Evidence for recombination between N- and B-tropic murine leukemia viruses: analysis of three virion proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.

We have sodium dodecyl sulfate-polyacrylamide gel electrophoresis to analyze the virion proteins of an N- and a B-tropic C-type virus derived from the BALB/c mouse and 21 putative recombinants, designated XLP-N viruses, obtained from seven crosses between these N- and B-tropic viruses. All the XLP-N viruses are N-tropic but posses the XC plaque morphology of their B-tropic virus parent. Three virion proteins, p15, p30, and gp70, of the parental viruses each differ in electrophoretic mobility. Two recombinants were found that possess a p15 that comigrates with p15 of the B virus; 19 possess a p15 that comigrates with N virus p15. Sixteen recombinants possess a gp70 that migrates like the gp70 of the B virus: four have gp70 with an electrophoretic mobility like that of the N virus gp70. All 21 recombinants possess a p30 that comigrates with p30 of their N virus parent. Given the origin and phenotype of XLP-N viruses, these results would seem to provide good evidence that these viruses are recombinants.     

Nucleotide sequences of gag-pol regions that determine the Fv-1 host range property of BALB/c N-tropic and B-tropic murine leukemia viruses.

Previously, in vitro recombinant DNA studies demonstrated that genetic determinants of N-tropism and B-tropism, or Fv-1-related host range properties of murine leukemia viruses, were located in a BamHI-HindIII DNA segment derived from the 5' portion of the cloned viral genome. We sequenced this segment and its immediate 5' region from cloned DNA of two BALB/c mouse C-type viruses (WN1802N and WN1802B) and found base differences at 12 positions out of the otherwise identical 1,390-base-pair sequences. Analysis of the most likely reading frame showed that 6 of the 12 base differences would result in four encoded amino acid changes, three of which occur at positions 109 (glutamine in WN1802N versus threonine in WN1802B), 110 (arginine in WN1802N versus glutamic acid in WN1802B), and 159 (glutamic acid in WN1802N versus glycine in WN1802B) of the p30 protein. The remaining one is located at position 36 (threonine in WN1802N versus isoleucine in WN1802B) of the viral polymerase protein. Significant conformational alteration of the p30 protein could be predicted from these amino acid changes.     

Intracellular Restriction of Ecotropic Murine Leukemia Virus in Rat NRK Cells and Its Abolishment by Adaptation

Ecotropic murine leukemia viruses, both N-tropic FN-2 (purified helper component of Friend leukemia virus) and B-tropic WNB-2 (purified WN1802B BALB/c-derived endogenous virus), were partially restricted in rat NRK cells. In NRK cells, they produced obscure small plaques at reduced efficiencies relative to their plaque-producing efficiencies in mouse SC-1 cells (10-fold for FN-2 and 100-fold for WNB-2). After three or four passages in NRK cells, the plaquing efficiencies of the viruses in NRK cells increased to levels close to their efficiencies in mouse cells, and the plaques in NRK cells became larger and clearer. The adaptation was more complete with FN-2 than with WNB-2. The adaptation was not due to simple selection of a virus in the FN-2 stock, but was host induced, as the viruses had been submitted to successive limiting dilutions in SC-1 cells before propagation in NRK cells. Possible commitment of xenotropic virus in the adaptation was excluded. The change was stable, even if the adapted viruses were propagated back into SC-1 cells. The NRK-adapted viruses were restricted in other rat cell lines of different origins, and the virus adapted in another rat cell line, RFL, was still restricted in NRK cells. The adaptation was mainly brought about by increased viral growth within the rat cells and not by an increased efficiency of viral penetration into the rat cells. This inversely suggests that the restriction of the ecotropic murine leukemia viruses in NRK cells was a mainly intracellular event. The mobilities of gp69/71 and p30 in sodium dodecyl sulfatepolyacrylamide gel electrophoresis remained unchanged after adaptation of FN-2 in NRK cells.     

Primary structure of p19 species of avian sarcoma and leukemia viruses.

