The mitogenic activity of pp60v-src, the oncogenic protein product of the src gene of avian sarcoma virus, is independent of external serum growth factors

The oncogenic pp60v-src product of ASV (avian sarcoma virus) is shown to be a potent endogenous mitogen, which, unlike mitogens such as PDGF (platelet derived growth factor), is able to stimulate host cell proliferation without the help of other growth factors. Thus, NRK rat cells, infected with a temperature-sensitive ASV mutant which produces an abnormally thermolabile pp60v-src, became proliferatively quiescent at a pp60v-src-inactivating 40 degrees C in medium containing either 0.2% calf serum or no serum at all. Adding PDGF stimulated the quiescent tsASV-NRK cells at 40 degrees C to initiate DNA replication in medium containing 0.2% serum, but not in serum-free medium. By contrast, activating internal pp60v-src by dropping the temperature to a permissive 36 degrees C stimulated these quiescent cells to transit G1, initiate DNA replication and to enter mitosis even in serum-free medium. Thus, relative to PDGF, endogenous pp60v-src behaves as a complete mitogen.     

Highly specific antibody to Rous sarcoma virus src gene product recognizes a novel population of pp60v-src and pp60c-src molecules

Antiserum to the Rous sarcoma virus (RSV)-transforming protein, pp60v-src, was produced in rabbits immunized with p60 expressed in Escherichia coli. alpha p60 serum immunoprecipitated quantitatively more pp60v-src than did tumor-bearing rabbit (TBR) sera. When RSV-transformed cell lysates were preadsorbed with TBR serum, the remaining lysate contained additional pp60v-src, which was recognized only by reimmunoprecipitation with alpha p60 serum and not by TBR serum. In subcellular fractions of RSV-infected chicken embryo fibroblasts (RSV-CEFs) and field vole cells probed with TBR serum, the majority of the pp60v-src was associated with the plasma membrane-enriched P100 fraction. However, alpha p60 serum revealed equal distribution of pp60v-src and its kinase activity between the P1 (nuclear) and P100 fractions. The same results were obtained for pp60c-src in uninfected CEFs. On discontinuous sucrose gradients nearly 50% of the P1-pp60v-src sedimented with nuclei, in fractions where no plasma membrane was detected. Indirect immunofluorescence microscopy of RSV-CEFs with alpha p60 serum revealed a distinct pattern of perinuclear fluorescence, in addition to staining at the cell periphery. Thus the use of a highly specific antibody reveals that enzymatically active pp60v-src and pp60c-src molecules are present in other intracellular structures, probably juxtareticular nuclear membranes, in addition to the plasma membrane in normal, uninfected, and wild-type RSV-infected cells.     

Evidence the pp60src, the product of the Rous sarcoma virus src gene, undergoes autophosphorylation.

F/St mice are unique in producing high levels of both ecotropic and xenotropic murine leukemia virus. The high ecotropic virus phenotype is determined by three or more V (virus-inducing) loci. A single locus for inducibility of xenotropic murine leukemia virus was mapped to chromosome 1 close to, but possibly not allelic to, Bxv-1. Although the high ecotropic virus phenotype is phenotypically dominant, the high xenotropic virus phenotype was recessive in all crosses tested. Suppression of xenotropic murine leukemia virus is governed by a single gene which is not linked to the xenotropic V locus.     

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.     

Phosphorylation of the solubilized insulin receptor by the gene product of the Rous sarcoma virus, pp60src

Both the insulin receptor and the gene product of the Rous sarcoma virus, pp60src, are protein kinases which phosphorylate themselves and other proteins on tyrosine residues. Addition of the solubilized insulin receptor to purified pp60src increased the phosphorylation of the beta-subunit of the insulin receptor. Phosphorylation of the insulin receptor by pp60src occurred both in the absence and presence of insulin but did not alter the insulin dose response for autophosphorylation of the receptor. Increasing concentrations of pp60src increased the phosphorylation of the receptor and at high concentrations equaled the maximal effect produced by insulin. Our observations suggest a possible mechanism by which the metabolically regulated insulin receptor tyrosine kinase could be altered by other tyrosine kinases such as that associated with pp60src. Further studies will be required to determine if the insulin receptor is phosphorylated by pp60src in Rous sarcoma virus-infected cells.     

Monoclonal antibodies to Rous sarcoma virus pp60src react with enzymatically active cellular pp60src of avian and mammalian origin

The derivation and characterization of 22 hybridoma clones producing monoclonal antibodies (Mabs) specific for the transforming protein of Rous sarcoma virus, pp60src, are described. All Mabs reacted with pp60v-src encoded by Prague, Schmidt-Ruppin, and Bratislava 77 strains of Rous sarcoma virus. Of these Mabs, 10 efficiently immunoprecipitated pp60c-src from chicken embryo cells. Of these 10 Mabs, 2 (GD11 and EB8) readily detected pp60c-src from a variety of rodent and human cultured cells and from rat brain tissue in an in vitro immune complex kinase assay. Mapping experiments have tentatively localized the determinant(s) recognized by GD11 and EB8 to a region of the src protein bounded by amino acid residues 82 to 169, whereas the remaining Mabs appeared to recognize determinants residing within residues 1 to 82 or 169 to 173. Most of the Mabs complexed denatured pp60v-src in a Western immunoblot, and several were used to localize pp60v-src in Rous sarcoma virus-transformed chicken embryo cells by indirect immunofluorescence microscopy.     

Amino acid alterations within a highly conserved region of the Rous sarcoma virus src gene product pp60src inactivate tyrosine protein kinase activity.

