Nucleic acid sequences of the oncogene v-rel in reticuloendotheliosis virus strain T and its cellular homolog, the proto-oncogene c-rel.

Reticuloendotheliosis virus strain T (Rev-T) is a highly oncogenic replication-defective retrovirus which contains the oncogene v-rel. It is thought that Rev-T arose when a virus similar to Rev-A, the helper virus of Rev-T, infected a turkey and recombined with c-rel from that turkey. There is one large c-rel locus in the turkey genome which contains all of the sequences homologous to v-rel (K. C. Wilhelmsen and H. M. Temin, J. Virol. 49:521-529, 1984). We have sequenced v-rel and its flanking sequences, each of the regions of the c-rel locus from turkey that are homologous to v-rel and their flanking sequences, and the coding sequence for env and part of pol of Rev-A. The v-rel coding sequences can be translated into a 503-amino acid env-v-rel-out-of-frame-env fusion polypeptide. We have not detected any sequences in the Los Alamos or University of California-San Diego data bases that are more significantly related to the amino acid or nucleic acid sequence of v-rel than to the randomized sequence of v-rel. Comparison of Rev-A, Rev-T, and c-rel indicates that the v-rel sequences may have been transduced from the c-rel (turkey) locus by a novel mechanism. There are sequences in Rev-A and c-rel that are similar to splicing signals, indicating that the 5' virus-rel junction of Rev-T may have been formed by cellular RNA splicing machinery. Eight presumed introns have presumably been spliced out of c-rel to generate v-rel. There are also short imperfect regions of homology between sequences at the boundaries of v-rel and sequences in Rev-A and c-rel (turkey), indicating that c-rel may have been transduced by homologous recombination. There are many differences between the amino acid sequences of the predicted translational products of v-rel and c-rel which may account for their difference in transformation potential. These sequence differences between v-rel and c-rel include 10 missense transitions, four missense transversions, and three places where Rev-T has a small in-frame deletion of sequences relative to c-rel. Most of the coding sequence differences between c-rel and v-rel are nonconservative amino acid changes.     

Insertion of several different DNAs in reticuloendotheliosis virus strain T suppresses transformation by reducing the amount of subgenomic mRNA.

The highly oncogenic retrovirus reticuloendotheliosis virus (Rev) strain T (Rev-T) has, relative to its helper virus Rev strain A, a substitution of the oncogene v-rel for most of the env gene and a large deletion of gag and pol sequences. When the helper virus sequences that are deleted in Rev-T are replaced, the recombinant virus is nontransforming (I. S. Y. Chen and H. M. Temin, Cell 31: 111-120, 1982). We show that suppression of transformation occurs when several different DNA sequences are inserted in Rev-T and that suppression is correlated with a reduction in the amount of v-rel mRNA and v-rel protein in infected cells. The reduced amount of v-rel protein is insufficient for transformation.     

Transforming viruses spontaneously arise from nontransforming reticuloendotheliosis virus strain T-derived viruses as a result of increased accumulation of spliced viral RNA.

The highly oncogenic avian retrovirus reticuloendotheliosis virus strain T (Rev-T) contains a substitution of the oncogene v-rel for much of env and a deletion of gag and pol relative to the helper virus Rev-A. Replacement of gag and pol sequences in Rev-T suppresses transformation by reducing the accumulation of spliced viral mRNA and v-rel protein in infected cells (C. K. Miller and H. M. Temin, J. Virol 58:75-80, 1986). After infection of spleen cells with viruses containing gag and pol sequences, revertant viruses that are strongly transforming were found. Approximately three-fourths of the revertant viruses appeared structurally the same as the parental virus, and approximately one-fourth of the revertant viruses had large deletions (similar in size and location to the deletion in Rev-T). Two revertant viruses that appeared structurally the same as the parental virus were molecularly cloned. The regions sufficient to change the parental virus to a strongly transforming virus were determined by construction of recombinant viruses. In one revertant virus, the region sufficient for transformation contained a 327-base-pair insertion 5' of the 3' splice site used by Rev-T. In the other revertant virus, the region sufficient for transformation contained a 1-base-pair transition and a deletion of one copy of a 9-base-pair direct repeat, both 3' of the 3' splice site used by Rev-T. These differences resulted in the accumulation of increased levels of subgenomic v-rel mRNA and protein, ultimately leading to transformation.     