The internal structural proteins of avian sarcoma and leukemia viruses are derived from a precursor polypeptide that is the product of the viral gag gene. The N-terminal domain of the precursor gives rise to p19, a protein that interacts with the lipid envelope of the virus and that may also interact with viral RNA. The C terminus of p19 from the Prague C strain of Rous sarcoma virus was previously assigned to a tyrosine residue 175 amino acids from the N terminus. We have used metabolic labeling and carboxypeptidase digestion to show that the C terminus of p19 is actually tyrosine 155. This implies the existence of a sixth gag protein 22 amino acids in length and located between p19 and p10 on the gag precursor. The p19 species of some recombinant avian sarcoma viruses and of the defective endogenous virus derived from the ev-1 locus migrate on sodium dodecyl sulfate-polyacrylamide gel electrophoresis as if they were about 4,000 daltons smaller than p19. We have elucidated the structure of these forms, called p19 beta, by analysis of the proteins and determination of the DNA sequence of the p19 region of the gag gene from ev-1 and ev-2. Esterification of carboxyl groups completely suppressed the differences in migration of p19 and p19 beta. Peptide mapping showed the altered mobility to be determined by sequences in the C-terminal cyanogen bromide fragment of the proteins. We conclude from the DNA sequence that a single glutamate-lysine alteration is responsible for the altered electrophoretic mobility.     

Mouse strain resistant to N-, B-, and NB-tropic murine leukemia viruses.

Mouse strain G was studied for its susceptibility to various strains of murine leukemia and sarcoma viruses. Both N- and NB-tropic Friend leukemia viruses neither induced splenomegaly nor grew efficiently in strain G mice. Using the XC test, cultured embryo cells were found to be resistant, but not absolutely, to all the tested viruses, N-tropic AKR virus, N- and NB-tropic Friend leukemia viruses, NB-tropic Rauscher leukemia virus, B-tropic WN1802B virus, NB-tropic Moloney leukemia and sarcoma viruses, and N-tropic Kirsten sarcoma virus, although the resistance to Moloney leukemia and sarcoma viruses is sometimes not as strong as that for other viruses. Thus, the strain G mice are unique among mouse strains because they show resistance that is not related to the N-B tropism of murine leukemia viruses.     

Polymorphism of B-tropic leukemia viruses from BALB/c mice: association of a p30 antigen with N- versus B-tropism.

Comparison of a number of murine leukemia virus clones by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed extensive protein polymorphism among B-tropic, but not N-tropic, isolates from BALB/c mice, particularly in migration of p30 proteins. A type-specific radioimmunoassay for p30 was developed which uniformly discriminated all B-tropic viruses from N-tropic viruses of BALB/c origin. N- and B-tropic viruses of C57BL/6 and AKR Fv-1b/b origin could also be distinguished by this assay.     

Biochemical analysis of the p30''s of N-, B-, and B leads to NB-tropic murine leukemia viruses of BALB/c origin.

Previous analysis of the virion proteins of an N- and a B-tropic type C virus of BALB/c mice, of 16 N-tropic recombinants (XLPN viruses) between these viruses, and of eight NB-tropic viruses derived from the B-tropic virus suggested that among these closely related viruses N-, B-, or NB-tropism was associated with the electrophoretic mobility of p30 on sodium dodecyl sulfate-polyacrylamide gels, and thus that p30 might determine this phenotype. To obtain further evidence for the association of structural markers of p30 with N-, B-, or NB-tropism, we have analyzed the p30's of these same viruses by using two-dimensional tryptic peptide mapping and slab gel isoelectric focusing. The results of these analyses suggest that (i) a single peptide unique to the N-tropic virus p30- is present in the p30 of all N-tropic recombinants; (ii) a single peptide unique to the B virus p30 is not present in p30's of the N-tropic recombinants, and this peptide is also absent in p30's of NB-tropic viruses derived from the B-tropic virus; and (iii) p30's of NB-tropic viruses possess a new tryptic peptide not found in the p30 of their B-tropic virus progenitors, and this new peptide is not found in the p30 of the N-tropic virus of BALB/c or the XLPN viruses. These results are consistent with the possibility that p30 may determine the N-, B-, or NB-tropism of murine leukemia viruses. In addition, these studies indicate that some of the N-tropic recombinants have experienced recombination within the p30 gene.     

