The specific interaction of the Rous sarcoma virus transforming protein, pp60src, with two cellular proteins

Sera from rabbits bearing tumors induced by Rous sarcoma virus (RSV) were previously found to contain antibody to the RSV transforming protein, pp60^src. Two additional transformation-specific phosphoproteins from RSV-transformed avian cells are immunoprecipitated with these sera. These proteins, having molecular weights of 90,000 (pp90) and 50,000 (pp50), are not precipitated from uninfected or transformation-defective virus-infected cells and are not related to any RSV structural proteins. Neither pp50 nor pp90 shares any partial or complete proteolytic cleavage peptides with pp60^src, suggesting that pp90 and pp50 do not represent either a precursor or a cleavage product of pp60^src. Sedimentation analysis of RSV-transformed cell lysates on glycerol gradients revealed that the RSV pp60^src protein is present as two forms, one of which represents the majority (95%) of pp60^src and sediments as a monomer, 60,000 molecular weight protein and the other of which sediments with pp90 and pp50 as an apparent 200,000 molecular weight complex. Lysates from cells transformed by viruses containing a temperature-sensitive defect in the src gene contain a greater percentage of pp60^src associated with pp90 and pp50 under both permissive (35°C) and nonpermissive (41°C) conditions compared to wild-type virus-infected cell lysates. Phosphoserine and phosphotyrosine were found associated with pp60^src molecules that sedimented as a monomer, whereas pp60^src molecules that are complexed with pp90 and pp50 contain phosphoserine and greatly reduced amounts of phosphotyrosine. Only the monomer form of pp60^src is capable of phosphorylating IgG in the immune complex phosphotransferase reaction. Normal uninfected chicken cells contain a protein that shares identical partial proteolytic cleavage peptides with the pp90 protein immunoprecipitated from RSV-transformed cells. This pp90 protein is one of the major cytoplasmic proteins in uninfected cells. Antibody directed against pp90 also immunoprecipitates pp60^src and pp50 from lysates of RSV-transformed chicken cells.     

Changes in amino-terminal sequences of pp60src lead to decreased membrane association and decreased in vivo tumorigenicity

We have suggested previously that the amino-terminal 8 kilodaltons of pp60^src may serve as a structural hydrophobic domain through which pp60^src attaches to plasma membranes. Two isolates of recovered avian sarcoma viruses (rASVs), 1702 and 157, encode pp60^src proteins that have alterations in this amino-terminal region. The rASV 1702 src protein (56 kilodaltons) and the 157 src protein (62.5 kilodaltons) show altered membrane association, and fractionate largely as soluble, cytoplasmic proteins in aqueous buffers, in contrast with the membrane association of more than 80% of the src protein of standard avian sarcoma virus under the identical fractionation procedure. Plasma membranes purified from cells transformed by these rASVs contain less than 10% of the amount of pp60^src found in membranes purified from cells transformed by Rous sarcoma virus or control rASVs. The altered membrane association of these src proteins had little or no effect on the properties of chick embryo fibroblasts transformed in monolayer culture. In contrast, rASV 1702 showed reduced in vivo tumorigenicity compared with Rous sarcoma virus or with other rASVs that encode membrane-associated src proteins. Rous sarcoma virus-induced tumors are malignant, poorly differentiated sarcomas that are lethal to their hosts. rASV 1702 induces a benign, differentiated sarcoma that regresses and is not lethal to its hosts. These data support the role of amino-terminal sequences in the membrane association of pp60^src, and suggest that the amino terminus of pp60^src may have a critical role in the promotion of in vivo tumorigenicity.     

The src gene product (pp60 src) of avian sarcoma virus rapidly induces DNA synthesis and proliferation of calcium-deprived rat cells

A general characteristic of neoplastic cells, but not their non-neoplastic counterparts, is the ability to proliferate in calcium-deficient medium. NRK cells infected with the transformation-defective, temperature-sensitive, ASV mutant, tsLA23, were unable to proliferate in calcium-deficient medium at the non-permissive 40°C, but they very rapidly initiated DNA synthesis (within 1 hour) and resumed proliferation in this medium after being shifted to 36°C, a temperature permissive for the production of active pp60^src and for neoplastic transformation. These observations suggest that activated pp60^src acts near the $\text{G1}\text{S}$ transition point in the cell cycle to bypass or stimulate a calcium-dependent mechanism required for the initiation of DNA synthesis, which enables the cells to display the neoplastic property of proliferating in calcium-deficient medium.     

