Partial characterization of a transformation-specific glycopeptide in SSV-NP cells.

An autologous antiserum against simian sarcoma virus-infected nonproducer cells (SSV-NP cells) recognized a SSV transformation-specific glycopeptide (SSV-TrSgp) [H.-J. Thiel, T.J. Matthews, E.M. Broughton, A.M. Butchko, and D.P. Bolognesi (1981) Virology 112, 642-650]. Gel filtration of this component on a Sephacryl S-200 column indicated an apparent molecular weight at about 200,000 (d). This antigen represented a proteoglycan-like molecule, as evidenced by the size of glycopeptides after Pronase treatment and by incubation with chondroitinases. The antigenicity of the SSV-TrSgp was completely destroyed after exposure to different proteases. On the other hand, incubation with neuraminidase or chondroitinases degraded the molecule to some extent, but did not affect its antigenicity as measured by immunoprecipitation. Trypsin and EDTA treatment of intact pulse-labeled cells, as well as surface iodination, indicated that the SSV-TrSgp represents a cell membrane-associated molecule.

Reactivity of antisera to endogenous primate retrovirus with a human T cell membrane protein: recognition of a nonviral glycoprotein by antibodies directed only against carbohydrate components.

A glycosylated protein of approximately 70,000 daltons (gp70) from the surface of human peripheral blood T cells was immunoprecipitated by antisera to the baboon endogenous retrovirus (BEV-M7) and the serologically related feline endogenous retrovirus (RD114) but not by antisera to other retroviruses. Whereas preliminary absorption experiments were consistent with a possible viral specificity for this reaction, detailed biochemical and serologic characterization of the purified cellular protein suggested that it was not related to the gp70 of either M7 or RD114 viruses. The specificity of the reaction was further analyzed by assays of cellular gp70 antigenicity after exposure to exo- and endoglycosidases or trypsin and carbohydrate hapten inhibition studies. The results of these experiments were consistent with the interpretation that the glycoprotein was being recognized by antibody binding to the carbohydrate moiety of the molecule. These results provide an example of an antibody activity that could lead to inappropriate conclusions when sensitive radioimmunoprecipitation techniques are used for the biochemical analysis of antigenic systems. They emphasize the necessity of purifying cellular antigens as a prerequisite to determining the exact basis for a serologic reaction.

A comparison of the intracellular precursor polyproteins of simian sarcoma-associated virus [SiSV(SiAV)] and three human virus isolates: HL23V, HEL12V and A1476V.

The intracellular precursor polyproteins of simian sarcoma-simian-associated virus [SiSV(SiAV)] were compared to the intracellular proteins of the human retrovirus isolates. HL23V, HEL12V and A1476V, by radioimmunoprecipitation followed by SDS-polyacrylamide gel electrophoresis and tryptic peptide analysis. Cells infected with SiSV(SiAV) were characterized by polyproteins Pr200gag-pol, gPr80env, Pr80gag, Pr60gag and Pr40gag. Identical intracellular precursor polyprotein profiles were obtained from cells infected with HL23V, HEL12V and A1476V. Tryptic digest mapping of peptides containing [3H]leucine showed the structural composition of Pr60gag to be the virus core proteins, p28, p15/p12 and p10. The SiSV(SiAV) envelope precursor, gPr80env, contained the structural determinants of mature viral gp70 and a non-glycosylated protein termed p15E. The homology of the human isolate viruses, HL23V, HEL12V and A1476V, to the SiSV(SiAV)/GaLV (gibbon ape leukaemia virus) family of viruses was confirmed by mapping studies. Both gPr80env and Pr60gag of SiAV were identical by tryptic peptide mapping to the respective proteins from the three human retrovirus isolates examined. The potential significance of these results to considerations of the origins of SiAV and the SiAV-like human isolates is discussed.

Studies on Proteins of simian sarcoma-associated virus with different growth history.

