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.     

Avian reticuloendotheliosis virus-transformed lymphoid cells contain multiple pp59v-rel complexes.

The v-rel oncogene of avian reticuloendotheliosis virus type T (REV-T) encodes a 59-kilodalton (kDa) phosphoprotein located principally in the cytosol of transformed lymphoid cells. All of the detectable pp59v-rel was present in high-molecular-weight complexes containing at least five cellular proteins (p124, p115, p75c-rel, p70hsc, and pp40). Antiserum was developed against the 40-kDa protein, the most abundant cellular protein associated with the complex. The 40-kDa phosphoprotein was complexed with pp59v-rel in REV-T-transformed lymphoid cell lines arrested at different stages of B-cell development as well as in lymphoid tumor cells and in fibrosarcomas. The half-life (8 h) of pp40 in REV-T-transformed lymphoid cells was the same as that of pp59v-rel. Antiserum against pp40 permitted the identification of two pp59v-rel complexes. The most abundant cytoplasmic complex contained approximately 75% of the pp59v-rel and all of the detectable pp40 in REV-T-transformed lymphoid cells. Twenty-five percent of the pp59v-rel was present in a minor complex that contained the majority of p75c-rel along with p115 and p124. In nuclear extracts of REV-T-transformed lymphoid cells, pp59v-rel was complexed with pp40. The two high-molecular-weight proteins (p115 and p124) and p75c-rel were not detected in the nuclear complex. In the cytosolic complexes, pp40 was heavily phosphorylated, whereas the nuclear form was much less extensively phosphorylated.     

Serine phosphorylation of the v-rel oncogene product/pp40 complex

The transforming protein encoded by the v-rel oncogene of reticuloendotheliosis virus has been purified from REV-T transformed lymphoid cells by sequential DEAE-Sepharose and immunoaffinity chromatography. The purified preparation consisted of pp59v-rel and the 40 kDa cellular protein which is complexed with the v-rel oncogene product in transformed cells as well as some minor proteins. Incubation of this purified preparation in the presence of Mg2+ and (gamma-32P)ATP resulted in phosphorylation of both pp59v-rel and the 40 kDa protein. This preparation was also able to phosphorylate casein on serine residues. Immunoprecipitates obtained from extracts of REV-T transformed lymphoid cells labeled with 32P-orthophosphate contained 59 and 40 kDa phosphoproteins. Both pp59v-rel and the 40 kDa protein were phosphorylated on serine residues in transformed 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.     

Localization of the v-rel protein in reticuloendotheliosis virus strain T-transformed lymphoid cells.

The protein (p59rel) encoded by the transforming gene of reticuloendotheliosis virus strain T (REV-T) has been identified in REV-T-transformed avian lymphoid cells by using antisera raised against synthetic peptides whose sequences were derived from three nonoverlapping regions of v-rel (N. R. Rice, T. D. Copeland, S. Simek, S. Oroszlan, and R. V. Gilden, Virology 149:217-229, 1986). To obtain polyclonal antibodies directed against a larger number of p59rel epitopes, a 262-amino acid segment was expressed in bacteria. Antisera raised against this fusion protein (v-delta-rel) precipitated p59rel from lysates of [35S]methionine-labeled REV-T-transformed cells, thus confirming previous results obtained with the peptide antisera. We used this new antiserum to localize p59rel in REV-T-transformed cells by subcellular fractionation using differential centrifugation and by indirect immune fluorescent staining. After fractionation and immune precipitation, the majority of p59rel was found in the cytosolic fraction. Indirect immunofluorescence experiments also gave results consistent with the cytoplasmic localization of the v-rel protein in transformed lymphoid cells. In previous studies (Rice et al., Virology 149:217-229, 1986) it was shown that immune precipitates formed with one of the three p59rel peptide antisera possessed in vitro protein kinase activity. Immune precipitates formed with the fusion protein antiserum also showed kinase activity in the in vitro assay. Most of this activity was found in the soluble cytoplasmic fraction, indicating that the kinase may be p59rel or a protein closely associated with it.     

Activation of oncogenicity of the c-rel proto-oncogene.

