Inversion of a chicken ets-1 proto-oncogene segment in avian leukemia virus E26.

The segment of the avian leukemia virus E26 genome near the termination of the p135gag-myb-ets open reading frame contains an inversion of the chicken ets-1 sequence. The inversion contains at least 41 bp and may be as large as 46 bp. This results in the replacement of 13 amino acids of chicken ets-1, with 16 amino acids derived from reverse complement of the normal ets-1 coding strand or read-through into E26 env sequences. At least 13 of these codons are specified by the inverted ets sequences. This represents the first reported occurrence of inverted oncogene sequences in a natural retrovirus. The inverted ets sequences are immediately followed by sequences homologous to the Rous sarcoma virus Prague B env gene. Since the E26 env sequence is more closely related to subgroup B avian retroviruses than to avian retroviruses from subgroups A, C, D, or E, the progenitor of E26 was a virus belonging to avian retrovirus subgroup B.     

Transduction of c-myb into avian myeloblastosis virus: locating points of recombination within the cellular gene.

The oncogene (v-myb) of avian myeloblastosis virus apparently arose by transduction of nucleotide sequences from a cellular gene (c-myb). In c-myb the nucleotide sequences that formed v-myb exist at seven distinct regions separated by nontransduced stretches of sequence that are flanked by eucaryotic splice signals. By contrast, the sequences at the outside boundaries of the transduced region of c-myb do not resemble splice sites. We mapped the nucleotide sequences that are homologous to the ends of v-myb with respect to the exons and introns of c-myb. The results indicate that the leftward recombination between c-myb and the transducing retrovirus occurred within an intron of the cellular gene, whereas the rightward recombination took place in an exon of c-myb. Transduction of c-myb sequences may therefore have involved a DNA rearrangement.     

Phosphorylation of the nonstructural proteins encoded by three avian acute leukemia viruses and by avian fujinami sarcoma virus.

The gag gene-related, nonstructural proteins of three avian acute leukemia viruses (namely, myelocytomatosis viruses MC29 and CMII and avian erythroblastosis virus) and of avian Fujinami sarcoma virus (FSV) isolated by immunoprecipitation from cellular lysates with anti-gag serum were shown to be phosphoproteins in vivo. The specific 32P radioactivity of the nonstructural proteins of MC29, CMII, and FSV was significantly higher than that of helper viral, intracellular gag proteins. Two of these proteins, i.e., the 140,000-dalton FSV and the 110,000-dalton MC29 proteins, were also phosphorylated in vitro by a kinase activity associated with immunocomplexes. This kinase activity is either separated from these proteins or inactivated by incubation of cellular lysates with normal serum followed by adsorption to staphylococcal protein A or sedimentation at 100,000 x g or both. It remains to be resolved whether the 110,000-dalton MC29 and 140,000-dalton FV proteins, in addition to being substrates for phosphorylation, also have intrinsic kinase activity.     

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.     

Transformation of Brown Leghorn chicken embryo fibroblasts by avian myeloblastosis virus proviral DNA.

Brown Leghorn chicken embryo fibroblasts were transfected with a mixture of avian myeloblastosis virus (AMV) and myeloblastosis-associated virus type 1 (MAV1) proviral DNA purified from lambda-Charon 4A recombinant clones. A transformed cell line (T1AM) able to grow without anchorage in semisolid medium was obtained. The presence of both proviral AMV and MAV sequences was detected in T1AM DNA by hybridization with v-myb- and MAV1-specific probes. Altered AMV and MAV1 proviral genomes were found in T1AM genome. Characterization of the RNA species expressed in transformed cells showed that in addition to a 2.5-kilobase (kb) putative subgenomic v-myb-specific RNA, three other myb-containing RNAs (9.4, 8.4, and 7.0 kb) were present in T1AM cells. No AMV genomic RNA was detected. Also, a new 5.0-kb MAV1-specific RNA species was expressed in transformed cells in addition to MAV1 genomic RNA species (7.8 kb). No infectious AMV virions are released by T1AM cells. Chicken embryo fibroblasts infected by T1AM-released virions contained and expressed all MAV1 sequences detected in T1AM transformed cells but did not express any transformation parameter. These results indicated that the presence of AMV proviral sequences in T1AM cells is responsible for their transformed phenotype.     

Expression of endogenous avian myeloblastosis virus information in different chicken cells.

Uninfected chicken cells were found to contain endogenous avian myeloblastosis virus (AMV)-specific information. Different tissues from chicken embryos and chickens expressed different amounts of the AMV-specific information. The endogenous AMV-related RNA was most abundant in bone marrow cells, which contained about 20 copies per cell. About 5 to 10 copies of AMV endogenous RNA per cell were found in embryonic yolk sac cells and bursa cells. The spleen, muscle, liver, and kidney cells of chickens and the fibroblasts of chicken embryos contained about two copies per cell. The amounts of AMV endogenous RNA in bone marrow, yolk sac, and bursa varied with age. From 19-day-old embryos to 2-week-old chickens, the bone marrow contained 20 copies of AMV RNA per cell. Bone marrow cells from 2-year-old chickens contained five copies per cell. Yolk sac cells of 10-day-old embryos and 1-day-old chickens were found to contain two copies per cell, whereas in 15- to 17-day-old embryos, these cells contained 5 to 10 copies. These results indicate that the level of endogenous AMV expression correlates with the development of granulopoiesis of the chicken hemopoietic system. The results of experiments on the thermostability of RNA-DNA hybrids indicated that the endogenous AMV RNA is closely related to viral AMV RNA. The expression of endogenous AMV information is independent of the activity of the chick helper factor. This endogenous AMV information is expressed as 20 to 21S RNA in both bone marrow and yolk sac cells.     

