The product of the retroviral transforming gene v-myb is a truncated version of the protein encoded by the cellular oncogene c-myb

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.

Expression in Escherichia coli of two mutated genes encoding the cholera toxin B subunit

To allow subsequent genetically mediated fusion of foreign antigens to cholera toxin B subunit (CTB), two mutated CTB encoding genes (ctxB) were constructed and overexpressed in Escherichia coli. The signal peptide coding sequence was deleted and restriction sites were created at both ends of the modified sequence. Both synthesized CTBs contain additional amino acid(s) at the N terminus (one and three). They were purified as insoluble products and refolded into the natural pentameric CTB structure by a denaturation-renaturation cycle. After renaturation, both recombinant proteins recovered CTB antigenicity and the ability to bind to GM1 gangliosides, as shown by in vitro analysis. Preliminary data indicated that both properties were unaltered by fusion of a foreign peptide to the mutated CTBs.

Chromosomal reallocation of the chicken c-myb locus and organization of 3'-proximal coding exons

In the course of our studies concerning the tissue-specific expression of the c-myb proto-oncogene, we have established the nucleotide sequence of the chicken c-myb 3'-proximal coding exons. In situ hybridization performed with different genomic DNA probes corresponding to nearly all the c-myb gene allowed us to localize the corresponding locus on the large acrocentric chromosome 3 in chicken. Our sequencing data also indicate that the 3'-proximal noncoding sequences represented in c-myb mRNA species are derived from non-contiguous exons.

Myb DNA binding inhibited by phosphorylation at a site deleted during oncogenic activation

The c-Myb nuclear oncoprotein is phosphorylated in vitro and in vivo at an N-terminal site near its DNA-binding domain by casein kinase II (CK-II) or a CK-II-like activity. This in vitro phosphorylation reversibly inhibits the sequence-specific binding of c-Myb to DNA. The site of this phosphorylation is deleted in nearly all oncogenically activated Myb proteins, resulting in DNA-binding that is independent of CK-II. Because CK-II activity is modulated by growth factors, loss of the site could uncouple c-Myb from its normal physiological regulator.

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.

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.

BAS1 has a Myb motif and activates HIS4 transcription only in combination with BAS2

The BAS1 and BAS2 proteins are both required for activation of GCN4-independent (basal) HIS4 transcription in yeast. BAS1 has an NH2-terminal region similar to those of the myb proto-oncogene family. BAS1 and BAS2, which contains a homeo box, bound to adjacent sites on the HIS4 promoter. The joint requirement of BAS1 and BAS2 for activation is probably not due to cooperative binding or the transcriptional control of one of the genes by the other. Although BAS1 and BAS2 were both required for activation of HIS4 transcription, BAS1 was not required for BAS2-dependent expression of the secreted acid phosphatases. The transcriptional activators of HIS4 have DNA binding domains that are conserved in evolution (BAS1 = Myb, BAS2 = homeo box, GCN4 = Jun). Their interactions, therefore, may be relevant to the control of gene expression in more complex systems.

Activation of transcription by v-myb: evidence for two different mechanisms

The retroviral oncogene v-myb encodes a nuclear, sequence-specific DNA-binding protein. To investigate the possibility that v-myb encodes a transcriptional regulator, we used a transient cotransfection assay to explore the potential of v-myb to influence the expression of other genes. We found that expression of a chicken lysozyme promoter/CAT gene construct was activated by v-myb in the presence of myb-specific binding sites. Action was not observed with a truncated v-myb protein lacking its DNA-binding domain. We also observed that expression of a hybrid human HSP70 promoter/CAT gene, lacking myb-specific binding sites, was activated by v-myb. However, in this case, the truncated v-myb protein, which lacked its DNA-binding domain, also activated HSP70/CAT expression, indicating that trans-activation of this gene construct was independent of the sequence-specific DNA-binding activity of the v-myb protein. These observations suggest that v-myb encodes a trans-activator and that activation of gene expression occurs by two different mechanisms, one of which involves specific binding of v-myb protein to the regulated gene.

Delineation of three functional domains of the transcriptional activator encoded by the c-myb protooncogene

The c-myb protooncogene encodes a sequence-specific DNA-binding protein (c-Myb) that induces transcriptional activation or repression. We have identified three functional domains of the mouse c-Myb protein that are responsible for DNA binding, transcriptional activation, and negative regulation, respectively. In addition to the DNA-binding domain, which is located near the N terminus, an adjacent region (the transcriptional activation domain) containing about 80 amino acids was found to be essential for transcriptional activation. Deletion of a region spanning about 175 amino acids of the C-proximal portion increased transcriptional activation markedly, revealing that this domain normally represses activation. Differences between the transcriptional activation and repression functions of c-Myb and v-Myb are discussed in the light of these functional domains. Our results suggest that transcriptional activation may be involved in transformation by myb gene products.

