Your search keyword '"Alpharetrovirus analysis"' showing total 77 results

1. Base-sequence relationships between avian ribonucleic acid endogenous and sarcoma viruses assayed by competitive ribonucleic acid-deoxyribonucleic acid hybridization.

Author

Wright SE and Neiman PE

Subjects

Animals, Base Sequence, Binding, Competitive, Chick Embryo, Chickens, Chromosomes, Culture Techniques, Digestive System analysis, Genes, Germ-Free Life, Haploidy, Kinetics, Models, Chemical, Nucleic Acid Hybridization, Phenotype, Tritium, Virus Cultivation, Alpharetrovirus analysis, Avian Sarcoma Viruses analysis, DNA analysis, Helper Viruses analysis, Nucleotides analysis, RNA, Viral analysis

Published

1974

2. The terminal oligonucleotides of avian tumor virus RNAs are genetically linked.

Author

Wang LH, Duesberg PH, Robins T, Yokota H, and Vogt PK

Subjects

Alpharetrovirus analysis, Alpharetrovirus classification, Base Sequence, Oligonucleotides analysis, Poly A analysis, RNA, Viral analysis, Recombination, Genetic, Ribonucleases metabolism, Alpharetrovirus genetics, Genetic Linkage, Oligonucleotides genetics, RNA, Viral genetics

Published

1977

3. Avian oncovirus MH2: preferential growth in macrophages and exact size of the genome.

Author

Hu SS, Duesberg PH, Lai MM, and Vogt PK

Subjects

Alpharetrovirus analysis, Animals, Chick Embryo, Coturnix, Defective Viruses analysis, Fibroblasts microbiology, Helper Viruses analysis, Helper Viruses growth & development, Molecular Weight, Virus Replication, Alpharetrovirus growth & development, Defective Viruses growth & development, Macrophages microbiology, RNA, Viral analysis

Published

1979

4. Oligonucleotide fingerprinting with RNA tumor virus RNA.

Author

Beemon KL

Subjects

Alpharetrovirus analysis, Alpharetrovirus genetics, Base Sequence, Gammaretrovirus analysis, Genes, Viral, RNA, Viral genetics, Recombination, Genetic, Retroviridae genetics, Transfection, Visna-maedi virus analysis, Oligonucleotides analysis, RNA, Viral analysis, Retroviridae analysis

Published

1978

5. Continuous tissue culture cell lines derived from chemically induced tumors of Japanese quail.

Author

Moscovici C, Moscovici MG, Jimenez H, Lai MM, Hayman MJ, and Vogt PK

Subjects

Alpharetrovirus analysis, Alpharetrovirus growth & development, Animals, Avian Sarcoma Viruses growth & development, Cell Division, Fibroblasts, Fibrosarcoma microbiology, Fibrosarcoma pathology, Glycoproteins analysis, Hexoses metabolism, Methylcholanthrene, Neoplasm Transplantation, Viral Proteins analysis, Virus Replication, Cell Line, Coturnix, Fibrosarcoma chemically induced

Abstract

Several continuous tissue culture cell lines were established from methylcholanthrene-induced fibrosarcomas of Japanese quail. The lines consist either of fibroblastic elements, round refractile cells or polygonal cells. They show transformed characteristics in agar colony formation and hexose uptake, and most are tumorigenic. Their cloning efficiency in plastic dishes is not increased over that of normal quail embryo fibroblasts. The quail tumor cell lines do not produce endogenous avian oncoviruses and fail to complement the Bryan high titer strain of Rous sarcoma virus; those tested lack the p27 protein of avian oncoviruses. Most of the cell lines are susceptible to subgroup A avian sarcoma viruses, but are relatively resistant to viruses of subgroups C, E and F as compared to normal quail embryo fibroblasts.

Published

1977

6. Chromatographic analyses of isoaccepting tRNAs from avian tumor viruses.

Author

Taylor MW, Wang S, Kothari RM, and Hung PP

Subjects

Amino Acyl-tRNA Synthetases metabolism, Animals, Arginine metabolism, Aspartic Acid metabolism, Carbon Radioisotopes, Cell Transformation, Neoplastic, Cell-Free System, Chick Embryo, Chickens, Chromatography, Culture Techniques, Fibroblasts, Liver analysis, Liver enzymology, Lysine metabolism, Methionine metabolism, RNA, Neoplasm analysis, RNA, Transfer metabolism, Tritium, Alpharetrovirus analysis, Avian Sarcoma Viruses analysis, RNA, Transfer analysis, RNA, Viral analysis, Satellite Viruses analysis

Abstract

Low-molecular-weight RNA from transforming viruses (Rous sarcoma virus-Rous-associated virus 1, Schmidt-Ruppin strain of Rous sarcoma virus, and sarcoma-B(77)), from nontransforming viruses (Rous-associated virus 1 and sarcoma-NTB(77)), and from chicken liver, chicken embryo fibroblast, and Rous sarcoma virus-Rous-associated virus 1-transformed chicken embryo fibroblast was isolated and purified. To determine if there are modified, qualitatively or quantitatively different isoaccepting species of tRNA in these avian sarcoma viruses as compared with the cell of virus origin, chicken embryo fibroblast or normal chicken liver, methionyl-, arginyl-, and lysyl-tRNA (with high amino acid acceptance activity), and aspartyl- and glutamyl-tRNA from viral-trans-formed cells (with low viral amino acid acceptance activity) were co-chromatographed on reversed phase-5 chromatography columns, and elution profiles were compared. Although in each case the elution profile between a particular viral and host cell tRNA differed quantitatively, there was no qualitative difference in the profiles of corresponding tRNAs from either transforming or nontransforming viruses examined. Minor quantitative differences in the elution profiles might be a reflection of the metabolic state of the cells, since all evidence points to acceptor activity being of host rather than viral origin. Since, with the exception of selective packaging of methionyl-tRNA (IV) species by both transforming and nontransforming viruses, no selectivity was found for isoacceptor species of other tRNAs, it seems that such preferential packaging of methionyl-tRNA (IV) species has no bearing on the event of viral transformation.

Published

1974

7. Structure and phosphorylation of the Fujinami sarcoma virus gene product.

Author

Pawson T, Kung TH, and Martin GS

Subjects

Alpharetrovirus physiology, Peptides analysis, Phosphoproteins physiology, Phosphorylation, Viral Proteins physiology, Alpharetrovirus analysis, Cell Transformation, Neoplastic, Phosphoproteins analysis, Viral Proteins analysis

Abstract

The Fujinami avian sarcoma virus (FSV) transforming gene product, P140, is a fusion protein which contains both gag-related and FSV-specific methionine-containing tryptic peptides. The virion protease p15 cleaved p140 into two fragments: an N-terminal 33K fragment which contained all but one of the gag-related tryptic peptides and a C-terminal 120K fragment which contained all of the FSV-specific tryptic peptides. The 33K gag-related fragment from P140 phosphorylated in FSV-transformed cells contained only phosphoserine, whereas the 120K C-terminal FSV-specific fragments contained both phosphoserine and phosphotyrosine. P140 isolated from cells infected at the nonpermissive temperature with an isolate of FSV which is temperature sensitive for transformation had a normally phosphorylated 33K fragment, but a hypophosphorylated 120K fragment deficient in both phosphotyrosine and phosphoserine. When P140 was immunoprecipitated from cells and phosphorylated in vitro at tyrosine residues in the immune complex kinase reaction, only the FSV-specific fragment was labeled. These data define the structure of FSV P140 and locate the phosphorylated amino acids within the two regions of the polypeptide.

