Characterization of the v-myb DNA binding domain.

The transforming protein encoded by the v-myb oncogene is a sequence-specific DNA-binding protein that is thought to be involved in the regulation of gene expression. The N-terminal region of the v-myb protein is composed of two highly conserved tandem repeat sequences of unknown function. It has been speculated that the N-terminal v-myb repeats might be crucial for DNA-binding, since N-terminal deletions destroy the DNA-binding activity of the v-myb protein. Here, we have studied the v-myb DNA-binding domain in more detail. Our results show that the N-terminal region of the v-myb protein is sufficient for specific DNA-binding. Dissection of this region suggests that both repeats are required for DNA-binding, but that both repeats play different roles in v-myb protein DNA interaction. We also show that the myb repeats of a drosophila melanogaster homolog of c-myb function as sequence-specific DNA-binding domain. Our results support the view that specific sequence-recognition, mediated by the conserved myb repeats, is a general feature of myb-related proteins.     

Subnuclear localization of proteins encoded by the oncogene v-myb and its cellular homolog c-myb.

The retroviral transforming gene v-myb encodes a 45,000-Mr nuclear transforming protein (p45v-myb). p45v-myb is a truncated and mutated version of a 75,000-Mr protein encoded by the chicken c-myb gene (p75c-myb). Like its viral counterpart, p75c-myb is located in the cell nucleus. As a first step in identifying nuclear targets involved in cellular transformation by v-myb and in c-myb function, we determined the subnuclear locations of p45v-myb and p75c-myb. Approximately 80 to 90% of the total p45v-myb and p75c-myb present in nuclei was released from nuclei at low salt concentrations, exhibited DNA-binding activity, and was attached to nucleoprotein particles when released from the nuclei after digestion with nuclease. A minor portion of approximately 10 to 20% of the total p45v-myb and p75c-myb remained tightly associated with the nuclei even in the presence of 2 M NaCl. These observations suggest that both proteins are associated with two nuclear substructures tentatively identified as the chromatin and the nuclear matrix. The function of myb proteins may therefore depend on interactions with several nuclear targets.     

Identification and characterization of the protein encoded by the human c-myb proto-oncogene.

We have identified the product of the human c-myb proto-oncogene as a 80,000-Mr protein, p80c-myb, by using polyclonal and monoclonal antibodies raised against a bacterially synthesized polypeptide from the amino terminus of the viral myb protein. p80c-myb shares at least two distinct antigenic sites with the amino terminal region of the v-myb protein. p80c-myb is found only in hematopoietic cells or in cells that contain amplified c-myb genes. Like the chicken myb proteins, p80c-myb is a nuclear DNA-binding protein that is predominantly associated with chromatin and exhibits a short half-life of approximately 1 hour.     

Analysis of the v-myb structural components important for transactivation of gene expression.

In order to define the domains of the v-myb protein that are important for transactivation of gene expression, we have studied transactivation by the v-myb gene and a set of v-myb deletion mutants using transient transfection assays in NIH 3T3 cells. Analysis of the set of v-myb deletion products demonstrated that a previously unidentified region in the carboxyl-terminal portion of the protein is required for transactivation. This region lies between amino acids 295-356 with respect to the 5' end of the v-myb gene. Switching the v-myb DNA binding domain with the DNA binding domain of the rat glucocorticoid receptor (rGR) switched the cis-element requirement for v-myb action: only reports containing glucocorticoid response elements were activated by myb-rGR fusion proteins. The carboxyl terminal region essential for transactivation by the intact v-myb gene was also necessary for transactivation by the rGR-fusion gene. Carboxyl-terminal deletion mutations that encompassed the novel transactivation region were able to block wild-type v-myb transactivation when tested in transient co-expression assays. In an unexpected sidelight to our studies, we could demonstrate that the lacZ gene present in the prokaryotic vector sequences contained a DNA element that fortuitously can act as a v-myb-dependent enhancer element, and that v-myb protein can bind to this element in vitro. The lacZ enhancer contains the myb consensus DNA binding site YAAC(G/T)G.     

Functional antagonism between members of the myb family: B-myb inhibits v-myb-induced gene activation.

