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.     

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.     

Nucleotide sequence analysis of the chicken c-myc gene reveals homologous and unique coding regions by comparison with the transforming gene of avian myelocytomatosis virus MC29, delta gag-myc.

Myelocytomatosis virus MC29 is a defective avian retrovirus with a hybrid transforming gene (delta gag-myc) consisting of a 1,358-base pair (bp) sequence from the retroviral gag gene and a 1,568-bp sequence (v-myc) shared with a cellular locus, termed c-myc. We have subjected to sequence analysis 2,735 bp of the cloned c-myc gene, which includes the v-myc-related region of 1,568 bp, an intervening sequence of 971 bp, and unique flanking sequences of 45 bp and 195 bp at the 5' and 3' ends, respectively. Analysis of the genetic information and alignment of the c-myc sequence with the known sequence of MC29 indicates that: (i) the two myc sequences share the same reading frame, including the translational termination signal; (ii) there are nine nucleotide changes between c-myc and v-myc that correspond to seven amino acid changes; (iii) the 971-bp intervening sequence of c-myc can be defined as an intron by consensus splice signals; (iv) the unique 5' sequence of c-myc could either extend its reading frame beyond the homology with v-myc or could be an intron because its junction with the myc region of the locus is a canonical 3' splice-acceptor site; (v) the v-myc contains 10 nucleotides at its 5' end not shared with the c-myc analyzed here and also not with known gag genes, probably derived from an upstream exon; and (vi) the c-myc locus can generate a mRNA whose termination signals have been identified to be located 83 bp and 119 bp from the point of divergence between the v-myc and c-myc. We conclude that the gene of the c-myc locus of the chicken and the onc gene of MC29 share homologous myc regions and differ in unique 5' coding regions and we speculate, on this basis, that their protein products may have different functions. The hybrid onc gene of MC29 must have been generated from the c-myc gene by deletion of the 5' cellular coding sequence, followed by substitution with the 5' region of the viral gag gene.     

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.     

DNA sequence of a major human leukocyte interferon gene.

The gene for human leukocyte interferon alpha 2 (designated either LeIF A or HuIFN-alpha 2) has been isolated from a human genome library. The DNA sequence of this gene demonstrates that it lacks introns. The 3' noncoding sequences of the IFN-alpha 2 gene correspond to two types of IFN-alpha 2 cDNA clones we have isolated that have alternate sites of polyadenylylation. A comparison of seven human IFN-alpha sequences shows that they are homologous in the 5' flanking region and contain identical "TATA box" sequences. The recombinant lambda clone containing the IFN-alpha 2 gene also contains two copies of the "Alu family" repeat sequence.     

Human cytomegalovirus (strain AD169) contains sequences related to the avian retrovirus oncogene v-myc.

We have detected nucleotide sequences related to the transforming gene (v-myc) of avian myelocytomatosis virus MC-29 in the DNA genome of human cytomegalovirus (HCMV) strain AD169. Cloned DNA representing the entire 1.5-kilobase-pair oncogene v-myc and subfragments of this gene were hybridized to EcoRI-cleaved HCMV virion DNA and cloned subgenomic HCMV DNA fragments. Only a 0.5-kilobase-pair Pst I-Sal I subfragment representing the 5' end of the coding sequence of the v-myc oncogene hybridized to the HCMV DNA. We have localized these v-myc-related sequences to five regions in the long unique segment of the HCMV genome corresponding to EcoRI fragments C, I, P, R, and b and to regions within the EcoRI junction fragments F and H at or near the repeats bounding the short unique segment. There was no hybridization of these HCMV sequences to other retroviral oncogenes tested including v-src, v-myb, v-erb, v-ST-fes, v-fos, v-ras (Harvey), v-mos, and v-abl.     

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.     

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.     

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.     

Genome of avian myelocytomatosis virus MC29: analysis by heteroduplex mapping.

The virion RNA of avian myelocytoma virus MC29 was hybridized to full genome length DNA of the Prague strain of Rous sarcoma virus and analyzed by heteroduplex mapping in the electron microscopy. The results show that MC29 specific sequences for which there are no homologous counterparts in the Rous sarcoma virus genome make up a contiguous stretch of RNA about 1.8 kilobases long. These sequences are located approximately in the middle of the genome, replacing the 3' half of the gag gene, the entire pol gene, and the 5' portion of the env gene, which are absent from MC29. This MC29 specific genetic substitution may contain information for the leukemogenic transformation of the host cell.     

Organization of the gene encoding common acute lymphoblastic leukemia antigen (neutral endopeptidase 24.11): multiple miniexons and separate 5'' untranslated regions.

