Restriction enzyme analysis of partially transformation-defective mutants of acute leukemia virus MC29

FH3, a v-myc avian retrovirus with limited transforming ability

We have isolated a new acute avian transforming virus which contains the oncogene myc. This virus, designated FH3, was isolated after injection of a 10-day-old chick embryo with avian leukosis virus. While FH3 shares many properties with other v-myc-containing avian retroviruses, it also has several unique properties. The primary target for transformation in vitro is chicken macrophages; infection of chicken fibroblasts does not lead to complete morphological transformation. FH3 also exhibits a limited host range, in that Japanese quail macrophages and fibroblasts are infected but are not completely transformed. FH3 induces in vivo a limited tumor type if injected into 10-day-old chick embryos; only a cranial myelocytoma, which does not appear to be metastatic, can be detected. The v-myc gene of FH3 is expressed predominantly as a P145 Gag-Myc protein which is encoded by a ca. 8-kilobase genomic RNA. This FH3-encoded polyprotein is localized in the nucleus of all infected cells, whether or not they are transformed.

A small deletion in the carboxy terminus of the viral myc gene renders the virus MC29 partially transformation defective in avian fibroblasts

In order to characterize the role of the carboxy terminus of the viral myc protein in the transformation of avian fibroblasts and macrophages, several Bal31 deletion mutants were created which removed varying portions of the carboxy terminus of the myc protein. Only one such mutant, S90.9, which had lost nine amino acids of myc retained biological activity when tested in macrophages and fibroblasts. This mutant transformed avian macrophages in a manner similar to that of wild-type, but appeared to be partially transformation defective in fibroblasts. Chicken embryo fibroblast cultures infected with S90.9 exhibited an intermediate phenotype morphologically when compared to wild-type-infected cells. When tested for growth in soft agar, the presence or absence of actin cables and fibronectin on the cell surface, and growth rate, S90.9-infected cells showed intermediate behavior when compared to wild-type or helper virus-infected fibroblasts. These experiments suggest that the carboxy terminus of the myc protein, which is highly basic in nature, is involved in the transformation of avian fibroblasts.

Definition of regions in human c-myc that are involved in transformation and nuclear localization

To study the relationship between the primary structure of the c-myc protein and some of its functional properties, we made in-frame insertion and deletion mutants of the normal human c-myc coding domain that was expressed from a retroviral promoter-enhancer. We assessed the effects of these mutations on the ability of c-myc protein to cotransform normal rat embryo cells with a mutant ras gene, induce foci in a Rat-1-derived cell line (Rat-1a), and localize in nuclei. Using the cotransformation assay, we found two regions of the protein (amino acids 105 to 143 and 321 to 439) where integrity was critical: one region (amino acids 1 to 104) that tolerated insertion and small deletion mutations, but not large deletions, and another region (amino acids 144) to 320) that was largely dispensable. Comparison with regions that were important for transformation of Rat-1a cells revealed that some are essential for both activities, but others are important for only one or the other, suggesting that the two assays require different properties of the c-myc protein. Deletion of each of three regions of the c-myc protein (amino acids 106 to 143, 320 to 368, and 370 to 412) resulted in partial cytoplasmic localization, as determined by immunofluorescence or immunoprecipitation following subcellular fractionation. Some abnormally located proteins retained transforming activity; most proteins lacking transforming activity appeared to be normally located.

MC29 deletion mutants which fail to transform chicken macrophages are competent for transformation of quail macrophages

A number of MC29 mutants with deleted myc genes have been previously characterized. Many of these mutants have been found to be defective for transformation of chicken macrophages in vitro and for tumor induction in chickens. Such mutants are capable of transforming Japanese quail macrophages in vitro and inducing a high incidence of tumors in Japanese quail. Thus, Japanese quail may contain a factor(s) capable of complementing the defective transforming proteins encoded by some deleted v-myc genes.

Definition of regions in human c-myc that are involved in transformation and nuclear localization

To study the relationship between the primary structure of the c-myc protein and some of its functional properties, we made in-frame insertion and deletion mutants of the normal human c-myc coding domain that was expressed from a retroviral promoter-enhancer. We assessed the effects of these mutations on the ability of c-myc protein to cotransform normal rat embryo cells with a mutant ras gene, induce foci in a Rat-1-derived cell line (Rat-1a), and localize in nuclei. Using the cotransformation assay, we found two regions of the protein (amino acids 105 to 143 and 321 to 439) where integrity was critical: one region (amino acids 1 to 104) that tolerated insertion and small deletion mutations, but not large deletions, and another region (amino acids 144) to 320) that was largely dispensable. Comparison with regions that were important for transformation of Rat-1a cells revealed that some are essential for both activities, but others are important for only one or the other, suggesting that the two assays require different properties of the c-myc protein. Deletion of each of three regions of the c-myc protein (amino acids 106 to 143, 320 to 368, and 370 to 412) resulted in partial cytoplasmic localization, as determined by immunofluorescence or immunoprecipitation following subcellular fractionation. Some abnormally located proteins retained transforming activity; most proteins lacking transforming activity appeared to be normally located.