The oncogene v-myb and its cellular progenitor c-myb encode nuclear, DNA binding phosphoproteins that control the expression of certain target genes in immature hematopoietic cells. Here, we report the isolation of a myb-related chicken gene, chicken B-myb. We show that expression of B-myb, unlike that of c-myb, is not restricted to hematopoietic cells, suggesting that B-myb functions in a broader spectrum of cell types than c-myb. We have identified the authentic chicken B-myb protein as a nuclear protein of approximately 110 kDa. We show that the B-myb protein specifically recognizes v-myb binding sites in vitro and that binding is mediated by an N-terminally located DNA binding domain. Although B-myb protein recognizes myb binding sites, B-myb fails to transactivate several myb-responsive gene constructs as well as the endogenous myb-responsive gene mim-1. Instead, we find that B-myb represses v-myb- and c-myb-mediated activation of the mim-1 gene, most likely by competing with other myb proteins for binding sites. Our results raise the possibility that B-myb is an inhibitory member of the myb family.     

DNA-binding activity is associated with purified myb proteins from AMV and E26 viruses and is temperature-sensitive for E26 ts mutants

Oncogene protein products from avian myeloblastosis virus, p48v-myb, and from avian leukemia virus E26, p135gag-myb-ets, are located predominantly in the nucleus of nonproducer bone marrow cell clones, as revealed by indirect immunofluorescence. Both oncogene proteins were purified by immunoaffinity chromatography using monoclonal antibodies against p19 and immunoglobulins specific for myb, which was expressed in bacteria for antibody production. The purified proteins bind to DNA in vitro. In contrast, purified p135gag-myb-ets proteins from several mutants of E26 virus, temperature-sensitive for myeloblast transformation, either lost their abilities to bind to DNA or exhibited highly thermolabile DNA-protein interactions in vitro. DNA binding of AMV and E26 oncogene proteins is inhibited by myb-specific immunoglobulins. Our results suggest that lesions in the myb oncogene affect transformation as well as DNA binding of myb proteins in vitro.     

A second c-myb protein is translated from an alternatively spliced mRNA expressed from normal and 5''-disrupted myb loci.

The major protein encoded by the c-myb oncogene in many species has been identified as an unstable, nuclear DNA-binding protein with an apparent molecular mass of 75 to 80 kilodaltons (p75c-myb). Recently, an alternatively spliced form of c-myb-encoded mRNA has been identified in murine cells containing either normal or rearranged c-myb genes. This mRNA includes a new exon, termed E6A, formed through use of cryptic splice sites located in the large intron between c-myb exons vE6 and vE7. E6A is predicted to contribute an internal 121-residue in-frame insertion into a region C terminal of the DNA-binding domain the c-myb-encoded protein. Here we report the identification of an 85-kilodalton (p85c-myb-E6A) protein as the translation product of the alternatively spliced E6A c-myb mRNA. This protein as well as p75c-myb were precipitated with anti-Myb antibodies raised against the conserved DNA-binding region of c-Myb. Proteolytic mapping studies showed that the two proteins are highly related but not identical. However, only the p85 protein reacted with an antiserum prepared against the E6A region expressed in bacteria, demonstrating that p85 but not p75 contains E6A sequences. In addition, the mobilities of both p85 and p75 were increased in myeloid tumor cell lines containing proviral integrations upstream of the 5' coding exons of v-myb, indicating that both proteins are truncated forms of c-Myb expressed from the same disrupted allele. p75c-myb and p85c-myb-E6A were indistinguishable with respect to nuclear localization and protein half-life. Furthermore, both forms of Myb were synthesized continuously throughout the cell cycle in 70Z ore-B cells. The contribution of the E6A domain to c-myb function remains to be elucidated.     

DNA-binding activity associated with the v-myb oncogene product is not sufficient for transformation.

The product of the v-myb oncogene of avian myeloblastosis virus is a nuclear protein with an associated DNA-binding activity. We demonstrated that the highly conserved amino-terminal domain of p48v-myb is required for its associated DNA-binding activity. This activity is not required for the nuclear localization of p48v-myb. Furthermore, the associated DNA-binding activity and nuclear localization of p48v-myb together are not sufficient for transformation.     

Transformation by v-myb correlates with trans-activation of gene expression.

The v-myb oncogene of avian myeloblastosis virus causes acute myelomonocytic leukemia in chickens and transforms avian myeloid cells in vitro. Its protein product p48v-myb is a nuclear, sequence-specific, DNA-binding protein which activates gene expression in transient DNA transfection studies. To investigate the relationship between transformation and trans-activation by v-myb, we constructed 15 in-frame linker insertion mutants. The 12 mutants which transformed myeloid cells also trans-activated gene expression, whereas the 3 mutants which did not transform also did not trans-activate. This implies that trans-activation is required for transformation by v-myb. One of the transformation-defective mutants localized to the cell nucleus but failed to bind DNA. The other two transformation-defective mutants localized to the cell nucleus and bound DNA but nevertheless failed to trans-activate. These latter mutants define two distinct domains of p48v-myb which control trans-activation by DNA-bound protein, one within the amino-terminal DNA-binding domain itself and one in a carboxyl-terminal domain which is not required for DNA binding.     