Published

1981

8. DNA intermediates of avian RNA tumor viruses.

Author

Taylor JM

Subjects

Alpharetrovirus genetics, Animals, Cell Transformation, Neoplastic, Cell Transformation, Viral, Cells, Cultured, Genes, Viral, Nucleic Acid Conformation, RNA, Viral analysis, RNA, Viral biosynthesis, Transcription, Genetic, Transfection, Alpharetrovirus analysis, DNA, Viral biosynthesis, DNA, Viral metabolism

Published

1979

9. Distribution of envelope-specific and sarcoma-specific nucleotide sequences from different parents in the RNAs of avian tumor virus recombinants.

Author

Wang LH, Duesberg P, Mellon P, and Vogt PK

Subjects

Base Sequence, Chromosome Mapping, Crossing Over, Genetic, Oligonucleotides analysis, Alpharetrovirus analysis, DNA, Viral analysis, Genes, Recombination, Genetic

Abstract

The distribution of leukosis-virus- and sarcoma-virus-specific oligonucleotide sequences was investigated in the RNAs of viral recombinants selected for an envelope gene (env) from a leukosis parent and a sarcoma gene (src) from a sarcoma parent. For this purpose 20 to 30 RNase-T1-resistant oligonucleotides were chemically analyzed and mapped within the 10,000 nucleotides of each viral RNA relative to the 3'-poly(A) end. The resulting oligonucleotide maps were compared. Proceeding from the 3' to the 5' end, the maps of four recombinants contained: (i) in a segment of 2000 nucleotides, three to four src-specific oligonucleotides, so identified because they were shared only with the sarcoma parent; and (ii) in a segment of 8000 nucleotides, 20 oligonucleotides shared with the leukosis parent, of which six to seven were also shared with the sarcoma parent. Two other recombinants contained: (1) in a segment of 2000 (one) or 3000 (the other) nucleotides, three src-specific oligonucleotides; (ii) in a segment of 3000 (one) or 2000 (the other) nucleotides, five (one) or four (the other) oligonucleotides, all or some of which are env-specific, because they were shared with the leukosis parent; (iii) in a segment of 5000 nucleotides (both), 11 functionally unidentified sarcoma-virus-derived oligonucleotides, of which seven were also shared with the leukosis parent. The map locations of parental oligonucleotides were not changed in recombinants and all viral strains tested shared six to eight highly conserved oligonucleotides at equivalent map locations. The partial map -env-src-poly(A) emerged from the analyses of these recombinants.

Published

1976

10. Biochemical properties of oncornavirus polypeptides.

Author

Bolognesi DP, Huper G, Green RW, and Graf T

Subjects

Alpharetrovirus analysis, Carbohydrates analysis, Chromatography, Gel, Electrophoresis, Polyacrylamide Gel, Gammaretrovirus analysis, Glycoproteins isolation & purification, Guanidines, Hydrogen-Ion Concentration, Indicators and Reagents, Leukemia Virus, Feline analysis, Molecular Weight, Oncogenic Viruses ultrastructure, Species Specificity, Spectrophotometry, Ultraviolet, Urea, Oncogenic Viruses analysis, Viral Proteins isolation & purification

Published

1974

11. Chicken leukosis virus genome sequences in DNA from normal chick cells and virus-induced bursal lymphomas.

Author

Neiman PE, Purchase HG, and Okazaki W

Subjects

Alpharetrovirus analysis, Animals, Avian Leukosis Virus growth & development, Avian Sarcoma Viruses analysis, Base Sequence, Cell Transformation, Neoplastic, Chickens, Iodine Radioisotopes, Lymphoma analysis, Lymphoma etiology, Nucleic Acid Hybridization, Satellite Viruses analysis, Avian Leukosis analysis, Avian Leukosis Virus analysis, Bursa of Fabricius analysis, DNA analysis, DNA, Neoplasm analysis, RNA, Viral analysis

Abstract

Genome sequences of two recent field isolates of avian leukosis viruses in the DNA of normal and neoplastic chicken cells were studied by DNA-RNA hybridization under conditions of DNA excess. Comparisons were made between 60-70S RNA from these viruses and that of a chicken endogenous type C virus (RAV-0), and of a series of "laboratory" leukosis and sarcoma viruses, by competitive hybridization analysis. A minimum of 18% of the genome sequences of both ALV isolates detected in DNA from lymphomas they induced were not detected in normal chicken DNA. The vast majority of the fraction of RNA sequences from ALV which do form hybrids with normal chick DNA appear to be reacting with the endogenous provirus of RAV-0. The genomic representation of a variety of avian leukosis and sarcoma viruses in normal chicken cells could not be distinguished by these methods (except that 13% of the RAV-0 genome was not shared with any of the other viruses). In contrast, the portion of the ALV genome exogenous to the normal chicken geome showed significant divergence from that of two sarcoma viruses (Pr RSV-C and B-77). The increased hybridization of ALV RNA with lymphoma DNA was used to detect the appearance of ALV specific sequences in the bursa of Fabricius following infection.increased hybridization was correlated with both the time after infection and the extent of replacement of the bursa by lymphoma. About one half of the increase in hybridization preceded histologic evidence of transformation.

Published

1975

12. Purification of DNA complementary to the env gene of avian sarcoma virus and analysis of relationships among the env genes of avian leukosis-sarcoma viruses.

Author

Tal J, Fujita DJ, Kawai S, Varmus HE, and Bishop JM

Subjects

Alpharetrovirus analysis, Base Sequence, Humans, Infant, Newborn, Mutation, Nucleic Acid Conformation, Nucleic Acid Hybridization, RNA, Viral analysis, Alpharetrovirus metabolism, Avian Sarcoma Viruses analysis, DNA, Viral isolation & purification, Genes, Glycoproteins biosynthesis, Viral Proteins biosynthesis

Abstract

The env gene of avian leukosis-sarcoma viruses encodes a glycoprotein that determines the host range and surface antigenicitiy of virions. We have purified radioactive DNA (cDNAgp) complementary to at least a portion of the env gene for viral subgroups A and C; complementary DNA was synthesized with purified virions of wild-type avian sarcoma virus, and RNA from a mutant with a deletion in env was used to select DNA specific to env by molecular hybridization. The genetic complexity of cDNAgp for subgroup A (ca. 2,000 nucleotides) was sufficient to represent the entire deletion and most or all of the env cistron. The deletions in env in two independently isolated strains of virus (Bryan and rdNY8SR) overlap, and cDNAgp represents nucleotide sequences common to both deletions. By contrast, we could detect no overlap between deletions in env and deletions in the adjacent viral gene src. Laboratory stocks of viral subgroups A, B, C, D and E do not contain detectable amounts of env deletions when tested by molecular hybridization; hence, segregation of deletions in env is a less frequent event that the segregation of deletions in the viral transforming gene src (Vogt, 1971). We found extensive homology among the nucleotide sequences encoding the env genes of virus strains indigenous to chickens (subgroups A, B, C, D, and E) although subgorups B, D and E appear to differ slightly from subgroups A and C at the env locus. By contrast, viruses obtained from pheasant cells (subgroups F and G) have env genes with little or no relationship to env genes of chikcen viruses. According to available data, viruses of subgroup F arose by recombination between an avarian sarcoma virus and viral genes in the genome of ring-necked pheasants, whereas subgroup G viruses may be entirely endogenous to golden pheasants.