Transcriptional activation by the v-myb oncogene and its cellular progenitor, c-myb

The v-myb oncogene, like its cellular progenitor c-myb, encodes a short-lived nuclear protein involved in processes affecting growth and differentiation in a number of cell types. Fusion proteins, in which v-myb sequences are linked to the DNA binding domain of the yeast transcriptional activator GAL4, can activate transcription from a reporter gene linked in cis to a GAL4 binding site. The domain of v-myb responsible for transcriptional activation is located between residues 204 and 254, and is both necessary and sufficient for activation. Intact v-myb and c-myb proteins can also activate transcription, via a myb binding site linked in cis to a reporter gene. A v-myb protein bearing a deletion in the activator domain is no longer capable of stimulating transcription.

Structural organization of upstream exons and distribution of transcription start sites in the chicken c-myb gene

We mapped and sequenced three upstream exons of the chicken c-myb gene and the regions flanking the first coding exon. We found multiple potential binding sites for transcription factors in the 5'-noncoding region, a T-rich stretch of 78 base pairs (bp) (68% T) in the first intron, and four fairly long open reading frames in the antisense direction of the first coding exon and its flanking regions. Three major transcription start sites, contained within a single 11-bp region, were identified by S1 nuclease analysis and primer extension. A sequence comparison of the avian and murine c-myb genes revealed a highly conserved sequence of 124 bp in the 5'-noncoding region. Its location between the putative transcription factor binding sites and the major transcription start sites suggests that it may play an important regulatory role in c-myb expression.

Structural organization of upstream exons and distribution of transcription start sites in the chicken c-myb gene

We mapped and sequenced three upstream exons of the chicken c-myb gene and the regions flanking the first coding exon. We found multiple potential binding sites for transcription factors in the 5'-noncoding region, a T-rich stretch of 78 base pairs (bp) (68% T) in the first intron, and four fairly long open reading frames in the antisense direction of the first coding exon and its flanking regions. Three major transcription start sites, contained within a single 11-bp region, were identified by S1 nuclease analysis and primer extension. A sequence comparison of the avian and murine c-myb genes revealed a highly conserved sequence of 124 bp in the 5'-noncoding region. Its location between the putative transcription factor binding sites and the major transcription start sites suggests that it may play an important regulatory role in c-myb expression.

Isolation of human cDNA clones of myb-related genes, A-myb and B-myb

cDNA clones of the myb-related genes A-myb and B-myb were obtained by screening human cDNA libraries. The predicted open reading frame of B-myb could encode a protein of 700 amino acid residues. Although the C-terminal end has not been cloned yet, an almost entire coding region of A-myb, which is 745 amino acid long, was determined. The A-myb and B-myb proteins are highly homologous with the myb protein in three regions. Domain I, which is 161 amino acid long, is well conserved in the myb gene family. The homology between human-myb and A-myb in domain I is 90% at the amino acid level. Domain II, which is about 85 amino acid long, is less well conserved. Although it is a short stretch, domain III is found in the C-terminal region. The mRNAs of A-myb and B-myb were 5.0 and 2.6 kb, respectively. The mRNA expression pattern of the myb gene family in various tumors is presented.

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.

Viral myb oncogene encodes a sequence-specific DNA-binding activity

The retroviral oncogene v-myb and its cellular progenitor c-myb encode nuclear DNA-binding proteins. Myb genes have been identified in a broad range of species, including vertebrates, the fruit fly Drosophila melanogaster and the plant Zea mays. The localization of the DNA-binding domain of the v-MYB protein to the highly conserved amino-terminal region suggests that the MYB/DNA interaction is important for MYB function. We show here that v-MYB specifically recognizes the nucleotide sequence pyAACG/TG. So like other nuclear transforming proteins, v-MYB seems to be a member of the class of sequence-specific DNA-binding factors presumably involved in gene regulation.

c-myc and c-myb protein degradation: effect of metabolic inhibitors and heat shock

