Selective shedding and congenital transmission of endogenous avian leukosis viruses.

Shedding and congenital transmission of endogenous avian leukosis viruses were studied in viremic White Leghorn hens exogenously infected with viruses with endogenous long terminal repeats (LTRs) and in four semicongenic lines of hens that naturally express infectious endogenous viruses (EVs). Relatively high titers of infectious virus EV7 (encoded at locus ev7), Rous-associated virus-0 (RAV-0), and recombinant 882/-16 RAV-0 were detected in blood cells and sera from exogenously infected hens, but marked differences were noted in the incidence of congenitally infected progeny. In enzyme immunoassays that detect viral group-specific antigen, little or no p27 was detected in albumens from dams infected with RAV-0. However, hatchmates infected with either EV7 or recombinant 882/-16 RAV-0, which was constructed with an RAV-0 LTR, shed high titers of p27. Similarly, semicongenic hens that expressed RAV-0 (EV2) (encoded at locus ev2) shed little or no p27 into albumens, but hens that harbored ev10, ev11, and ev12 shed high titers of p27. A slower electrophoretic mobility of p27, considered to be characteristic of EVs that are restricted in congenital transmission, was not associated with low levels of shedding or congenital transmission; p27 from other EVs and p27 from an avian leukosis virus field strain, all of which are shed at high levels, had mobilities identical to that of p27 from RAV-0. Although shedding and congenital transmission appear to be controlled by the viral genome, there was no correlation between low efficiency of shedding or congenital transmission and endogenous LTR or p27 sequences.     

Recombination between endogenous and exogenous RNA tumor virus genes as analyzed by nucleic acid hybridization.

Certain chicken cells that do not spontaneously release virus particles have been shown to produce a subgroup E avian RNA tumor virus, Rous-associated virus 60 (RAV-60), after infection with viruses of other subgroups. The nucleic acids of RAV-60 were analyzed for sequence homologies with the viral nucleic acids contained in the uninfected cell and with those of RAV-2, the exogenous virus used for the preparation of this particular RAV-60 isolate. In addition, these nucleic acids were compared with those of RAV-0, an endogenous virus spontaneously released from line 100 chicken cells. RAV-60 appears to be intermediate between RAV-0 and RAV-2 in its genetic composition, based on the pattern of hybridization obtained with the nucleic acids of these viruses and on the melting profiles of the various hybrid combinations. Of the three viruses tested, RAV-0 appears to have the greatest sequence homology with the viral nucleic acids of the uninfected cell. Hybridization between RAV-60 3-H-labeled complementary DNA and either DNA or RNA from the uninfected cell indicates that RAV-60 contains some nucleic acid sequences which are not present in the cell. In addition, some RAV-60 sequences which hybridize with the cell nucleic acid contain significant amounts of mismatching, as indicated by the lower thermal stability of these hybrid duplexes. Hybrid formation between these partially homologous sequences was excluded under stringent annealing conditions. The data indicate that RAV-60 is a recombinant between exogenous and endogenous viral genes.     

Embryonic infection with the endogenous avian leukosis virus Rous-associated virus-0 alters responses to exogenous avian leukosis virus infection.

We inoculated susceptible chicken embryos with the endogenous avian leukosis virus Rous-associated virus-0 (RAV-0) on day 6 of incubation. At 1 week after hatching, RAV-0-infected and control chickens were inoculated with either RAV-1 or RAV-2, exogenous viruses belonging to subgroups A and B, respectively. The chickens injected with RAV-0 as embryos remained viremic with exogenous virus longer and either failed to develop type-specific humoral immunity to exogenous virus or developed it later than the control chickens not inoculated with RAV-0. The RAV-0-injected chickens also developed neoplasms at a much higher frequency than did the control chickens. We suggest that the lower immune responses of the RAV-0-injected chickens were due to an immunological tolerance to envelope group-specific glycoproteins shared among endogenous and exogenous viruses.     

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

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.     

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

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.     

