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Query: UNIPROT:P06889 (Mol)
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The oncoprotein c-Myc must heterodimerize with Max to bind DNA and perform its oncogenic activity. The c-Myc-Max heterodimer binds DNA through a basic helix-loop-helix leucine zipper (b-HLH-zip) motif and it is proposed that leucine zipper domains could, in concert with the HLH regions, provide the specificity and stability of the b-HLH-zip motif. In this context, we have synthesized the peptides corresponding to the leucine zipper domains of Max and c-Myc with a N-terminal Cys-Gly-Gly linker and studied their dimerization behavior using reversed-phase HPLC and CD spectroscopy. The preferential formation of a fully helical parallel c-Myc-Max heterodimeric coiled-coil was observed under air-oxidation and redox conditions at neutral pH. We show that the stability and the helicity of the disulfide-linked c-Myc-Max heterostranded coiled-coil is modulated by pH, with a maximum around pH 4.5, supporting the existence of stabilizing and specific interhelical electrostatic interactions. We present a molecular model of the c-Myc-Max heterostranded coiled-coil describing potential electrostatic interactions responsible for the specificity of the interaction, the main feature being putative buried electrostatic interactions between a histidine side-chain (in the Max leucine zipper) and two glutamic acid side-chains (in the c-Myc leucine zipper) at the heterodimer interface. This model is supported by the fact that the apparent pKa (as determined by [1H]-NMR spectroscopy) of this histidine side-chain at 25 degrees C is 0.42 (+/- 0.05) pKa units higher in the folded form than in the unfolded form. This indicates that the charged histidine side-chain contributes approximately 0.57 (+/- 0.07) kcal/mol (2.38 (+/- 0.30) kJ/mol) of stabilization free energy to the c-Myc-Max heterostranded coiled-coil through favorable electrostatic interaction.
J Mol Biol 1995 Dec 01
PMID:Preferential heterodimeric parallel coiled-coil formation by synthetic Max and c-Myc leucine zippers: a description of putative electrostatic interactions responsible for the specificity of heterodimerization. 749 Jul 66

The mouse surfeit locus is a tight cluster of at least six genes (surf-1 to -6), unrelated by sequence homology, whose unique organization is conserved in vertebrates. We show that the surf-4 coding sequence is conserved between mouse and human. Primary sequence analysis predicts that the mouse surf-4 protein contains seven transmembrane domains and a double lysine endoplasmic reticulum (ER) retrieval motif on the carboxyl terminus. Translation of the mouse surf-4 cDNA in vitro resulted in the production of a 30 kDa membrane protein. Salt and detergent extraction procedures showed that the surf-4 protein associated tightly with the microsomal membranes. Proteolysis protection of 14 and 3 kDa fragments indicates that the surf-4 protein contains at least two membrane spanning domains: this is consistent with the proposed topology. Addition of the c-Myc epitope into three different regions of the surf-4 protein resulted in transfectants that expressed a myc-tagged protein. Immunofluorescence analysis of the three surf-4 myc chimeras yielded a cytoplasmic staining pattern. Consistent with the presence of the ER retrieval motif, the surf-4 myc protein was not detected at the plasma membrane. A model for the proposed structure of the surf-4 protein is presented.
Mol Membr Biol
PMID:The surf-4 gene encodes a novel 30 kDa integral membrane protein. 754 Sep 14

The decision to enter the cell division cycle is governed by the interplay between growth activators and growth inhibitors. The retinoblastoma protein (RB) is an example of a growth inhibitor whose main function appears to be the binding and inactivation of key cell cycle activators. One target of RB is a proto-oncoprotein, the c-Abl tyrosine kinase. RB binds to the ATP-binding lobe in the kinase domain and inhibits the nuclear pool of c-Abl in quiescent and G1 cells. Phosphorylation of RB at G1/S releases c-Abl, leading to the activation of this nuclear tyrosine kinase. In this report, we describe the construction of a mutant Abl, replacing the ATP-binding lobe of c-Abl with that of c-Src. The mutant protein AS2 is active as a tyrosine kinase and can phosphorylate Abl substrates, such as the C-terminal repeated domain of RNA polymerase II. AS2, however, does not bind to RB, and its activity is not inhibited by RB. As a result, the nuclear pool of AS2 is no longer cell cycle regulated. Excess AS2, but not its kinase-defective counterpart, can overcome RB-induced growth arrest in Saos-2 cells. Interestingly, wild-type c-Abl, in both its kinase-active and -inactive forms, can also overcome RB. Furthermore, overexpression of a kinase-defective c-Abl in rodent fibroblasts accelerates the transition from quiescence to S phase and cooperates with c-Myc to induce transformation. These effects, however, do not occur with the kinase-defective form of AS2. Thus, the growth-stimulating function of the kinase-defective c-Abl is dependent on the binding and the abrogation of RB function. That RB function can be abolished by the overproduction of one of its binding proteins is consistent with the hypothesis that RB induces cell cycle arrest by acting as a "molecular matchmaker" to assemble protein complexes. Exclusive engagement of RB by one of its many targets is incompatible with the biological function of this growth suppressor protein.
Mol Cell Biol 1995 Oct
PMID:Abrogation of retinoblastoma protein function by c-Abl through tyrosine kinase-dependent and -independent mechanisms. 756 6

