UNIPROT:P06889 - FACTA Search

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MRF4 is a member of the basic helix-loop-helix muscle regulatory factor family that also includes MyoD, myogenin, and Myf-5. Overexpression of MRF4 or the other muscle regulatory factors in fibroblasts converts the cells to differentiated muscle fibers and transcriptionally activates expression of endogenous and cotransfected muscle genes. Although these factors induce a similar phenotype, they also exhibit some distinct biological activities. For example, MyoD trans activates alpha-actin and troponin I reporter genes to very high levels, whereas MRF4 efficiently activates only alpha-actin expression. Since these proteins have a common basic helix-loop-helix domain, it is likely that portions of the proteins outside of this region impart some specificity to the activity of each muscle regulatory factor. As an initial step in determining the mechanism by which MRF4 and MyoD activate gene transcription, the transcriptional activation domain of MRF4 has been characterized. Experiments utilizing chimeric proteins containing the yeast GAL4 DNA-binding domain and portions of the MRF4 protein indicate that the MRF4 activation domain is located within amino acids 10 to 30. This amino terminus is both necessary and sufficient to elicit a transcriptional response in transfected cells. The MRF4 activation domain and the related amino-terminal MyoD activation domain are capable of substituting for one another in converting fibroblasts to a myogenic phenotype and in activating expression of an alpha-actin reporter gene, although the MRF4 and MyoD activation domains on these chimeric proteins also dictate the specificity of transcriptional activation. The different primary amino acid sequences of these regions leave open the possibility that different coregulator proteins interact with the muscle regulatory factors to elicit their correct transcriptional activity during skeletal muscle development.
Mol Cell Biol 1992 Oct
PMID:The MRF4 activation domain is required to induce muscle-specific gene expression. 132 51

Sodium butyrate reversibly inhibits muscle differentiation and blocks the expression of many muscle-specific genes in both proliferating myoblasts and differentiated myotubes. We investigated the role of the basic helix-loop-helix (bHLH) myogenic determinator proteins MyoD and myogenin in this inhibition. Our data suggest that both MyoD and myogenin are not able to function as transcriptional activators in the presence of butyrate, although both apparently retain the ability to bind DNA. Transcription of MyoD itself is extinguished in butyrate-treated myoblasts and myotubes, an effect that may be due to the inability of MyoD to autoactivate its own transcription. We present evidence that the HLH region of MyoD is essential for butyrate inhibition of MyoD. In contrast to MyoD and myogenin, butyrate does not inhibit the ubiquitous basic HLH protein E2-5 from functioning as a transcriptional activator.
Mol Cell Biol 1992 Nov
PMID:Sodium butyrate inhibits myogenesis by interfering with the transcriptional activation function of MyoD and myogenin. 132 72

A murine cardiac lambda gt11 expression library was screened with an amphipathic helix antibody, and a recombinant representing the C-terminal 194 residues of murine HSP90 (HSP84) was cloned. Both recombinant and native HSP90s were then found to rapidly convert a basic helix-loop-helix protein (MyoD1) from an inactive to an active conformation, as assayed by sequence-specific DNA binding. The conversion process involves a transient interaction between HSP90 and MyoD1 and does not result in the formation of a stable tertiary complex. Conversion does not require ATP and occurs stoichiometrically in a dose-dependent fashion. HSP90 is an abundant, ubiquitous, and highly conserved protein present in most eukaryotic cells. These results provide direct evidence that HSP90 can affect the conformational structure of a DNA-binding protein.
Mol Cell Biol 1992 Nov
PMID:Conformational activation of a basic helix-loop-helix protein (MyoD1) by the C-terminal region of murine HSP90 (HSP84). 140 81

Transforming growth factor beta (TGF-beta) is the name of a group of closely related polypeptides characterized by a multiplicity of effects, including regulation of extracellular proteolysis and turnover of the extracellular matrix. Its cellular mechanism of action is largely unknown. TGF-beta 1 is a strong and fast inducer of type 1 plasminogen activator inhibitor gene transcription. We have identified a TGF-beta 1-responsive element in the 5'-flanking region of the human type 1 plasminogen activator inhibitor gene and shown that it is functional both in its natural context and when fused to a heterologous nonresponsive promoter. Footprinting and gel retardation experiments showed that two different nuclear factors, present in extracts from both TGF-beta 1-treated and nontreated cells, bind to adjacent sequences contained in the responsive unit. A palindromic sequence binds a trans-acting factor(s) of the CCAAT-binding transcription factor-nuclear factor I family. A partially overlapping dyad symmetry interacts with a second protein that much evidence indicates to be USF. USF is a transactivator belonging to the basic helix-loop-helix family of transcription factors. Mutations which abolish the binding of either CCAAT-binding transcription factor-nuclear factor I or USF result in reduction of transcriptional activation upon exposure to TGF-beta 1, thus showing that both elements of the unit are necessary for the TGF-beta 1 response. We discuss the possible relationship of these findings to the complexity of the TGF-beta action.
Mol Cell Biol 1992 Apr
PMID:Transforming growth factor beta 1-responsive element: closely associated binding sites for USF and CCAAT-binding transcription factor-nuclear factor I in the type 1 plasminogen activator inhibitor gene. 154 30

