env Gene of Chicken RNA Tumor Viruses: Extent of Conservation in Cellular and Viral Genomes

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.     

Genome of Reticuloendotheliosis Virus: Characterization by Use of Cloned Proviral DNA

Reticuloendotheliosis virus is an avian type C retrovirus that is capable of transforming fibroblasts and hematopoietic cells both in vivo and in vitro. This virus is highly related to the three other members of the reticuloendotheliosis virus group, including spleen necrosis virus, but it is apparently unrelated to the avian leukosis-sarcoma virus family. Previous studies have shown that it consists of a replication-competent helper virus (designated REV-A) and a defective component (designated REV) that is responsible for transformation. In this study we used restriction endonuclease mapping and heteroduplex analysis to characterize the proviral DNAs of REV-A and REV. Both producer and nonproducer transformed chicken spleen cells were used as sources of REV proviral DNA; this genome was mapped in detail, and fragments of it were cloned in lambdagtWES.lambdaB. The infected canine thymus line Cf2Th(REV-A) was used as a source of REV-A proviral DNA. The restriction maps and heteroduplexes of the REV and REV-A genomes showed that (proceeding from 5' to 3') (i) REV contains a large fraction of the REV-A gag gene (assuming a gene order of gag-pol-env and gene sizes similar to those of other type C viruses), for the two genomes are very similar over a distance of 2.1 kilobases beginning at their 5' termini; (ii) most or all of REV-A pol is deleted in REV; (iii) REV contains a 1.1 kilobase segment derived from the 3' end of REV-A pol or the 5' end of env or both; (iv) this env region in REV is followed by a 1.9-kilobase segment which is unrelated to REV-A; and (v) the helper-unrelated segment of REV extends essentially all of the way to the beginning of the 3' long terminal repeat. Therefore, like avian myeloblastosis virus but unlike the other avian acute leukemia viruses and most mammalian and avian sarcoma viruses, REV appears to be an env gene recombinant. We also found that the REV-specific segment is derived from avian DNA, for a cloned REV fragment was able to hybridize with the DNA from an uninfected chicken. Therefore, like the other acute transforming viruses, REV appears to be the product of recombination between a replication-competent virus and host DNA. Two other defective genomes in virus-producing chicken cells were also cloned and characterized. One was very similar to REV in its presumptive gag and env segments, but instead of a host-derived insertion it contained additional env sequences. The second was similar (but not identical) to the first in its gag and env regions and appeared to contain an additional 1-kilobase inversion of REV-A sequences.     

Heteroduplex Analysis of the Sequence Relationships Between the Genomes of Kirsten and Harvey Sarcoma Viruses, Their Respective Parental Murine Leukemia Viruses, and the Rat Endogenous 30S RNA

The sequence relations between Kirsten murine sarcoma virus (Ki-SV), Harvey murine sarcoma virus (Ha-SV), and a rat endogenous 30S RNA were studied by electron microscope heteroduplex analysis. The sequence relationships between the sarcoma viruses and their respective parental murine leukemia viruses (Kirsten and Moloney murine leukemia viruses), as well as between the two murine leukemia viruses, were also studied. The only observed nonhomology feature of the Kirsten murine leukemia virus/Moloney murine leukemia virus heteroduplexes was a substitution loop with two arms of equal length extending from 1.80 +/- 0.18 kilobases (kb) to 2.65 +/- 0.27 kb from the 3' end of the RNA. It is believed that this feature lies in the env gene region of the viral genomes. The Ha-SV and Moloney murine leukemia virus genomes (respective lengths, 6.0 and 9.0 kb) were homologous in a 1.0 +/- 0.05-kb region at the 3' end and possibly over a 200-nucleotide region at the 5' ends; otherwise, they were nonhomologous. Ha-SV and Ki-SV (length, 7.5 kb) were homologous in the first 4.36 +/- 0.37-kb region from the 3' end and in a 0.70 +/- 0.15-kb region at the 5' end. In between, there was a nonhomology region, possibly containing a short (0.23-kb) region of partial or total homology. The heteroduplex analysis between rat endogenous 30S RNA and Ki-SV shows that there are mixed regions of sequence homology and nonhomology at both the 5' and 3' ends. However, there is a large (4-kb) region of homology between Ki-SV and the rat 30S RNA in the center of the genomes, with only a small nonhomology hairpin feature. These studies help to define the regions of homology between the Ha-SV and Ki-SV genomes with each other and with the rat endogenous 30S RNA. These regions may be related to the sarcoma genicity of the viruses. In particular, the 0.7-kb region of homology of Ha-SV with Ki-SV at the 5' ends may be related to the formation of a 21,000-dalton phosphoprotein in cells transformed by either virus.     