Structural analysis of the avian sarcoma virus transforming protein: sites of phosphorylation.

The avian sarcoma virus (ASV) protein responsible for cellular transformation in vitro and sarcomagenesis in animals was studied structurally with special reference to the sites of phosphorylation on the polypeptide. The product of the ASV src gene, pp60src, is a phosphoprotein of 60,000 daltons. We found that pp60src contained two major sites of phosphorylation, one involving phosphoserine and the other involving phosphothreonine and possible addtional minor sites of phosphorylation. By using N-formyl[35S]methionyl-tRNAf as a radiolabeled precursor in the cell-free synthesis of the src protein in conjunction with partial proteolysis mapping, we determined that the major phosphoserine residue was located on the amino-terminal two-thirds of the molecule and that the phosphothreonine was located on the carboxy-terminal third. We further determined that the phosphorylation of pp60src in cell extracts involved at least two protein kinases, the one that phosphorylated the major serine site being cyclic AMP dependent and the other, acting on the threonine residue, being a cyclic nucleotide-independnet phosphotransferase. Finally, analysis of the pp60src isolated from cells infected with a temperature-sensitive src gene mutant of ASV revealed that phosphorylation of the major threonine residue was severely reduced when infected cells were grown at the nonpermissive temperature, whereas a phosphorylation pattern characteristic of the wild-type pp60src was observed at the permissive temperature. As pp60src has an associated protein kinase activity, the possible involvement of phosphorylation-dephosphorylation reactions in the functional regulation of ASV transforming protein enzymatic activity is discussed.     

Detection of the Viral Sarcoma Gene Product in Cells Infected with Various Strains of Avian Sarcoma Virus and of a Related Protein in Uninfected Chicken Cells

Genetic analyses have defined a single gene (src) as that portion of the avian sarcoma virus (ASV) genome which encodes the protein directly responsible for ASV-induced neoplastic transformation. We have recently identified the polypeptide product of the src gene of the Schmidt-Ruppin (SR) strain of ASV, a 60,000-dalton phosphoprotein designated pp60(src), and have further determined that pp60(src) acts as a protein kinase. Essential to the identification and characterization of the pp60(src) protein of SR-ASV was the use of serum (TBR serum) from rabbits bearing SR-ASV-induced tumors. TBR serum was, however, strain specific, recognizing pp60(src) from SR-ASV-transformed cells only. We report here that sera from marmosets bearing tumors induced by the Bryan or SR strains of ASV (TBM sera) contain antibody which precipitates the transforming gene product from cells transformed by the SR, Bryan, Prague, or Bratislava strains of ASV. In contrast, rabbits bearing tumors induced by either the Bratislava or Bryan strains of ASV, or hamsters with SR-ASV-induced tumors did not produce antibody to pp60(src) from any strain of ASV. The 60,000-dalton polypeptides immunoprecipitated with TBM serum from cells transformed by each of the above virus strains are phosphoproteins. One-dimensional peptide mapping by limited proteolysis revealed that the pp60(src) proteins are structurally very similar, but not identical. Furthermore, all of the viral pp60(src) proteins have an associated phosphotransferase activity. In addition to detecting the viral src proteins, TBM serum was able to immunoprecipitate an antigenically related protein from normal uninfected avian cells.     

Nucleotide sequences of feline retroviral oncogenes (v-fes) provide evidence for a family of tyrosine-specific protein kinase genes

The nucleotide sequences encoding the transforming polyproteins of the Snyder-Theilen and Gardner-Arnstein strains of feline sarcoma virus (FeSV) have been determined. These sequences include a viral transforming gene (v-fes), derived from cellular proto-oncogene sequences (c-fes) of domestic cats by recombination with feline leukemia virus (FeLV). The v-fes sequences are predicted to encode a polypeptide domain strikingly similar to that specified by the transforming gene (v-fps) of the avian Fujinami sarcoma virus. In addition, the 3′ 0.8 kilobase pairs of v-fes encode amino acid sequences homologous to the carboxy-terminal portion of pp60^src, the transforming protein encoded by the avian Rous sarcoma virus src gene. Thus different feline and avian retroviral transforming genes, all of which encode functionally related proteins with associated tyrosine-specific kinase activities, must be derived from divergent members of the same protooncogene family.     