The c-Myc protein is a transcription factor with an N-terminal transcriptional regulatory domain and C-terminal oligomerization and DNA-binding motifs. Previous studies have demonstrated that p107, a protein related to the retinoblastoma protein, binds to the c-Myc transcriptional activation domain and suppresses its activity. We sought to characterize the transforming activity and transcriptional properties of lymphoma-derived mutant MYC alleles. Alleles encoding c-Myc proteins with missense mutations in the transcriptional regulatory domain were more potent than wild-type c-Myc in transforming rodent fibroblasts. Although the mutant c-Myc proteins retained their binding to p107 in in vitro and in vivo assays, p107 failed to suppress their transcriptional activation activities. Many of the lymphoma-derived MYC alleles contain missense mutations that result in substitution for the threonine at codon 58 or affect sequences flanking this amino acid. We observed that in vivo phosphorylation of Thr-58 was absent in a lymphoma cell line with a mutant MYC allele containing a missense mutation flanking codon 58. Our in vitro studies suggest that phosphorylation of Thr-58 in wild-type c-Myc was dependent on cyclin A and required prior phosphorylation of Ser-62 by a p107-cyclin A-CDK complex. In contrast, Thr-58 remained unphosphorylated in two representative mutant c-Myc transactivation domains in vitro. Our studies suggest that missense mutations in MYC may be selected for during lymphomagenesis, because the mutant MYC proteins have altered functional interactions with p107 protein complexes and fail to be phosphorylated at Thr-58.
Mol Cell Biol 1995 Aug
PMID:A link between increased transforming activity of lymphoma-derived MYC mutant alleles, their defective regulation by p107, and altered phosphorylation of the c-Myc transactivation domain. 762 99

In vivo, the steady-state level of c-myc mRNA is mainly controlled by posttranscriptional mechanisms. Using a panel of transgenic mice in which various versions of the human c-myc proto-oncogene were under the control of major histocompatibility complex H-2Kb class I regulatory sequences, we have shown that the 5' and the 3' noncoding sequences are dispensable for obtaining a regulated expression of the transgene in adult quiescent tissues, at the start of liver regeneration, and after inhibition of protein synthesis. These results indicated that the coding sequences were sufficient to ensure a regulated c-myc expression. In the present study, we have pursued this analysis with transgenes containing one or the other of the two c-myc coding exons either alone or in association with the c-myc 3' untranslated region. We demonstrate that each of the exons contains determinants which control c-myc mRNA expression. Moreover, we show that in the liver, c-myc exon 2 sequences are able to down-regulate an otherwise stable H-2K mRNA when embedded within it and to induce its transient accumulation after cycloheximide treatment and soon after liver ablation. Finally, the use of transgenes with different coding capacities has allowed us to postulate that the primary mRNA sequence itself and not c-Myc peptides is an important component of c-myc posttranscriptional regulation.
Mol Cell Biol 1995 Aug
PMID:Both coding exons of the c-myc gene contribute to its posttranscriptional regulation in the quiescent liver and regenerating liver and after protein synthesis inhibition. 762 34

We report here unusual features of c-Myc specific to early embryonic development in Xenopus laevis, a period characterized by generalized transcriptional quiescence and rapid biphasic cell cycles. Two c-Myc protein forms, p61 and p64, are present in large amounts in the oocyte as well as during early development. In contrast, only p64 c-Myc is present in Xenopus somatic cells. p61 c-Myc is the direct translation product from both endogenous c-myc mRNAs and c-myc recombinant DNA. It is converted to the p64 c-Myc form after introduction into an egg extract, in the presence of phosphatase inhibitors. p61 and p64 belong to two distinct complexes localized in the cytoplasm of the oocyte. A 15S complex contains p64 c-Myc, and a 17.4S complex contains p61 c-Myc. Fertilization triggers the selective and total entry of only p64 c-Myc into the nucleus. This translocation occurs in a nonprogressive manner and is completed during the first cell cycles. This phenomenon results in an exceptionally high level of c-Myc in the nucleus, which returns to a somatic cell-like level only at the end of the blastulation period. During early development, when the entire embryonic genome is transcriptionally inactive, c-Myc does not exhibit a DNA binding activity with Max. Moreover, embryonic nuclei not only prevent the formation of c-Myc/Max complexes but also dissociate such preformed complexes. These peculiar aspects of c-Myc behavior suggest a function that could be linked to the rapid DNA replication cycles occurring during the early cell cycles rather than a function involving transcriptional activity.
Mol Cell Biol 1995 Sep
PMID:Selective and rapid nuclear translocation of a c-Myc-containing complex after fertilization of Xenopus laevis eggs. 765 22