The proteins encoded by both viral and cellular forms of the c-myc oncogene have been previously demonstrated to have exceptionally short in vivo half-lives. In this paper we report a comparative study on the parameters affecting turnover of nuclear oncoproteins c-myc, c-myb, and the rapidly metabolized cytoplasmic enzyme ornithine decarboxylase. The degradation of all three proteins required metabolic energy, did not result in production of cleavage intermediates, and did not involve lysosomes or ubiquitin. A five- to eightfold increase in the half-life of c-myc proteins, and a twofold increase in the half-life of c-myb proteins was detected after heat-shock treatment at 46 degrees C. In contrast, heat shock had no effect on the turnover of ornithine decarboxylase. Heat shock also had the effect of increasing the rate of c-myc protein synthesis twofold, whereas c-myb protein synthesis was decreased nearly fourfold. The increased stability and synthesis of c-myc proteins led to an overall increase in the total level of c-myc proteins in response to heat-shock treatment. Furthermore, treatments which reduced c-myc and c-myb protein turnover, such as heat shock and exposure to inhibitors of metabolic energy production, resulted in reduced detergent solubility of both proteins. The recovery from heat shock, as measured by increased turnover and solubility, was energy dependent and considerably more rapid in thermotolerant cells.

Retroviral activation of a novel gene encoding a zinc finger protein in IL-3-dependent myeloid leukemia cell lines

Normal hematopoietic stem cells proliferate and differentiate in the presence of growth factors such as interleukin-3 (IL-3). Transformation can alter their growth factor requirements, the ability of the cells to differentiate, or both. To identify genes that are capable of transforming hematopoietic cells, IL-3-dependent cell lines, isolated from retrovirus induced myeloid leukemias, were examined for viral insertions in proto-oncogenes and in common sites of viral integration. Five of 37 cell lines contained proviruses in a common viral integration site termed the ecotropic virus integration 1 site (Evi-1). The integrations were correlated with the activation of transcription from the locus. Sequencing of cDNA clones and genomic clones demonstrated that the integrations had occurred near or in 5' noncoding exons of a novel gene. The sequence of the cDNA clones predicts that the gene product is a 120 kd protein that contains two domains with seven and three repeats of a DNA binding consensus sequence (zinc finger) initially described in the Xenopus transcription factor III A (TFIIIA). This represents the first demonstration of the retroviral activation of a gene encoding a zinc finger protein and the first implication for a member of this gene family in the transformation of hematopoietic cells.

Determination of the molecular weight of DNA-bound protein(s) responsible for gel electrophoretic mobility shift of linear DNA fragments examplified with purified viral myb protein

A protein-DNA complex has less gel electrophoretic mobility than the free DNA fragment. One parameter for the degree of retardation of a linear DNA fragment in a protein-DNA complex is the molecular weight of the bound protein(s). The quotient of the migration distances of free DNA (m) and protein-DNA complex (m') is a function of the molecular weight (MW) of the bound protein(s). Based on the evaluation of the lac repressor induced mobility shift of a 203 bp DNA fragment containing the lac operator in a 5% non-denaturating polyacrylamide gel a direct proportionality could be shown between (m/m'-1) and MW with the proportionality factor K = 215 kDa. The factor K depends on the acrylamide concentration in the gel, getting lower values with increasing acrylamide concentrations. A calculation is given to determine the molecular weight of DNA-binding factors responsible for the decreased electrophoretic mobility of a linear DNA fragment. As an example this calculation was used in order to analyse DNA-binding of the isolated viral myb protein. It could be demonstrated that the viral myb protein binds to DNA as a monomer and as a dimer.

Structural and functional domains of the myb oncogene: requirements for nuclear transport, myeloid transformation, and colony formation

The v-myb oncogene of avian myeloblastosis virus causes acute myelomonocytic leukemia in vivo and transforms only myeloid cells in vitro. Its product, p48v-myb, is a nuclear protein of unknown function. To determine structure-function relationships for this protein, we constructed a series of deletion mutants of v-myb, expressed them in retroviral vectors, and studied their biochemical and biological properties. We used these mutants to identify two separate domains of p48v-myb which had distinct roles in its accumulation in the cell nucleus. We showed that the viral sequences which normally encode both termini of p48v-myb were dispensible for transformation. In contrast, both copies of the highly conserved v-myb amino-terminal repeat were required for transformation. We also identified a carboxyl-terminal domain of p48v-myb which was required for the growth of v-myb-transformed myeloblasts in soft agar but not for morphological transformation.

c-myc and c-myb protein degradation: effect of metabolic inhibitors and heat shock