Simian sarcoma-associated virus (SSaV) was repeatedly passaged on three human cell lines. The proteins of the progeny virus were analysed for the presence of variant polypeptides. Occasionally, a few variant polypeptides were observed. One-dimensional peptide maps of the major virus protein p30 revealed no modifications after 25 cycles of infection on the three cell lines studied. The peptide map of Pr65gag of virus grown through 25 passages on a human chondrosarcoma cell line was slightly different from that of the virus stock before passaging. The relative amount of the virus protein p30 as compared to p18 and p16 (possibly the SSaV equivalents of p15E and p12E) was variable depending on the host cell. Virus grown on Daudi cells was relatively deficient in p18 and p16. These virus particles were morphologically altered and had a low infectivity.

Comparative oligonucleotide analysis of exogenous and endogenous primate type C viruses.

RNAs of representative viruses of the exogenous simian sarcoma virus-gibbon ape lymphosarcoma virus (SiSV/GALV) and endogenous baboon virus (BaEV) classes of subhuman primate type C viruses were compared and related to HEL-12 virus, an isolate derived from human embryonic lung cells. The extent of sequence identity between different viral RNA preparations was determined by comparison of fingerprint patterns obtained after electrophoretic separation of RNase T1-resistant oligonucleotides. The studies presented indicate that HEL-12 viral RNA and simian sarcoma-simian associated virus [SiSV(SSAV)] RNA share 90 to 95% of the large oligonucleotides. From 5 to 10% of virus-specific oligonucleotides were detected in each of several virus preparations examined and their occurrence was independent of the cell line on which the virus ws propagated. HEL-12 virus and GALV-SF have 50% unique oligonucleotides in common. These are the same oligonucleotides that are shared between GALV-SF and SisV(SSAV) RNA. Two BaEV isolates, M7 and BILN, and RD114, and BaEV-related endogenous virus of cats, each easily displayed distinguishable oligonucleotides patterns. Large oligonucleotides characteristic for these three endogenous virus isolates were not detected in the fingerprints of HEL-12 virus, SiSV(SSAV) and GALV-SF.

Immunochemical reactivity of simian sarcoma virus polypeptides isolated by preparative sodium dodecyl sulfate polyacrylamide gel electrophoresis.

The polypeptides associated with a zonal centrifugation purified simian sarcoma virus propagated in lymphoblastoid NC-37 cells were isolated by preparative polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate (SDS) using a procedure designed to minimize the loss of immunochemical reactivity. The proteins p10, p15, p28, p36, p44, p75, and p86 were obtained in large yield and high degree of homogeneity. The electrophoretically purified p28 was analyzed by competition radioimmunoassay using antiserum to a pore exclusion and ion exchange purified simian sarcoma virus p28. Complete competition was observed with extracts of simian sarcoma virus infected cells. No competition was observed with uninfected or unrelated, infected cell extracts. The antigen-antibody affinity as measured by the slope of the competition curve using antiserum to p28 and 125I-labeled and electrophoretically purified p28 was the same as that for the p28 released from sonication-disrupted simian sarcoma virus. The data indicates that preparative purifications by polyacrylamide gel electrophoresis in the presence of SDS may be generally applicable for the isolation of proteins with essentially the same immunospecificities and affinity for a specific antiserum as proteins isolated by procedures that avoid the use of SDS and electrophoresis.

Isolation of a virus closely related to gibbon ape leukaemia virus from cells infected with virus (HL-23V) released by human leukaemic cells.

Canine thymus cells infected with virus (HL-23V) produced by human acute myelogenous leukaemia cells in culture were shown in previous reports to produce transforming and non-transforming type C virus similar or identical to the simian sarcoma virus complex SSV(SSAV) and to induce tumours in marmoset monkeys (Bergholz et al. 1977a). In these earlier studies the appearance of breakthrough foci at low dilutions of antiserum in neutralization tests with high-titred anti-SSV(SSAV) serum suggested the presence of another virus, distinct from SSV-(SSAV). We now report the isolation of this component and, by comparative neutralization analysis, demonstrate that it is most closely related to gibbon ape leukaemia virus (GALV). It is distinguished from SSV(SSAV) by kinetics of neutralization and molecular hybridization experiments. This component was readily cloned both from virus produced by HL-23V chronically-infected canine thymus cells established by Teich et al. (1975) when HL-23V was first isolated and from virus produced by HL-23V-induced marmoset tumour cells in culture. The presence of this component in the original leukaemic cell cultures is discussed.