Published

1977

13. Purification and properties of a fifth major viral gag protein from avian sarcoma and leukemia viruses.

Author

Pepinsky RB and Vogt VM

Subjects

Alpharetrovirus analysis, Chromatography, Ion Exchange, Electrophoresis, Polyacrylamide Gel, Gene Products, gag, Molecular Weight, Solubility, Avian Leukosis Virus analysis, Avian Myeloblastosis Virus analysis, Viral Proteins isolation & purification

Abstract

We have developed procedures for the purification of a 6,000-dalton protein from avian myeloblastosis virus. This protein is a major component of avian myeloblastosis virus, accounting for over 7% of total protein, and thus is equimolar with the other internal structural proteins in virions. As described in the accompanying paper (Hunter et al., J. Virol. 45:885-888, 1983), the results of N-terminal amino acid sequence analysis identify the protein as a product of the gag gene. We suggest denoting this protein as p10, according to nomenclature that is already in use for a previously identified but poorly defined low-molecular-weight protein or proteins of avian sarcoma and leukemia viruses. In virions p10 appears to be located between the core and the membrane. Several of its properties may explain why p10 has not been characterized previously. Among these are its abnormal amino acid composition, its solubility under conditions where most proteins are fixed into sodium dodecyl sulfate-polyacrylamide gels, and the variability in its electrophoretic migration in different avian sarcoma viruses.

Published

1983

14. DNA related to the transforming gene(s) of avian sarcoma viruses is present in normal avian DNA.

Author

Stehelin D, Varmus HE, Bishop JM, and Vogt PK

Subjects

Animals, Avian Sarcoma Viruses analysis, Biological Evolution, Birds, Chickens, Ducks, Nucleic Acid Denaturation, Nucleic Acid Renaturation, Quail, Alpharetrovirus analysis, Cell Transformation, Neoplastic, DNA analysis, DNA, Viral analysis, Genes, Dominant

Published

1976

15. RNA specific for the transforming component of avian erythroblastosis virus strain R.

Author

Kamahora T, Sugiyama H, Nomoto A, Yoshida M, and Toyshima K

Subjects

Animals, Cell Line, Chick Embryo, Fibroblasts, Helper Viruses analysis, Oligonucleotides analysis, Alpharetrovirus analysis, Avian Leukosis Virus analysis, Cell Transformation, Neoplastic, Cell Transformation, Viral, RNA, Viral analysis

Published

1979

16. Peptide analysis of the transformation-specific antigen from avian sarcoma virus-transformed cells.

Author

Brugge J, Erikson E, Collett MS, and Erikson RI

Subjects

Alpharetrovirus analysis, Cell Line, Molecular Weight, Phosphopeptides analysis, Viral Proteins analysis, Alpharetrovirus immunology, Antigens, Viral analysis, Cell Transformation, Neoplastic, Cell Transformation, Viral, Peptides analysis

Abstract

Sera from rabbits bearing tumors induced by avian sarcoma virus (ASV) were ussed to immunopecipitate virus-specific proteins from extracts of chicken, hamster, and field vole cells transformed by ASV. Two virus-specific proteins having molecular weights of 76,000 and 60,000 were found in all cell lines examined. The 76,000-molecular-weight protein, Pr76, is the precursor to the internal core proteins of ASV. The 60,000-molecular-weight (60K) transformation-specific antigen from each cell line was subjected to peptide analysis, using chymotrypsin and Staphylococcus aureus V8 protease. The resulting peptide maps of the 60K protein from the different ASV-infected cell types were similar for each enzyme, strongly suggesting that the 60K protein is virus coded. Two-dimensional analysis of chymotryptic peptides from Pr76 and 60K reveals that 60K is not related to the gs antigen precursor. Radiolabeling of ASV-transformed cells with inorganic phosphate revealed that 60K is phosphorylated in vivo. The 60K proteins isolated from both ASV-transformed chicken and field vole cells were found to contain one tryptic phosphopeptide. The tryptic phosphopeptides of 60K from both cell lines migrated identically upon two-dimensional peptide analyses, and their migration differed from that of the principal phosphopeptide of Pr76.

Published

1978

17. env Gene of chicken RNA tumor viruses: extent of conservation in cellular and viral genomes.

Author

Fujita DJ, Tal J, Varmus HE, and Bishop JM

Subjects

Alpharetrovirus analysis, Animals, Base Sequence, Birds, Chickens, DNA analysis, Nucleic Acid Conformation, Nucleic Acid Denaturation, Nucleic Acid Hybridization, RNA, Viral analysis, Species Specificity, Alpharetrovirus genetics, DNA genetics, Genes, Viral, Glycoproteins genetics, RNA, Viral genetics, Viral Proteins genetics

Abstract

The env gene of avian sarcoma-leukosis viruses codes for envelope glycoproteins that determine viral host range, antigenic specificity, and interference patterns. We used molecular hybridization to analyze the natural distribution and possible origins of the nucleotide sequences that encode env; our work exploited the availability of radioactive DNA (cDNA(gp)) complementary to most or all of env. env sequences were detectable in the DNAs of chickens which synthesized an env gene product (chick helper factor positive) encoded by an endogenous viral gene and also in the DNAs of chickens which synthesized little or no env gene product (chick helper factor negative). env sequences were not detectable in DNAs from Japanese quail, ring-necked pheasant, golden pheasant, duck, squab, salmon sperm, or calf thymus. The detection of sequences closely related to viral env only in chicken DNA contrasts sharply with the demonstration that the transforming gene (src) of avian sarcoma viruses has readily detectable homologues in the DNAs of all avian species tested [D. Stehelin, H. E. Varmus, J. M. Bishop, and P. K. Vogt, Nature (London) 260: 170-173, 1976] and in the DNAs of other vertebrates (D. Spector, personal communication). Thermal denaturation studies on duplexes formed between cDNA(gp) and chicken DNA and also between cDNA(gp) and RNAs of subgroup A to E viruses derived from chickens indicated that these duplexes were well matched. In contrast, cDNA(gp) did not form stable hybrids with RNAs of viruses which were isolated from ring-necked and golden pheasants. We conclude that substantial portions of nucleotide sequences within the env genes of viruses of subgroups A to E are closely related and that these genes probably have a common, perhaps cellular, evolutionary origin.

Published

1978

18. Detection and enumeration of transformation-defective strains of avian sarcoma virus with molecular hybridization.

Author

Stehelin D, Fujita DJ, Padgett T, Varmus HE, and Bishop JM

Subjects

Alpharetrovirus analysis, Alpharetrovirus growth & development, Base Sequence, Cell Line, Genes, Nucleic Acid Hybridization, Nucleotides analysis, RNA, Viral analysis, Alpharetrovirus isolation & purification, Cell Transformation, Neoplastic, Mutation

Published

1977

19. Characterization of avian erythroblastosis virus p75.

Author

Anderson SM and Hanafusa H

Subjects

Acetylglucosamine metabolism, Alpharetrovirus physiology, Animals, Cell Line, Chick Embryo, Coturnix, Phosphorylation, Phosphoserine analysis, Protein Kinases metabolism, Viral Proteins metabolism, Virion metabolism, Alpharetrovirus analysis, Avian Leukosis Virus analysis, Cell Transformation, Neoplastic, Cell Transformation, Viral, Viral Proteins analysis

Published

1982

20. The transforming gene of avian tumor viruses.

Author

Stéhelin D

Subjects

Cell Transformation, Neoplastic, DNA, Neoplasm analysis, DNA, Viral analysis, Genetics, Microbial, Alpharetrovirus analysis, Neoplasms, Experimental etiology, Transformation, Genetic

Published

1976

21. Ultraviolet inactivation of avian sarcoma viruses: biological and biochemical analysis.

Author

Owada M, Ihara S, Toyoshima K, Sugino Y, and Kozai Y

Subjects

Alpharetrovirus analysis, Alpharetrovirus growth & development, Animals, Avian Sarcoma Viruses enzymology, Cell Transformation, Neoplastic, Chick Embryo, Culture Techniques, Ducks, Mutation, RNA, Viral analysis, RNA, Viral radiation effects, RNA-Directed DNA Polymerase metabolism, Radiation Effects, Temperature, Virus Replication, Alpharetrovirus radiation effects, Ultraviolet Rays