The proteins encoded by both viral and cellular forms of the c-myc oncogene have been previously demonstrated to have exceptionally short in vivo half-lives. In this paper we report a comparative study on the parameters affecting turnover of nuclear oncoproteins c-myc, c-myb, and the rapidly metabolized cytoplasmic enzyme ornithine decarboxylase. The degradation of all three proteins required metabolic energy, did not result in production of cleavage intermediates, and did not involve lysosomes or ubiquitin. A five- to eightfold increase in the half-life of c-myc proteins, and a twofold increase in the half-life of c-myb proteins was detected after heat-shock treatment at 46 degrees C. In contrast, heat shock had no effect on the turnover of ornithine decarboxylase. Heat shock also had the effect of increasing the rate of c-myc protein synthesis twofold, whereas c-myb protein synthesis was decreased nearly fourfold. The increased stability and synthesis of c-myc proteins led to an overall increase in the total level of c-myc proteins in response to heat-shock treatment. Furthermore, treatments which reduced c-myc and c-myb protein turnover, such as heat shock and exposure to inhibitors of metabolic energy production, resulted in reduced detergent solubility of both proteins. The recovery from heat shock, as measured by increased turnover and solubility, was energy dependent and considerably more rapid in thermotolerant cells.

Organization of 5'-proximal c-myb exons in chicken DNA. Implications for c-myb tissue-specific transcription

The organization of 5'-proximal c-myb exons in chicken DNA has been established by restriction enzyme mapping and nucleotide sequencing. Hybridization studies performed with cDNA probes revealed that yolk sac and thymic c-myb RNAs differ in their 5'-termini. A comparison of the genomic c-myb sequence with that of cDNAs isolated from normal thymic and lymphoma avian cells suggests that different promoter regions are used to initiate c-myb transcription in hematopoietic cells of different origins.

Constitutive expression of a c-myb cDNA blocks Friend murine erythroleukemia cell differentiation

A full-length human c-myb cDNA clone has been isolated from a CCRF-CEM leukemia cell cDNA library. The plasmid vector contains simian virus 40-derived promotor, splice, and polyadenylation sequences as well as a transcription unit for a dihydrofolate reductase cDNA. We have introduced this construct into Friend erythroleukemia (F-MEL) cells and have isolated a number of clones which contain intact and transcriptionally active human c-myb sequences. F-MEL clones expressing the highest levels of the human c-myb mRNA differentiate poorly in response to dimethyl sulfoxide. Two clones which initially expressed low levels of human c-myb transcripts and which differentiated normally were subsequently inhibited in their ability to differentiate when grown in successively higher concentrations of methotrexate, due to amplification and enhanced expression of plasmid sequences. The inhibitory effect on F-MEL differentiation appeared to be independent of the early decline in c-myc transcripts which were normally regulated in all cases examined. Our results indicate that constitutive expression of a nontruncated human c-myb cDNA can exert profound effects on erythroid differentiation and argue for a causal role of c-myb in the F-MEL differentiation process.

Rapid induction of B-cell lymphomas: insertional activation of c-myb by avian leukosis virus

EU-8 is a recombinant avian leukosis virus (ALV) constructed in vitro, which carries long terminal repeats and gag and pol genes from ring-necked pheasant virus and the env gene from UR2AV. Unlike either parent virus, when injected into 10-day-old chicken embryos, EU-8 induces a high incidence of clonally arising B-cell lymphomas within an unusually short latent period, often causing death within 5 to 7 weeks after infection. These tumors differ from the classic lymphoid leukosis induced by ALV in several respects, both biologically and at the molecular level. Most notably, in all of the EU-8-induced tumors examined, the provirus was integrated in the c-myb locus, and in no tumors were c-myc integrations found. Most of the proviral integrations were downstream of the initiation codon of c-myb and thus presumably resulted in some truncation of the c-myb gene product, although not to the same extent as has been found in other cases of c-myb activation. In addition, several of the proviruses were integrated well upstream of the c-myb coding region. This is the first report of ALV interaction with the c-myb proto-oncogene and the first report of c-myb activation resulting in tumors of lymphoid rather than myeloid origin, suggesting that the target cell specificity of transformation by the myb gene is not as restricted as previously believed.

Solid-phase synthesis of a nonadecapeptide coded for by the v-myb oncogene

A nonadecapeptide comprising a predicted B-cell determinant from the v-myb oncoprotein was synthesized by Merrifield's solid-phase method. Hydrogen chloride in dichloromethane was used for protective t-butyloxycarbonyl group removal; the deprotection was monitored using a new qualitative deprotection test. The nonadecapeptide coupled to a carrier elicited a high titre of protein-reactive antipeptide antibodies.