Structure and dimorphism of c-rel (turkey), the cellular homolog to the oncogene of reticuloendotheliosis virus strain T.

A locus has been identified in turkey DNA that contains nucleotide sequences homologous to the oncogene (v-rel) in the avian retrovirus, reticuloendotheliosis virus strain T. This locus, c-rel, has been molecularly cloned from an apparently heterozygous turkey. c-rel is approximately 23 kilobase pairs in length, with at least seven apparent introns, and contains sequences sufficient to account for all of v-rel. Nucleic acid sequence differences exist between v-rel and homologous regions of c-rel. We examined a population of turkeys to determine whether these sequence differences are the result of polymorphism in the population. Within the turkey population, c-rel is dimorphic in apparent introns and 3' flanking sequences, but polymorphism has not been detected within the regions of the c-rel locus that are homologous to v-rel. Additionally, no nucleic acid sequence differences have been detected between the regions of c-rel in turkeys that are homologous to v-rel and the sequences related to v-rel of a homologous locus in chickens (Chen et al., J. Virol. 245:104-113, 1983). The general organization of introns and flanking sequences is conserved for both c-rel in turkeys and this locus in chickens, indicating that c-rel, like other proto-oncogenes, may have an important development or metabolic function.     

v-rel oncoproteins in the nucleus and in the cytoplasm transform chicken spleen cells.

The transforming protein encoded by the v-rel oncogene of the highly oncogenic avian retrovirus reticuloendotheliosis virus strain T (Rev-T) is a 59,000-dalton protein, p59v-rel. The mechanism by which p59v-rel induces transformation of early lymphoid cells is unknown. As a step towards understanding the mechanism of v-rel-induced transformation, we sought to establish the subcellular site of action of p59v-rel. In this report, we show that p59v-rel contains sequences that are necessary for its efficient localization in the nucleus of infected chicken embryo fibroblasts. These v-rel sequences when added to the normally cytoplasmic protein, beta-galactosidase, directed that protein to the nucleus. A mutation in the v-rel nuclear-localizing sequence did not affect the transforming function, although it did alter the nuclear-localizing function. The addition of a supplemental nuclear-localizing sequence from simian virus 40 large T-antigen to v-rel resulted in the expression of a transforming rel protein which was located exclusively in the nucleus of transformed spleen cells, in contrast to wild-type p59v-rel, which was largely cytoplasmic in transformed spleen cells. Our results support the hypothesis that v-rel encodes a protein which can act either in the nucleus or in the cytoplasm to transform spleen cells.     

Transformation of avian lymphoid cells by reticuloendotheliosis virus

Avian reticuloendotheliosis virus (REV-T) is the most virulent of all retroviruses, inducing an invariably fatal leukemia in chickens with a latent period of 7-10 days. Unlike avian cells transformed by other acutely transforming viruses, lymphoid cells transformed by REV-T are immortalized. Furthermore, in vitro derived, REV-T transformed cells which do not produce virus are tumorigenic and induce lethal reticuloendotheliosis when injected into histocompatible birds. Thus REV-T transforms its target cell both in vitro and in vivo. In addition this transformation is independent of any helper virus functions. Like other acute leukemia viruses, REV-T is replication-defective and must co-replicate with a reticuloendotheliosis associated virus (REV-A). During evolution, a substantial portion of its genome has been deleted and replaced with a host-derived genetic sequence, designated v-rel. Presumably, the v-rel oncogene was transduced from a normal turkey DNA locus, c-rel. There are 9 regions of homology between c-rel and v-rel, however, several differences exist between these genes, suggesting that transformation by REV-T results from the production of an altered v-rel protein. The v-rel sequence is distinct from other known oncogenes and encodes a 57-kDa phosphoprotein. In REV-T transformed cells, this pp57v-rel protein is localized in the cytoplasm. The product of the v-rel oncogene is present at a low level, representing only about 0.003% of total methionine-labelled protein. In addition, pp57v-rel is relatively stable, having an estimated half-life of 4-10 h. The v-rel protein when purified close to homogeneity is complexed with a 40-kDa cellular phosphoprotein in transformed lymphoid cells and possesses serine kinase activity. This review discusses the molecular aspects of transformation by REV-T in the context of other oncogene-encoded proteins.     

The avian retrovirus env gene family: molecular analysis of host range and antigenic variants.