Transformation-defective mutant of avian myeloblastosis virus that is temperature sensitive for production of transforming protein p45v-myb.

We have characterized a mutant of avian myeloblastosis virus (strain GA907/7) that shows a reduced capacity to transform myelomonocytic cells at the nonpermissive temperature. Myeloblasts transformed by this mutant suffer a substantial decrease in the amount of the transforming protein p45v-myb when shifted from the permissive to the nonpermissive temperature. We presume that the 5- to 10-fold decrease in the amount of p45v-myb causes the loss of the transformed phenotype. The decrease is due to a reduction in the level of v-myb mRNA. Mutant GA907/7 thus provides genetic evidence that p45v-myb is the transforming protein of avian myeloblastosis virus and apparently represents an unusual defect in the production or stability of mRNA.     

env-encoded residues are not required for transformation by p48v-myb.

The v-myb oncogene of avian myeloblastosis virus induces acute myeloblastic leukemia in chickens and transforms avian myeloid cells in vitro. The protein product of this oncogene, p48v-myb, is partially encoded by the retroviral gag and env genes. We demonstrated that the env-encoded carboxyl terminus of p48v-myb is not required for transformation. Our results showed, in addition, that a coding region of c-myb which is not essential for transformation was transduced by avian myeloblastosis virus.     

Generation of altered transcripts by retroviral insertion within the c-myb gene in two murine monocytic leukemias

Two murine monocytic leukemia cell lines, WEHI-265 and WEHI-274, were found to carry a rearranged c-myb gene. The rearrangements are due to insertion of a deleted Moloney murine leukemia virus (Mo-MLV) provirus in the 5' region of the c-myb gene and thus are similar to rearrangements in the ABPL tumors (G. L. C. Shen-Ong, M. Potter, J. F. Mushinski, S. Lavu, and E. P. Reddy, Science 226:1077-1080, 1984). In each cell line, the retroviral insertion has induced high levels of two aberrant RNA species, which, as in the ABPL tumors (G. L. C. Shen-Ong, H. C. Morse, M. Potter, and J. F. Mushinski, Mol. Cell. Biol. 6:380-392, 1986), contain both viral (Mo-MLV) and cellular (myb) sequences. Both species lack the sequences encoding the amino terminus of the c-myb protein and thus could encode a protein which, like the v-myb gene products (and the predicted ABPL myb proteins), is truncated at the amino terminus. We have found that the larger (5.3 kilobase [kb]) and more abundant of the tumor-specific myb RNAs was predominantly nuclear, while the smaller species (3.9 kb) was cytoplasmic. Furthermore, our data imply that the 3.9-kb RNA was derived from the 5.3-kb RNA by an additional splice which utilized a cryptic splice acceptor site within the viral gag sequences. On the basis of subcellular distribution and predicted translational potential, we conclude that the 3.9-kb RNA is probably the mRNA which encodes a truncated myb protein. We also show that, due to different insertion points in W265 and W274, the W274 myb RNAs contained sequences from a c-myb exon upstream of the exons represented in the W265 (and ABPL) RNAs. The significance of our findings with regard to transformation by myb in these tumors is discussed.     

Oncogenic truncation of the first repeat of c-Myb decreases DNA binding in vitro and in vivo.

Oncogenic activation of c-Myb in both avian and murine systems often involves N-terminal truncation. In particular, the first of three DNA-binding repeats in c-Myb has been largely deleted during the genesis of the v-myb oncogenes of avian myeloblastosis virus and E26 avian leukemia virus. This finding suggests that the first DNA-binding repeat may have an important role in cell growth control. We demonstrate that truncation of the first DNA-binding repeat of c-Myb is sufficient for myeloid transformation in culture, but deletion of the N-terminal phosphorylation site and adjacent acidic region is not. Truncation of the first repeat decreases the ability of a Myb-VP16 fusion protein to trans activate the promoter of a Myb-inducible gene (mim-1) involved in differentiation. Moreover, truncation of the first repeat decreases the ability of the Myb protein to bind DNA both in vivo and in vitro. These results suggest that N-terminal mutants of c-Myb may transform by regulating only a subset of those genes normally regulated by c-Myb.