Constitutive expression of a c-myb cDNA blocks Friend murine erythroleukemia cell differentiation

A full-length human c-myb cDNA clone has been isolated from a CCRF-CEM leukemia cell cDNA library. The plasmid vector contains simian virus 40-derived promotor, splice, and polyadenylation sequences as well as a transcription unit for a dihydrofolate reductase cDNA. We have introduced this construct into Friend erythroleukemia (F-MEL) cells and have isolated a number of clones which contain intact and transcriptionally active human c-myb sequences. F-MEL clones expressing the highest levels of the human c-myb mRNA differentiate poorly in response to dimethyl sulfoxide. Two clones which initially expressed low levels of human c-myb transcripts and which differentiated normally were subsequently inhibited in their ability to differentiate when grown in successively higher concentrations of methotrexate, due to amplification and enhanced expression of plasmid sequences. The inhibitory effect on F-MEL differentiation appeared to be independent of the early decline in c-myc transcripts which were normally regulated in all cases examined. Our results indicate that constitutive expression of a nontruncated human c-myb cDNA can exert profound effects on erythroid differentiation and argue for a causal role of c-myb in the F-MEL differentiation process.

Requirements for immortalization of primary mouse embryo fibroblasts probed with mutants bearing deletions in the 3' end of SV40 gene A

The influence of specific contiguous stretches of amino acids predominantly in the carboxy terminal third of the SV40 large T antigen on the immortalization of cells in culture was investigated. Mutants that bear either small in-phase or frameshift deletions in the large T antigen coding sequence were transfected into primary mouse embryo fibroblasts of C57Bl/6 origin (B6/MEF). The frequency of immortalization was determined as the number of colonies that developed from cells escaping senescence. The results indicated that the terminal 81 amino acids of large T antigen are not needed for efficient immortalization or tumorigenicity. In contrast removal of as few as three amino acids encoded in the vicinity of the Dde-1 site at 0.234 map units (m.u.) severely restricted immortalization, suggesting that this region of the coding sequence either structurally or functionally is essential to at least one parameter of the transformed cell phenotype. The T antigen produced by dlA2433 which bears a deletion of nine nucleotides at 0.234 m.u. fails to associate stably with the cellular protein p53. The results showed that the addition of long stretches of amino acids (96 or 97 residues) from the open reading frame at the 3' end of the early region inactivated immortalizing functions, although the addition of as many as 18 amino acids from other reading frames was not detrimental. The evidence presented also confirmed that wild-type levels of ATPase activity are not necessary for immortalization or tumorigenicity of B6/MEF. Finally, we show that one of the mutants that immortalized primary cells did not produce dense foci on a cell monolayer. This last result indicated that independent functions are required for these two parameters of the transformed cell phenotype.

Chapter 12 Compound Biopolymers and Biooligomers

This chapter is devoted to the separation of simple saccharides. In this chapter, the rapid chromatographic separation of natural oligomeric or polymeric compounds containing important molecular moieties of a different type are discussed, such as nucleoprotein complexes, glycolipids, glycopeptides and glycoside oligomeric derivatives. In addition, separations of several natural complex substances that are not well known are discussed. This chapter concludes with a brief discussion on the separation techniques used for the miscellaneous polymeric and oligomeric substances.

Subnuclear associations of the v-myb oncogene product and actin are dependent on ionic strength during nuclear isolation

The method used to isolate nuclei has a direct effect on the subnuclear association of the v-myb product, p48v-myb, and nuclear actin. Analysis of nuclei subjected to various isolation procedures showed that disruption of native nuclear structure during hypotonic treatment resulted in dissociation of p48v-myb from the nuclear matrix.

v-myb does not prevent the expression of c-myb in avian erythroblasts

The v-myb oncogene of avian myeloblastosis virus transforms myeloid cells exclusively, both in vivo and in vitro. The c-myb proto-oncogene from which v-myb arose is expressed at relatively high levels in immature hematopoietic cells of the lymphoid, erythroid, and myeloid lineages but not in myeloblasts transformed by v-myb. This finding suggested that the nuclear v-myb gene product p48v-myb might act directly to inhibit the normal expression of the c-myb gene. I have therefore used a selectable avian retroviral vector to express p48v-myb in avian erythroblasts which normally express high levels of the c-myb gene product p75c-myb. The results demonstrate that p48v-myb and p75c-myb can be coexpressed in the nuclei of cloned cells. Therefore, p48v-myb does not invariably prevent the expression of p75c-myb.