Published

1976

22. The nucleotide sequence of an untranslated but conserved domain at the 3' end of the avian sarcoma virus genome.

Author

Czernilofsky AP, DeLorbe W, Swanstrom R, Varmus HE, Bishop JM, Tischer E, and Goodman HM

Subjects

Base Sequence, Cloning, Molecular, DNA Restriction Enzymes, Molecular Weight, Nucleic Acid Hybridization, Alpharetrovirus analysis, DNA, Viral, Genes, Viral

Abstract

The genomes of numerous avian retroviruses contain at their 3' termini a conserved domain denoted "c". The precise boundaries and function of "c" have been enigmas. In an effort to resolve these issues, we determined the sequence of over 900 nucleotides at the 3' end of the genome of the Schmidt-Ruppin subgroup A strain of avian sarcoma virus (ASV). We obtained the sequence from a suitable fragment of ASV DNA that had cloned into the single-stranded DNA phage M13mp2. Computer-assisted analysis of the sequence revealed the following structural features: i) the length of "c" - 473 nucleotides; ii) the 3' terminal domain of src, ending in an amber codon at the 5'boundary of "c"; iii) terminator codons that preclude continuous translation from "c"; iv) suitably located sequences that may serve as signals for the initiation of viral RNA synthesis and for the processing and/or polyadenylation of viral mRNA; v) a repeated sequence that flanks src and that could facilitate deletion of this gene; vi) repeated sequences within "c"; and vii) unexplained homologies between sequences in "c" and sequences in several other nucleic acids, including the 5' terminal domain of the ASV genome, tRNATrp and its inversion, the complement of tRNATrp and its inversion, and the 18S RNA of eukaryotic ribosomes. We conclude that "c" probably does not encode a protein, but its sequence may nevertheless serve several essential functions in viral replication.

Published

1980

23. Type C viral gag gene expression in chicken embryo fibroblasts and avian sarcoma virus-transformed mammalian cells.

Author

Reynolds FH Jr, Hanson CA, Aaronson SA, and Stephenson JR

Subjects

Alpharetrovirus immunology, Animals, Antigens, Viral analysis, Avian Sarcoma Viruses growth & development, Cell Line, Cell Transformation, Neoplastic, Chick Embryo, Culture Techniques, Molecular Weight, Radioimmunoassay, Rats, Retroviridae immunology, Viral Proteins immunology, Alpharetrovirus analysis, Genes, Retroviridae analysis, Viral Proteins analysis

Abstract

Sensitive radioimmunoassays were developed for avian type C viral gag gene-coded proteins. These assays were used to examine the restriction to virus production by avian embryo cells and mammalian cells transformed by avian sarcoma viruses. The results indicate that although a high-molecular-weight primary translational product of the gag gene is expressed, its cleavage and processing are incomplete. Furthermore, analysis of intermediate cleavage products provided information regarding the order of sequences coding for the individual viral proteins within the avian type C viral gag gene.

Published

1977

24. Chicken macrochromosomes contain an endogenous provirus and microchromosomes contain sequences related to the transforming gene of ASV.

Author

Padgett TG, Stubbledield E, and Varmus HE

Subjects

Animals, Avian Leukosis Virus analysis, Base Sequence, Cell Line, Chickens, Karyotyping, Lymphoma, Marek Disease, Nucleic Acid Hybridization, RNA, Viral, Alpharetrovirus analysis, Chromosomes analysis, DNA, Neoplasm analysis, DNA, Single-Stranded analysis, DNA, Viral analysis, Genes

Abstract

Chicken chromosomes from a euploid Marek's lymphoma cell line have been partially fractionated according to size by rate zonal centrifugation in a zonal rotor. DNA-DNA hybridization tests, using unlabeled DNA extracted from gradient fractions and labeled single-stranded, virus-specific DNAs prepared in vitro, indicate that large macrochromosomes harbor the provirus for the endogenous RNA tumor virus of chickens (RAVO), whereas a cellular sequence related to the transforming gene of avian sarcoma virus (ASV) is located in microchromosomes. In support of the method, we have also shown that the single gene for ovalbumin can be assigned to macrochromosomes.

Published

1977

25. Identification and characterization of dimeric and trimeric circular forms of avian sarcoma virus-specific DNA.

Author

Kung HJ, Shank PR, Bishop JM, and Varmus HE

Subjects

Centrifugation, Density Gradient, DNA Restriction Enzymes pharmacology, DNA, Circular isolation & purification, DNA, Viral isolation & purification, Electrophoresis, Agar Gel, Alpharetrovirus analysis, DNA, Circular analysis, DNA, Viral analysis

Published

1980

26. gag-Related polypeptides encoded by replication-defective avian oncoviruses.

Author

Rettenmier CW, Anderson SM, Riemen MW, and Hanafusa H

Subjects

Alpharetrovirus analysis, Alpharetrovirus genetics, Avian Leukosis Virus analysis, Defective Viruses analysis, Helper Viruses analysis, Peptides analysis, Viral Proteins genetics, Avian Leukosis Virus genetics, Defective Viruses genetics, Genes, Viral, Viral Proteins analysis

Abstract

The content of viral structural (gag) protein sequences in polypeptides encoded by replication-defective avian erythroblastosis virus (AEV) and myelocytomatosis virus MC29 was assessed by immunological and peptide analyses. Direct comparison with gag proteins of the associated helper viruses revealed that MC29 110K polypeptide contained p19, p12, and p27, whereas the AEV 75K polypeptide had sequences related only to p19 and p12. Both of these polypeptides contained some information that was unrelated to gag, pol, or env gene products. In addition, no homology was detected between these unique peptides of MC29 110K and AEV 75K. The AEV 75K polypeptide shared strain-specific tryptic peptides with the p19 encoded by its naturally occurring helper virus; this observation suggests that gag-related sequences in 75K were originally derived from the helper viral gag gene. Digestion of oxidized MC29 110K and AEV 75K proteins with the Staphylococcus aureus V8 protease generated a fragment which comigrated with N-acetylmethionylsulfoneglutamic acid, a blocked dipeptide which is the putative amino-terminal sequence of structural protein p19 and gag precursor Pr76gag. This last finding is evidence that the gag sequences are located at the N-terminal end of the MC29 110K and AEV 75K polypeptides.

Published

1979

27. Evidence for crossing-over between avian tumor viruses based on analysis of viral RNAs.

Author

Beemon K, Duesberg P, and Vogt P

Subjects

Electrophoresis, Molecular Weight, Oligonucleotides analysis, Phosphorus Radioisotopes, Polyploidy, Recombination, Genetic, Alpharetrovirus analysis, Crossing Over, Genetic, RNA, Viral analysis

Abstract

The RNAs of several avian tumor virus recombinants that had inherited their focus-forming ability from a sarcoma virus and their host range marker from a leukosis virus were investigated. Electrophoretic analyses showed that the cloned sarcoma virus recombinants contained only size class a RNA, although they had acquired a marker that resided on class b RNA in the leukosis virus parent. Class a RNA of different recombinant clones, derived from the same pair of parental viruses and selected for the same biological markers, differed slightly in electrophoretic mobility from each other and from the parental sarcoma virus. They were also found to have different fingerprints of RNase T1-resistant oligonucleotides. The average complexity of the 60-70S RNA prepared from Prague Rous sarcoma virus of subgroup B was estimated to be 3.5 x 10(6) daltons from the size of 20 RNase T1-resistant oligonucleotides, which represented 3.9% of the RNA and that of a recombinant to be 3.3 x 10(6) daltons from 23 oligonucleotides, which represented 4.7% of the RNA. This result suggests that the genome of wild-type and of recombinant RNA tumor viruses is polyploid. The sum of these observations led us to propose that recombination among avian tumor viruses occurred by crossing-over between homologous pieces of nucleic acid.

