Nucleotide sequence analysis of human c-myc locus, chicken homologue, and myelocytomatosis virus MC29 transforming gene reveals a highly conserved gene product.

We have determined the complete nucleotide sequence of human cellular c-myc, which is homologous to the transforming gene, v-myc, of myelocytomatosis virus MC29. Analysis of the genetic information and alignment with the known sequence of chicken c-myc and v-myc indicates: (i) An intervening sequence can be identified by consensus splice signals. The unique 5' sequence of c-myc and its junction with the v-myc region may be a canonical 3' splice acceptor. (ii) The c-myc locus can generate a mRNA whose termination signals are downstream from the translational termination signal. (iii) The three myc genes share the same reading frame, including translational termination signals. (iv) The homology is conserved only in the coding region. (v) Most changes at the nucleotide level result in no change in the amino acid. (vi) There are two distinct domains--the 5' unique domain, which is different from the viral, and the 3' coding domain, which contains amino acids coded by the two exons whose sequences have been determined here. In the latter domain, the amino acid variation between v-myc and chicken c-myc is less than 2%, whereas that between the chicken v-myc and the human is 27%, with the variation concentrated in the region that flanks the splicing points.     

Nucleotide sequence of avian carcinoma virus MH2: two potential onc genes, one related to avian virus MC29 and the other related to murine sarcoma virus 3611.

The 5.2-kilobase (kb) RNA genome of avian carcinoma virus MH2 has the genetic structure 5'-delta gag (0.2 kb)- mht (1.2 kb)-myc (1.4 kb)-c (0.4 kb)-poly(A) (0.2 kb)-3'. delta gag is a partial retroviral core protein gene, mht and myc are cell-derived MH2-specific sequences, and c is the 3'-terminal retroviral vector sequence. Here we have determined the nucleotide sequence of 3.5 kb from the 3' end of delta gag to the 3' end of molecularly cloned proviral MH2 DNA, in order to elucidate the genetic structure of the virus and to compare it with other mht - and myc-containing oncogenic viruses as well as with the chicken proto-myc gene. The following results were obtained: (i) delta gag- mht forms a hybrid gene with a contiguous reading frame of 2682 nucleotides that terminates with a stop codon near the 3' end of mht . The 3' 969 nucleotides of mht up to the stop codon are 80% sequence related to the onc-specific raf sequence of murine sarcoma virus 3611 (94% homologous at the deduced amino acid level). (ii) The myc sequence is preceded by an RNA splice acceptor site shared with the cellular proto-myc gene, beyond which it is colinear up to a 3'-termination codon and 40 noncoding nucleotides with the myc sequences of avian retrovirus MC29 and chicken proto-myc. Thus, myc forms, together with a 5' retroviral exon, a second MH2-specific gene. (iii) myc is followed by the 3'-terminal c region of about 400 nucleotides, which is colinear with that of Rous sarcoma virus except for a substitution near the 5' end of the long terminal repeat. It is concluded that MH2 contains two genes with oncogenic potential, the delta gag- mht gene, which is closely related to the delta gag-raf transforming gene of MSV 3611, and the myc gene, which is related to the transforming gene of MC29. Furthermore, it may be concluded that the cellular proto-onc genes, which on sequence transduction become viral onc genes, are a small group because among the 19 known onc sequences, 5 are shared by different taxonomic groups of viruses of which the mht /raf homology is the closest determined so far.     

Cloning and characterization of different human sequences related to the onc gene (v-myc) of avian myelocytomatosis virus (MC29).

We have studied the genomic organization of human cellular sequences (c-myc) homologous to the transforming gene (v-myc) of avian myelocytomatosis virus (MC29). Southern blotting experiments using v-myc probes showed that several fragments of the human genome contain sequences related to the central part of v-myc but only few of them are homologous to the 3' portion of the viral gene. Several recombinant phages which represent different regions of the genome containing c-myc-related sequences were isolated from a human DNA library. Two clones (lambda-LMC-12 and -41) overlap over approximately 17 kilobases of DNA where a sequence homologous to that of the entire v-myc is present. Restriction mapping experiments and heteroduplex analysis show that c-myc sequences of this locus are interrupted by one intron, suggesting that lambda-LMC-12 and -41 contain the complete functional c-myc gene. Three other clones (lambda-LMC-3, -4, and -26) do not overlap and contain sequences related to only approximately 0.3 kilobase of v-myc but lack 5' and 3' portions of the gene. These sequences are not interrupted by introns and are more divergent from v-myc than is the complete gene, suggesting that they may represent either pseudogenes or parts of distantly related genes.     