Expression of enzymatically active poliovirus RNA-dependent RNA polymerase in Escherichia coli

The poliovirus genome is replicated by a virus-encoded RNA-dependent RNA polymerase (RNA polymerase). The RNA polymerase is first synthesized as a larger precursor polypeptide, which is subsequently processed by a viral proteinase, 3Cpro, to give the mature polymerase molecule, 3Dpol. To further characterize the poliovirus RNA polymerase, we have constructed plasmids that expressed this protein in Escherichia coli. The plasmids consisted of fusions between the E. coli DNA encoding the first 13 amino acids of the trp operon leader protein and viral genes encoding the 3Cpro and 3Dpol polypeptides. E. coli harboring such plasmids gave significant, inducible levels of enzymatically active RNA polymerase as determined by the poly(A).oligo(U) poly(U) polymerase assay. The purified RNA polymerase activity from E. coli corresponded to a protein with the approximate molecular weight of the mature 3Dpol protein. The availability of a recombinant, enzymatically active poliovirus RNA polymerase provides a system in which we can precisely delineate the role this enzyme plays in the regulation of poliovirus replication.

Subnuclear associations of the v-myb oncogene product and actin are dependent on ionic strength during nuclear isolation

The method used to isolate nuclei has a direct effect on the subnuclear association of the v-myb product, p48v-myb, and nuclear actin. Analysis of nuclei subjected to various isolation procedures showed that disruption of native nuclear structure during hypotonic treatment resulted in dissociation of p48v-myb from the nuclear matrix.

The highly conserved amino-terminal region of the protein encoded by the v-myb oncogene functions as a DNA-binding domain

The retroviral oncogene v-myb encodes a 45,000 Mr nuclear protein (p45v-myb) that is predominantly associated with the chromatin of transformed cells. It has previously been shown that p45v-myb, when released from chromatin by salt-treatment, binds to DNA. To analyse the biochemical properties of p45v-myb in more detail we have expressed the v-myb coding region in Escherichia coli. Our results demonstrate that bacterially expressed myb protein has an intrinsic DNA-binding activity. Using two alternative strategies, (i) inhibition of DNA-binding by monoclonal antibodies and (ii) analysis of DNA-binding activities of partially deleted forms of the bacterial myb protein, we show that the DNA-binding domain is located in the amino-terminal region of the v-myb protein. This region has been highly conserved between myb genes of different species. Our results are therefore consistent with the hypothesis that DNA-binding is an important aspect of myb protein function.

Activation of human raf transforming genes by deletion of normal amino-terminal coding sequences

Three activated cellular raf genes have been detected by transfection of NIH 3T3 cells with human tumor DNAs. Blot hybridization analysis indicated that all three transforming raf genes had recombined with non-raf sequences in the vicinity of raf exon 7-intron 7, resulting in the deletion of about 40% of the normal coding sequence from the raf amino terminus. By cloning sequences upstream of the truncated raf loci we have shown that the rearrangements involve the fusion of three different 5' non-raf human sequences to the human raf gene. No rearrangements could be detected in the raf loci of the three original human tumor DNAs, suggesting that the raf genes were activated by DNA rearrangements occurring during transfection. Significant overexpression of raf mRNA was not evident in two of the three transformant lines, indicating that raf overexpression is not necessary and 5' truncation alone may be sufficient to activate the transforming potential of cellular raf genes.

Activation of human raf transforming genes by deletion of normal amino-terminal coding sequences

Three activated cellular raf genes have been detected by transfection of NIH 3T3 cells with human tumor DNAs. Blot hybridization analysis indicated that all three transforming raf genes had recombined with non-raf sequences in the vicinity of raf exon 7-intron 7, resulting in the deletion of about 40% of the normal coding sequence from the raf amino terminus. By cloning sequences upstream of the truncated raf loci we have shown that the rearrangements involve the fusion of three different 5' non-raf human sequences to the human raf gene. No rearrangements could be detected in the raf loci of the three original human tumor DNAs, suggesting that the raf genes were activated by DNA rearrangements occurring during transfection. Significant overexpression of raf mRNA was not evident in two of the three transformant lines, indicating that raf overexpression is not necessary and 5' truncation alone may be sufficient to activate the transforming potential of cellular raf genes.

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.