Reticuloendotheliosis virus strain T (Rev-T) induces a lethal lymphoma in young birds and transforms avian lymphoid cells in vitro. The transforming gene of Rev-T, v-rel, was derived from the turkey proto-oncogene c-rel. Comparison of the nucleotide sequences of v-rel and c-rel indicates that in addition to several internal amino acid changes relative to c-rel, p59v-rel has amino acid sequences at both ends derived from the reticuloendotheliosis virus strain A-related virus env gene (K. C. Wilhelmsen, K. Eggleton, and H. M. Temin, J. Virol. 52:172-182, 1984). In this report, the v-rel sequences important for transformation were defined by constructing recombinant retroviruses in which c-rel sequences replaced the analogous v-rel sequences. These recombinant viruses expressing chimeric proteins were tested for their ability to transform spleen cells in vitro and to induce tumors in young chickens. Activation of the oncogenicity of c-rel in Rev-T required alteration of the amino terminus and the central region of the protein. Deletion of the noncoding sequences 3' to c-rel and of most of the helper virus-related env sequences was necessary for the formation of Rev-T.     

Immunofluorescence on avian sarcoma virus-transformed cells: localization of the src gene product.

The localization of the avian sarcoma virus src gene product (termed p60src) was examined by indirect immunofluorescence in cells transformed by the Schmidt-Ruppin strain of Rous sarcoma virus, subgroup D (SR-RSV-D). Antiserum to p60src was obtained from rabbits bearing SR-RSV-D-induced tumors, and immunofluorescence was performed on chicken embryo fibroblasts (CEF) transformed with SR-RSV-D, as well as normal rat kidney (NRK) cells transformed by the same virus (termed SR-RK cells). Both acetone and formaldehyde fixation were used for the immunofluorescence tests. The specificity of the anti-tumor serum was first demonstrated in both cell systems by gel electrophoresis of immunoprecipitates prepared from 35S--methionine-labeled cells. Anti-tumor serum precipitated p60src from SR-RSV-D-transformed CEF but not from CEF infected with a transformation-defective mutant of SR-RSV-D. All viral structural proteins and precursors contained in these immunoprecipitates could be eliminated by competition with unlabeled virus. Similar experiments on SR-RK cells indicated that no viral proteins other than p60src were expressed in these cells, and this observation was supported by immunofluorescence tests using antiserum to whole virus. For immunofluorescence localization of p60src, reactions with viral structural proteins were blocked with unlabeled virus. This presaturation step, obligatory for p60src detection in the SR-RSV-D-transformed CEF, was unnecessary when antitumor serum was tested on SR-RK cells, since p60src was the only viral protein detectable in these cells. With acetone-fixed cells, p60src-specific immunofluorescence revealed a characteristic fluorescence pattern which was similar in both cell systems. The principal pattern was diffuse and situated in the cytoplasm. A clear nuclear fluorescence was never observed. Immunofluorescence on formaldehyde-fixed cells also indicated the cytoplasmic location of p60src and revealed a specific subcytoplasmic concentration of the fluorescence. With both fixation methods, an additional fluorescence pattern was seen between cells in contact, and was also found in both SR-RK cells and SR-RSV-D-transformed CEF. Immunofluorescence on viable cells suggested that p60src was not on the surface of these transformed cells. The fluorescence patterns were specific for avian sarcoma virus-transformed cells and were not found in uninfected cells, cells infected with a transformation-defective mutant of SR-RSV-D or cells transformed by an antigenically unrelated murine sarcoma virus. Furthermore, anti-tumor serum did not contain antibodies to proteins of the microtubules or intermediate filaments.     

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.     

Transformation of chicken embryo fibroblast cells by avian retroviruses containing the human Fyn gene and its mutated genes.

The transforming activity of the human fyn protein, p59fyn, which is a kinase of the src family, was investigated by testing the effect of recombinant avian retrovirus (Fyn virus) expressing p59fyn on chickens or cultured chicken embryo fibroblast (CEF) cells. The Fyn virus did not induce transformed foci. After several passages of the virus stock on CEF cells, however, a few foci were detected in the presence of dimethyl sulfoxide. Chickens inoculated with Fyn virus at the stage of 12-day-old embryos developed fibrosarcomas 3 to 6 weeks after hatching. The viruses obtained from these foci and from one of the tumor tissues showed high transforming activity in the presence of dimethyl sulfoxide, suggesting that these viruses carry spontaneous mutations of the fyn gene. Four fyn genes from CEF DNAs infected with transforming viruses were molecularly cloned, and their products were confirmed to possess transforming activity. DNA sequence analysis of the fyn genes showed that two of the four mutants have Thr instead of Ile at position 338 in the kinase domain. The other two mutants carry deletions of 78 and 108 base pairs, respectively, which result in complete loss of region C of SH2. The overall level of proteins containing phosphotyrosine was significantly higher in transformed cells than in normal CEF cells. Our data indicate that when expressed at high levels in a retrovirus, normal p59fyn cannot cause cellular transformation, but that mutant p59fyn with either a single amino acid substitution in the kinase domain or a deletion including region C produces a transforming protein, perhaps due to enhanced tyrosine kinase activity. This is the first observation that deletion of region C can unmask the potential transforming activity of a src family kinase.     