Characterization of Molecular Species Carrying Gross Cell Surface Antigen

The Gross cell surface antigen (GCSA), associated with expression of endogenous Gross-type murine leukemia virus (G-MuLV) in tissues of mice, is defined by the cytotoxic reaction of a C57BL/6 antiserum, anti-AKR spontaneous leukemia K36, with cells of the Gross virus-induced C57BL/6 leukemia, Emale symbolG2. Sequential lactoperoxidase-catalyzed radioiodination of Emale symbolG2 cells, Nonidet P-40 lysis, precipitation with anti-K36 serum, and sodium dodecyl sulfate-polyacrylamide gel electrophoresis identified molecules with properties of polyproteins encoded by the gag region of the viral genome. These cell surface species could also be labeled by in vitro culturing of Emale symbolG2 with radioactive glucosamine. The viral specificity of these molecules and their participation in the GCSA typing system were established as follows. (i) Absorption of anti-K36 serum with GCSA(+), but not GCSA(-), leukemias led to a marked decrease in precipitation of these proteins. (ii) The same Emale symbolG2 cell surface proteins were also precipitated by antisera against the MuLV virion proteins p30 and p15. (iii) Anti-K36 was shown to possess antibodies against Gross virus p30 and p15. (iv) "Clearing" the Emale symbolG2 lysate of molecules reactive with anti-p30 or anti-p15 sera removed molecules reactive with anti-K36 serum. (v) Absorption of anti-K36 serum with disrupted G-MuLV virions or with Gross p30 or p15 removed GCSA cytotoxic antibodies; partial absorption was achieved with disrupted Rauscher-MuLV (R-MuLV) or with R-MuLV p30, and no absorption was found with R-MuLV p15. These data show that Emale symbolG2 cells express, on their surfaces, MuLV core polyproteins that apparently can be glycosylated and on which the determinants of GCSA are located.     

Six-NB-tropic murine leukemia viruses derived from a B-tropic virus of BALB/c have altered p30.

We have examined the electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gels of three virion proteins of B-tropic murine leukemia virus from BALB/c and six of its NB-tropic derivatives. The gp70 protein and a 13,000-molecular-weight virion protein tentatively identified as p15 of the NB-tropic viruses migrated with the corresponding B virus proteins. However, the major internal structural protein of type C virions, p30, of all the NB-tropic viruses migrated more rapidly than the p30 of their B virus progenitor. Although this change in p30 raises the possibility that p30 may be involved in determining the N-, B-, or NB-tropism of MuLV's, it is also possible that the change accompanies but does not directly determine the change in tropsim.     

Spontaneous regression of Friend virus-induced erythroleukemia. VI. Structural and antigenic differences between the regressing and conventional strains of virus.

The regressing and conventional strains of Friend virus were compared by neutralization assays, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and tryptic peptide mapping of the individual viral components. Neutralization rates of the two viruses differed in the presence of monospecific anti-gp70 antiserum and sera from regressed or immunized mice. Neutralization of regressing Friend virus, but not conventional Friend virus, occurred when the viruses were incubated with anti-p15(E) and complement. Human serum inactivated conventional Friend virus more rapidly than regressing Friend virus, probably as a result of virolysis induced by the reaction of viral p15(E) with human complement component C1. Structural differences between the viruses were detected in their gp70 viral glycoproteins and p15(E) and p12 proteins. Analysis of different stocks and clonal isolates of the viruses showed that the differences between the gp70 and p15(E), but not the p12 proteins, were associated with the regressing phenotype of the regressing strain of Friend virus.     

Core Particles of Hepatitis B Virus and Ground Squirrel Hepatitis Virus I. Relationship Between Hepatitis B Core Antigen- and Ground Squirrel Hepatitis Core Antigen-Associated Polypeptides by Sodium Dodecyl Sulfate-Polyacrylamide Gel Electrophoresis and Tryptic Peptide Mapping