The nucleotide sequence of the env gp85-coding domain from two avian sarcoma and leukosis retrovirus isolates was determined to identify host range and antigenic determinants. The predicted amino acid sequence of gp85 from a subgroup D virus isolate of the Schmidt-Ruppin strain of Rous sarcoma virus was compared with the previously reported sequences of subgroup A, B, C, and E avian sarcoma and leukosis retroviruses. Subgroup D viruses are closely related to the subgroup B viruses but have an extended host range that includes the ability to penetrate certain mammalian cells. There are 27 amino acid differences shared between the subgroup D sequence and three subgroup B sequences. At 16 of these sites, the subgroup D sequence is identical to the sequence of one or more of the other subgroup viruses (A, C, and E). The remaining 11 sites are specific to subgroup D and show some clustering in the two large variable regions that are thought to be major determinants of host range. Biological analysis of recombinant viruses containing a dominant selectable marker confirmed the role of the gp85-coding domain in determining the host range of the subgroup D virus in the infection of mammalian cells. We also compared the sequence of the gp85-coding domain from two subgroup A viruses, Rous-associated virus type 1 and a subgroup A virus of the Schmidt-Ruppin strain of Rous sarcoma virus. The comparison revealed 24 nonconservative amino acid changes, of which 6 result in changes in potential glycosylation sites. The positions of 10 amino acid differences are coincident with the positions of 10 differences found between two subgroup B virus env gene sequences. These 10 sites identify seven domains in the sequence which may constitute determinants of type-specific antigenicity. Using a molecular recombinant, we demonstrated that type-specific neutralization of two subgroup A viruses was associated with the gp85-coding domain of the virus.     

p59v-rel, the transforming protein of reticuloendotheliosis virus, is complexed with at least four other proteins in transformed chicken lymphoid cells

Previous studies have identified the protein product of v-rel, the oncogene carried by reticuloendotheliosis virus (REV), as a 59,000-dalton phosphoprotein located predominantly in the cytosol of transformed chicken lymphoid cells. In immune precipitates of p59v-rel, there is a closely associated protein kinase activity. In chicken lymphoid cells that do not contain REV, p68c-rel is found free in the cytosol not associated with other proteins and not detectably phosphorylated. In this study, we found that immune precipitates of 59v-rel from REV-transformed cells contain at least four other proteins, of approximate molecular weights 124, 115, 68, and 36 kilodaltons (kDa). The 124-, 115-, and 36-kDa proteins are apparently unrelated to p59v-rel in sequence, and their coprecipitation suggests that they are complexed with p59v-rel. The coprecipitating 68-kDa protein was found to be p68c-rel, which, like the other three proteins, precipitates by virtue of its association with p59v-rel. Glycerol gradient analysis suggested the presence of more than one type of complex: one containing p115, p68c-rel, p59v-rel, and p36, and another containing p124, p115, p59v-rel, and possibly p68c-rel. In vitro kinase activity was found in all size classes, coinciding with the distribution of p115 and p59v-rel. The complex(es) was stable under a variety of conditions, including a wide range of ionic strengths, chelators, and detergents, and through multiple cycles of immune precipitation and elution. This suggests a specific and functionally significant interaction among the members that may be of direct relevance to the mechanism of REV-induced transformation.     

Analysis of mutations in the V3 domain of gp160 that affect fusion and infectivity.

The third hypervariable (V3) domain of the human immunodeficiency virus type 1 (HIV-1) envelope glycoprotein has been proposed to play an important role in mediating viral entry. Antibodies to the V3 domain block HIV-1 infection but not virus binding to CD4. At the center of the V3 domain is a relatively conserved sequence of amino acids, GPGRA. It has previously been shown that mutation of some of these amino acids reduced the ability of gp160 expressed on the surface of cells to induce fusion with CD4-bearing cells. In order to analyze the role of V3 domain sequences in mediating HIV entry, we introduced several amino acid substitution mutations in the GPGRA sequence of gp160 derived from HIV-1 strain HXB2 and in the analogous sequence of strain SF33, GPGKV. Virus was generated by cotransfecting the env constructs and a selectable env-negative HIV vector, HIV-gpt. When complemented with a retrovirus env gene, infectious virus capable of a single round of replication was produced. The viral particles produced were analyzed biochemically for core and envelope proteins and for infectious titer. The transfected envs were also analyzed for ability to bind to CD4 and mediate cell fusion. Several of the amino acid substitutions resulted in moderate to severe decreases in virus infectivity and fusion activity. Envelope glycoprotein assembly onto particles and CD4 binding were not affected. These results provide evidence that V3 sequences are involved in mediating the fusion step of HIV-1 entry.     