Published

1974

28. tRNATrp as primer for RNA-directed DNA polymerase: structural determinants of function.

Author

Cordell B, Swanstrom R, Goodman HM, and Bishop JM

Subjects

Base Sequence, Genes, Viral, Nucleic Acid Conformation, Protein Binding, Structure-Activity Relationship, Transcription, Genetic, Tryptophan, Virus Cultivation, Alpharetrovirus analysis, DNA, Viral biosynthesis, RNA, Transfer metabolism, RNA-Directed DNA Polymerase metabolism

Abstract

The specific interactions between the RNA-directed DNA polymerase of avian oncornavirus and the tRNATrp primer required for initiation of viral DNA synthesis in vitro were examined. Two distinct interactions, stable binding of the tRNATrp to the enzyme and initiation of viral DNA synthesis by the enzyme with tRNATrp as primer, were characterized as to the structure of tRNATrp required. Different structural features of the tRNATrp were shown to be necessary for each type of interaction. The entire primary structure and native conformation of tRNATrp are both required for binding to reverse transcriptase. Fragments of tRNATrp and intact tRNATrp in an altered conformation cannot be bound by the enzyme using an assay which detects high affinity binding between reverse transcriptase and native tRNATrp. In contrast, fragments of the tRNATrp molecule can serve as primers for viral DNA synthesis with normal efficiency as compared to intact tRNATrp. The fragments which initiate transcription must contain a minimum specific nucleotide sequence which extends from the 3' terminus of the tRNATrp through 27 residues of the molecule. This portion of the tRNATrp may be a major structural determinant of specificity in initiation.

Published

1979

29. Use of DNA-DNA annealing to detect new virus-specific DNA sequences in chicken embryo fibroblasts after infection by avian sarcoma virus.

Author

Varmus HE, Heasley S, and Bishop JM

Subjects

Alpharetrovirus enzymology, Alpharetrovirus growth & development, Animals, Base Sequence, Carbon Radioisotopes, Cell-Free System, Cells, Cultured, Chick Embryo, DNA analysis, DNA, Single-Stranded biosynthesis, DNA, Viral biosynthesis, Ducks, Nucleotides metabolism, Phosphorus Radioisotopes, Quail, RNA, Viral, RNA-Directed DNA Polymerase metabolism, Thymidine, Tritium, Alpharetrovirus analysis, DNA, Viral analysis, Fibroblasts analysis, Nucleic Acid Hybridization

Abstract

Labeled, virus-specific DNA synthesized in vitro by the virion-associated polymerase of avian sarcoma virus (ASV) was used to measure virus-specific sequences in cell DNA in three ways: (i) by determining the effect of cell DNA upon the reassociation rate of double-stranded polymerase products; (ii) by measuring the kinetics of annealing of single-stranded polymerase product (cDNA) to cell DNA; or (iii) by measuring the amount of cDNA which anneals to a large excess of cell DNA. With these three assays and modifications of them, we show that fewer than five copies of ASV-specific DNA sequences are present per diploid cell in uninfected chicken embryos; that a two- to several-fold increase in copy number of viral DNA follows infection by ASV; that infection introduces to the cell viral sequences not present before infection; and that DNAs from uninfected Pekin duck and Japanese quail embryos show no homology with DNA synthesized by the ASV polymerase. Some of these results differ from data in a previous report from this laboratory (H. E. Varmus, R. A. Weiss, R. R. Friis, W. Levinson, and J. M. Bishop, 1972) and, in general, reconcile our observations with those from other laboratories.

Published

1974

30. Avian leukosis-sarcoma virus gene expression. Noncoordinate control of group-specific antigens in virus-negative avian cells.

Author

Smith EJ, Stephenson JR, Crittenden LB, and Aaronson SA

Subjects

Alpharetrovirus analysis, Animals, Avian Leukosis Virus growth & development, Avian Leukosis Virus immunology, Avian Myeloblastosis Virus immunology, Cell Line, Cell-Free System, Chick Embryo, Molecular Weight, Peptides analysis, Species Specificity, Viral Proteins analysis, Virus Replication, Alpharetrovirus immunology, Antigens, Viral analysis, Genes, Dominant, Peptides immunology

Published

1976

31. Identification of nucleotide sequences which may encode the oncogenic capacity of avian retrovirus MC29.

Author

Sheiness D, Fanshier L, and Bishop JM

Subjects

Alpharetrovirus analysis, Base Sequence, Cell Line, Defective Viruses genetics, Genes, Viral, Nucleic Acid Conformation, RNA Viruses, Retroviridae genetics, Cell Transformation, Neoplastic, Cell Transformation, Viral, Defective Viruses analysis, Nucleotides analysis, RNA, Viral analysis, Retroviridae analysis

Abstract

The retrovirus strain MC29 induces a variety of tumors in chickens, including myelocytomatosis and carcinomas of the kidney and liver. In addition, the virus can transform cultures of embryonic avian macrophages and fibroblasts. We have characterized the genome of MC29 virus and have identified nucleotide sequences that may encode the oncogenic potential ofthe virus. MC29 virus can replicate only with the assistance of a related helper virus. The defect in replication is apparently a consequence of a deletion in one or more viral genes: the haploid genome of the MC29 virus has a molecular weight of ca. 1.7 X 10(6), whereas the genome of the helper virus MCAV has a molecular weight of ca. 3.1 X 10(6). Although MC29 virus transforms fibroblasts in culture, its genome has no detectable homology with the gene src that is responsible for transformation of fibroblasts by avian sarcoma viruses. We prepared radioactive single-stranded DNA complementary to nucleotide sequences present in the genome of MC29 virus but not in the genome of MCAV (cDNA(MC29)). If they are contiguous, these sequences (ca. 1,500 nucleotides) are sufficiently complex to encode at least one protein. Homologous sequences were not detectable in several strains of avian sarcoma viruses or in an endogenous virus of chickens. Our findings confirm and extend recent reports from other laboratories and lead to the conclusion that MC29 virus may contain a previously unidentified gene(s) that is capable of transforming several distinct target cells. The evolutionary origins of this putative gene and its location on the viral genome can be explored with cDNA(MC29).

Published

1978

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

Author

Bister K and Duesberg PH

Subjects

Base Sequence, Molecular Weight, Nucleic Acid Hybridization, Oligoribonucleotides analysis, Ribonuclease T1, Ribonucleases, Transformation, Genetic, Alpharetrovirus analysis, Avian Leukosis Virus analysis, RNA, Viral

Abstract

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.

Published

1979

33. Chromatographic separation and antigenic analysis of proteins of the oncornaviruses. III. Avian viral proteins with group-specific antigenicity.

Author

Fletcher P, Nowinski RC, Tress E, and Fleissner E

Subjects

Alpharetrovirus analysis, Amino Acids analysis, Chromatography, Gel, Cross Reactions, Electrophoresis, Immunodiffusion, Molecular Weight, Peptides analysis, Trypsin, Viral Proteins analysis, Alpharetrovirus immunology, Antigens, Viral analysis, Viral Proteins immunology

Published

1975

34. Characterization of DNA complementary to nucleotide sequences at the 5'-terminus of the avian sarcoma virus genome.

Author

Friedrich R, Kung HJ, Baker B, Varmus HE, Goodman HM, and Bishop JM

Subjects

Alpharetrovirus metabolism, Base Sequence, Cell Line, DNA, Viral biosynthesis, Nucleic Acid Conformation, Nucleic Acid Hybridization, Oligonucleotides analysis, Poly A analysis, Pyrimidine Nucleotides analysis, RNA, Viral analysis, Transcription, Genetic, Alpharetrovirus analysis, DNA, Single-Stranded analysis, DNA, Viral analysis, Nucleotides analysis

Published

1977

35. A third class of avian sarcoma viruses, defined by related transformation-specific proteins of Yamaguchi 73 and Esh sarcoma viruses.