Structural analysis of the genomes of gibbon ape and woolly monkey leukosis viruses.

Infectious retroviruses have been isolated from gibbon apes and a woolly monkey. Previous studies have shown that these isolates share some antigenic determinants and that they exhibit partial nucleic acid homology. To further define the relationships in this group of viruses, we compared the RNAs of the viruses of the woolly monkey-gibbon ape class by two-dimensional polyacrylamide gel electrophoresis of the large RNase T1-resistant oligonucleotides. The degree of sequence identity between the RNAs was determined by the similarity of the fingerprint patterns and in some cases by partial sequence analysis of individual oligonucleotides. This technique permitted us to determine the degree of sequence identity in related RNA species. These studies showed that as much as 80% of the genomes of gibbon ape leukosis virus-Halls' Island and gibbon ape leukosis virus-brain could be identical. The other viruses, simian sarcoma-associated virus, gibbon ape leukosis virus-Thailand, and gibbon ape leukosis virus-San Francisco, showed an extensive but somewhat lower degree of sequence identity (between 40 to 60% of the genomes.

Sequences homologous to BAV component of HL23V in baboon tissues.

The BAV component of HL23V virus (HL23V-BAB) hybridized to DNA from different Baboon tissues and appears to be an endogenous Baboon virus. Competition hybridization studies show that HL23V-BAB is closely related to viruses isolated from various Baboon species: P. hamadrys, P. papio, and P. cynocephalus. Competition hybridization studies also show that normal Baboon tissues contain more copies of proviral DNA than cells infected in vitro.

Gibbon ape leukemia virus-Hall's Island: new strain of gibbon ape leukemia virus.

Gibbon ape leukemia virus-Hall's Island (GaLV-H), a type C virus related to previous isolates of GaLV and simian sarcoma virus, was isolated from a gibbon ape with lymphocytic leukemia from a small colony of free-ranging gibbon apes on Hall's Island near Bermuda. We show here by molecular hybridization experiments that GaLV-H is approximately 60% related to three previous isolates of GaLV (GaLV-SF, GaLV-SEATO, and GaLV-Br) and is less closely related to simian sarcoma virus. The oligopyrimidine pattern of a transcript of the terminal 135 +/- 5 nucleotides of the viral RNA of GaLV-H is similar to that of GALV-Br but distinct from that of GaLV-SF and simian sarcoma virus. GaLV-H thus represents a fifth distinct strain of the infectious primate type C viruses, which among the previously described isolates of GaLV is most closely related to GaLV-Br.

Molecular mechanisms involved in the differential expression of gag gene products by clonal isolates of a primate sarcoma virus.

Clonal isolates of an early passage stock of woolly monkey sarcoma virus (WSV) have been shown to code for different numbers of woolly monkey helper leukemia virus gag gene products. In the present report, the molecular mechanisms responsible for their differential expression of gag gene products have been analyzed. Three WSV RNA genomes were shown to possess sedimentation coefficients consistent with the differences demonstrated in their allotments of helper viral sequences. The WSV variant (WSV clone 9) that expressed no detectable proteins was shown to contain the largest amount of helper viral information. Moreover, there was no additive hybridization of the WLV complementary DNA probe by RNA of this WSV clone and that of a WSV clone coding for several gag gene products. These results suggest that the lack of expression of gag gene products by WSV clone 9 is not due to a major deletion of helper viral gag gene sequences. Similar levels of WLV-specific RNA were demonstrated in cells nonproductively transformed by each WSV clone, arguing that the ability to express gag gene proteins was not related to the magnitude of viral RNA transcription. Taken together, the results are most consistent with a mechanism by which small deletions or point mutations in the genomes of some WSV variants result in premature termination of translation or synthesis of immunologically nonreactive gag gene proteins. The present findings have implications concerning the effects of evolutionary selective pressures on helper viral genetic information in mammalian transforming viruses.