Ribonucleotide sequence homology among avian oncornaviruses.

RNA sequence relatedness among avian RNA tumor virus genomes was analyzed by inhibition of DNA-RNA hybrid formation between 3H-labeled 35S viral RNA and an excess of leukemic or normal chicken cell DNA with increasing concentrations of unlabeled 35S viral RNA. The avian viruses tested were Rous associated virus (RAV)-3, avian myeloblastosis virus (AMV), RAV-60, RAV-61, and B-77 sarcoma virus. Hybridization of 3H-labeled 35S AMV RNA with DNA from normal chicken cells was inhibited by unlabeled 35S RAV-0 RNA as effeciently (100%) as by unlabeled AMV RNA. Hybridization between 3H-labeled 35S AMV RNA and DNA from leukemic chicken myeloblasts induced by AMV was suppressed 100 and 68% by unlabeled 35S RNA from AMV and RAV-0, respectively. Hybridization between 3H-labeled RAV-0 and leukemic chicken myeloblast DNA was inhibited 100 and 67% by unlabeled 35S RNA from RAV-0 and AMV, respectively. It appears therefore that the AMV and RAV-0 genomes are 67 to 70% homologous and that AMV hybridizes to RAV-0 like sequences in normal chicken DNA. Hybridization between AMV RNA and leukemic chicken DNA was inhibited 40% by RNA from RAV-60 or RAV-61 and 50% by B-77 RNA. Hybridization between RAV-0 RNA and leukemic chicken DNA was inhibited 80% by RAV-60 or RAV-61 and 70% by B-77 RNA. Hybridization between 3H-labeled 35S RNA from RAV-60 or RAV-61 and leukemic chicken myeloblast DNA was reduced equally by RNA from RAV-60, RAV-61, AMV or RAV-0; this suggests that RNA from RAV-60 and RAV-61 hybridizes with virus-specific sequences in leukemic DNA which are shared by AMV, RAV-0, RAV-60, and RAV-61 RNA'S. Hybridization between 3H-labeled 35S RNA from RAV-61 and normal pheasant DNA was inhibited 100% by homologous viral RNA, 22 TO 26% BY RNA from AMV or RAV-0, and 30 to 33% by RNA from RAV-60 or B-77. Nearly complete inhibition of hybricization between RAV-0 RNA and leukemic chicken DNA by a mixture of AMV and B-77 35S RNAs indicates that the RNA sequences shared by B-77 virus and RAV-0. It appears that different avian RNA tumor virus genomes have from 50 to 80% homology in nucleotide sequences and that the degree of hybridization between normal chicken cell DNA and a given viral RNA can be predicted from the homology that exists between the viral RNA tested and RAV-0 RNA.     

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.     

The genome-associated,specific RNA binding proteins of avian and mammalian type C viruses

A structural protein purified from the Rous sarcoma virus (RSV) can specifically bind in vitro to purified avian, but not mammalian, type C viral RNA. Following ultraviolet irradiation of viral particles under conditions which stabilize the polyploid 70S viral RNA, the same polypeptide can be directly purified from the RSV genome. Based on its electrophoretic mobility in polyacrylamide gels containing sodium dodecylsulfate, the RNA binding protein has been identified as the major phosphoprotein (p19) of avian type C viruses. Similar experiments show that the major phosphoproteins of mammalian type C viruses (p12 for murine viruses and p16 for endogenous primate viruses) are also the specific RNA binding proteins and, similarly, are found closely associated with the 70S RNA genomes in the intact viral particles.     

Intracellular restriction on the growth of induced subgroup E avian type C viruses in chicken cells.

