentiation of the mouse muscle cell line BC3H1; however, the signal transduction pathways whereby these growth factors exert their effects on this system are unknown. The goal of this study was to determine whether the program for differentiation of BC3H1 cells was susceptible to negative regulation by signaling pathways involving cAMP or protein kinase C and whether these intracellular effectors participate in the mechanism by which growth factors prevent establishment of the myogenic phenotype. Exposure of BC3H1 cells to dibutyryl cAMP, 8-bromo-cAMP, or compounds that stimulate adenylate cyclase, i.e. forskolin, prostaglandin E1, and cholera toxin, prevented up-regulation of muscle-specific gene products following growth arrest in mitogen-deficient medium. Conversely, addition of cAMP to differentiated BC3H1 myocytes caused down-regulation of muscle-specific mRNAs. In contrast to the ability of cAMP to block differentiation, chronic exposure to O-tetradecanoylphorbol-13-acetate, the potent activator of protein kinase C, exhibited no apparent effects on expression of muscle-specific gene products. The proto-oncogenes c-myc and c-fos were up-regulated rapidly by cAMP in a manner similar to that observed previously by serum, FGF, and TGF-beta. However, these growth factors failed to increase intracellular cAMP levels, and they did not induce ornithine decarboxylase, which was subject to positive regulation by cAMP and O-tetradecanoyl-13-acetate. Together, these data indicate that differentiation of BC3H1 cells is subject to negative regulation through a cAMP-dependent pathway and that serum mitogens, FGF, and TGF-beta inhibit differentiation through a mechanism independent of cAMP or protein kinase C.     

Control of muscle differentiation in BC3H1 cells by fibroblast growth factor and vanadate

We have examined the control of actin isoform synthesis by pituitary-derived fibroblast growth factor and serum in BC3H1 cells, a tumor-derived nonfusing muscle cell line. Under differentiating conditions in BC3H1 cells, the synthesis of beta- and gamma-actin ceases, and the rate of alpha-actin synthesis is increased concomitant with cessation of cell growth. Addition of fetal calf serum to differentiated cells reverses the process, whereas the addition of pituitary-derived fibroblast growth factor inhibits synthesis of alpha-actin but fails to induce the synthesis of beta- and gamma-actin. Analysis of RNA from differentiated BC3H1 cells after the addition of fetal calf serum indicated that the serum-induced increase in beta- and gamma-actin synthesis reflected an increase in their mRNA levels. In contrast, the repression of alpha-actin synthesis by fetal calf serum or fibroblast growth factor appears to reflect the translation efficiency of alpha-actin mRNA. Fibroblast growth factor is a competence factor for BC3H1 cells which allows them to progress from G0 4 h into the G1 phase of the cell cycle. In order to understand the nature of the intracellular signals responsible for the effect of fibroblast growth factor, we treated cells with vanadate, a known inhibitor of tyrosine-specific protein phosphatases. Vanadate fully mimics the action of fibroblast growth on actin synthesis and creatine phosphokinase synthesis and causes BC3H1 cells to exit the G0 portion of the cell cycle, as demonstrated by the induction of the c-fos proto-oncogene following addition of serum, vanadate, or bovine pituitary-derived fibroblast growth factor to these cells. We conclude that repression of alpha-actin synthesis and induction of the synthesis of beta- and gamma-actin are under independent control and that the induction of beta- and gamma-nonmuscle actin synthesis following serum addition is independent from movement into the cell cycle, and dependent on as yet unidentified serum components. The rate of synthesis of alpha-actin can be controlled by a defined mitogenic polypeptide fibroblast growth factor, which in short term experiments primarily affects the rate of translation of alpha-actin mRNA. The repression by fibroblast growth factor is most likely due to activation of a tyrosine specific protein kinase(s).     

Regulation of creatine phosphokinase expression during differentiation of BC3H1 cells

The intracellular mechanisms involved in the regulation of creatine phosphokinase expression in the BC3H1 muscle-like cell line have been examined under conditions of enzyme induction and repression. In the presence of low serum concentrations, BC3H1 cells cease to grow and synthesize high levels of creatine phosphokinase. When differentiated BC3H1 cultures are exposed to media containing high serum concentrations, cell division is reinitiated and further induction of creatine phosphokinase is inhibited. Accumulation of creatine phosphokinase-mRNA appears to be intimately coupled to the state of growth of BC3H1 cells. Log phase cells do not contain detectable levels of translatable creatine phosphokinase-mRNA; however, following cessation of growth, creatine phosphokinase-mRNA accumulates in approximate proportion to the increase in creatine phosphokinase activity. Reinitiation of cell division in quiescent differentiated cultures results in the arrest of further accumulation of creatine phosphokinase-mRNA but does not inhibit the translation of pre-existing creatine phosphokinase-mRNA. Under conditions of enzyme repression, however, the newly synthesized creatine phosphokinase appears to be enzymatically inactive. These results indicate that the expression of the muscle phenotype in BC3H1 cells is regulated by components present in serum and that myogenic differentiation is at least partially reversible following re-entry of quiescent cells into the cell cycle.     