Structure of the protein encoded by the chicken proto-oncogene c-myb

The retroviral oncogene v-myb arose by transduction of the chicken proto-oncogene c-myb. We isolated and sequenced cDNA that represents the entire coding domain of chicken c-myb. By transcribing the cDNA into mRNA in vitro and then translating the RNA, we were able to document the integrity of the cDNA and to identify the codon responsible for initiation of translation from c-myb. Two different alleles of v-myb are extant, one in the genome of avian myeloblastosis virus (AMV) and the other in the genome of erythroblastosis virus 26 (E26V). The proteins encoded by the AMV and E26V alleles of v-myb differ from the product of c-myb in three ways: at their amino termini, they lack 71 and 80 amino acids respectively; at their carboxy termini, they are deficient in 199 and 278 residues; and 11 substitutions of amino acids are scattered throughout the product of AMV allele, whereas the product of the E26V allele contains only a single substitution. The structural origins of tumorigenicity by v-myb and the biological functions of c-myb remain enigmatic. The findings and molecular clones described here should now permit a systematic exploration of these enigmas.

Activation of oncogenicity of the c-rel proto-oncogene

Reticuloendotheliosis virus strain T (Rev-T) induces a lethal lymphoma in young birds and transforms avian lymphoid cells in vitro. The transforming gene of Rev-T, v-rel, was derived from the turkey proto-oncogene c-rel. Comparison of the nucleotide sequences of v-rel and c-rel indicates that in addition to several internal amino acid changes relative to c-rel, p59v-rel has amino acid sequences at both ends derived from the reticuloendotheliosis virus strain A-related virus env gene (K. C. Wilhelmsen, K. Eggleton, and H. M. Temin, J. Virol. 52:172-182, 1984). In this report, the v-rel sequences important for transformation were defined by constructing recombinant retroviruses in which c-rel sequences replaced the analogous v-rel sequences. These recombinant viruses expressing chimeric proteins were tested for their ability to transform spleen cells in vitro and to induce tumors in young chickens. Activation of the oncogenicity of c-rel in Rev-T required alteration of the amino terminus and the central region of the protein. Deletion of the noncoding sequences 3' to c-rel and of most of the helper virus-related env sequences was necessary for the formation of Rev-T.

Coordinate regulation of myelomonocytic phenotype by v-myb and v-myc

Both avian myeloblastosis virus (by the action of v-myb) and avian myelocytomatosis virus MC29 (by the action of v-myc) transform cells of the myelomonocytic lineage. Whereas avian myeloblastosis virus elicits a relatively immature phenotype, cells transformed by MC29 resemble mature macrophages. When cells previously transformed by v-myb were superinfected with MC29, their phenotype was rapidly altered to that of a more mature cell. These superinfected cells expressed both v-myb (at a level similar to that found before superinfection) and v-myc. It therefore appears that the expression of v-myc can elicit certain properties of a more differentiated phenotype. In addition, unlike cells transformed by v-myb alone, the cells expressing both v-myb and v-myc could not be induced by the tumor promoter 12-O-tetradecanoylphorbol-13-acetate to differentiate to fully mature macrophages. Cells with a morphology similar to that of the superinfected cells were elicited by simultaneously infecting yolk sac macrophages with avian myeloblastosis virus and MC29. Such cells expressed both v-myb and v-myc. These results indicate that expression of v-myb and v-myc in infected cells coordinately regulates myelomonocytic phenotype and that the two viral oncogenes vary in their ability to interfere with tumor promoter-induced differentiation. Our findings also sustain previous suggestions that the oncogenes v-myb and v-myc may not transform target cells by simply blocking differentiation.

Two modes of c-myb activation in virus-induced mouse myeloid tumors

Two modes of disruption of the protooncogene c-myb by viral insertional mutagenesis in mouse myeloid tumor cells are described. The first mode was found in six tumors in which a Moloney murine leukemia virus component had inserted in the same transcriptional orientation upstream of the 5'-most exon with v-myb homology (vE1). cDNA sequence data indicate the presence of a truncated c-myb mRNA that is initiated in the upstream 5' long terminal repeat of the integrated provirus and processed via a cryptic splice donor sequence in the gag region to the splice acceptor site in vE1 of the c-myb gene, thus removing the remaining downstream viral and myb intronic sequences. Unlike most gag-onc transcripts, the gag and myb sequences in the hybrid transcript were not in the same reading frame. It is presumed that the gag sequence provides a cryptic translation initiation site for the novel amino-truncated c-myb protein. The second mode of disruption was by downstream virus insertion at the 3' side of the c-myb, which results in the synthesis of a small (approximately 2 kilobase) myb transcript. The 5' long terminal repeat of the inserted provirus provides a TGA termination codon that results in the elimination of 240 normal c-myb amino acid residues from the carboxyl terminus of the tumor-specific myb protein. These results suggest that truncated myb proteins play a role in neoplastic transformation of myeloid cells.