Subgroup E avian type C viruses produced by bromodeoxyuridine-treated 100 X 7, line 7, or line C chicken cells were restricted in their intracellular growth on K28 chicken cells but not on line 15 chicken cells. Cells from embryos of line 15 chickens bred with K28 chickens did not restrict the growth of the subgroup E induced leukosis viruses (ILVs). This result indicates that the phenotype for the intracellular restriction of the growth of subgroup E ILVs found in K28 cells is recessive. Long-term growth of the subgroup E ILVs in K28 cells resulted in the appearance of subgroup E virus that grew well on K28 cells. No change in growth characteristics was observed for subgroup E ILVs grown in line 15 cells indicating that appearance of nonrestricted virus occurred only during growth of the subgrouo E ILVs on a restrictive host. RAV-0, a subgroup E virus closely related to the ilvs, had the same growth characteristics as the subgroup E ILVs. RAV-60, a subgroup E virus formed by recombination of exogenous avian leukosis virus with endogenous subgroup E virus coat information, grew well on both line 15 and K28 cells.     

Ribonucleotide Sequence Homology Among Avian Oncornaviruses

RNA sequence relatedness among avian RNA tumor virus genomes was analyzed by inhibition of DNA-RNA hybrid formation between ³H-labeled 35S viral RNA and an excess of leukemic or normal chicken cell DNA with increasing concentrations of unlabeled 35S viral RNA. The avian viruses tested were Rous associated virus (RAV)-0, avian myeloblastosis virus (AMV), RAV-60, RAV-61, and B-77 sarcoma virus. Hybridization of ³H-labeled 35S AMV RNA with DNA from normal chicken cells was inhibited by unlabeled 35S RAV-0 RNA as efficiently (100%) as by unlabeled AMV RNA. Hybridization between ³H-labeled 35S AMV RNA and DNA from leukemic chicken myeloblasts induced by AMV was suppressed 100 and 68% by unlabeled 35S RNA from AMV and RAV-0, respectively. Hybridization between ³H-labeled RAV-0 and leukemic chicken myeloblast DNA was inhibited 100 and 67% by unlabeled 35S RNA from RAV-0 and AMV, respectively. It appears therefore that the AMV and RAV-0 genomes are 67 to 70% homologous and that AMV hybridizes to RAV-0 like sequences in normal chicken DNA. Hybridization between AMV RNA and leukemic chicken DNA was inhibited 40% by RNA from RAV-60 or RAV-61 and 50% by B-77 RNA. Hybridization between RAV-0 RNA and leukemic chicken DNA was inhibited 80% by RAV-60 or RAV-61 and 70% by B-77 RNA. Hybridization between ³H-labeled 35S RNA from RAV-60 or RAV-61 and leukemic chicken myeloblast DNA was reduced equally by RNA from RAV-60, RAV-61, AMV or RAV-0; this suggests that RNA from RAV-60 and RAV-61 hybridizes with virus-specific sequences in leukemic DNA which are shared by AMV, RAV-0, RAV-60, and RAV-61 RNAs. Hybridization between ³H-labeled 35S RNA from RAV-61 and normal pheasant DNA was inhibited 100% by homologous viral RNA, 22 to 26% by RNA from AMV or RAV-0, and 30 to 33% by RNA from RAV-60 or B-77. Nearly complete inhibition of hybridization between RAV-0 RNA and leukemic chicken DNA by a mixture of AMV and B-77 35S RNAs indicates that the RNA sequences shared by B-77 virus and RAV-0 are different from the sequences shared by AMV and RAV-0. It appears that different avian RNA tumor virus genomes have from 50 to 80% homology in nucleotide sequences and that the degree of hybridization between normal chicken cell DNA and a given viral RNA can be predicted from the homology that exists between the viral RNA tested and RAV-0 RNA.     

Membrane Proteins of Uninfected and Rous Sarcoma Virus-Transformed Avian Cells

A method for preparing large membrane fragments and cell ghosts was developed for uninfected and Rous sarcoma virus-transformed chicken embryo fibroblasts in culture. Membrane proteins were analyzed by electrophoresis in acrylamide gels containing sodium dodecyl sulfate. A major amino-acid-containing component of uninfected cell membranes was greatly diminished in amount or absent in membranes of virus-transformed cells. This component, called MP-1, had an electrophoretic mobility in sodium dodecyl sulfate-containing gels similar to that of a protein of a mol wt of 1.42 x 10(5). MP-1 was not altered by changes in cell growth rate or in cells infected with the nontransforming virus RAV-1.     

