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Query: UNIPROT:P06889 (Mol)
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Expression of the mammalian muscle regulatory factors MyoD1, myogenin, and MRF4 will convert C3H10T1/2 fibroblasts to stable muscle cell lineages. Recent studies have shown that MyoD1 and myogenin also trans-activate expression of a number of cotransfected contractile protein genes, suggesting that these muscle regulatory factors are involved in controlling terminal differentiation events. The extent and specificity of trans activation by the muscle regulatory factors, however, have not been compared directly. In this study, we found that MyoD1, myogenin, and MRF4 exhibited different trans-activation capacities. In contrast to MyoD1 and myogenin, MRF4 was inefficient in trans-activating most of the genes tested, although conversion of C3H10T1/2 fibroblasts to a myogenic lineage was observed at similar frequencies with all three factors. Addition of basic fibroblast growth factor to cells expressing exogenous muscle regulatory factors inhibited the transcriptional activation of cotransfected genes, demonstrating that MyoD1, myogenin, or MRF4 proteins alone are not sufficient to produce a terminally differentiated phenotype. In all cases, trans activation was dependent on signal transduction pathways that are regulated by fibroblast growth factor. Our observations, coupled with previous studies showing differences in the temporal expression and protein structure of MyoD1, myogenin, and MRF4, suggest that the individual members of the muscle regulatory factor family have distinct biological roles in controlling skeletal muscle development.
Mol Cell Biol 1990 Aug
PMID:Differential trans activation associated with the muscle regulatory factors MyoD1, myogenin, and MRF4. 169 19

A family of proteins has recently been identified, each member of which has the capacity to initiate muscle differentiation in many non-muscle cell types. These factors, which include MyoD1, myogenin, myf-5 and MRF4, share homologies with each other and belong to a superfamily of Myc-related proteins. Expression of these regulatory proteins results in auto-activation and cross-activation of other members of the family and in the transcriptional activation of the markers of terminal differentiation. Sequence analysis has shown a conserved basic domain in each protein that is required for binding to specific DNA sequences of the E-box type and for myogenic activation. A conserved helix-loop-helix (HLH) domain allows homo- and heterodimerization of these muscle-specific proteins with each other and with ubiquitously expressed proteins such as the E2A gene products (E12/E47). This review describes the discovery and characterization of these muscle regulatory proteins and their actions in the context of proposed models for the determination and differentiation of muscle tissue.
Mol Biol Med 1991 Apr
PMID:Molecular biology of myogenic regulatory factors. 180 61

The quail fast skeletal troponin I (TnI) gene is a member of the contractile protein gene set and is expressed exclusively in differentiated skeletal muscle cells. TnI gene transcription is controlled by an internal regulatory element (IRE), located within the first intron, that functions as a muscle-specific enhancer. Recent studies have shown that the TnI IRE may interact directly with the muscle regulatory factors MyoD, myogenin, and Myf-5 to produce a muscle-specific expression pattern, since these factors trans-activate cotransfected TnI gene constructs in C3H10T1/2 fibroblasts. In this study, we have examined the protein-IRE interactions that are responsible for transcriptionally activating the TnI gene during skeletal muscle development. We demonstrate that the helix-loop-helix muscle regulatory factors MyoD, myogenin, Myf-5, and MRF4, when complexed with the immunoglobulin enhancer-binding protein E12, interact with identical nucleotides within a muscle regulatory factor-binding site (MRF site) located in the TnI IRE. The nuclear proteins that bind to the MRF site are restricted to skeletal muscle cells, since protein extracts from HeLa, L, and C3H10T1/2 fibroblasts do not contain similar binding activities. Importantly, the TnI MRF site alone is not sufficient to elicit the full enhancer activity associated with the IRE. Instead, two additional regions (site I and site II) are required. The proteins that interact with site I and site II are expressed in both muscle and nonmuscle cell types and by themselves are ineffective in activating TnI gene expression. However, when the MRF site is positioned upstream or downstream of site I and site II, full enhancer activity is restored. We conclude that helix-loop-helix muscle regulatory factors must interact with ubiquitously expressed proteins to generate the active TnI transcription complex that is present in differentiated muscle fibers.
Mol Cell Biol 1991 Jan
PMID:Muscle-specific expression of the troponin I gene requires interactions between helix-loop-helix muscle regulatory factors and ubiquitous transcription factors. 184 22