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.

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.     

An avian transforming retrovirus isolated from a nephroblastoma that carries the fos gene as the oncogene.

A new avian transforming retrovirus, NK24, was isolated from a chicken with a nephroblastoma. This transforming virus induced fibrosarcomas with osteogenic cell proliferation and nephroblastomas in vivo and transformed fibroblast cells in vitro. From extracts of NK24-transformed cells, anti-gag serum immunoprecipitated a 100-kilodalton nonglycosylated protein with no detectable protein kinase activity. An NK24 provirus present in infected quail cells was molecularly cloned and subjected to nucleotide sequence analysis. The genome of NK24 was 5.3 kilobases long and had a 1,126-base-pair sequence of cellular origin in place of a viral sequence of avian leukosis virus containing the 3' half of the gag gene and the 5' half of the pol gene. Although the entire env gene was retained, it appeared to be inactive, possibly owing to the loss of function of its splice acceptor site as a result of a second deletion of 1,598 bases in the 3' half of the pol gene that extended to the acceptor site. Nucleotide sequence analysis revealed that the NK24 virus contained the fos gene, previously identified as the oncogene of FBJ and FBR murine osteosarcoma viruses. Unlike the v-fos gene products of FBJ and FBR, which suffer a structural alteration at their carboxyl termini, the NK24 v-fos gene product seemed to have the same carboxyl-terminal structure as the chicken c-fos gene product. A comparison of the structures of the products of the NK24 v-fos and mouse c-fos genes suggested that the fos gene product consists of highly conserved regions and relatively divergent regions.     

Nucleotide Sequences Derived from Pheasant DNA in the Genome of Recombinant Avian Leukosis Viruses with Subgroup F Specificity

Recombination between viral and cellular genes can give rise to new strains of retroviruses. For example, Rous-associated virus 61 (RAV-61) is a recombinant between the Bryan high-titer strain of Rous sarcoma virus (RSV) and normal pheasant DNA. Nucleic acid hybridization techniques were used to study the genome of RAV-61 and another RAV with subgroup F specificity (RAV-F) obtained by passage of RSV-RAV-0 in cells from a ring-necked pheasant embryo. The nucleotide sequences acquired by these two independent isolates of RAV-F that were not shared with the parental virus comprised 20 to 25% of the RAV-F genomes and were indistinguishable by nucleic acid hybridization. (In addition, RAV-F genomes had another set of nucleotide sequences that were homologous to some pheasant nucleotide sequences and also were present in the parental viruses.) A specific complementary DNA, containing only nucleotide sequences complementary to those acquired by RAV-61 through recombination, was prepared. These nucleotide sequences were pheasant derived and were not present in the genomes of reticuloendotheliosis viruses, pheasant viruses, and avian leukosis-sarcoma viruses of subgroups A, B, C, D, and E. They were partially endogenous, however, to avian DNA other than pheasant. The fraction of these nucleotide sequences present in other avian DNAs generally paralleled the genetic relatedness of these avian species to pheasants. However, there was a high degree of homology between these pheasant nucleotide sequences and related nucleotide sequences in the DNA of normal chickens as indicated by the identical melting profiles of the respective hybrids.     

Transforming Sloan-Kettering viruses generated from the cloned v-ski oncogene by in vitro and in vivo recombinations.