Characterization and location of myc homologous sequences in human cytomegalovirus DNA.

Specific DNA fragments from human cytomegalovirus (HCMV) strains Towne and AD169 exhibited homology to myc DNA sequences under hybridization conditions corresponding to a 22-28% base mismatch. In a specific subset of hybridizing HCMV fragments, the homology was restricted to the 5' half of viral v-myc and the 5' half of human c-myc. No hybridization was observed between HCMV fragments and the 3' v-myc and 3' human c-myc probes. In Towne DNA, myc homologous sequences mapped in four regions within the long unique segment (0.070-0.094, 0.134-0.156, 0.454-0.470, and 0.591-0.605 map unit) and one region in each of the short terminal repeats (0.832-0.847 and 0.984-1.0 map unit). In strain AD169, myc homology mapped in three regions within the long unique segment (0.123-0.147, 0.174-0.198, and 0.583-0.606 map unit) and one region in each of the short terminal repeats (0.833-0.863 and 0.976-1.0 map unit). By utilizing probes specific for the 5' and 3' portions of v-myc and human c-myc, we established that the regions of homology in a specific subset of HCMV restriction fragments corresponded to the 5' half of myc and were not due to MC29 viral helper sequences, flanking cellular sequences, or binding of probe to G.C-rich DNA.     

Avian carcinoma virus MH2 contains a transformation-specific sequence, mht, and shares the myc sequence with MC29, CMII, and OK10 viruses.

Avian carcinoma virus MH2 has been grouped together with MC29, CMII, and OK10, because all of these viruses share a transformation-specific sequence termed myc. A 5.2-kilobase (kb) DNA provirus of MH2 has been molecularly cloned. The complete genetic structure of MH2 is 5''-delta gag(1.9-kb)-mht(1.2-kb)-myc(1.3-kb)-delta env(?) and noncoding c-region (0.2-kb)-3''. delta gag, delta env, and c are genetic elements shared with nondefective retroviruses, whereas mht is a unique, possibly MH2 transformation-specific, sequence. Hybridizations with normal chicken DNA and cloned chicken c-myc DNA indicate that the mht sequence probably derives from a normal cellular gene that is distinct from the c-myc gene. The genetic structure of MH2 suggests that the delta gag and mht sequences function as a hybrid gene that encodes the p100 putative transforming protein. The myc sequence of MH2 appears to encode a second transforming function. Therefore, it seems that MH2 contains two genes with possible oncogenic function, whereas MC29, CMII, and OK10 each carries a single hybrid delta gag-myc transforming gene. It is remarkable that, despite these fundamental differences in their primary structures and mechanisms of gene expression, MH2 and MC29 have very similar oncogenic properties.     

OK10, an avian acute leukemia virus of the MC29 subgroup with a unique genetic structure

The RNA of defective avian acute leukemia virus OK10 was isolated from a defective virus particle, released by OK10-transformed nonproducer avian fibroblasts, as a 60S complex consisting of 8.6-kilobase subunits. Oligonucleotide fingerprinting and RNA.cDNA hybridization identified two sets of sequences in OK10 RNA: group-specific sequences, which are related to all nondefective members of the avian tumor virus group, and a sequence closely related to the subgroup-specific sequences (mcv) of the myelocytomatosis virus (MC29) subgroup of avian acute leukemia viruses. Hence, OK10 is classified as a member of the MC29 subgroup of avian tumor viruses, in agreement with classification based on its oncogenic spectrum. The group-specific sequences of OK10 RNA include partial (Delta) pol and env genes, a c-region, and, unlike those of all other members of the MC29 subgroup, a complete gag gene. Oligonucleotide mapping revealed 5'-gag-Deltapol-mcv-Deltaenv-c-3' as the order of the subgroup-specific and group-specific elements of OK10 RNA. The genetic unit gag-Deltapol-mcv, measuring approximately 6.4 kilobases, codes for the nonstructural, presumably transforming, 200,000-dalton OK10-specific protein and also includes the gag gene coding for the internal virion proteins. Because gag is the only intact virion gene shared in addition to regulatory RNA sequences between OK10 and nondefective avian tumor viruses, it is concluded that the gag gene is sufficient for the formation of a defective virus particle. Comparisons among the RNAs and gene products of different viruses of the MC29 subgroup show that they share 5'-terminal gag-related and internal mcv sequences but differ from each other in intervening gag-, pol-, and mcv-related sequences. It follows that the probable transforming genes and their protein products have two essential domains, one consisting of conserved 5' gag-related and the other of 3' mcv-related sequence elements. In the light of this and previous knowledge we can now distinguish two designs among five different transforming onc genes of avian tumor viruses: onc genes with coding sequences unrelated to virion genes, like those of Rous sarcoma virus and avian myeloblastosis virus, and onc genes with coding sequences that are hybrids of virion genes and specific sequences, like those of the MC29 subgroup viruses, of avian erythroblastosis virus, and of Fujinami sarcoma virus.     