Characterization of the env gene in avian oncoviruses by heteroduplex mapping.

The genome of ring-necked pheasant virus, an avian oncovirus, is largely homologous to the genomes of chicken oncoviruses except for a specific nonhomology in env, the gene coding for the surface glycoprotein of the virion (J. Tal, D. J. Fujita, S. Kawai, H. E. Varmus, and J. M. Bishop, J. Virol. 21:497--505, 1977). We have used this nonhomology between ring-necked pheasant virus and chicken oncoviruses in electron microscopic studies of heteroduplex molecules. The env-specific region of nonhomology is 1.5 to 1.7 kilobases in length. Its 3' boundary is located 0.6 to 0.7 kilobases from the 3' end of the genome in transformation-defective viruses and 2.5 kilobases from the 3' end in nondefective avian sarcoma viruses. Comparison of several strains of avian oncoviruses shows that the 3' half of this env region is conserved, while the 5' half is more diverged. A small area at the very 3' end of env also shows divergence between different avian oncoviruses. We found no evidence for the presence of a previously unrecognized gene between env and src. An electrophoretic comparison of the glycoproteins from various avian oncoviruses shows that those of ring-necked pheasant virus and Chinese quail virus differ in molecular weight from the glycoproteins of the chicken oncoviruses.     

HMG-like protein in barley and corn nuclei

Chromosomal proteins have been isolated from barley (Hordeum vulgare) and corn (Zea mays) nuclei by extraction with 5% perchloric acid. In each plant, one protein was shown to belong to the HMG proteins. Their molecular weights are very close to that of HMG 14 from chicken erythrocytes, as shown by electrophoretic mobility in SDS polyacrylamide gels. In acetic acid-urea-Triton polyacrylamide gels they migrate between HMG 1,2 and HMG 14, from chicken erythrocytes. Their amino acid compositions are typical of HMG proteins, with equivalent high values of acidic and basic residues. Extraction of HMG's from purified barley chromatin fractions with 0.35 M NaCl considerably reduces histone H2 contamination and increases the yield of HMG up to 0.7% of the total histones. In this technique a second protein was extracted which is soluble in 2% Trichloroacetic acid and shows electrophoretic mobility analogous to those of HMG 14 and 17 from chicken erythrocytes. Whether or not these proteins are counterparts of the animal HMG's 1–2 or HMG's 14–17 is discussed.     

Interaction between membrane properties and protein synthesis: In vitro synthesis of membrane proteins during erythropoiesis

Membrane protein synthesis was investigated by incubating rabbit reticulocytes, in vitro, with radioactive amino acids. The kinetics of membrane protein synthesis showed linear incorporation for approx. 15 min, after which there was only a slight increase in incorporation. On the other hand, intracellular protein synthesis was linear for an incubation period of 60 min. Membranes isolated from such rabbit reticulocytes were analysed on sodium dodecyl sulfate (SDS)-polyacrylamide gels. Two major radioactive bands were found in the 50–60 000 D region, whilst another labelled band had a molecular weight of 43 000 D. This latter band had an electrophoretic mobility identical with rabbit muscle actin (and chick brain actin), when run on one-dimensional SDS polyacrylamide gels. Absolute identity between rabbit brain actin and a newly synthesized reticulocyte membrane protein was shown by comigration on a two-dimensional (first dimension isoelectric focusing and second dimension SDS gel) electrophoresis system. Another band that was radioactively labelled was found to have a molecular weight of approx. 32 000 D. Separation of reticulocytes into different age groups showed that young reticulocytes synthesized a membrane protein species that was not radioactively labelled in the old reticulocyte population.     

HPRS-103 (exogenous avian leukosis virus, subgroup J) has an env gene related to those of endogenous elements EAV-0 and E51 and an E element found previously only in sarcoma viruses.