The Sloan-Kettering viruses (SKVs) are replication-defective retroviruses that transform avian cells in vitro. Each of the three SKV isolates is a mixture of viruses with genomes ranging in size from 4.1 to 8.9 kilobases (kb) with a predominant genome of 5.7 kb. Using a cDNA representing a sequence, v-ski, that is SKV specific and held in common by the multiple SKV genomes, we generated a restriction map of the 5.7-kb SKV genome and molecularly cloned a ski-containing fragment from SKV proviral DNA. Southern hybridization and sequence analysis showed that the cloned DNA fragment consisted of the 1.3-kb ski sequence embedded in the p19gag sequence and followed by the remaining 5' half of the gag gene and small portions of both the pol and env genes. A large deletion encompassing the 3' half of gag and the 5' 80% of pol was mapped to a position about 1 kb downstream from the 3' ski-gag junction. To determine whether the cloned ski sequence had transforming activity, the ski-containing fragment and a cloned Rous-associated virus 1 (RAV-1) genome were used to construct an analog of the 5.7-kb SKV genome, RAV-SKV. Cotransfection of chicken embryo cells with RAV-SKV and RAV-1 yielded foci of transformed cells whose morphology was identical to that induced by the natural SKVs. The transformed transfected cells produced transforming virus with a 5.7-kb ski-containing genome and synthesized a gag-containing polyprotein of 110 kilodaltons (kDa). Several nonproducer clones of RAV-SKV-transformed cells were analyzed, and most were found to synthesize a 5.7-kb SKV RNA and a 110-kDa polyprotein. One clone was found to contain an 8.9-kb SKV RNA, and this clone synthesized a 125-kDa polyprotein. Since both the 5.7- and 8.9-kb genomes and the 110- and 125-kDa polyproteins had been identified in studies on the natural SKVs, the present results not only demonstrate the transforming activity of these individual SKVs but also suggest mechanisms for their generation.     

Genetic determinants of neoplastic diseases induced by a subgroup F avian leukosis virus.

Two subgroup F avian leukosis viruses, ring-necked pheasant virus (RPV) and RAV-61, were previously shown to induce a high incidence of a fatal proliferative disorder in the lungs of infected chickens. These lung lesions, termed angiosarcomas, appear rapidly (4 to 5 weeks after infection), show no evidence of proto-oncogene activation by proviral integration, and are not induced by avian leukosis viruses belonging to other subgroups. To identify the viral sequences responsible for induction of these tumors, we constructed recombinant viruses by exchanging genomic segments of molecularly cloned RPV with those of a subgroup A leukosis virus, UR2AV. The ability to induce rapid lung tumors segregated only with the env sequences of RPV; the long terminal repeat of RPV was not required. However, recombinants carrying both env and long terminal repeat sequences of RPV induced lung tumors with a shorter latency. In several cases, recombinant viruses exhibited pathogenic properties differing from those of either parental virus. Recombinants carrying the gag-pol region of RPV and the env gene of UR2AV induced a high incidence of a muscle lesion termed infiltrative intramuscular fibromatosis. One recombinant, EU-8, which carries the gag-pol and LTR sequences of RPV, and the env gene of UR2AV, induced lymphoid leukosis after an unusually short latent period. The median time of death from lymphoid leukosis was 6 to 7 weeks after infection with EU-8 compared with approximately 5 months for UR2AV.     

Avian leukosis viruses of different subgroups and types isolated after passage of Rous sarcoma virus-Rous-associated virus-0 in cells from different ring-necked pheasant embryos.

Avian leukosis viruses of subgroups A and F (RAV-A and RAV-F) arose at a low rate after passage of Rous sarcoma virus-Rous-associated virus-0, which is subgroup E, in cells from ring-necked pheasant embryos. In cells of two embryos, all of the viruses isolated after virus passage were RAV-F. However, in cells of a third embryo, both RAV-A and RAV-F were isolated. In addition, there sometimes were type-specific differences among the different isolates of RAV-A and RAV-F from the cells of single embryos. These results indicate that the RAV-A and RAV-F probably arose by recombination of viral and cellular genes, that different ring-necked pheasant embryo may have different endogenous avian leukosis virus-related nucleotide sequences, and that recombination at different sites in these endogenous sequences might give rise to type-specific differences among the RAV-A and RAV-F.     

Heteroduplex analysis of the sequence relations between the RNAs of mink cell focus-inducing and murine leukemia viruses.

The sequence relationships betwen AKR ecotropic virus and an AKR-derived "mink cell focus-inducing" (MCF) isolate (AKR MCF 247), between Moloney murine leukemia virus (M-MLV) and an M-MLV MCF isolate (M-MLV83), and between AKR and M-MLV were studied by electron microscopic heteroduplex analysis. The MCF-specific sequences were found to map from 1.95 kilobases (kb) to 2.75 kb (+/- 0.15 kb) from the 3' end of the RNAs for both MCF isolates. The major sequence nonhomology regions between AKR and M-MLV lie between 0.9 and 3.5 kb from the 3' end. However, the AKR and M-MLV sequences immediately adjacent to the 1.95- and 2.75-kb junctions with MCF-specific sequences are relatively similar in AKR and M-MLV. Our results suggest that the env gene of MLVs maps from 1 kb to 3 kb from the 3' end of the genomic RNA and that the carboxyl end of the glycoprotein of each MCF strain is similar (or identical) to that of its ecotropic parent.     