Peptide analysis of the transformation-specific antigen from avian sarcoma virus-transformed cells.

Sera from rabbits bearing tumors induced by avian sarcoma virus (ASV) were ussed to immunopecipitate virus-specific proteins from extracts of chicken, hamster, and field vole cells transformed by ASV. Two virus-specific proteins having molecular weights of 76,000 and 60,000 were found in all cell lines examined. The 76,000-molecular-weight protein, Pr76, is the precursor to the internal core proteins of ASV. The 60,000-molecular-weight (60K) transformation-specific antigen from each cell line was subjected to peptide analysis, using chymotrypsin and Staphylococcus aureus V8 protease. The resulting peptide maps of the 60K protein from the different ASV-infected cell types were similar for each enzyme, strongly suggesting that the 60K protein is virus coded. Two-dimensional analysis of chymotryptic peptides from Pr76 and 60K reveals that 60K is not related to the gs antigen precursor. Radiolabeling of ASV-transformed cells with inorganic phosphate revealed that 60K is phosphorylated in vivo. The 60K proteins isolated from both ASV-transformed chicken and field vole cells were found to contain one tryptic phosphopeptide. The tryptic phosphopeptides of 60K from both cell lines migrated identically upon two-dimensional peptide analyses, and their migration differed from that of the principal phosphopeptide of Pr76.     

Demonstration of avian sarcoma virus-coded pp60src in vivo and the anti-pp60src immune response in chickens.

The avian sarcoma virus (ASV)-coded transforming protein pp60src was originally detected in vitro in ASV-transformed avian and mammalian cells in experiments involving mammalian antisera to ASV-induced tumors. It is demonstrated here that pp60src is also expressed in vivo in ASV tumors of chickens. Furthermore, the existence of the endogenous pp60src in all chicken cells does not impair the immune response to exogenous pp60src in the chicken. Whereas chicken antibodies can bind to pp60src, they do not serve as substrates for the protein kinase activity of this transforming protein.     

The size and genetic composition of virus-specific RNAs in the cytoplasm of cells producing avian sarcoma-leukosis viruses.

The genome of avian sarcoma virus (ASV) contains four known genes: gag, encoding structural proteins of the viral core; pol, encoding the viral RNA-directed DNA polymerase; env, encoding the glycoprotein(s) of the viral envelope; and src, which is responsible for neoplastic transformation of the host cell. We have located these genes on virus-specific RNAs in cells productively infected with both nondefective and defective strains of ASV by using molecular hybridization with DNAs complementary to specific portions of the ASV genome.The cytoplasm of cells producing nondefective ASV contains three species of polyadenylated virus-specific RNA, each of which has chemical polarity identical to that of the viral genome. The largest species has a molecular weight of 3.3 × 10⁶ daltons and a sedimentation coefficient of 38S, encodes all four viral genes, and is probably identical to the viral genome. A second species has a molecular weight of 1.8 × 10⁶ daltons and a sedimentation coefficient of 28S, and encodes the 3′ half of the viral genome, including env, src and a genetically silent region known as “c.” The smallest species has a molecular weight of 1.2 × 10⁶ daltons and a sedimentation coefficient of 21S, and encodes only src and “c.” All three species of virus-specific RNA contain nucleotide sequences at least partially homologous to a sequence of 101 nucleotides found at the extreme 5′ end of the ASV genome. This sequence may not be present in the portions of the ASV genome which encode the 28S and 21S virus-specific RNAs, and hence may be joined to these RNAs during their maturation from precursor molecules.The size and genetic composition of virus-specific RNAs in cells producing defective deletion mutants reflect the nature of the deletion. Deletions of either src or env eliminate the 28S virus-specific RNA, leaving a 21S RNA (which contains either env and “c” in the case of src deletions or src and “c” in the case of env deletions) and a 35S RNA which is probably identical to the viral genome.Based on these and related results, we propose a model for viral gene expression which conforms to previous suggestions that eucaryotic cells initiate translations only at the 5′ termini of messenger RNAs.     