Protein product of proto-oncogene c-mil

Using antipeptide antibodies with specificity for the carboxyl termini of v-raf and v-mil protein products, two proteins with apparent molecular weights of approximately 71,000/73,000 and 215,000 were detected in immunoprecipitates from normal uninfected chicken cells. The 71,000/73,000-molecular-weight protein was identified as the product of the c-mil proto-oncogene by the close structural relationship of its 42,000-molecular-weight carboxyl-terminal domain to the v-mil-encoded domain of the hybrid protein p100gag-mil specified by the avian retrovirus MH2. The amino-terminal domain of the cellular protein is encoded by 5' c-mil sequences that have not been transduced into the genome of MH2. The c-mil protein (p71/73c-mil) was found to be phosphorylated in vivo, and homologous proteins were detected at variable levels in a variety of vertebrate cells, including human cells.

The molecular genetics of cancer

The search for genetic damage in neoplastic cells now occupies a central place in cancer research. Diverse examples of such damage are in hand, and they in turn hint at biochemical explanations for neoplastic growth. The way may be open to solve the riddles of how normal cells govern their replication and why cancer cells do not.

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.

The 5' extremity of the v-ets oncogene of avian leukemia virus E26 encodes amino acid sequences not derived from the major c-ets-encoded cellular proteins

Antibodies were prepared against bacterially expressed polypeptides corresponding to various portions of the v-ets-encoded domain of P135gag-myb-ets, the transforming protein of avian leukemia virus E26. Immunoprecipitation analyses show that ca. 80 v-ets-encoded amino-acids located immediately after the v-myb/v-ets junction are not found in P54/56c-ets, the translation product of the c-ets proto-oncogene, nor in a set of cellular proteins of 64, 62, and 60 kDa related to but distinct from P54/56c-ets. In addition, Northern blot analyses show that these 5' v-ets sequences neither derive from the nontranslated region of the known cellular transcripts hybridizing to a v-ets probe nor from the c-myb transcript or the helper virus genetic information. Tryptic peptide analyses furthermore indicate that, except for these sequences and the last 16 carboxy terminal amino acids of P135gag-myb-ets, the amino acids encoded by v-ets are essentially colinear with those of P54c-ets.

Human c-myb protooncogene: nucleotide sequence of cDNA and organization of the genomic locus

We have isolated cDNA clones of the human c-myb mRNA that contain approximately 3.4 kilobases of the approximately 3.8-kilobase mRNA sequence. Nucleotide sequence analysis shows that the c-myb mRNA contains an open reading frame of 1920 nucleotides, which could encode a 72-kDa protein. The cDNA nucleotide sequence and the predicted amino acid sequence of the c-myb protein are highly homologous to the corresponding chicken and mouse proteins. In particular, a region toward the NH2 terminus of the protein containing a 3-fold tandem repeat of 51 residues is evolutionarily conserved and is the only region of homology with the Drosophila c-myb protein. This region may represent a functionally important structure, most likely the DNA-binding domain. cDNA clones have been used to isolate genomic clones and to define a preliminary intron/exon organization of the c-myb gene. Identification of 5' and 3' coding and noncoding exons indicates that the human c-myb locus spans a 40-kilobase region.

Activation of oncogenicity of the c-rel proto-oncogene

Reticuloendotheliosis virus strain T (Rev-T) induces a lethal lymphoma in young birds and transforms avian lymphoid cells in vitro. The transforming gene of Rev-T, v-rel, was derived from the turkey proto-oncogene c-rel. Comparison of the nucleotide sequences of v-rel and c-rel indicates that in addition to several internal amino acid changes relative to c-rel, p59v-rel has amino acid sequences at both ends derived from the reticuloendotheliosis virus strain A-related virus env gene (K. C. Wilhelmsen, K. Eggleton, and H. M. Temin, J. Virol. 52:172-182, 1984). In this report, the v-rel sequences important for transformation were defined by constructing recombinant retroviruses in which c-rel sequences replaced the analogous v-rel sequences. These recombinant viruses expressing chimeric proteins were tested for their ability to transform spleen cells in vitro and to induce tumors in young chickens. Activation of the oncogenicity of c-rel in Rev-T required alteration of the amino terminus and the central region of the protein. Deletion of the noncoding sequences 3' to c-rel and of most of the helper virus-related env sequences was necessary for the formation of Rev-T.