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.     

Subcellular localization and immunological detection of proteins encoded by the vir locus of Bordetella pertussis

The DNA sequence of the central regulatory locus vir of Bordetella pertussis predicts that three gene products, BvgA, BvgB, and BvgC, are encoded. Features of the predicted primary structures of these proteins and their homology to other two-component systems suggest that BvgA is located in the cytoplasm, BvgB is located in the periplasm, and BvgC spans the inner membrane. We have used gene fusions to the phoA and lacZ genes of Escherichia coli to investigate the subcellular localization and membrane topology of these proteins. PhoA fusion proteins were also purified and used to raise antibodies that allowed visualization of the vir-encoded polypeptides by Western immunoblotting. Our results have largely confirmed the predictions of the DNA sequence, with the exception that BvgB and BvgC were found to constitute one larger protein that was homologous to the sensor class of two-component systems. We propose that this protein be named BvgS (for sensor) and that its gene be named bvgS.     

Acquisition of new DNA sequences after infection of chicken cells with avian myeloblastosis virus

DNA-RNA hybridization studies between 70S RNA from avian myeloblastosis virus (AMV) and an excess of DNA from (i) AMV-induced leukemic chicken myeloblasts or (ii) a mixture of normal and of congenitally infected K-137 chicken embryos producing avian leukosis viruses revealed the presence of fast- and slow-hybridizing virus-specific DNA sequences. However, the leukemic cells contained twice the level of AMV-specific DNA sequences observed in normal chicken embryonic cells. The fast-reacting sequences were two to three times more numerous in leukemic DNA than in DNA from the mixed embryos. The slow-reacting sequences had a reiteration frequency of approximately 9 and 6, in the two respective systems. Both the fast- and the slow-reacting DNA sequences in leukemic cells exhibited a higher T_m (2 C) than the respective DNA sequences in normal cells. In normal and leukemic cells the slow hybrid sequences appeared to have a T_m which was 2 C higher than that of the fast hybrid sequences. Individual non-virus-producing chicken embryos, either group-specific antigen positive or negative, contained 40 to 100 copies of the fast sequences and 2 to 6 copies of the slowly hybridizing sequences per cell genome. Normal rat cells did not contain DNA that hybridized with AMV RNA, whereas non-virus-producing rat cells transformed by B-77 avian sarcoma virus contained only the slowly reacting sequences. The results demonstrate that leukemic cells transformed by AMV contain new AMV-specific DNA sequences which were not present before infection.     

Generation of avian myeloblastosis virus structural proteins by proteolytic cleavage of a precursor polypeptide.

The four major internal structural proteins (the group-specific antigens) of avian myeloblastosis virus are formed by sequential cleavage of a precursor polypeptide with M_r = 76,000 (Pr76). The evidence for this conclusion is based on analysis of immune precipitates from lysates of AMV⁴-infected cells treated with a multivalent antiserum directed against these proteins. Sodium dodecyl sulfate gel electrophoresis of such immune precipitates from cells pulse-labeled with [³⁵S]-methionine reveals five metabolically unstable radioactive polypeptides. These polypeptides behave kinetically as precursors to virion proteins. Double-label ion-exchange chromatography of tryptic digests of the unstable polypeptides demonstrates that the largest precursor, Pr76, contains the amino acid sequences of all four virion proteins. It appears not to contain the sequence of the fifth and smallest internal virion protein. The four smaller precursors are intermediate cleavage products of Pr76.The arrangement of the virion proteins in Pr76 was determined by labeling cells shortly after inhibiting polypeptide chain initiation. The relative amounts of radioactivity both in completed virion proteins and in the tryptic peptides of Pr76 implies the same order for three of the four proteins. The exact position of one protein remains uncertain.On the basis of these experiments, we propose a cleavage pathway for the generation of the structural proteins of AMV. We also demonstrate that cleavage of precursors can proceed in crude extracts of AMV-infected cells. This proteolysis, while resistant to several protease inhibitors, is completely blocked by addition of agents that disrupt membranes.     

Subcellular localization of avian sarcoma virus and human immunodeficiency virus type 1 integrases.

The composition and subcellular trafficking of subviral preintegration complexes are reported to vary among the different retroviruses. The process by which the avian sarcoma virus (ASV) preintegration complex gains access to target chromatin remains unknown. Here we report that ASV integrase (IN) expressed as a fusion to beta-galactosidase accumulates in the nuclei of transfected COS-1 cells. In contrast, human immunodeficiency type 1 (HIV-1) IN-beta-galactosidase fusions expressed similarly are predominantly cytoplasmic. To identify the region of ASV IN that specifies nuclear localization, various subdomains of the protein were expressed as beta-galactosidase fusions and their subcellular locations were assessed cytochemically and by indirect immunofluorescence. These analyses showed that the ASV IN protein possesses a functional nuclear localization signal that spans amino acids 206 to 235 and displays limited homology with known nuclear transport signals.     

Isolation of the proviral coding strand of avian myeloblastosis virus from leukemic chicken myeloblast by affinity chromatography.

The coding strand of the integrated proviral DNA of avian myeloblastosis virus (AMV) was isolated from the DNA of leukemic chicken myeloblast. The three-step isolation procedure employed a combination of affinity chromatography with Sepharose-linked RNA, nucleic acid hybridization, and hydroxypatite chromatography techniques. At each step of purification the product was analyzed for the enrichment of AMV coding strand by hybridization with AMV RNA. The final product was the coding strand of the AMV DNA (90% pure). These results show that such a procedure can be used for the isolation and analysis of a specific structural gens of eukaryotic cells.