Evidence that the phosphorylation of tyrosine is essential for cellular transformation by Rous sarcoma virus

All cells transformed by Rous sarcoma virus contain levels of phosphotyrosine in protein which are 6–10 fold greater than the very low levels present in uninfected cells. The increase is due largely to modification of cellular polypeptides. The abundance of phosphorylated tyrosines in protein in cells infected with tsLA29, a mutant of Rous sarcoma virus which is temperature-sensitive for cellular transformation, increases to 60% of maximum within 60 min of a shift to the permissive temperature and drops to a level close to that in uninfected cells within 60 min of a shift to the restrictive temperature. In light of the fact that pp60^src phosphorylates tyrosine in vitro, these results suggest strongly that the modification of one or more cellular polypeptides by way of pp60^src is critical for cellular transformation by Rous sarcoma virus. There is, however, no increase in the abundance of phosphotyrosine in protein in mouse cells transformed by Kirsten sarcoma virus, Moloney sarcoma virus, or SV40 virus, in chick embryo cells infected with avian myelocytomatosis virus MC29, and in rat and hamster cells transformed by polyoma virus. Thus increased phosphorylation of tyrosine is neither a universal mechanism of transformation nor an inevitable secondary cellular response to transformation.     

Inhibition of the transformation-specific kinase in ASV-transformed cells by N-alpha-tosyl-L-lysyl chloromethyl ketone.

We find that the protease inhibitor N-α-tosyl-L-lysyl chloromethyl ketone (TLCK) inhibits the transformation-specific kinase activity (Collett and Erikson, 1978) associated with p60^src, the avian sarcoma virus (ASV) gene product responsible for the transformation of fibroblasts. TLCK has been shown to induce the phenotypic reversion of ASV-transformed cells to normal (Weber, 1975). Kinase activity was measured in extracts of chick embryo fibroblasts (CEF) transformed by the Schmidt-Ruppin strain of ASV (SR-ASV) with antiserum from rabbits bearing ASV-induced tumors. The immunoprecipitates were incubated with γ-³²P-ATP under conditions in which the phosphorylation of the IgG heavy chain in the immunoprecipitate was directly proportional to the concentration of cell extract. When ASV-transformed CEF were treated with 0.1 mM TLCK, the kinase activity was reduced by 60% after 2 hr and by 80% after 6 hr, and continued to remain low for up to 40 hr when TLCK was present. When TLCK was removed, the kinase activity rose slowly over a period of many hours, suggesting that the enzyme is irreversibly inactivated by TLCK and new enzyme must be synthesized. The effect of TLCK in vivo is concentration-dependent and specific. Other serine protease inhibitors had no effect on kinase activity. At low concentrations (0.03 mM), TPCK produced partial inhibition (≤20%), but at higher concentrations TPCK was extremely toxic to the cells and therefore could not be tested. The inhibition by TLCK was not due to its ability to inhibit protein synthesis since cycloheximide treatment (1 μg/ml) did not significantly reduce kinase activity. TLCK also inhibited kinase activity when added directly to cell extracts, but about 5 times higher concentrations of TLCK were required to produce 50% inhibition. Under these conditions both TLCK and TPCK were comparable inhibitors, whereas PMSF had no effect. Our finding that the inhibition of the kinase by TLCK in vivo parallels the reversion of cell morphology to normal suggests that the kinase has an important role in transformation and offers a biochemical rationale for treatment of tumors with this agent.     