The relationships among the core antigen polypeptides of hepatitis B virus (HBV) and ground squirrel hepatitis virus (GSHV) were studied using sodium dodecyl sulfate-polyacrylamide gel electrophoresis and tryptic peptide mapping. The major core antigen polypeptides of liver-derived HBV (p22) and GSHV (p20.5) shared 56% of the spots in their peptide maps. Comparison of hepatitis B core antigen (HBcAg) p19 or ground squirrel hepatitis core antigen (GSHcAg) p16.5 with their respective major polypeptides indicated that these components probably resulted from cleavage of the major polypeptide of each virus. Other polypeptides smaller than the major component of each virus were often faint on polyacrylamide gels and probably resulted from the cleavage or degradation of components larger than p22 of HBcAg or p20.5 of GSHcAg, since their peptide maps contained spots unique to these high-molecular-weight components. p26 of GSHcAg and p27.5 of HBcAg shared approximately two-thirds of the spots on their peptide maps with those of their respective major core polypeptides. Furthermore, p37.5 of GSHcAg and p40 of HBcAg shared about 60% homology with their respective major polypeptides, and also shared many of the spots that were unique to p26 of GSHcAg or p27.5 of HBcAg but were not found in the peptide map of their respective core antigen polypeptides. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis bands larger than 40,000 daltons were variably present, and peptide mapping indicated that these were aggregates of various smaller core antigen-associated polypeptides. The results suggest that p40 of HBcAg and p37.5 of GSHcAg are the largest unique polypeptides in these core particles, and that they are encoded for by the genome of each virus. That a subset of the spots unique to p40 or p37.5 was also found in p27.5 of HBcAg or p26 of GSHcAg, respectively, as compared to the major core polypeptides, also suggests that p27.5 and p26 are unique proteins encoded by the genome of each virus. It is proposed that the core antigen gene of each virus is larger than that which would encode the major polypeptide of each virus, and that the genetic organizations of the core genes of HBV and GSHV are very similar.     

Control of RFM strain endogenous retrovirus in RFM mouse cells

RFM/Un mice express an endogenous type C retrovirus throughout their life span in many tissues; primary or established embryo fibroblast cell cultures do not express a virus but can be induced by exposure to 5-iodo-2'-deoxyuridine. All of our sources yielded a single ecotropic virus (RFV) which appeared to be related more closely to the endogenous N-tropic virus (WN1802N) of BALB/c mice than to Gross leukemia virus on the basis of two-dimensional gel electropherograms of virion proteins. No xenotropic or recombinant viruses were isolated by cocultivation techniques. RFV is N-tropic, and RFM/Un cells possess the Fv-1n allele, as indicated by restriction of B-tropic virus and susceptibility to Gross strain N-tropic virus. However, RFM cells are highly resistant to RFV and other endogenous N-tropic viruses. This resistance is expressed by two-hit titration kinetics and by inhibition of viral linear duplex DNA formation. This is similar to the effects of the Fv-1 locus, but preliminary work has shown no apparent genetic linkage between the two restrictions. The relative strength of the restriction, the presence of a single class of ecotropic virus, and the absence of recombinant viruses suggest that in RFM mice virus is expressed only in cells in which it is induced and not by cell-to-cell transmission.     

Polymorphism of avian sarcoma virus src proteins.

The src gene products of seven different avian sarcoma viruses were compared. In vitro translation of virion RNA yielded products identified unambiguously as p60src in the case of two stocks of the Schmidt-Ruppin strain, three stocks of the Prague strain, the Bryan strain, and the Bratislava 77 strain of avian sarcoma virus. Differences in the electrophoretic mobility of these seven p60src proteins in sodium dodecyl sulfate-polyacrylamide gels, corresponding to variation in the apparent molecular weights ranging from 56,000 to 60,500, were observed. Antigenic variability was also found; only three of the seven viruses tested encoded a p60src, which was precipitated by antisera derived from rabbits bearing tumors induced by the Schmidt-Ruppin strain of Rous sarcoma virus. Examination of the methionine-containing tryptic peptides of the seven ;60src proteins by two-dimensional mapping revealed four common peptides but marked variability in the five to eight other peptides in each protein. Clear differences in the peptide maps of p60src were observed, both between different strains of virus and within strains. In the three cases examined, p60src synthesized in transformed cells was found to be essentially identical to that synthesized in vitro. We conclude that there is significant polymorphism in the p60src proteins of the avian sarcoma viruses.     

A 50-kDa cytosolic protein complexed with the 90-kDa heat shock protein (hsp90) is the same protein complexed with pp60v-src hsp90 in cells transformed by the Rous sarcoma virus.