The common acute lymphoblastic leukemia antigen (CALLA) is a 749-amino acid type II integral membrane protein that has been identified recently as the neutral endopeptidase 24.11 [NEP (EC 3.4.24.11)]. Herein, we characterize the organization of the human CALLA/NEP gene and show that it spans more than 80 kilobases (kb) and is composed of 24 exons. Exons 1 and 2 encode 5' untranslated sequences; exon 3 [170 base pairs (bp)] encodes the initiation codon and transmembrane and cytoplasmic domain; 20 short exons (exons 4-23), ranging in size from 36 to 162 bp, encode most of the extracellular portion of the enzyme; and exon 24 (approximately 3400 bp) encodes the COOH-terminal 32 amino acids of the protein and contains the entire 3' untranslated region (UTR). Of note, the pentapeptide sequence (His-Glu-Ile-Thr-His) associated with metalloprotease zinc binding and substrate catalysis is encoded within a single exon (exon 19). Three types of CALLA/NEP cDNAs have been identified: these clones contain 5' UTR sequences differing from one another upstream of exon 3. These human 5' sequences are homologous to those found in rat brain and rabbit kidney NEP cDNAs. The three human CALLA cDNA types result from alternative splicing of exons 1, 2a, or 2b to the common exon 3. Moreover, exons 2a and 2b share the same 5' sequence but differ from each other by the use of two distinct donor splice sites 171 bp apart in the gene. The substantial conservation of 5' untranslated sequences among species and the existence of 5' alternative splicing suggest that CALLA gene expression may be differentially controlled in a tissue-specific and/or developmentally regulated fashion.     

Hybrid hepatitis B virus-host transcripts in a human hepatoma cell.

The human PLC/PRF/5 hepatoma cell line (the Alexander cell) contains at least seven copies of hepatitis B virus (HBV) DNA integrated in its genome; but it selectively expresses the HBV surface antigen (HBsAg) gene and perhaps low levels of the core gene. We have prepared a cDNA library from PLC/PRF/5 cell poly(A)+ RNA and isolated clones containing HBV sequences. Hybridization experiments show that the great majority of HBV-specific RNAs in this cell line contain HBsAg coding sequences and are presumably derived from the HBsAg gene. Primer extension experiments show that these HBsAg mRNAs are, however, derived from multiple initiation sites in the HBsAg gene and involve two promoters: one at the 5' end of the gene that can produce a protein of 45 kDa, and one located in the pre-S region that can produce two proteins of 31 kDa and the mature HBsAg, 25 kDa, respectively. The HBV RNAs are hybrid RNA species that contain HBV sequences at their 5' ends and host DNA sequences at the 3' ends. The great majority of these hybrid RNAs are transcribed from two closely related yet distinct HBV integrants. The viral-host sequences of these two related hybrid RNAs suggest that the related HBV sequences were generated from a parental fragment via duplication, translocation, and mutagenesis. These processes may play a role in HBV-related oncogenesis.     

Structural organization of glycophorin A and B genes: glycophorin B gene evolved by homologous recombination at Alu repeat sequences.

Glycophorins A (GPA) and B (GPB) are two major sialoglycoproteins of the human erythrocyte membrane. Here we present a comparison of the genomic structures of GPA and GPB developed by analyzing DNA clones isolated from a K562 genomic library. Nucleotide sequences of exon-intron junctions and 5' and 3' flanking sequences revealed that the GPA and GPB genes consist of 7 and 5 exons, respectively, and both genes have greater than 95% identical sequence from the 5' flanking region to the region approximately 1 kilobase downstream from the exon encoding the transmembrane regions. In this homologous part of the genes, GPB lacks one exon due to a point mutation at the 5' splicing site of the third intron, which inactivates the 5' cleavage event of splicing and leads to ligation of the second to the fourth exon. Following these very homologous sequences, the genomic sequences for GPA and GPB diverge significantly and no homology can be detected in their 3' end sequences. The transition site from homologous to nonhomologous sequences can be localized within Alu repeat sequences. The analysis of the Alu sequences and their flanking direct repeat sequences suggest that an ancestral genomic structure has been maintained in the GPA gene, whereas the GPB gene has arisen from the acquisition of 3' sequences different from those of the GPA gene by homologous recombination at the Alu repeats during or after gene duplication.     

Isolation and characterization of overlapping genomic clones covering the chicken alpha 2 (type I) collagen gene.

A series of overlapping recombinant clones, which cover the alpha 2 (type I) collagen gene, have been isolated by stepwise screening of two libraries of chicken genomic DNA fragments. The first genomic clone was isolated by using a cloned cDNA containing alpha 2 collagen DNA sequences as hybridization probe. The other clones were obtained by a sequence of screenings using defined fragments of the successive genomic clones as hybridization probes. Several types of experiments indicated that the DNA of these clones are truly overlapping and span 55 kilobase pairs of contiguous DNA sequences in the chicken genome. Sequence analysis of small DNA segments of some of these clones confirm that they contain coding sequences which specify alpha 2 collagen. Electron microscopic analysis of hybrids between type I alpha 2 collagen mRNA and the overlapping genomic clones indicates that the chicken alpha 2 collagen gene has a length of at least 37 kilobases, about 7.4 times longer than the corresponding translatable cytoplasmic mRNA. The coding information for alpha 2 collagen is distributed in more than 50 coding sequences which are interrupted by intervening sequences of various sizes. The structure of the gene implies that the conversion of precursor RNA to mature mRNA for alpha 2 collagen includes at least 50 splicing events.