Intercellular communication and the control of growth: XI. Alteration of junctional permeability by thesrc gene in a revertant cell with normal cytoskeleton

Summary To learn whether the reduction of cell-to-cell communication in transformation is a possible primary effect of pp60^src phosphorylation or secondary to a cytoskeletal alteration, we examined the junctional permeability in transformed cells with normal cytoskeleton. The permeability to fluorescentlabelled mono- and diglutamate was compared in clones of Faras' vole cells—clones transformed by Rous sarcoma virus and reverted from that transformation. One revertant clone (partial revertant), had the high levels of pp60^src kinase activity and tumorigenicity of the fully transformed parent clone, but had lost the cytoskeletal alterations of that clone. Another revertant clone (full revertant) had lost the tumorigenicity and most of the pp60^src kinase activity, in addition (J.F. Nawrocki et al., 1984,Mol. Cell Biol. 4:212). The junctional permeability of thepartial revertant with normal cytoskeleton was similar to that of the fully transformed parent clone with abnormal cytoskeleton. The permeabilities of both were lower than those of thefull revertant and the normal uninfected cell, demonstrating that the junctional change by thesrc gene is independent of the cytoskeletal one.     

Evidence that the transforming gene of avian sarcoma virus encodes a protein kinase associated with a phosphoprotein.

Avian sarcoma virus (ASV) induces sarcomas in animals and transforms fibroblasts to a neoplastic state in cell culture. A single viral gene (src) is responsible for both the induction and maintenance of neoplastic transformation. Recent work has identified a protein with a molecular weight of 60,000 daltons that is apparently encoded in src and may be the effector molecule for the gene (Brugge and Erikson, 1977; Purchio et al, 1978). The putative product of src can be immunoprecipitated by antisera obtained from rabbits bearing tumors induced by ASV. We have used this approach to isolate the protein to characterize further its genetic origins and possible function. Our rabbit tumor antisera precipitated a protein with a molecular weight of 60,000 daltons; according to serological, biochemical and genetic criteria, this protein is encoded in src. We found that this protein is phosphorylated and therefore denoted it pp60. Phosphorylation of pp60 could be accomplished in vitro with extracts of ASV-infected cells. A temperature-sensitive conditional mutation in src had no demonstrable effect on either the production or stability of pp60 in the infected cell, but phosphorylation of the protein was temperature-sensitive. Since the mutant src is not expressed at the restrictive temperature, our findings raise the possibility that phosphorylation of pp60 is required for its function as the putative effector of src. Immunoprecipitates prepared with extracts of ASV-infected cells and the rabbit tumor antisera contained a protein kinase activity that catalyzed phosphorylation of the heavy chains of immunoglobulin molecules, using either ATP or GTP as phosphate donor. The kinase activity immunoprecipitated in parallel with pp60 was obtained only from cells that contained a functioning product of src and could not be precipitated with antisera directed against structural proteins of ASV. A temperature-sensitive conditional mutation in src caused the kinase activity to be thermally inactivated in vitro far more rapidly than the activity from cells infected with wild-type virus. We conclude that both the protein kinase and pp60 are encoded in src, and that the enzymatic activity may be an intrinsic property of pp60. Phosphorylation of pp60 in cellular extracts was inhibited by calcium ion, whereas the immunoprecipitable kinase activity was not, suggesting that the kinase responsible for pp60 phosphorylation may be distinct from that encoded in src. Collett and Erikson (1978) have also identified a protein kinase activity associated with pp60. These findings raise the possibility that phosphorylation of specific cellular targets might account for transformation of the host cell by src.     

Cytoskeletal association of pp60 : The transforming protein of the rous sarcoma virus

Immunoferritin labelling methods have been employed to examine the distribution of the Rous Sarcoma virus (RSV)-transforming protein pp60^src in the detergent-resistant cytoskeleton of transformed cells. pp60^src was found to be localized on actin microfilaments present in adhesion plaques, at adherens junctions between cells and also in microfilament bundles. This localization is consistent with the hypothesis that some of the morphological effects of transformation result from the interaction in situ of pp60^src with microfilament-bound target proteins.     

Expression of the ASV src gene in hybrids between normal and virally transformed cells: Specific suppression occurs in some hybrids but not others

Somatic cell hybrids have been made between clones of rat cells transformed by avian sarcoma virus and rat or mouse cells that are untransformed. Intraspecies hybrids were either predominantly morphologically normal or predominantly transformed, some clones that formed transformed intraspecies hybrids yielding normal interspecies hybrids. Untransformed hybrids usually showed no detectable alteration in the structure or location of the integrated provirus, but viral RNA and pp60^src kinase activities were much reduced. No decrease in viral gene expression was seen in transformed hybrids. Thus hybrid suppression of viral transformation, mediated in trans by the untransformed parent, is a specific event that depends on both untransformed and transformed parental parameters.     