Actin isoform utilization during differentiation and remodeling of BC3H1 myogenic cells

Mouse BC3H1 myogenic cells and a bi-functional chemical cross linking reagent were utilized to investigate the polymerization of newly-synthesized vascular smooth muscle (α-actin) and non-muscle (β- and γ-actin) actin monomers into native F-actin filament structures during myogenesis. Two actin dimer species were identified by SDS-PAGE analysis of phenylenebismaleimide-cross linked fractions of BC3H1 myoblasts and myocytes. P-dimer was derived from the F-actin-enriched, detergent-insoluble cytoskeleton. Pulse-chase analysis revealed that D-dimer initially was associated with the cytoskeleton but then accumulated in the soluble fraction of lysed muscle cells that contained a non-filamentous or aggregated actin pool. Immunoblot analysis indicated that non-muscle and smooth muscle actins were capable of forming both types of dimer. However, induction of smooth muscle α-actin in developing myoblasts coincided with an increase in D-dimer level which may facilitate actin stress fiber assembly. Smooth muscle α-actin was rapidly utilized in differentiating myoblasts to assemble extraction-resistant F-actin filaments in the cytoskeleton whereas non-muscle β- and γ-actin filaments were more readily dissociated from the cytoskeleton by an extraction buffer containing ATP and EGTA. The data indicate that cytoarchitectural remodeling in developing BC3H1 myogenic cells is accompanied by selective actin isoform utilization that effectively segregates multiple isoactins into different sub-cellular domains and/or supramolecular entities. J. Cell. Biochem. 67:514–527, 1997. © 1997 Wiley-Liss, Inc.     

Nanoparticle-mediated intracellular lipid accumulation during C2C12 cell differentiation

In this report, we sought to elucidate whether multiwall carbon nanotubes are involved in the modulation of the proliferation and differentiation of the skeletal muscle cell line C2C12. Skeletal muscle is a major mass peripheral tissue that accounts for 40% of total body weight and 50% of energy consumption. We focused on the differentiation pathway of myoblasts after exposure to a vapor-grown carbon fiber, HTT2800, which is one of the most highly purified carbon nanotubes. This treatment leads in parallel to the expression of a typical adipose differentiation program. We found that HTT2800 stimulated intracellular lipid accumulation in C2C12 cells. We have also shown by quantified PCR analysis that the expression of adipose-related genes was markedly upregulated during HTT2800 exposure. Taken together, these results suggest that HTT2800 specifically converts the differentiation pathway of C2C12 myoblasts to that of adipoblast-like cells.     

Protein kinases predominately expressed in human ES cell lines during differentiation

Capacity of human embryonic stem cells (ESC) for unlimited proliferation and differentiation make them an attractive object in fundamental science and medicine. Little is known about the mechanisms that direct cells to particular differentiation or sustain them in an undifferentiated state. Activation of these mechanisms is determined by gene expression mediated by cascades of signal transduction. Protein kinases are essential components of signal pathways. The study of protein kinases expression in ESC and embryoid bodies facilitates a better understanding of the processes underlying the differentiation stages. We isolated cDNA libraries with fragments of catalytic domains of protein kinases expressed in human ESC and embryoid bodies (EB) of hESM01 and hESM02 cell lines. Using Northern hybridization, we revealed a high level of protein kinases MAK-V in human ESC. Expressions of MAK-V, A-RAF-1, MAPK3, IGF1R, NEK3, and NEK7 in ESC and EB in hESM01 and hESM02 cell lines were compared by the semiquantitative method RT-PCR.     

Myostatin inhibits cell proliferation and protein synthesis in C2C12 muscle cells

Myostatin mutations in mice and cattle are associated with increased muscularity, suggesting that myostatin is a negative regulator of skeletal muscle mass. To test the hypothesis that myostatin inhibits muscle cell growth, we examined the effects of recombinant myostatin in mouse skeletal muscle C2C12 cells. After verification of the expression of cDNA constructs in a cell-free system and in transfected Chinese hamster ovary cells, the human recombinant protein was expressed as the full-length (375-amino acid) myostatin in Drosophila cells (Mst375D), or the 110-amino acid carboxy-terminal protein in Escherichia coli (Mst110EC). These proteins were identified by immunoblotting and were purified. Both Mst375D and Mst110EC dose dependently inhibited cell proliferation (cell count and Formazan assay), DNA synthesis ([3H]thymidine incorporation), and protein synthesis ([1-14C]leucine incorporation) in C2C12 cells. The inhibitory effects of both proteins were greater in myotubes than in myoblasts. Neither protein had any significant effects on protein degradation or apoptosis. In conclusion, recombinant myostatin proteins inhibit cell proliferation, DNA synthesis, and protein synthesis in C2C12 muscle cells, suggesting that myostatin may control muscle mass by inhibiting muscle growth or regeneration.     