The ski oncogene induces muscle differentiation in otherwise nonmyogenic quail embryo cells (C. Colmenares and E. Stavnezer, Cell 59:293-303, 1989). Here we report that v-ski induces both MyoD and myogenin expression, suggesting that activation of these muscle regulatory genes may be a critical step in ski-induced myogenesis. We also describe a transformation-defective mutant of v-ski (tdM5i) that fails to induce myotube formation, although it induces the expression of many muscle-specific genes, including the MyoD and myogenin genes. Therefore, if activation of MyoD and myogenin expression is a necessary component of the myogenic program triggered by ski, it is clearly insufficient to account for complete muscle differentiation.
Mol Cell Biol 1991 Feb
PMID:Transformation-defective v-ski induces MyoD and myogenin expression but not myotube formation. 184 65

Recent studies have shown that two genes regulating myogenesis (MyoD and myogenin) are coexpressed with cardiac alpha-actin during early stages of skeletal muscle development. Myogenin and MyoD are members of a family of regulatory proteins which share a helix-loop-helix (HLH) motif required for dimerization and DNA binding. Myogenin and MyoD form heterodimers with the ubiquitous HLH protein E12 which bind cis-acting DNA elements that have an E box (CANNTG) at their core. E boxes are present in the control regions of numerous muscle-specific genes, although their functional importance in regulating many of these genes has not yet been evaluated. In this report we examine the possibility that myogenin (or MyoD) directly transactivates the cardiac alpha-actin promoter. Heterodimers of myogenin and E12 (or MyoD and E12) specifically bound a restriction fragment extending from -200 to -103 relative to the start of cardiac alpha-actin transcription. Methylation interference footprints pinpointed the site of interaction to an E box immediately adjacent to a previously identified CArG box (CArG3). Site-directed mutations to the DNA-binding site revealed that either an intact E box or an intact CArG3 is required for induction of the cardiac alpha-actin promoter in myoblasts and for transactivation by myogenin in cotransfected fibroblasts. However, deletion and substitution experiments indicate that the complex E box/CArG3 element alone does not confer muscle-specific expression to a minimal promoter. These results suggest that direct and indirect pathways involving multiple cis-acting elements mediate the induction of the cardiac alpha-actin promoter by myogenin and MyoD.
Mol Cell Biol 1991 May
PMID:Heterodimers of myogenic helix-loop-helix regulatory factors and E12 bind a complex element governing myogenic induction of the avian cardiac alpha-actin promoter. 185 96

In vertebrate development, a prominent feature of several cell lineages is the coupling of cell cycle regulation with terminal differentiation. We have investigated the basis of this relationship in the skeletal muscle lineage by studying the effects of the proliferation-associated regulator, c-myc, on the differentiation of MyoD-initiated myoblasts. Transient cotransfection assays in NIH 3T3 cells using MyoD and c-myc expression vectors demonstrated c-myc suppression of MyoD-initiated differentiation. A stable cell system was also developed in which MyoD expression was constitutive, while myc levels could be elevated conditionally. Induction of this conditional c-myc suppressed myogenesis effectively, even in the presence of MyoD. c-myc suppression also prevented up-regulation of a relative of MyoD, myogenin, which is normally expressed at the onset of differentiation in all muscle cell lines examined and may be essential for differentiation. Additional experiments tested whether failure to differentiate in the presence of myc could be overcome by providing myogenin ectopically. Cotransfection of c-myc with myogenin, MyoD, or a mixture of myogenin and MyoD showed that neither myogenin alone nor myogenin plus MyoD together could bypass the c-myc block. The effects of c-myc were further dissected by showing that c-myc can inhibit differentiation independently of Id, a negative regulator of muscle differentiation. These results lead us to propose that c-myc and Id constitute independent negative regulators of muscle differentiation, while myogenin and any of the other three related myogenic factors (MyoD, Myf-5, and MRF4/herculin/Myf-6) act as positive regulators.
Mol Cell Biol 1991 May
PMID:c-myc inhibition of MyoD and myogenin-initiated myogenic differentiation. 185 Jan 5