Author

Ghysdael J, Neil JC, and Vogt PK

Subjects

Alpharetrovirus analysis, Cations, Divalent pharmacology, Isoelectric Point, Molecular Weight, Peptide Fragments analysis, Phosphorylation, Protein Kinases analysis, Species Specificity, Alpharetrovirus classification, Cell Transformation, Viral, Viral Proteins analysis

Abstract

The gag-linked transformation-specific protein (polyprotein) p80 of Esh avian sarcoma virus (ESV) has been compared by tryptic peptide mapping with the homologous protein p90 of Yamaguchi 73 avian sarcoma virus (Y73). p80 of ESV and p90 of Y73 were found to share all four of their major nonstructural, transformation-specific, methionine-containing peptides and to have at least seven cysteine-containing transformation-specific peptides in common. Two nonstructural cysteine-containing peptides unique for ESV p80 and three specific for Y73 p90 were also identified. None of these peptides were found in the transforming gene product pp60src of Rous sarcoma virus (RSV) or in the transformation-specific polyproteins p105 of avian sarcoma virus PRCII (PRCII) or p140 of Fujinami sarcoma virus (FSV). ESV p80 and Y73 p90 are phosphorylated, and their tryptic phosphopeptides appear to be identical. In each polyprotein two major phosphopeptides were demonstrated, one containing phosphoserine, the other phosphotyrosine. The latter serves as phosphoacceptor for the protein kinase activities (ATP:protein phosphotransferase, EC 2.7.1.37) associated with p80 and p90. These protein kinase activities were found to be functionally indistinguishable but could be easily distinguished from the activities associated with PRCII p105 and FSV p140 on the basis of their cation requirement and target site specificity. On that basis also, p80/p90-associated protein kinases were found to be more similar to the enzymatic activity of pp60src than to those associated with the PRCII and FSV transformation-specific polyproteins. These results document a close genetic relationship between the two independently isolated sarcoma viruses Y73 and ESV. On the basis of the relatedness of transformation-specific proteins, ESV and Y73 constitute class III of avian sarcoma viruses, with class I containing the various strains of RSV and class II encompassing FSV and PRCII.

Published

1981

36. Sarcoma and transformation-defective viruses produced with infectious DNA(s) from Rous sarcoma virus (RSV)-transformed chicken cells.

Author

Hillova J, Dantchev D, Mariage R, Plichon MP, and Hill M

Subjects

Alpharetrovirus analysis, Alpharetrovirus growth & development, Animals, Carbon Radioisotopes, Cell Line, Cells, Cultured, Centrifugation, Density Gradient, Chick Embryo, Chickens, Defective Viruses analysis, Defective Viruses growth & development, Fibroblasts, Microscopy, Electron, Neoplasms, Experimental microbiology, RNA, Viral analysis, Rats, Retroviridae growth & development, Tritium, Uridine, Viral Interference, Alpharetrovirus isolation & purification, Avian Sarcoma Viruses, Cell Transformation, Neoplastic, DNA, Neoplasm, DNA, Viral, Defective Viruses isolation & purification, Retroviridae isolation & purification

Published

1974

37. Fine structure mapping of an avian tumor virus RNA by immunoelectron microscopy.

Author

Castleman H, Meredith RD, and Erlanger BF

Subjects

Antibodies, Haptens, Microscopy, Electron methods, Molecular Weight, Radioimmunoassay, Alpharetrovirus analysis, RNA, Viral

Abstract

The RNA of a deleted strain (lacking Src gene) of an avian sarcoma virus (ASV) was examined by a newly developed immunoelectron microscopic procedure which uses anti-nucleotide antibodies as probes. After denaturation of the RNA and reaction with a high affinity, highly specific anti-7-methylguanosine-5'-phosphate (anti-pm 7G), 81% of 106 molecules examined were found to have antibody at one terminus, in agreement with the presence of a pm 7G cap in ASV-RNA. Hapten inhibition by pm 7G could be demonstrated. Experiments with anti-A and with anti-poly A gave results consistent with the known structure of ASV-RNA, in particular the presence of a 3' poly A tail. These studies illustrate the feasibility of using anti-nucleotide antibodies in a combined immunochemical and electron microscopic study of the fine structure of nucleic acids.

Published

1980

38. Avian myeloblastosis virus RNA is terminally redundant: implications for the mechanism of retrovirus replication.

Author

Stoll E, Billeter MA, Palmenberg A, and Weissmann C

Subjects

Alpharetrovirus analysis, Avian Sarcoma Viruses analysis, Base Sequence, Codon, DNA, Viral analysis, DNA, Viral biosynthesis, Models, Biological, Transcription, Genetic, Avian Leukosis Virus analysis, Avian Myeloblastosis Virus analysis, RNA, Viral analysis, Virus Replication

Abstract

We have determined the terminal heteropolymeric sequences of AMV RNA by the following procedures: first, RNA sequence determination on the 5' terminal and the poly(A)-linked 3' terminal T1 oligonucleotides, and second, analysis by the Maxam and Gilbert (1977) method of AMV strong stop DNA and of DNA complementary to the poly(A)-linked T1 oligonucleotide, synthesized with reverse transcriptase and (pdT)13 as primer. The structure deduced for the 5' terminal region is (5')7mGpppGmCCAUUCUACCUCUCACCACAUUGGUGUGCACCUGGGUUGAUGGCCGGACCGUCGAUUCCCUGACGACUACGAGCACCUGCAUGAAGCAGAAGGCUUCAU... Two distinct 3' terminal sequences were deduced: GCCAUUCUACCUCUCAAA...AOH and GCCAUUCUACCUCUCACCAAA...AOH. The two termini, differing by a C-C-A sequence, may reflect genetic heterogeneity of the AMV stock or, more probably, may be generated at or after RNA transcription. These results demonstrate a terminal redundancy of the hetero polymeric sequence of 16 and 19 nucleotides, respectively. The terminal redundancy allows for mechanisms which involve transfer of the DNA segment synthesized on the 5' terminal redundant sequence to the 3' terminal redundant sequence.

Published

1977

39. Defective cleavage of a precursor polypeptide in a temperature-sensitive mutant of avian sarcoma virus.

Author

Rohrschneider JM, Diggelmann H, Ogura H, Friis RR, and Bauer H

Subjects

Alpharetrovirus analysis, Alpharetrovirus growth & development, Centrifugation, Density Gradient, Mutation, Peptides analysis, Temperature, Viral Proteins analysis, Alpharetrovirus metabolism, Viral Proteins biosynthesis

Published

1976

40. Modification of avian sarcoma proviral DNA sequences in nonpermissive XC cells but not in permissive chicken cells.

Author

Guntaka RV, Rao PY, Mitsialis SA, and Katz R

Subjects

5-Methylcytosine, Alpharetrovirus genetics, Alpharetrovirus physiology, Animals, Base Sequence, Cell Line, Chick Embryo, Cytosine analogs & derivatives, Cytosine analysis, DNA Restriction Enzymes pharmacology, DNA, Viral genetics, Methylation, Rats, Recombination, Genetic, Alpharetrovirus analysis, Cell Transformation, Viral, DNA, Viral analysis

Abstract

For the first time, we present evidence with restriction enzymes HpaII and MspI which indicates that the proviral DNA sequence of avian sarcoma virus is modified by methylation in a nonpermissive rat cell line but not in permissive chicken cells. Some of the endogenous viral sequences in the permissive cells were also methylated. No 5-methylcytosine could be detected in the unintegrated viral DNA.