Low-density lipoprotein receptor-related protein 1 is an essential receptor for trichosanthin in 2 choriocarcinoma cell lines

Type-I ribosome-inactivating protein-trichosanthin (TCS) exhibits selective cytotoxicity toward different types of cells. It is believed that the cytotoxicity results from the inhibition of ribosomes to decrease protein synthesis, thereby indicating that there are specific mechanisms for TCS entry into target cells to reach the ribosomes. Low-density lipoprotein (LDL) receptor-related protein 1 (LRP1) is a large scavenger receptor that is responsible for the binding and endocytosis of diverse biological ligands on the cell surface. In this study, we demonstrated that 2 choriocarcinoma cell lines can significantly bind and internalize TCS. In contrast, Hela cell line displayed no obvious TCS binding and endocytosis. Furthermore LRP1 gene silencing in JAR and BeWo cell lines blocked TCS binding; TCS could also interact with LRP1.The results of our study established that LRP1 was a major receptor for phagocytosis of TCS in JAR and BeWo cell lines and might be the molecular basis of TCS abortificient and anti-choriocarcinoma activity.     

The topoisomerase 1-interacting protein BTBD1 is essential for muscle cell differentiation

DNA topoisomerase I (Topo1) contributes to vital biological functions, but its regulation is not clearly understood. The BTBD1 protein was recently cloned on the basis of its interaction with the core domain of Topo1 and is expressed particularly in skeletal muscle. To determine BTBD1 functions in this tissue, the in vitro model used was the C2C12 mouse muscle cell line, which expresses BTBD1 mainly after myotube differentiation. We studied the effects of a stably overexpressed BTBD1 protein truncated of the 108 N-terminal amino-acid residues and harbouring a C-terminal FLAG tag (Delta-BTBD1). The proliferation speed of Delta-BTBD1 C2C12 cells was significantly decreased and no myogenic differentiation was observed, although these cells maintained their capacity to enter adipocyte differentiation. These alterations could be related to Topo1 deregulation. This hypothesis is further supported by the decrease in nuclear Topo1 content in Delta-BTBTD1 proliferative C2C12 cells and the switch from the main peripheral nuclear localization of Topo1 to a mainly nuclear diffuse localization in Delta-BTBTD1 C2C12 cells. Finally, this study demonstrated that BTBD1 is essential for myogenic differentiation.     

Intermediate-conductance Ca2+-activated K+ channel is expressed in C2C12 myoblasts and is downregulated during myogenesis

We report here the expression in C₂C₁₂ myoblasts of the intermediate-conductance Ca²⁺-activated K⁺ (IK_Ca) channel. The IK_Ca current, recorded under perforated-patch configuration, had a transient time course when activated by ionomycin (0.5 µM; peak current density 26.2 ± 3.7 pA/pF; n = 10), but ionomycin (0.5 µM) + 5,6-dichloro-1-ethyl-1,3-dihydro-2H-benzimidazol-2-one (100 µM) evoked a stable outward current (28.4 ± 8.2 pA/pF; n = 11). The current was fully inhibited by charybdotoxin (200 nM), clotrimazole (2 µM), and 5-nitro-2-(3-phenylpropylamino)benzoic acid (300 µM), but not by tetraethylammonium (1 mM) or D-tubocurarine (300 µM). Congruent with the IK_Ca channel, elevation of intracellular Ca²⁺ in inside-out patches resulted in the activation of a voltage-insensitive K⁺ channel with weak inward rectification, a unitary conductance of 38 ± 6 pS (at negative voltages), and an IC₅₀ for Ca²⁺ of 530 nM. The IK_Ca channel was activated metabotropically by external application of ATP (100 µM), an intracellular Ca²⁺ mobilizer. Under current-clamp conditions, ATP application resulted in a membrane hyperpolarization of 35 mV. The IK_Ca current downregulated during myogenesis, ceasing to be detectable 4 days after the myoblasts were placed in differentiating medium. Downregulation was prevented by the myogenic suppressor agent basic FGF (bFGF). We also found that block of the IK_Ca channel by charybdotoxin did not inhibit bFGF-sustained myoblast proliferation. These observations show that in C₂C₁₂ myoblasts the IK_Ca channel expression correlates inversely with differentiation, yet it does not appear to have a role in myoblast proliferation. ATP; cell proliferation