Nucleotide sequence analysis of the proviral genome of avian myelocytomatosis virus (MC29).

The nucleotide sequence of the integrated proviral genome of avian myelocytomatosis virus (MC29) coding for gag-myc protein has been determined. By comparison of this nucleotide sequence with the helper virus as well as the c-myc region, it was possible to localize the junction points between helper viral and v-myc sequences. These studies demonstrate that (i) the large terminal repeat sequence of MC29 is very similar to that of Rous sarcoma virus, (ii) the viral genome has suffered extensive deletions in the gag, pol, and env genes, (iii) the gag region can code for p19, p10, and part of p27, (iv) the recombination between viral and cellular sequences occurred in the coding region of p27 such that the open reading frame extends for an additional stretch of 1,266 base pairs, resulting in a gag-myc hybrid protein, (v) the open reading frame terminated within the v-myc region 300 bases upstream of v-myc-helper viral junction, and (vi) the v-myc helper-viral junction at the 3' end occurred in the middle of env gene, rendering it defective.     

Nucleotide sequence to the v-myc oncogene of avian retrovirus MC29.

Avian myelocytomatosis viruses are retroviruses whose oncogene (v-myc) induces an unusually wide variety of tumors, including carcinomas, endotheliomas, sarcomas, and myelocytomatoses. The viral gene v-myc arose by transduction of an undetermined portion of a cellular gene known as c-myc. In order to facilitate further studies of the functions of v-myc and c-myc and to permit detailed comparisons between the two genes, we have determined the nucleotide sequence of v-myc in the genome of the MC29 strain of myelocytomatosis virus. The v-myc domain in MC29 virus encodes a hydrophilic polypeptide with a molecular weight of 47,000, fused to a portion of the polyprotein encoded by the viral structural gene gag. The carboxyl-terminal half of the v-myc polypeptide is rich in basic amino acid residues. This feature may account for the DNA-binding properties of the hybrid gag-myc-encoded protein which would have a molecular weight of approximately 100,000, in accord with results from previous studies of the protein encoded by v-myc. The junctions between v-myc and the genome of the transducing virus are apparent but reveal no clues to the mechanism by which transduction might occur.     

myc products induce the expression of catecholaminergic traits in quail neural crest-derived cells.

The avian myelocytomatosis virus strain MC29 v-myc oncogene transforms a wide panel of avian cells in vitro and either blocks or maintains differentiation, depending on the cell type. In the present work, we have investigated the effect of this oncogene on the differentiation of early embryonic cells, neural crest cells, grown in vitro. We report that the MC29 v-myc gene product induces a strong cellular proliferation of 2-day quail neural crest with the appearance of catecholaminergic traits. Other v-myc as well as the c-myc gene products also trigger this phenotype. Retroviruses carrying some other oncogenes do not elicit this phenotypic expression, although they activate cell multiplication. Thus, our results indicate that myc gene products induce (directly or indirectly) a differentiated phenotype in a subpopulation of neural crest cells.     

Nucleotide sequence of two overlapping myc-related genes in avian carcinoma virus OK10 and their relation to the myc genes of other viruses and the cell.

Avian carcinoma virus OK10 has the genetic structure gag-delta pol-myc-delta env. It shares the transformation-specific myc sequence with three other avian carcinoma viruses (MC29, MH2, CMII) and also with a normal chicken gene proto-myc and the gag, pol, and env elements with non-transforming retroviruses. Unlike the other myc-containing viruses, which synthesize singular myc proteins, OK10 synthesizes two different myc-related proteins of 200 and 57 kDa. Here we have sequenced the myc region of an infectious OK10 provirus to investigate how OK10 synthesizes two different proteins from the same myc domain and to identify characteristic differences between the normal proto-myc gene and the myc-related viral transforming genes. It was found that the 1.6-kilobase myc domain of OK10 is colinear and coterminal with the myc domains of MC29, MH2, and the terminal two exons of proto-myc. It is preceded by the same splice acceptor as the myc sequence of MH2 and as the second proto-myc exon. From this and the known structure of retroviruses, it follows that the OK10 gene encoding the 57-kDa protein is discontinuous with a small 5' exon that includes six gag codons and a large 3' myc exon (delta gag-myc). This gene and the delta gag-myc gene of MH2 are isogenic. The proto-myc-derived intron preceding the myc domain of OK10 is in the same reading frame as the adjacent delta pol and myc domains and, hence, is part of the gag-delta pol-myc gene encoding the 200-kDa protein. Sequence comparisons with proto-myc and MC29 and MH2 indicate that there are no characteristic mutations that set apart the viral myc domains from proto-myc. It is concluded that transforming function of viral myc-related genes correlates with the lack of a viral equivalent of the first proto-myc exon(s) and conjugation of the viral myc domains with large or small retroviral genetic elements rather than with specific point mutations. Because OK10 and MH2 each contain two genes with potential transforming function (namely, delta gag-myc and gag-delta pol-myc or delta gag-mht, respectively), it remains to be determined whether the delta gag-myc genes have transforming function on their own or need helper genes. The possible helper requirement cannot be very specific because the two potential helper genes are very different.     