Molecular cloning of proviral DNA and structural analysis of the transduced myc oncogene of avian oncovirus CMII.

Molecularly cloned proviral DNA of avian oncogenic retrovirus CMII was isolated by screening a genomic library of a CMII-transformed quail cell line with a myc-specific probe. On a 10.4-kilobase EcoRI fragment, the cloned DNA contained 4.4 kilobases of CMII proviral sequences extending from the 5' long terminal repeat to the EcoRI site within the partial (delta) complement of the env gene. The gene order of CMII proviral DNA is 5'-delta gag-v-myc-delta pol-delta env-3'. All three structural genes are partially deleted: the gag gene at the 3' end, the env gene at the 5' end, and the pol gene at both ends. The delta gag (0.83 kilobases)-v-myc (1.50 kilobases) sequences encode the p90gag-myc transforming protein of CMII. In comparison with the p110gag-myc protein of acute leukemia virus MC29, p90gag-myc lacks amino acids corresponding to additional 516 bases of gag sequences and 12 bases of 5' v-myc sequences present in the MC29 genome. Nucleotide sequence analysis of CMII proviral DNA at the delta gag-v-myc and the v-myc-delta pol junctions revealed significant homologies between avian retroviral structural genes and the cellular oncogene c-myc precisely at the positions corresponding to the gene junctions in CMII. Furthermore, the delta gag-v-myc junction in CMII corresponds to sequence elements in gag and C-myc that are possible splicing signals. The data suggest that transduction of cellular oncogenes may involve RNA splicing and recombination with homologous sequences on retroviral vectors. Different sequence elements of both the retroviral vectors and the c-myc gene recombined during genesis of highly oncogenic retroviruses CMII, MC29, or MH2.     

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).     

Avian reticuloendotheliosis virus: characterization of genome structure by heteroduplex mapping

The genome structure of defective, oncogenic avian reticuloendotheliosis virus (REV) was studied by heteroduplex mapping between the full-length complementary DNA of the helper virus REV-T1 and the 30S REV RNA. The REV genome (5.5 kilobases) had a deletion of 3.69 kilobases in the gag-pol region, confirming the genetic defectiveness of REV. In addition, REV lacked the sequences corresponding to the env gene but contained, instead, a contiguous stretch (1.6 to 1.9 kilobases) of the specific sequences presumably related to viral oncogenicity. Unlike those of other avian acute leukemia viruses, the transformation-specific sequences of REV were not contiguous with the gag-pol deletion. Thus, REV has a genome structure similar to that of a defective mink cell focus-inducing virus or a defective murine sarcoma virus. An additional class of heteroduplex molecules containing the gag-pol deletion and two other smaller deletion loops was observed. These molecules probably represented recombinants between the oncogenic REV and its helper virus.     

Conversion of Friend mink cell focus-forming virus to Friend spleen focus-forming virus by modification of the 3'' half of the env gene.

The 3' half of the env gene of the dualtropic Friend mink cell focus-forming virus was modified by replacing the restriction enzyme fragment of the genome DNA with the corresponding fragment of the acutely leukemogenic, polycythemia-inducing strain of Friend spleen focus-forming virus (F-SFFVP) genome DNA. Replacement with the fragment of F-SFFVP env containing the 585-bp deletion, the 6-bp duplication, and the single-base insertion converted the resulting chimeric genome so that the mutant had a pathogenic activity like that of F-SFFVP. Replacement with the fragment containing only the 585-bp deletion did not result in a pathogenic virus. However, when this virus pseudotyped by Friend murine leukemia virus was passaged in newborn DBA/2 mice, we could recover weakly pathogenic viruses with a high frequency. Molecular analysis of the genome of the recovered virus revealed the presence of a single-base insertion in the same T5 stretch where the wild-type F-SFFV env has the single-base insertion. These results provided evidence that the unique genomic structures present in the 3' half of F-SFFV env are the sole determinants that distinguish the pathogenicity of F-SFFV from that of Friend mink cell focus-forming virus. The importance of the dualtropic env-specific sequence present in the 5' half of F-SFFV env for the pathogenic activity was evaluated by constructing a mutant F-SFFV genome in which this sequence was replaced by the ecotropic env sequence of Friend murine leukemia virus and by examining its pathogenicity. The results indicated that the dualtropic env-specific sequence was essential to pathogenic activity.     

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.