We have previously shown that a 50-kDa protein is one component of a heteromeric complex immunoprecipitated by the 90-kDa heat shock protein (hsp90) monoclonal antibodies 8D3 and 3G3 (Perdew, G. H., and Whitelaw, M. L. (1991) J. Biol. Chem. 266, 6708-6713). In this report, we compare the 50-kDa protein with that found in pp60v-src-hsp90-p50 complexes immunoprecipitated from Rous sarcoma virus-transformed cells with antibodies to pp60v-src. 35S- and 32P-labeled p50 proteins from each system were identical in their mobilities by sodium dodecyl sulfate-polyacryl-amide gel electrophoresis. The profile of N-chlorosuccinimide cleavage products derived from each 32P-labeled p50 protein were also identical when resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. We have developed a mouse monoclonal antibody, 3M/1B5p50, capable of detecting p50 on Western blots. This antibody detected the 50-kDa protein which co-purified with the pa104 pp60v-src mutant of the avian sarcoma virus oncoprotein in 44A rat fibroblasts. We did not detect p50 in association with native glucocorticoid receptor in L cells or with the overexpressed glucocorticoid receptor in Chinese hamster ovary cells. Two experiments utilizing immunochemical staining implied that essentially all cytosolic p50 is associated with hsp90. Firstly, immunoprecipitating hsp90 from Hepa 1 cytosol with monoclonal antibody 3G3 left the cytosol depleted of p50. Secondly, cytosol fractionated by sucrose gradient revealed that p50 cosedimented with hsp90, confirming the existence of p50 only in association with hsp90.     

Simultaneous isolation of major viral proteins in one step.

We have developed a rapid and simple technique for the simultaneous isolation of all the major viral proteins from RNA tumor viruses. The basis for this procedure is analytical sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Using dansylated virus as internal marker it is possible to follow the migration of unlabeled viral proteins since dansylation does not change the mobility of labeled proteins (8). The method results in approximately 80% recovery of starting protein and is very reproducible. Using radioimmunoassay no alteration of the purified proteins is detectable.     

Antigenic and structural relationships of the surface antigens of hepatitis B virus, ground squirrel hepatitis virus, and woodchuck hepatitis virus.

The surface antigens of human hepatitis B (HBsAg), ground squirrel hepatitis (GSHsAg), and woodchuck hepatitis (WHsAg) viruses were compared serologically, and their major polypeptides were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and tryptic peptide mapping. Results showed that both GSHsAg and WHsAg are antigenically cross-reactive, that their major pairs of polypeptides have identical mobilities on sodium dodecyl sulfate gels, and that the major polypeptides of GSHsAg and WHsAg migrate faster in sodium dodecyl sulfate-polyacrylamide gel electrophoresis than do the corresponding bands of HBsAg. The peptide maps of the major (P-22) surface antigen polypeptides of GSHsAg and WHsAg showed that they shared over half of their spots. Peptide mapping of HBsAg subtypes indicated a close relationship between the major polypeptides (P-24) of adw and adr and a more distal relationship to ayw. Only about 25% of the spots shared by the combined HBsAg subtypes were also found in the peptide maps of GSHsAg and WHsAg, indicating at least some structural homology among the major polypeptides of the human and animal virus surface antigen particles. This is also reflected in the serological cross-reactivity among HBsAg, GSHsAg, and WHsAg. Further, the detection of ground squirrel and woodchuck antigens by Ausria II radioimmunoassay, combined with peptide mapping data indicating the common origin of these viruses, suggests that the common a determinant is shared by each and is restricted to approximately 25% of the sequences in their major polypeptides.     

Biochemical, biophysical, and biological properties of densonucleosis virus. I. Structural proteins.

The polypeptide composition of highly purified densonucleosis virus was studied by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The viral proteins showed a different behavior in sodium dodecyl sulfate-gels in comparison with the marker proteins. Therefore, the molecular weights were estimated by analyzing the retardation of the electrophoretic mobility of these proteins in gels with increasing polyacrylamide concentrations. Four structural proteins with molecular weights of 49,000, 58,500, 69,000, and 98,000 were found, ant they were designated p49, p59, p69, and p98, respectively. There are several indications that p98 is a dimer of p49. The relative quantity of the structural proteins in a virion suggests that at least p49 (accounting for +/-70% of total protein mass) is a capsid protein and that there will be 12 capsomers per virion.     