The Drosophila pair-rule gene, hairy (h), encodes a nuclear basic helix-loop-helix (bHLH) protein that regulates embryonic segmentation and adult bristle patterning. In both cases, the h protein behaves as a transcriptional repressor. In this study, we determined the molecular nature of 12 h alleles. One mutation maps within the HLH domain, consistent with h function requiring homodimerization or heterodimerization with other HLH proteins. A second mutation lies in the basic domain, suggesting that DNA binding is required for h activity. Several mutations show that the h C terminus, in particular the WRPW domain, is also required for h activity, perhaps by interacting with other proteins to mediate transcriptional repression. We show that the h protein in Drosophila virilis closely resembles that in D. melanogaster and includes completely conserved bHLH and WRPW domains.
Mol Cell Biol 1992 Jun
PMID:Point mutations in the Drosophila hairy gene demonstrate in vivo requirements for basic, helix-loop-helix, and WRPW domains. 158 51

Expression of MRF4, a myogenic regulatory factor of the basic helix-loop-helix type, produced multiple changes in the myogenic program of the BC3H-1 cell line. BC3H-1 cells that stably expressed exogenous MRF4 were prepared and termed BR cell lines. Upon differentiation, the BR cells were found to have three muscle-specific properties (endogenous MyoD expression, myoblast fusion, and fast myosin light-chain 1 expression) that the parent BC3H-1 cells did not have. Of the four known myogenic regulatory factors (MyoD, myogenin, Myf-5, and MRF4), only MRF4 was capable of activating expression of the endogenous BC3H-1 myoD gene. In addition, the pattern of Myf-5 expression in BR cells was the opposite of that in BC3H-1 cells. Myf-5 expression was low in BR myoblasts and showed a small increase upon myotube formation, whereas Myf-5 expression was high in BC3H-1 myoblasts and decreased upon differentiation. Though the MRF4-transfected BR cells fused to form large myotubes and expressed fast myosin light-chain 1, the pattern of myosin heavy-chain isoform expression was the same in the BR and the nonfusing parent BC3H-1 cells, suggesting that factors in addition to the MyoD family members regulate myosin heavy-chain isoform expression patterns in BC3H-1 cells. In contrast to the changes produced by MRF4 expression, overexpression of Myf-5 did not alter BC3H-1 myogenesis. The results suggest that differential expression of the myogenic regulatory factors of the MyoD family may be one mechanism for generating cells with diverse myogenic phenotypes.
Mol Cell Biol 1992 Jun
PMID:Expression of MRF4, a myogenic helix-loop-helix protein, produces multiple changes in the myogenic program of BC3H-1 cells. 158 52

Members of the Myc family of proteins share a number of protein motifs that are found in regulators of gene transcription. Conserved stretches of amino acids found in the N-terminal transcriptional activation domain of c-Myc are required for cotransforming activity. Most of the Myc proteins contain the basic helix-loop-helix zipper (bHLH-Zip) DNA-binding motif which is also required for the cotransforming activity of c-Myc. L-Myc, the product of a myc family gene that is highly amplified in many human lung carcinomas, was found to cotransform primary rat embryo cells with an activated ras gene. However, L-Myc cotransforming activity was only 1 to 10% of that of c-Myc (M. J. Birrer, S. Segal, J. S. DeGreve, F. Kaye, E. A. Sausville, and J. D. Minna, Mol. Cell. Biol. 8:2668-2673, 1988). We sought to determine whether functional differences between c-Myc and L-Myc in either the N-terminal or the C-terminal domain could account for the relatively diminished L-Myc cotransforming activity. Although the N-terminal domain of L-Myc could activate transcription when fused to the yeast GAL4 DNA-binding domain, the activity was only 5% of that of a comparable c-Myc domain. We next determined that the interaction of the C-terminal bHLH-Zip region of L-Myc or c-Myc with that of a Myc partner protein, Max, was equivalent in transfected cells. A Max expression vector was found to augment the cotransforming activity of L-Myc as well as that of c-Myc. In addition, a bacterially synthesized DNA-binding domain of L-Myc, like that o c-Myc, heterodimerizes with purified Max protein to bind the core DNA sequence CACGTG. To determine the region of L-Myc responsible for its relatively diminished cotransforming activity, we constructed chimeras containing exons 2 (constituting activation domains) and 3 (constituting DNA-binding domains) of c-Myc fused to those of L-Myc. The cotransforming potencies of these chimeras were compared with those of full-length L-Myc of c-Myc in rat embryo cells. The relative cotransforming activities suggest that the potencies of the activation domains determine the cotransforming efficiencies for c-Myc and L-Myc. This correlation supports the hypothesis that the Myc proteins function in neoplastic cotransformation as transcription factors.
Mol Cell Biol 1992 Jul
PMID:Activation domains of L-Myc and c-Myc determine their transforming potencies in rat embryo cells. 162 Jan 20