Insight into the molecular mechanisms that control establishment of the skeletal muscle phenotype has recently been obtained through cloning of a family of muscle-specific regulatory factors that can activate myogenesis when transfected into non-muscle cells. This family of factors, which includes MyoD, myogenin, myf-5, and MRF4, can bind DNA and transactivate muscle-specific genes in collaboration with ubiquitous cellular factors. Growth factors play an antagonistic role in myogenesis by suppressing the actions of the myogenic regulatory factor family. This review will focus on the regulation and mechanism of action of this family of myogenic regulatory factors and on the central role of peptide growth factors in modulating their expression and biological activities.
Mol Cell Biochem
PMID:Molecular control of myogenesis: antagonism between growth and differentiation. 192 4

BC3H-1 mouse muscle cells in culture were employed to study the mechanisms which regulate insulin receptor gene expression during differentiation. When BC3H-1 myoblasts were plated in low serum media (1% fetal bovine serum), cell division ceased. Within 1 week cells had the morphological features of myocytes and expressed muscle specific proteins such as creatine phosphokinase and the nicotinic acetylcholine receptor. It is known that following incubation in low serum media, the steady state mRNA levels for the key muscle transcription factor, myogenin are increased. Exposure of BC3H-1 cells to a 20-base myogenin antisense oligomer blocked morphological differentiation, and resulted in nearly complete inhibition of the expression of the acetylcholine receptor but not the insulin receptor(IR). In order to study further the relationship between differentiation and IR gene expression, fibroblast growth factor (FGF), a known inhibitor of myogenic differentiation, was employed. FGF treatment inhibited the transcription of both myogenin and the acetylcholine receptor. However FGF did not inhibit the transcription of the IR. These studies indicate therefore that IR transcription increases during muscle cell differentiation, and suggest that during differentiation the control of IR gene expression differs from the control of muscle specific proteins.
Mol Endocrinol 1990 Jun
PMID:Differential effects of fibroblast growth factor on insulin receptor and muscle specific protein gene expression in BC3H-1 myocytes. 217 94

Insulin-like growth factor binding proteins (IGFBPs) comprise a family of secreted proteins that bind insulin-like growth factors-I and -II (IGF-I and -II) with high affinity and potentially modulate their biological effects. We have demonstrated previously that IGFBP-5, the most conserved of the six known IGFBPs, is expressed in muscle cells in the developing embryo and during the terminal differentiation of several myogenic cell lines. In this study we show that an IGF-I analog that binds minimally to IGFBPs potently enhances the differentiation of the stringently controlled inducible C2 myoblast (C2l) cell line and identify IGFBP-5 as the sole IGFBP secreted during C2l differentiation. We find that induction of IGFBP-5 mRNA and protein is coincident with the onset of myogenin gene expression and occurs secondary to the rapid activation of IGFBP-5 gene transcription. By transient gene transfer experiments we demonstrate that a 1004 base pair segment of the IGFBP-5 promoter is very active in directing expression of the reporter gene luciferase in C2l myoblasts. A promoter fragment containing only 156 nucleotides of 5'-flanking DNA retained more than 70% of maximal activity and mediated at least part of the differentiation-dependent rise in IGFBP-5 gene transcription. Within this active segment are several potential binding sites for muscle-enriched transcription factors. Our results show that induction of IGFBP-5 expression is an early event in the myogenic differentiation of the C2l cell line and suggest that one function of this IGFBP is to modulate IGF-induced differentiation. C2l cells are thus an excellent in vitro model for elucidating the developmental factors that control IGFBP-5 gene transcription and action in skeletal muscle.
Mol Endocrinol 1995 Jul
PMID:Rapid activation of insulin-like growth factor binding protein-5 gene transcription during myoblast differentiation. 747 73

Acidic fibroblast growth factor (FGF) and related family members regulate differentiation in organisms as diverse as Xenopus laevis and mammals. We utilized a well-characterized model of myogenic development to directly assess the importance of endogenously produced FGF in controlling differentiation. A role for endogenous FGF is suggested by the previous finding that acidic and basic FGF abundance in cultured myocytes decreases during differentiation. In this study we inhibited the endogenous production of FGF in murine Sol 8 myoblasts by using antisense RNA and observed precocious myogenic differentiation. Exogenously supplied acidic FGF rescues this phenotype. Further results suggest that the effect of FGF on myogenic differentiation is mediated in part through inhibition of myogenin expression. These results demonstrate a direct role for endogenously synthesized growth factors in regulating myogenesis and provide support for a general role for related proteins in mammalian development.
Mol Cell Biol 1994 Jun
PMID:Myogenic differentiation triggered by antisense acidic fibroblast growth factor RNA. 751 50


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