The avian leukosis and sarcoma virus (ALSV) group comprises eight subgroups based on envelope properties. HPRS-103, an exogenous retrovirus recently isolated from meat-type chicken lines, is similar to the viruses of these subgroups in group antigen but differs from them in envelope properties and has been assigned to a new subgroup, J. HPRS-103 has a wide host range in birds, and unlike other nontransforming ALSVs which cause late-onset B-cell lymphomas, HPRS-103 causes late-onset myelocytomas. Analysis of the sequence of an infectious clone of the complete proviral genome indicates that HPRS-103 is a multiple recombinant of at least five ALSV sequences and one EAV (endogenous avian retroviral) sequence. The HPRS-103 env is most closely related to the env gene of the defective EAV-E51 but divergent from those of other ALSV subgroups. Probing of restriction digests of line 0 chicken genomic DNA has identified a novel group of endogenous sequences (EAV-HP) homologous to that of the HPRS-103 env gene but different from sequences homologous to EAV and E51. Unlike other replication-competent nontransforming ALSVs, HPRS-103 has an E element in its 3' noncoding region, as found in many transforming ALSVs. A deletion found in the HPRS-103 U3 EFII enhancer factor-binding site is also found in all replication-defective transforming ALSVs (including MC29, which causes rapid-onset myelocytomas).     

Analytical techniques for cell fractions. XXIV. Isoelectric point stadnards for two-dimensional electrophoresis.

We have investigated the two-dimensional electrophoretic behavior of a number of proteins throughout the course of carbamylation induced by heating in urea solution. Stepwise charge changes occur which are apparently commensurate with the number of free amino groups in the protein. Characteristic changes also occur in the sodium dodecyl sulfate (SDS) electrophoretic mobility (SDS molecular weight) of some heavily carbamylated proteins, implying altered structure or SDS binding. A mixture of all carbamylation intermediates of a protein provides a simple solution to the problem of internal isoelectric point standardization in the two-dimensional electrophoretic technique of P. H. O'Farrell (1975, J. Biol. Chem.250, 4007–4021).     

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

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.     

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.     

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

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.     

Sequence comparison in the crossover region of an oncogenic avian retrovirus recombinant and its nononcogenic parent: genetic regions that control growth rate and oncogenic potential.

NTRE 7 is an avian retrovirus recombinant of the endogenous nononcogenic Rous-associated virus-0 (RAV-0) and the oncogenic, exogenous, transformation-defective (td) Prague strain of Rous sarcoma virus B (td-PrRSV-B). Oligonucleotide mapping had shown that the recombinant virus is indistinguishable from its RAV-0 parent except for the 3'-end sequences, which were derived from td-PrRSV-B. However, the virus exhibits properties which are typical of an exogenous virus: it grows to high titers in tissue culture, and it is oncogenic in vivo. To accurately define the genetic region responsible for these properties, we determined the nucleotide sequences of the recombinant and its RAV-0 parent by using molecular clones of their DNA. These were compared with sequences already available for PrRSV-C, a virus closely related to the exogenous parent td-PrRSV-B. The results suggested that the crossover event which generated NTRE 7 took place in a region -501 to -401 nucleotides from the 3' end of the td-PrRSV parental genome and that sequences to the right of the recombination region were responsible for its growth properties and oncogenic potential. These sequences included a 148-base-pair exogenous-virus-specific region that was absent from the RAV-0 genome and the U3 region of the long terminal repeat. Since the exogenous-virus-specific sequences are expected to be missing from transformation-defective mutants of the Schmidt-Ruppin strain of RSV, which, like other exogenous viruses, grow to high titers in tissue culture and are oncogenic in vivo, we concluded that the growth properties and oncogenic potential of the exogenous viruses are determined by sequences in the U3 region of the long terminal repeat. However, we propose that the exogenous-virus-specific region may play a role in determining the oncogenic spectrum of a given oncogenic virus.