Site-directed mutagenesis of the gag-myc gene of avian myelocytomatosis virus 29: biological activity and intracellular localization of structurally altered proteins

Transfection of chicken embryo cells with pMC29, a plasmid vector containing the sequences for the acute transforming virus MC29, and a cloned transformation-defective helper virus, p delta Mst, resulted in morphological transformation, the synthesis of P110gag-myc (the product of the gag-myc oncogene), and the production of infectious virus. MC29 mutants bearing site-directed deletions within the gag-specific sequences or within the middle portion of the myc sequences efficiently induced transformation of chicken embryo cells in culture. However, variants containing deletions of sequences in the amino-terminal half or carboxy-terminal portion of the myc gene were defective for transformation. The gag-myc proteins encoded by these variants efficiently localized to the cell nucleus. Premature termination mutants were isolated which encoded gag-myc proteins lacking the carboxy-terminal 185 residues; these truncated proteins localized to both the nucleus and the cytoplasm. Deletion of as few as 11 residues within the middle of the myc-specific sequences (residues Ile-239 to Glu-249) significantly reduced the efficiency of chicken hematopoietic cell transformation.

Nucleotide sequence of HBI, a novel recombinant MC29 derivative with altered pathogenic properties

HBI is a recombinant avian retrovirus with novel pathogenic properties that was derived from the myc-containing virus MC29. In contrast to MC29, which causes endotheliomas in chickens, HBI induces lymphoid tumors. The results of molecular cloning and nucleotide sequencing of HBI reported here show that the virus contains sequences derived from both c-myc and ring-neck pheasant virus, in addition to MC29. The 3' half of the myc gene was largely replaced by c-myc sequences, and most of the long terminal repeat and gag regions were replaced by ring-neck pheasant virus sequences. The long terminal repeat contained a triplicate sequence which was homologous to the core enhancer sequence of the simian virus 40 72-base-pair repeat. The significance of these changes in relation to the unusual biological properties of the virus are discussed.

Molecular analysis of myc gene mutants

We describe the generation and characterization of a series of deletion mutants of the avian acute leukaemia virus MC29 which allow the study of the function of the myc in transformation of quail embryo fibroblasts in vitro and tumour induction in vivo. These mutants, which are deleted in the 3' portion of the myc gene, fail to transform macrophages in vitro or induce tumours in vivo but are still able to transform morphologically fibroblasts. From one of these mutants a 'recovered' MC29 virus was generated which, like wild type MC29, transformed fibroblasts and macrophages in vitro. When tested in vivo this virus induced lymphomas of T and B cells rather that the endotheliomas induced by wild type MC29. This system allows us to investigate another question which is the mechanism by which the virus (or oncogene it contains) preferentially transforms one cell type.

Nucleotide sequence of a transduced myc gene from a defective feline leukemia provirus

The nucleotide sequence of a feline v-myc gene and feline leukemia virus (FeLV) flanking regions was determined. Both the nucleotide and predicted amino acid sequences are very similar to the murine and human c-myc genes (ca. 90% identity). The entire c-myc coding sequence is represented in feline v-myc and replaces portions of the gag and env genes and the entire pol gene. The coding sequence is in phase with the gag gene reading frame; v-myc, therefore, appears to be expressed as a gag-myc fusion protein. Viral sequences at the 3' myc-FeLV junction begin with the hexanucleotide CTCCTC, which is also found at the 3' fes-FeLV junction of both Gardner-Arnstein and Snyder-Theilen feline sarcoma viruses. These similarities suggest that some sequence specificity may exist for the transduction of cellular genes by FeLV. Feline v-myc lacks a potential phosphorylation site at amino acid 343 in the putative DNA-binding domain, whereas both human and murine c-myc have such sites. Avian v-myc has lost a potential phosphorylation site which is present in avian c-myc five amino acids from the potential mammalian site. If these sites are actually phosphorylated in normal c-myc proteins, their loss may alter the DNA-binding affinity of v-myc proteins.

Immunological analysis of v-myc gene products using antibodies against a myc-specific synthetic peptide

Rabbit antisera were prepared against a synthetic peptide corresponding to the carboxyterminal amino acid sequences of the transforming protein p110gag-myc of avian oncovirus MC29. Analysis of immunoprecipitates formed with these sera (anti-mycC) demonstrated that the gag-myc hybrid proteins encoded by the avian leukemia viruses MC29, CMII, and OK10 were recognized by the anti-peptide sera, but not the gag or pol precursor proteins of helper viruses or the MH2-encoded p100gag-mil protein. In cells transformed by OK10 or MH2, putative v-myc proteins of 60K (OK10) and 59/61K (MH2) were also precipitated by anti-mycC. In addition, the anti-peptide sera reacted specifically with the gag-myc proteins encoded by three partially transformation-defective mutants of MC29, td10A, td10C, and td10H, and by MC29 variant HBI.