Substitution of 5' helper virus sequences into non-rel portion of reticuloendotheliosis virus strain T suppresses transformation of chicken spleen cells

The genome of the highly oncogenic avian retrovirus reticuloendotheliosis virus strain T (REV-T) differs from that of the helper virus reticuloendotheliosis virus strain A by a substitution (rel and a large deletion. Further deletions, constructed in vitro, within the helper-virus-related sequences of REV-T have little effect on the ability of the virus to transform chicken spleen cells in vitro. However, deletions that extend into rel abolish transformation. Substitution of helper-virus-related sequences for the deleted region in the non-rel portion of REV-T also abolishes transformation. Viruses with revertant phenotype were obtained both spontaneously and by construction in vitro from these substituted recombinants. The revertant viruses have various mutations, including deletions and insertions, in the helper-virus-related sequences. Thus the additional helper-virus-related sequences suppress expression of transformation in cis, and the deletion in REV-T seems necessary for expression of the transforming properties of the virus.     

Cooperation of p53 and polyoma virus middle T antigen in the transformation of primary rat embryo fibroblasts.

Cell transformation in vivo seems to be a multistep process. In in vitro studies certain combinations of two oncogenes, a cytoplasmic gene product together with a nuclear gene product, are sufficient to transform primary rodent cells. Polyoma virus large T antigen can immortalize and, in cooperation with polyoma virus middle T antigen, transform primary cells. On the other hand mutant mouse p53 can also immortalize and, in cooperation with an activated Ha-ras oncogene, transform primary cells. In the present study we analyzed whether mutant p53 can replace polyoma virus large T antigen in a cell transformation assay with polyoma virus middle T antigen. Transfection of mutant p53 alone resulted in a cell line which had retained the actin cable network, grew poorly in medium with low concentration of serum, and failed to grow in semisolid agar. Cotransfection of mutant p53 together with polyoma virus middle T led to cells which grew in medium containing low serum concentration, grew well in semisolid agar, and displayed an altered morphology with the tendency to overgrow the normal monolayer. By these criteria these cells were considered fully transformed. The rate of p53 synthesis was similar in both cell lines. However, only p53 from the transformed cell line turned out to be stable. Cells transformed by mutant p53 and polyoma virus middle T expressed nearly the same amount of the c-src-encoded pp60c-src protein as cells transformed by the same p53 and cotransfected activated Ha-ras oncogene. However, only the polyoma virus middle T/p53-transformed cells exhibited an elevated level of pp60c-src-specific tyrosine kinase activity. Thus, despite different mechanisms leading to cell transformation, mutant p53 can replace polyoma virus large T antigen and polyoma virus middle T can replace the activated Ha-ras oncogene in cell transformation.     

Avian reticuloendotheliosis virus: identification of the hematopoietic target cell for transformation

Non-virus-producing hematopoietic cells transformed in vitro by reticuloendotheliosis virus (REV-T) induce lethal "reticuloendotheliosis" when inoculated into histocompatible chickens. This is the first direct demonstration that an in vivo target cell of an avian acute leukemia virus can be transformed in vitro. The tumorigenic, REV-T-transformed non-virus-producing cells fail to express helper-virus-coded proteins. REV-T transformed tumorigenic cells therefore do not require helper-virus functions. Cells transformed in vivo or in vitro by REV-T have lymphoblastoid morphology and express low levels of terminal-deoxynucleotidyl-transferase activity and bursal-cell determinants. One clone synthesized Ig mu. The preferred target cells for REV-T transformation are therefore immature lymphoid cells that express B-cell determinants. We propose that the unique transforming sequence of REV-T be designated rel (lymphoid).     

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.