Unstable resistance of G mouse fibroblasts to ecotropic murine leukemia virus infection.

G mouse cells were resistant to N- and NB-tropic Friend leukemia viruses and to B-tropic WN 1802B. Though the cells were resistant to focus formation by the Moloney isolate of murine sarcoma virus, they were relatively sensitive to helper component murine leukemia virus. To amphotropic murine leukemia virus and to focus formation by amphotropic murine sarcoma virus, G mouse cells were fully permissive. When the cell lines were established starting from the individual embryos, most cell lines were not resistant to the murine leukemia viruses. Only one resistant line was established. Cloning of this cell line indicated that the resistant cells constantly segregated sensitive cells during the culture; i.e., the G mouse cell cultures were probably always mixtures of sensitive and resistant cells. Among the sensitive cell clones, some were devoid of Fv-1 restriction. Such dually permissive cells, and also feral mouse-derived SC-1 cells, retained glucose-6-phosphate dehydrogenase-1 and apparently normal number 4 chromosomes. The loss of Fv-1 restriction in these mouse cells was not brought about by any gross structural changes in the vicinity of Fv-1 on number 4 chromosomes.     

Biochemical analysis of murine leukemia viruses isolated from radiation-induced leukemias of strain BALB/c.

Murine leukemia viruses isolated from radiation-induced BALB/c leukemias were characterized with respect to viral proteins and RNA. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the viral structural proteins revealed that for p12, p15, p30, and gp70, three of four electrophoretic variants of each could be detected. There was no correlation found between any of these mobilities and N- or B-tropism of the viruses. Proteins of all xenotropic viral isolates were identical in their gel electrophoretic profiles. The similar phenotypes of multiple viral clones from individual leukemias and of isolates grown in different cells suggest that the polymorphism of ecotropic viruses was generated in vivo rather than during in vitro virus growth. By two-dimensional fingerprinting of RNase T1-resistant oligonucleotides from 70S viral DNA, the previously reported association of N- and B-tropism with two distinct oligonucleotides was confirmed. The presence of two other oligonucleotides was correlated with positive and negative phenotypes of the virus-coded GIX cell surface antigen. The RNAs of two B-tropic isolates with distinctive p15 and p12 phenotypes differed from the RNA of a prototype N-tropic virus by the absence of three oligonucleotides mapping in the 5' portion (gag region) of the prototype RNA. In addition, one small-plaque B-tropic virus displayed extensive changes in the RNA sequences associated with the env region of the prototype.     

Structural protein markers in the avian oncoviruses.

The proteins of purified avian oncoviruses were analyzed by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis and isoelectric focusing. Certain members of the avian leukosis-sarcoma viruses (ALSV) had group-specific antigens with altered electrophoretic properties. (i) The p27 protein of Rous-associated virus 0 (RAV-0) had a lower electrophoretic mobility in SDS gels and a lower isoelectric point than the p27 of other ALSV. (ii) The p19 proteins of RAV-1, RAV-2, and the Bryan high-titer strain of Rous sarcoma virus had higher mobilities in SDS gels than did the corresponding protein of other viruses. This altered electrophoretic mobility was correlated with specific differences in the tryptic peptides of radioiodinated p19s. (iii) The p15 protein of RAV-7 had a lower mobility in SDS gels than did the p15 of other ALSV. These markers were used in a study of the structural proteins of subgroup E RAV-60 produced after infection of chicken embryo cells by exogenous ALSV. Although exogenous group-specific protein markers could often be identified in the subgroup E isolates, one RAV-60 had a p27 that comigrated with the p27 of RAV-0. The p19s of two other RAV-60 isolates had electrophoretic properties that were different than those of p19s from either RAV-0 or the exogenous viruses. These results support the hypothesis that RAV-60 is generated by recombination between endogenous and exogenous oncoviruses and indicate that at least the p27 encoded by RAV-0 is closely related to a protein specified by endogenous viral information in chicken cells.