A recovered avian myelocytomatosis virus that induces lymphomas in chickens: pathogenic properties and their molecular basis

The avian myelocytomatosis virus MC29 induces neoplastic diseases in chicken, including myelocytomas and tumors of kidney and liver, which are due to the action of the v-myc gene. However, MC29 has never been reported to cause lymphoid tumors, the disease associated with activation of the c-myc gene by the insertion of a lymphoid leukosis virus genome. We have analyzed a recovered MC29 virus, HBI, which has a myc gene containing c-myc sequences, acquired by recombination with the cellular gene, and some v-myc sequences. Inoculation of HBI into chickens resulted in lymphoid tumors independent of the bursa. Antigenically these tumors were made up of T and B cells. Molecular analysis showed HBI proviral DNA in 36 of 39 tumors analyzed, with no obvious alteration of c-myc, and the HBI gag-myc fusion protein, p 108, could be detected in tumor cells. These data are discussed in terms of the mechanism of target-cell specificity for transformation by the myc gene.

Avian oncovirus MH2: molecular cloning of proviral DNA and structural analysis of viral RNA and protein

Viral RNA, molecularly cloned proviral DNA, and virus-specific protein of avian retrovirus MH2 were analyzed. The complexity and sequence conservation of the transformation-specific v-myc sequences of MH2 RNA were compared with those of the other members of the MC29 subgroup of acute leukemia viruses, MC29, CMII, and OK10, and with chicken cellular c-myc sequences. All T1 oligonucleotides mapping within the 1.3-kilobase coding region of MC29 v-myc have homologous counterparts in the RNAs of all MC29 subgroup viruses and in c-myc. These counterparts are either identical in composition or altered by single point mutations. Hence, the 47,000-dalton carboxy-terminal sequences of the transforming proteins of these viruses and of the cellular gene product are probably highly conserved but may contain single amino acid substitutions. T1 oligonucleotide mapping of MH2 RNA indicated that the MH2 v-myc sequences map close to the 3' end of viral RNA. A genomic library of an MH2-transformed quail cell line was prepared by using the Charon 4A vector system. By screening with an myc-specific probe, a clone containing the entire MH2 provirus (lambda MH2-1) was isolated. Digestion of cloned DNA with KpnI yielded a 5.1-kilobase fragment hybridizing to both gag- and myc-specific probes. Further restriction mapping of lambda MH2-1 DNA showed that about 1.6 kilobases of the gag gene are present near the 5' end of proviral DNA, and the conserved part of v-myc, i.e., 1.3 kilobases, is present near the 3' end of proviral DNA. These two domains are separated by a segment of at least 1 kilobase of different genetic origin, including additional unique sequences unrelated to virion genes. Tryptic peptide analysis of the gag-related protein of MH2, p100, revealed gag-specific peptides and several unique methionine-containing peptides. One of the latter is possibly shared with the polymerase precursor protein Pr180gag-pol, but no myc-specific peptides, defined for the MC29 protein p110gag-myc, appear to be present in MH2 p100. The data on viral RNA, proviral DNA, and protein of MH2 reveal a unique genetic structure for this virus of the MC29 subgroup and suggest that its v-myc gene is not expressed as a gag-related protein.

Genome structure of HBI, a variant of acute leukemia virus MC29 with unique oncogenic properties

We have analyzed the viral RNA of a variant of avian acute leukemia virus MC29, termed HBI. This virus was isolated during in vitro passage of a partially transformation-defective (td) mutant of MC29 (td10H-MC29) in chicken macrophages. While td10H-MC29 has a reduced ability to transform macrophages in vitro or to induce tumors in vivo, HBI-MC29 transforms macrophages efficiently and induces in vivo a high incidence of lymphoid tumors. Electrophoretic analysis of HBI-MC29 genomic RNA revealed that it has a complexity of 5.7 kilobases, like the RNA of wild-type (wt) MC29, and that it is 0.6 kilobases longer than the 5.1-kilobase RNA of the deletion mutant td10H-MC29. Analysis of the viral RNAs of two clonal isolates of HBI-MC29 by T1 oligonucleotide fingerprinting showed that sequences from the viral transformation-specific region, v-myc, which are deleted in td10H RNA, are present in HBI RNA. Moreover, hybridization of HBI RNA to molecularly cloned subgenomic fragments of wtMC29 proviral DNA, followed by fingerprint analysis of hybridized RNA, showed that the entire v-myc-specific RNA sequences defined previously are present. Hybridization to cloned DNA of the normal chicken locus c-myc shows a close relationship between HBI v-myc RNA and c-myc DNA, especially in the sequences which were deleted from td10H-MC29. T1 oligonucleotide maps of HBI and td10H RNAs were prepared and compared. Total conservation of the oligonucleotide pattern is observed in the overlapping v-myc regions, while the partial structural genes gag and env show some variations, most of which can be directly proven to be due to point mutations or recombination with helper viral RNAs that were analyzed in parallel. Recombination of td10H-MC29 with c-myc, followed by recombinational and mutational changes in the structural genes during passage with helper virus, could be a possible explanation for the origin of HBI.

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.