Structure and specific sequences of avian erythroblastosis virus RNA: evidence for multiple classes of transforming genes among avian tumor viruses.

Two major RNA species were found in several clonal isolates of avian erythroblastosis virus (AEV) and avian erythroblastosis-associated helper virus (AEAV) complexes: one of 8.7 kilobases (kb), the other of 5.5 kb. The 5.5-kb species was identified as AEV RNA because (i) it was absent from non-transforming AEAV isolated from the same virus complex, (ii) it was present in complexes of AEV and different helper viruses, and (iii) its structure is similar to that of avian acute leukemia viruses of the MC29 group. Molecular hybridization indicated that 54% of AEV RNA is specific and 46% is related to other viruses of the avian tumor virus group, particularly to AEAV, therefore termed group-specific. The genetic structure of AEV RNA was deduced by mapping oligonucleotides representing specific and group-specific sequences and by comparing the resulting map to maps of AEAV and of other avian tumor viruses derived previously. AEV RNA contains a gag gene-related, 5' group-specific section of 1 kb, an internal AEV-specific section of 3 kb unrelated to any other viral RNA tested, and a 3' group-specific section of 1.5 kb. The 5' section of AEV RNA is closely related to analogous 5' sections of the MC29 group viruses and is homologous with a 5' RNA section that is part of the gag gene of AEAV. The 3' section is also shared with AEAV RNA and includes a variant C-oligonucleotide near the 3' end that is different from the highly conserved counterparts of all other exogenous avian tumor viruses. By analogy with Rous sarcoma virus and the acute leukemia viruses of the MC29 group, the internal specific section of AEV RNA is thought to signal a third class of onc genes in avian tumor viruses. Comparisons with AEAV and the MC29 group viruses suggest that both the 5' gag-related and the internal specific RNA sections of AEV are necessary for onc gene function.     

Specific RNA sequences and gene products of MC29 avian acute leukemia virus

The 28S RNA of the defective avian acute leukemia virus MC29 contains two sets of sequences: 60% are hybridized by DNA complementary to other avian tumor virus RNAs (group-specific cDNA) and 40% are hybridized only by MC29-specific cDNA. Specific and group-specific sequences of viral RNA, defined in terms of their large RNase T(1)-resistant oligonucleotides, were located on a map of all large T(1) oligonucleotides of viral RNA. Oligonucleotides representing MC29-specific sequences of viral RNA mapped between 0.4 and 0.7 unit from the 3'-poly(A) end. Oligonucleotides of group-specific sequences mapped between 0 and 0.4 and between 0.7 and 1 map unit. Cell-free translation of viral RNA yielded three proteins with approximate molecular weights of 120,000, 56,000, and 37,000, termed P120(mc), P56(mc), and P37(mc). P120(mc) contained both MC29-specific peptides and serological determinants and peptides of the conserved, internal group-specific antigens of avian tumor viruses. P120(mc) is translated only from full-length 28S RNA. Furthermore, MC29 RNA contains sequences related to the group-specific antigen gene (gag), near the 5' end, which are followed by MC29-specific sequences. We conclude that this protein is translated from the 5' 60% of the RNA, and that it includes a segment translated from the specific sequences. It is suggested that the transforming (onc) gene of MC29 may consists of the specific and some group-specific RNA sequences and that P120(mc), which is also found in transformed cells, may be the onc gene product.     

Recovery of myc-specific sequences by a partially transformation-defective mutant of avian myelocytomatosis virus, MC29, correlates with the restoration of transforming activity.