Southwestern (DNA-protein) screening of a murine L-cell cDNA library by using a probe for the microE3 site in the immunoglobulin heavy-chain enhancer yielded a clone, mTFE3, which is a member of the subset of basic helix-loop-helix (BHLH) proteins that also contain a leucine zipper (ZIP). Since the individual contribution of these domains is not well understood for proteins which contain them both, mutational analyses were performed to assess the functional roles of the HLH and ZIP regions for DNA binding and multimerization. The HLH region is stringently required for DNA binding but not for multimerization. The ZIP region is not stringently required for binding or multimerization, but stabilizes both multimer formation and DNA binding. A high degree of conservation at both the amino acid and nucleotide levels between the human transcription factor TFE3 and mTFE3 suggests that mTFE3 is the murine homolog of human TFE3. By using fluorescent in situ hybridization, mTFE3 was mapped to mouse chromosome X in band A2, which is just below the centromere. We show that in addition to the immunoglobulin heavy-chain microE3 site, mTFE3 binds to transcriptional elements important for lymphoid-specific, muscle-specific, and ubiquitously expressed genes. Binding of mTFE3 to DNA induces DNA bending.
Mol Cell Biol 1992 Feb
PMID:mTFE3, an X-linked transcriptional activator containing basic helix-loop-helix and zipper domains, utilizes the zipper to stabilize both DNA binding and multimerization. 173 46

Expression of the CD4 and CD8 glycoproteins is a tightly regulated process tied to the maturation of functionally distinct classes of thymocytes. Therefore, understanding of the mechanism of expression of the genes encoding CD4 and CD8 is likely to yield important insight into regulation of the differentiated functions of T cells. Here, we report the identification of a T-cell-specific enhancer in a DNase I-hypersensitive region about 13 kb 5' of the transcription initiation site of the murine CD4 gene. Within the minimal enhancer element, at least three nuclear protein binding sites were identified by DNase I footprint analysis. One site contains the consensus motif for TCF-1 alpha/LEF-1, a recently identified HMG box transcription factor primarily expressed in pre-B and T cells. By Southwestern (DNA-protein) blotting and binding competition analyses, the protein binding to this site was found to be indistinguishable from TCF-1 alpha/LEF-1. Mutagenesis of this site resulted in loss of factor binding but had a relatively minor effect on enhancer activity. In contrast, mutations in another site, containing two consensus binding motifs for basic helix-loop-helix proteins, abolished factor binding and dramatically reduced enhancer activity. None of the protein binding sites had activity on its own, suggesting that the CD4 enhancer requires the interaction of multiple regulatory sites.
Mol Cell Biol 1991 Nov
PMID:Identification and characterization of a T-cell-specific enhancer adjacent to the murine CD4 gene. 192 61

The pancreatic beta-cell-specific expression of the insulin gene is mediated, at least in part, by the interaction of unique trans-acting beta-cell factors with a cis-acting DNA element found within the insulin enhancer (5'-GC CATCTG-3'; referred to as the insulin control element [ICE]) present in the rat insulin II gene between positions -100 and -91. This sequence element contains the consensus binding site for a group of DNA-binding transcription factors called basic helix-loop-helix proteins (B-HLH). As a consequence of the similarity of the ICE with the DNA sequence motif associated with the cis-acting elements of the B-HLH class of binding proteins (CANNTG), the ability of this class of proteins to regulate cell-type-specific expression of the insulin gene was addressed. Cotransfection experiments indicated that overexpression of Id, a negative regulator of B-HLH protein function, inhibits ICE-mediated activity. Antibody to the E12/E47 B-HLH proteins attenuated the formation, in vitro, of a previously described (J. Whelan, S. R. Cordle, E. Henderson, P. A. Weil, and R. Stein, Mol. Cell. Biol. 10:1564-1572, 1990) beta-cell-specific activator factor(s)-ICE DNA complex. Both of these B-HLH proteins (E12 and E47) bound efficiently and specifically to the ICE sequences. The role of B-HLH proteins in mediating pancreatic beta-cell-specific transcription of the insulin gene is discussed.
Mol Cell Biol 1991 Mar
PMID:Pancreatic beta-cell-type-specific transcription of the insulin gene is mediated by basic helix-loop-helix DNA-binding proteins. 199 19

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