Published

1980

41. The forms of tRNATrp found in avian sarcoma virus and uninfected chicken cells have structural identity but functional distinctions.

Author

Cordell B, DeNoto FM, Atkins JF, Gesteland RF, Bishop JM, and Goodman HM

Subjects

Animals, Base Sequence, Chickens, Nucleic Acid Conformation, Oligoribonucleotides analysis, Pancreas enzymology, Protein Biosynthesis, Ribonuclease T1, Species Specificity, Tryptophan, Alpharetrovirus analysis, RNA, Transfer metabolism, RNA, Viral metabolism

Abstract

We have determined the complete nucleotide sequence of the avian tRNATrp which serves as primer for avian retrovirus DNA synthesis by the viral polymerase. The sequence is identical to that reported for tRNATrp present in uninfected avian cells (Harada, F., Sawyer, R. C., and Dahlberg, J. E. (1975) J. Biol. Chem. 250, 3487-3497). Although there appears to be only a single species of tRNATrp in avian cells, two functionally different forms within the population can be distinguished. We show that the tRNATrp isolated from virions can act in vitro as an efficient suppressor for UGA. The suppressor activity is roughly 3-fold greater with viral tRNATrp than with cellular tRNATrp. In addition, it has been reported (Panet, A., Haseltine, W. A., Baltimore, D., Peters, G., Harada, F., and Dahlberg, J. E. (1975) Proc. Natl. Acad. Sci. U. S. A. 72, 2535-2539) that the viral polymerase can bind 100% of viral tRNATrp, but only 30% of cellular tRNATrp. Hence, avian retroviruses seem to selectively incorporate and utilize only one of these forms. Since the nucleotide sequence and nucleoside modifications are identical between viral and cellular tRNATrp, two conformations of avian tRNATrp may exist which can influence several biological activities of the molecule.

Published

1980

42. Structural analysis of the avian sarcoma virus transforming protein: sites of phosphorylation.

Author

Collett MS, Erikson E, and Erikson RL

Subjects

Animals, Arvicolinae, Cell-Free System, Chick Embryo, Culture Techniques, Molecular Weight, Phosphorylation, Alpharetrovirus analysis, Cell Transformation, Neoplastic, Cell Transformation, Viral, Peptides analysis, Phosphoproteins analysis, Viral Proteins analysis

Abstract

The avian sarcoma virus (ASV) protein responsible for cellular transformation in vitro and sarcomagenesis in animals was studied structurally with special reference to the sites of phosphorylation on the polypeptide. The product of the ASV src gene, pp60src, is a phosphoprotein of 60,000 daltons. We found that pp60src contained two major sites of phosphorylation, one involving phosphoserine and the other involving phosphothreonine and possible addtional minor sites of phosphorylation. By using N-formyl[35S]methionyl-tRNAf as a radiolabeled precursor in the cell-free synthesis of the src protein in conjunction with partial proteolysis mapping, we determined that the major phosphoserine residue was located on the amino-terminal two-thirds of the molecule and that the phosphothreonine was located on the carboxy-terminal third. We further determined that the phosphorylation of pp60src in cell extracts involved at least two protein kinases, the one that phosphorylated the major serine site being cyclic AMP dependent and the other, acting on the threonine residue, being a cyclic nucleotide-independnet phosphotransferase. Finally, analysis of the pp60src isolated from cells infected with a temperature-sensitive src gene mutant of ASV revealed that phosphorylation of the major threonine residue was severely reduced when infected cells were grown at the nonpermissive temperature, whereas a phosphorylation pattern characteristic of the wild-type pp60src was observed at the permissive temperature. As pp60src has an associated protein kinase activity, the possible involvement of phosphorylation-dephosphorylation reactions in the functional regulation of ASV transforming protein enzymatic activity is discussed.

Published

1979

43. Characteristics of avian sarcoma virus strain PRCIV and comparison with strain PRCII-p.

Author

Breitman ML, Hirano A, Wong T, and Vogt PK

Subjects

Alpharetrovirus analysis, Animals, Cells, Cultured, Chick Embryo, Genes, Viral, Protein Kinases metabolism, RNA, Viral, Viral Proteins biosynthesis, Virus Replication, Alpharetrovirus physiology, Cell Transformation, Neoplastic, Cell Transformation, Viral, Viral Proteins analysis

Published

1981

44. DNA and RNA from uninfected vertebrate cells contain nucleotide sequences related to the putative transforming gene of avian myelocytomatosis virus.

Author

Sheiness D and Bishop JM

Subjects

Animals, Base Sequence, Cell Transformation, Neoplastic, Cell Transformation, Viral, Nucleotides analysis, Vertebrates, Alpharetrovirus analysis, DNA analysis, DNA, Viral analysis, Genes, Viral, Nucleic Acid Conformation, RNA analysis

Abstract

The avian carcinoma virus MC29 (MC29V) contains a sequence of approximately 1,500 nucleotides which may represent a gene responsible for tumorigenesis by MC29V. We present evidence that MC29V has acquired this nucleotide sequence from the DNA of its host. The host sequence which has been incorporated by MC29V is transcribed into RNA in uninfected chicken cells and thus probably encodes a cellular gene. We have prepared radioactive DNA complementary to the putative MC29V transforming gene (cDNA(mc) (29)) and have found that sequences homologous to cDNA(mc) (29) are present in the genomes of several uninfected vertebrate species. The DNA of chicken, the natural host for MC29V, contains at least 90% of the sequences represented by cDNA(mc) (29). DNAs from other animals show significant but decreasing amounts of complementarity to cDNA(mc) (29) in accordance with their evolutionary divergence from chickens; the thermal stabilities of duplexes formed between cDNA(mc) (29) and avian DNAs also reflect phylogenetic divergence. Sequences complementary to cDNA(mc) (29) are transcribed into approximately 10 copies per cell of polyadenylated RNA in uninfected chicken fibroblasts. Thus, the vertebrate homolog of cDNA(mc) (29) may be a gene which has been conserved throughout vertebrate evolution and which served as a progenitor for the putative transforming gene of MC29V. Recent experiments suggest that the putative transforming gene of avian erythroblastosis virus, like that of MC29V, may have arisen by incorporation of a host gene (Stehelin et al., personal communication). These findings for avian erythroblastosis virus and MC29V closely parallel previous results, suggesting a host origin for src (D. H. Spector, B. Baker, H. E. Varmus, and J. M. Bishop, Cell 13:381-386, 1978; D. H. Spector, K. Smith, T. Padgett, P. McCombe, D. Roulland-Dussoix, C. Moscovici, H. E. Varmus, and J. M. Bishop, Cell 13:371-379, 1978; D. H. Spector, H. E. Varmus, and J. M. Bishop, Proc. Natl. Acad. Sci. U.S.A. 75:4102-4106, 1978; D. Stehelin, H. E. Varmus, J. M. Bishop, and P. K. Vogt, Nature [London] 260:170-173, 1976), the gene responsible for tumorigenesis by avian sarcoma virus. Avian sarcoma virus, avian erythroblastosis virus, and MC29V, however, induce distinctly different spectra of tumors within their host. The putative transforming genes of these viruses share no detectable homology, although sequences homologous to all three types of putative transforming genes occur and are highly conserved in the genomes of several vertebrate species. These data suggest that evolution of oncogenic retroviruses has frequently involved a mechanism whereby incorporation and perhaps modification of different host genes provides each virus with the ability to induce its characteristic tumors.