Avian myelocytomatosis virus MC29 transforms fibroblasts and macrophages in vitro. Recently we isolated three deletion mutants of MC29 that have a decreased ability to transform macrophages while retaining their capacity to transform fibroblasts. One of these mutants, MC29 td10H, on passage through chicken embryo cultures gave rise to a recovered virus MC29 10H B1, which has regained the ability to transform macrophages efficiently. Immunoprecipitation analysis of MC29 10H B1-infected cells revealed a 108,000-dalton gag-myc polyprotein as opposed to the 90,000-dalton protein of MC29 td10H or the 110,000-dalton polyprotein of wtMC29. Tryptic peptide mapping studies demonstrated that the 108,000-dalton protein had acquired v-myc peptides that were lost from the td10H 90,000-dalton polyprotein and two novel peptides. Restriction enzyme analysis of the MC29 10H B1 proviral DNA also showed that myc sequences had been acquired. These results suggest that MC29 td10H has recombined with c-myc sequences to generate a recovered virus, MC29 10H B1.     

The delta beta crossover region in Lepore boston hemoglobinopathy is restricted to a 59 base pairs region around the 5'' splice junction of the large globin gene intervening sequence

Genomic DNA from a hemoglobin (Hb) Lepore Boston (delta 87 Gln beta 116 His) homozygote of Southern Italian origin has been studied in order to map the fusion point between the delta and beta genes. An Ava II restriction endonuclease recognition sequence, located 12 base pairs (bp) downstream from the 5' end of the beta gene large intervening sequence, has been taken as marker of the beta-like portion of the fusion gene. This site was present even in the delta beta gene, allowing the localization of the crossover area to a 59-bp region extending from the first nucleotide of the Leu codon in position 88 to the 11th nucleotide of the large intervening sequence. The analysis of the DNA restriction polymorphisms in the gamma delta beta globin gene region provides evidence that a single mutational event originated the Lepore delta beta genes, at least in the Italian population.     

Human c-myc onc gene is located on the region of chromosome 8 that is translocated in Burkitt lymphoma cells.

Human sequences related to the transforming gene (v-myc) of avian myelocytomatosis virus (MC29) are represented by at least one gene and several related sequences that may represent pseudogenes. By using a DNA probe that is specific for the complete gene (c-myc), different somatic cell hybrids possessing varying numbers of human chromosomes were analyzed by the Southern blotting technique. The results indicate that the human c-myc gene is located on chromosome 8. The analysis of hybrids between rodent cells and human Burkitt lymphoma cells, which carry a reciprocal translocation between chromosomes 8 and 14, allowed the mapping of the human c-myc gene on region (q24 leads to qter) of chromosome 8. This chromosomal region is translocated to either human chromosome 2, 14, or 22 in Burkitt lymphoma cells.     

Fujinami sarcoma virus: An avian RNA tumor virus with a unique transforming gene

The oncogenic properties and RNA of the Fujinami avian sarcoma virus (FSV) and the protein it encodes were investigated and compared to those of other avian tumor viruses with sarcomagenic properties such as Rous sarcoma virus and the acute leukemia viruses MC29 and erythroblastosis virus. Cloned stocks of FSV caused sarcomas in all chickens inoculated and were found to contain a 4.5-kilobase (kb) and an 8.5-kb RNA species. The 4.5-kb RNA was identified as the genome of defective FSV because it was absent from nondefective FSV-associated helper virus and because the titer of focus-forming units increased with the ratio of 4.5-kb to 8.5-kb RNA in virus preparations. This is, then, the smallest known tumor virus RNA with a transforming function. Comparisons with other viral RNAs, based on oligonucleotide mapping and molecular hybridization, indicated that 4.5-kb FSV RNA contains a 5' gag gene-related sequence of 1 kb, an internal specific sequence of about 3 kb that is unrelated to Rous sarcoma virus, MC29, and erythroblastosis virus, and a 3'-terminal sequence of about 0.5 kb related to the conserved C region of avian tumor viruses. The lack of some or all nucleotide sequences of the essential virion genes, gag, pol, and env, and the isolation of FSV-transformed nonproducer cell clones indicated that FSV is replication defective. A 140,000-dalton, gag-related non-structural protein was found in FSV-transformed producer and nonproducer cells and was translated in vitro from full-length FSV RNA. This protein is expected to have a transforming function both because its intracellular concentration showed a positive correlation with the percentage of transformed cells in a culture and because FSV is unlikely to code for major additional proteins since the genetic complexities of FSV RNA and the FSV protein are almost the same. It is concluded that the transforming onc gene of FSV is distinct from that of Rous sarcoma virus and other avian tumor viruses with sarcomagenic properties. Hence, multiple mechanisms exist for sarcomagenic transformation of avian cells.