2,3,7,8-Tetrachlorodibenzo-p-dioxin causes elevation of the levels of the protein tyrosine kinase pp60c-src

2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD) has been found to cause increases in cellular levels of pp60^src, a protein tyrosine kinase in hepatocytes from the rat and guinea pig, in the thymus of the mouse in vivo and in NIH-3T3 mouse fibroblast cell lines in vitro. Such cellular changes take place in vivo at early stages of TCDD poisoning (as early as one day after treatment in the case of mouse thymus) and at very low doses (single intraperitoneal injections of 1 μg/kg for guinea pigs, 25 μg/ kg for rats, and 30 μg/kg for mice). In addition such an effect of TCDD was observed only in a TCDD-responsive mouse strain but not in a nonresponsive strain. This effect of TCDD is a long-lasting one (eg, even 25 days after single dosing, the levels of pp60^src in the hepatic membrane remained high). In vitro this effect was observed in a wild-type 3T3 cell line but was more pronounced in one of the transfected lines with a v-src gene, a virus-derived oncogene known to code for pp60^src protein.     

Association of pp60src and src protein kinase activity with the plasma membrane of nonpermissive and permissive avian sarcoma virus-infected cells.

The intracellular localization of pp60src and src protein kinase activity in avian sarcoma virus (ASV)-infected chicken embryo fibroblasts and transformed and morphologically reverted field vole cells was examined by subcellular fractionation procedures. Fractionation by differential centrifugation of Dounce-homogenized cellular extracts prepared from vole cells showed that 83 to 91% of pp60src sedimented with particulate subcellular components from both transformed and revertant vole cells. A slightly lesser amount (60 to 70%) of pp60src was found associated with the particulate fraction from ASV-infected chicken embryo fibroblasts. The distribution of src protein kinase activity in the cytosol and particulate cell fractions was identical to that of pp60src, indicating no detectable differences in the activity of cytosol- and particulate-associated pp60src. When subcellular components of the cell were fractionated by discontinuous sucrose gradient centrifugation, similar amounts of both pp60src and src protein kinase activity cosedimented with the plasma membrane fractions from both transformed and revertant vole cells, as well as from ASV-infected chicken embryo fibroblasts. src protein kinase activity associated with plasma membrane fractions prepared from vole cells and ASV-infected chicken embryo fibroblasts was resistant to extraction with high salt concentrations, but partial elution was achieved with nonionic detergent. Thus, in both transformed and morphologically reverted vole cells, pp60src is intimately associated with the plasma membrane. Since transforming virus can be rescued from revertant vole cells by fusion to chicken embryo fibroblasts, revertant vole cell pp60src is capable of inducing morphological transformation. Thus, although the data presented herein suggest that transformation requires the association of pp60src with the plasma membrane, the binding of pp60src to the plasma membrane per se is insufficient to induce morphological transformation and requires the additional interaction with a specific target membrane protein which appears to be defective in revertant vole cells.     

Towards a molecular description of cell transformation by avian sarcoma virus

The avian sarcoma virus transforming gene product has been identified and partially purified from extracts of transformed cells. It is a phosphoprotein with a relative molecular mass of 60 000 (pp60src) with two major sites of phosphorylation. pp60src appears to be a cyclic-AMP-independent protein kinase as judged by protein phosphorylation with partly purified fractions. The specificity of the phosphorylation observed was judged by inhibition with anti-pp60src IgG but not by normal IgG and by the fact that the protein kinase activity isolated from ts transformation-mutant infected cells was more thermolabile than that from wild-type transformed cells, thus showing more directly the origin of the enzymic activity. A cellular protein substrate of pp60src has been identified as a 34 000 molecular mass protein. These data together suggest that protein phosphorylation by pp60src may be a function of the molecule that plays a major role in transformation.