Published

1979

45. Pheasant virus: new class of ribodeoxyvirus.

Author

Hanafusa T, Hanafusa H, Metroka CE, Hayward WS, Rettenmier CW, Sawyer RC, Dougherty RM, and Distefano HS

Subjects

Alpharetrovirus analysis, Animals, Antigens, Viral analysis, DNA, Viral analysis, Glycoproteins metabolism, Helper Viruses isolation & purification, Inclusion Bodies, Viral ultrastructure, Peptides analysis, RNA Viruses analysis, RNA Viruses enzymology, RNA Viruses isolation & purification, RNA, Viral analysis, RNA-Directed DNA Polymerase metabolism, Reticuloendotheliosis virus analysis, Viral Proteins analysis, Birds microbiology, Oncogenic Viruses classification, RNA Viruses classification

Abstract

Cocultivation of cells derived from embryos of golden pheasants or Amherst pheasants with chicken embryo cells infected with Bryan strain of Rous sarcoma virus resulted in the detection of viruses which appear to be endogenous in these pheasant cells. The pheasant viruses (PV) were similar to avian leukosis-sarcoma viruses (ALSV) in their gross morphology, in the size of their RNA, in the presence of a virion-associated RNA-dependent DNA polymerase (DNA nucleotidyltransferase; deoxynucleoside triphosphate: DNA deoxynucleotidyltransferase; EC 2.7.7.7), and in their growth characteristics. PV also serves as a helper for the glycoprotein-defective Rous sarcoma virus. However, PV was shown to be different from both ALSV and reticuloendotheliosis virus in the following properties: (i) PV does not have ALSV group specific antigens; (ii) the protein composition of PV is different from those of the other two groups of viruses; (iii) PV fails to complement the defective polymerase of alpha type Rous sarcoma virus; and (iv) PV RNA shows no detectable homology with nucleic acids of the other two groups of viruses. Thus, PV appears to be a new class of RNA viruses which contain RNA-dependent DNA polymerase.

Published

1976

46. Polypeptides of endogenous avian C-type viruses: their detection in the plasma membrane of normal and infected cells.

Author

Kurth R, Bosch V, and Bolognesi DP

Subjects

Alpharetrovirus immunology, Animals, Avian Leukosis Virus growth & development, Avian Sarcoma Viruses growth & development, Birds, Cell Membrane analysis, Culture Techniques, Epitopes, Helper Viruses growth & development, Mammals, Molecular Weight, Peptides immunology, Retroviridae immunology, Species Specificity, Viral Proteins immunology, Virus Replication, Alpharetrovirus analysis, Peptides analysis, Retroviridae analysis, Viral Proteins analysis

Published

1977

47. Homology between avian oncornavirus RNAs and DNA from several avian species.

Author

Shoyab M and Baluda MA

Subjects

Animals, Avian Leukosis analysis, Avian Leukosis Virus analysis, Avian Myeloblastosis Virus analysis, Avian Sarcoma Viruses analysis, Base Sequence, Chickens, Coturnix, Ducks, Hot Temperature, Nucleic Acid Conformation, Nucleic Acid Hybridization, Poultry, Quail, Species Specificity, Turkeys, Alpharetrovirus analysis, DNA analysis, DNA, Neoplasm analysis, RNA, Viral analysis

Abstract

3H-labeled 35S RNA from avian myeloblastosis virus (AMV), Rous associated virus (RAV)-0, RAV-60, RAV-61, RAV-2, or B-77(w) was hybridized with an excess of cellular DNA from different avian species, i.e., normal or leukemic chickens, normal pheasants, turkeys, Japanese quails, or ducks. Approximately two to three copies of endogenous viral DNA were estimated to be present per diploid of normal chicken cell genome. In leukemic chicken myeloblasts induced by AMV, the number of viral sequences appeared to have doubled. The hybrids formed between viral RNA and DNA from leukemic chicken cells melted with a Tm 1 to 6 C higher than that of hybrids formed between viral RNA and normal chicken cell DNA. All of the viral RNAs tested, except RAV-61, hybridized the most with DNA from AMV-infected chicken cells, followed by DNA from normal chicken cells, and then pheasant DNA. RAV-61 RNA hybridized maximally (39%) with pheasant DNA, followed by DNA from leukemic (34%), and then normal (29%) chicken cells. All viral RNAs tested hybridized little with Japanese quail DNA (2 to 5%), turkey DNA (2 to 4%), or duck DNA (1%). DNA from normal chicken cells contained only 60 to 70% of the RAV-60 genetic information, and normal pheasant cells lacked some RAV-61 DNA sequences. RAV-60 and RAV-61 genomes were more homologous to the RAV-0 genome than to the genome of RAV-2, AMV, or B-77(s). RAV-60 and RAV-61 appear to be recombinants between endogenous and exogenous viruses.

Published

1975

48. Characterization of DNA complementary to nucleotide sequences adjacent to poly(A) at the 3'-terminus of the avian sarcoma virus genome.

Author

Tal J, Kung HJ, Varmus HE, and Bishop JM

Subjects

Alpharetrovirus metabolism, Base Sequence, Cell Line, Nucleic Acid Conformation, Nucleic Acid Hybridization, Poly A analysis, RNA, Viral analysis, Transcription, Genetic, Alpharetrovirus analysis, DNA, Single-Stranded analysis, DNA, Viral analysis, DNA, Viral biosynthesis, Nucleotides analysis

Published

1977

49. Characteristics and regulation of interaction of avian retrovirus pp12 protein with viral RNA.

Author

Leis J and Jentoft J

Subjects

Avian Myeloblastosis Virus analysis, Avian Sarcoma Viruses analysis, DNA, Single-Stranded metabolism, Hydrogen-Ion Concentration, Magnetic Resonance Spectroscopy, Peptides metabolism, Phosphoproteins analysis, Phosphorylation, Viral Proteins analysis, Alpharetrovirus analysis, Phosphoproteins metabolism, RNA, Viral metabolism, Viral Proteins metabolism

Abstract

We investigated the interaction of the avian retrovirus pp12 protein with viral RNA to assess its possible role in virion assembly. Using chemical modification techniques, we found that reagents specific for lysine or arginine residues inactivated the RNA-binding capacity of the protein. The binding of pp12 to 60S viral RNA was also strongly affected by pH (pKapp of 5.5); the affinity for viral RNA decreased by as much as 40-fold after protonation of one or more titratable groups on the protein. When the protein was cleaved by cyanogen bromide, each of the two polypeptide products bound to RNA (with low affinity), but pH dependence was lost. Thus, an intact protein was required for this effect. Since histidine and phosphoserine residues have pKa values close to the pKapp of the pp12-RNA interaction, they were studied to determine whether they were involved in this process. Each of the two histidyl residues in pp12 had pKa values of 6.2, as determined by proton nuclear magnetic resonance titrations, values too high to account for the pKapp of binding. The involvement of phosphoserine residues, which have pKa values similar to the pKapp, was investigated by removal of phosphate from pp12. When phosphate groups were chemically or enzymatically removed from the avian myeloblastosis virus, Rous sarcoma virus (Pr-C), and PR-E 95C virus pp12 proteins, the Kapp for binding 60S viral RNA was reduced 100-fold at pH 7.5. Thus, it seems possible that phosphorylation of the pp12 protein could favor viral nucleocapsid formation by increasing its affinity for the viral RNA genome. Dephosphorylation could provide for its release from the viral RNA during reverse transcription after viral infection of cells.

Published

1983

50. Characterization of the avian sarcoma virus protein p60src.

Author

Brugge JS, Steinbaugh PJ, and Erikson RL

Subjects

Alpharetrovirus genetics, Antibodies, Viral, Antigens, Viral, Cell Line, Genes, Viral, Hot Temperature, Species Specificity, Viral Proteins immunology, Alpharetrovirus analysis, Cell Transformation, Viral, Cytoplasm analysis, Viral Proteins analysis

Published

1978