The polymerization of alpha- and beta-tubulin into microtubules results in a complex network of microfibrils that have important structural and functional roles in all eukaryotic cells. In addition, microtubules can interact with a diverse family of polypeptides which are believed to directly promote the assembly of microtubules and to modulate their functional activity. We have demonstrated that the c-Myc oncoprotein interacts in vivo and in vitro with alpha-tubulin and with polymerized microtubules and have defined the binding site to the N-terminal region within the transactivation domain of c-Myc. In addition, we have shown that c-Myc colocalizes with microtubules and remains tightly bound to the microtubule network after detergent extraction of intact cells. These findings suggest a potential role for Myc-tubulin interaction in vivo.
Mol Cell Biol 1995 Sep
PMID:The N-terminal domain of c-Myc associates with alpha-tubulin and microtubules in vivo and in vitro. 765 36

A number of transcription factors have been shown to be phosphorylated by casein kinase II (CKII). We have identified CKII phosphorylation sites in c-Myc, Max, and c-Myb which are phosphorylated in the cell. Whereas little evidence to any functional significance of the CKII sites in c-Myc has been obtained, phosphorylation of its heterodimeric partner Max alters DNA binding properties. CKII phosphorylation of Ser-2 and -11 in Max resulted in enhanced DNA binding kinetics of both Max/Max homo- and Myc/Max heterodimers without altering steady state binding. Replacing these serine by alanine residues and comparing the wild type with the mutant Max proteins in transactivation assays did not reveal any significant differences. For c-Myb mutational analysis of the CKII phosphorylation sites showed altered steady state DNA binding. Replacing Ser-11/12 by alanine residues resulted in increased DNA binding compared to wt c-Myb or Myb Asp-11/12 as demonstrated by up to 10-fold differences in the dissociation constants. In transactivation assays, the Ala mutant showed consistently an increased activity both on a synthetic and on the mim-1 promoter. A potential CKII phosphorylation site in c-Fos was not phosphorylated in vitro. Analysis with peptides demonstrated that a proline residue at position +1 relative to the acceptor serine was inhibitory.
Cell Mol Biol Res 1994
PMID:Regulation of transcription factors c-Myc, Max, and c-Myb by casein kinase II. 773 24

To better understand the signaling pathways which lead to DNA synthesis in mammalian cells, we have studied the transcriptional activation of genes needed during the S phase of the cell cycle. Transcription of the gene encoding a pyrimidine biosynthetic enzyme, carbamoyl-phosphate synthase (glutamine-hydrolyzing)/aspartate carbamoyltransferase/dihydroorotase (cad), increases at the G1/S-phase boundary. We have mapped the growth-dependent response element in the hamster cad gene to the extended palindromic E-box sequence, CCACGTGG, which is centered at +65 in the 5' untranslated sequence. Mutation of the E box abolished growth-dependent transcription, and an oligonucleotide corresponding to the cad sequence at +55 to +75 (+55/+75) restored growth-dependent regulation to nonresponsive cad promoter mutants when placed down-stream of the transcription start site. The same oligonucleotide conferred less G1/S-phase induction when placed upstream of basal promoter elements. An analogous oligonucleotide containing the mutant E box had no effect in either location. Nuclear proteins bound the cad +55/+75 element in a cell cycle-dependent manner in electromobility shift assays; antibodies specific to USF and Max blocked the DNA-binding activity of different growth-regulated protein-DNA complexes. Expression of c-Myc mutants which have been shown to dominantly interfere with the function of c-Myc and Max significantly inhibited cad transcription during S phase but had no effect on transcription from another G1/S-phase-activated promoter, dhfr. These data support a model whereby E-box-binding proteins activate serum-induced transcription from the cad promoter at the G1/S-phase boundary and suggest that a Max-associated protein complex contributes to the serum response.
Mol Cell Biol 1995 May
PMID:An E-box-mediated increase in cad transcription at the G1/S-phase boundary is suppressed by inhibitory c-Myc mutants. 773 36

The c-myc oncogene c-Myc is commonly activated in cancer and transactivates gene expression by binding to CACGTG DNA sequences as a heterodimeric complex with Max. The ornithine decarboxylase (ODC), p53, prothymosin alpha and ECA39 promoters are transactivated by c-Myc, and are considered direct targets, as activation is mediated by CACGTG sequences. Interestingly, the c-Myc-responsive CACGTG sequences in the p53, prothymosin alpha, ECA39 and murine ODC genes are all downstream of the RNA CAP site, suggesting that downstream sequences are preferred c-Myc targets. Using a series of heterologous reporter constructs, we have tested the effects of position and orientation of c-Myc-responsive CACGTG sequences on c-Myc's ability to activate transcription. A single binding site conferred c-Myc-responsiveness independent of position and orientation, and over distances of 1.7 kbp. The extent of transactivation was not significantly influenced by position of the responsive elements. By contrast, the extent of transactivation was dependent upon the number of c-Myc binding sites. The results demonstrate that c-Myc activates transcription independent of position and orientation and that considerable flexibility exists in the interaction of c-Myc transactivation domains with the general transcription machinery.
Cell Mol Biol Res 1994
PMID:Position and orientation independent transactivation by c-Myc. 778 88

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