Genetic analysis of the Rous sarcoma virus subgroup D env gene: mammal tropism correlates with temperature sensitivity of gp85.

Subgroup D avian sarcoma and leukosis viruses can penetrate a variety of mammalian cells in addition to cells from their natural host, chickens. Sequences derived from the gp85-coding domain within the env gene of a mammal-tropic subgroup D virus (Schmidt-Ruppin D strain of Rous sarcoma virus [SR-D RSV]) and a non-mammal-tropic subgroup B virus (Rous-associated virus type 2) were recombined to map genetic determinants that allow penetration of mammalian cells. The following conclusions were based on host range analysis of the recombinant viruses. (i) The determinants of gp85 that result in the mammal tropism phenotype of SR-D RSV are encoded within the 160 codons that lie 3' of codon 121 from the corresponding amino terminus of the gp85 protein. (ii) Small linear domains of the SR-D RSV gp85-coding domain placed in the subgroup B background did not yield viruses with titers equal to that of the subgroup D virus in a human cell line. (iii) Recombinant viruses that contained subgroup D sequences within the hr1 variable domain of gp85 showed modest-to-significant increases in infectivity on human cells relative to chicken cells. A recombinant virus that contained three fortuitous amino acid substitutions in the gp85-coding domain was found to penetrate the human cell line and give a titer similar to that of the subgroup D virus. In addition, we found that the subgroup D virus, the mutant virus, and recombinant viruses with an increased mammal tropism phenotype were unstable at 42 degrees C. These results suggest that the mammal tropism of the SR-D strain is not related to altered receptor specificity but rather to an unstable and fusogenic viral glycoprotein. A temperature sensitivity phenotype for infectivity of mammalian cells was also observed for another mammal-tropic avian retrovirus, the Bratislava 77 strain of RSV, a subgroup C virus, but was not seen for any other avian retrovirus tested, strengthening the correlation between mammal tropism and temperature sensitivity.     

Three laboratory strains of spleen focus-forming virus: comparison of their genomes and translational products

The molecular properties of three laboratory strains of the spleen focus-forming virus were compared. All strains contain genetic sequences related to the env gene of mink cell focus-inducing murine type C leukemia viruses, and each strain codes for a glycoprotein of 50,000 to 52,000 daltons which shares specific immunological properties with the gp70's of mink cell focus-inducing viruses. In contrast to this constancy, gag gene products coded for by these strains vary significantly. The gag and env gene products are synthesized from separate mRNA's, and the mRNA for the env gene product is approximately 18S. Unlike other acute leukemia viruses, which can transform various undifferentiated cells, have large unique sequence cellular gene inserts fused to helper virus gag genes, and have one known genome-length intracellular mRNA, the spleen focus-forming virus transforms only specific hematopoietic stem cells, is an env gene rather than a gag gene recombinant virus, and has a second distinct and smaller class of intracellular mRNA. Our data therefore indicate that the Friend strain of the spleen focus-forming virus is a unique replication-defective acute leukemia virus.     

Molecular basis of host range variation in avian retroviruses.

Previous genetic analysis has localized the region of the Rous sarcoma virus (RSV) env gene responsible for host range specificity to that encoding the middle one-third of gp85. To better understand the host range determinants, the relevant regions of the genomes of infectious molecular clones of the transformation-defective Prague strain of RSV, subgroup B (Pr-RSV-B) and Rous-associated virus 0 (RAV-0) (subgroup E) were sequenced and compared with the sequence of Pr-RSV-C. This comparative analysis identified two variable regions of low amino acid sequence homology flanked by highly conserved amino acid sequences. The first variable region (hr1) begins at base 5654 in the Pr-RSV-C sequence and encodes 32 amino acids. The second variable region (hr2) begins at base 5846 and encodes 27 amino acids. To test the role of the variable regions in host range specificity, we determined the sequence of this region of the env gene of NTRE-4, a recombinant virus between Pr-RSV-B and RAV-0 which exhibits an extended host range. This analysis revealed that the recombinant subgroup-encoding region of NTRE-4 is composed of 200 bases of RAV-0 sequence, including hr2, flanked by sequences which are otherwise of Pr-RSV-B origin. This study indicates that hr1 and hr2 are the domains of gp85 responsible for host range determination in avian retroviruses.