Bisulfite mutagenesis techniques have been used to introduce single-point mutations within a region of the Rous sarcoma virus src gene defined by a BglI restriction endonuclease cleavage site. The mutants of Rous sarcoma virus that are produced by these techniques encode src proteins which contain single amino acid changes within a highly conserved amino acid sequence encompassing residues 430 to 433. DNA from the mutants CHpm26 ( Ala430 to Val), CHpm9 ( Pro431 to Ser), CHpm6 ( Glu432 to Lys), and CHpm65 ( Ala433 to Thr) each failed to transform chicken cells upon transfection, whereas DNA from CHpm59 (a third base alteration in the codon for Glu432 ) readily transformed chicken cells. Analysis of immune complexes containing the altered src proteins indicates that these proteins have decreased tyrosine protein kinase activity in vitro. In vivo labeling of cells infected with the mutant virus revealed diminished levels of the tyrosine-phosphorylated 34,000-molecular-weight protein. These data indicate that mutations within the sequence Ala430 - Pro431 - Glu432 - Ala433 lead to alterations in pp60src-specific tyrosine protein kinase activity and a concomitant loss of transforming potential of the mutant virus.     

Reconstitution of the Rous sarcoma virus transforming protein pp60v-src into phospholipid vesicles.

An artificial membrane system was developed to study the molecular basis for interaction of pp60v-src, the Rous sarcoma virus transforming protein, with lipid bilayers. pp60v-src was extracted from cell membranes by detergent solubilization and reincorporated into phospholipid vesicles. Reconstituted pp60v-src retained tyrosine kinase activity and was integrally associated with the liposome through a 10-kilodalton (kDa) amino-terminal domain. The same 10-kDa domain was shown to anchor pp60v-src to the plasma membrane of transformed cells. Reconstitution experiments performed with nonmyristylated pp60v-src proteins revealed that these polypeptides did not interact with phospholipid vesicles. In contrast, myristylated, soluble pp60v-src molecules (including a highly purified pp60v-src preparation) could be reconstituted into liposomes, but their interaction with the liposomal bilayer was not mediated by the 10-kDa amino-terminal domain. When membrane proteins were included during reconstitution of purified pp60v-src, binding through the 10-kDa anchor was restored. A model is presented to accommodate the different types of interactions of pp60v-src with liposomes; the model postulates the existence of an additional membrane component that anchors the pp60v-src polypeptide to the phospholipid bilayer.     

Cytoskeletal association of pp60src. 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 pp60src in the detergent-resistant cytoskeleton of transformed cells. pp60src 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 pp60src with microfilament-bound target proteins.     

Isolation and partial characterization of a monoclonal antibody to the Rous sarcoma virus transforming protein pp60src.

Transformation of cells by Rous sarcoma virus is mediated by the product of the viral src gene, pp60src. A hybridoma cell line producing an immunoglobulin G3 antibody to pp60src was isolated after lymph node cells from immune mice were fused with mouse myeloma cells (P3-NS1-1). Mice were immunized with p60src purified from Escherichia coli cells expressing the src gene product. The monoclonal antibody immunoprecipitated pp60src from Rous sarcoma virus-transformed cells and recognized an antigenic determinant located in the amino-terminal third of the pp60src protein.     

Inhibition of epidermal growth factor receptor biosynthesis caused by the src oncogene product, pp60v-src.

We have previously shown that an intracellular mechanism down regulates epidermal growth factor (EGF) receptor levels in rodent fibroblasts transformed by the src oncogene (W. J. Wasilenko, L. K. Shawver, and M. J. Weber, J. Cell. Physiol. 131:450-457, 1987). We now report that this down regulation is due to an inhibition of EGF receptor biosynthesis. With Rat-1 (R1) cells infected with a temperature-sensitive src mutant, we found that 125I-labeled EGF binding to cells began to decrease soon after the activation of pp60v-src by shift down to the permissive temperature for transformation. This effect of src on EGF receptors was reversible. Pulse-chase studies with [35S]methionine-labeled cells revealed that the tyrosine protein kinase activity of pp60v-src had little if any effect on EGF receptor degradation rate. By contrast, the expression of pp60v-src caused a large reduction in the apparent rate of EGF receptor biosynthesis. Northern (RNA) blot analysis demonstrated that pp60v-src also caused marked reductions in the steady-state level of EGF receptor mRNA. These data indicate that one way the expression of the src oncogene can affect the machinery of growth control is by affecting the expression of specific genes for growth factor receptors.     

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 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.     

Monoclonal antibody against the carboxy terminal peptide of pp60src of Rous sarcoma virus reacts with native pp60src.

A monoclonal mouse antibody has been prepared against a synthetic peptide corresponding to the six carboxy-terminal amino acids (C' peptide) of the src gene product pp60v -src of Rous sarcoma virus (RSV). The antibody was able to precipitate pp60v -src and to bind pp60v -src kinase activity in a competition test, indicating that this peptide can serve as an antibody-binding site (epitope). Furthermore, the finding that three out of 28 pp60src-specific tumor-bearing rabbit (TBR) sera contained antibody against the C' peptide argues for an in vivo role for the carboxy terminus of pp60src. C' peptide-specific IgG was purified from one TBR serum using affinity chromatography, and was shown to precipitate significant amounts of pp60src, and bind most of the pp60src kinase activity from SRA, PrA, and B77-C strains of avian sarcoma virus (ASV), but not endogenous pp60c -src, a cellular homologue to the viral pp60v -src. Similar results were obtained with IgG isolated from a C' peptide immune rabbit serum. None of the three C' peptide-specific IgGs could serve as a phosphate acceptor in an immune complex protein kinase reaction.     

A 90,000-dalton binding protein common to both steroid receptors and the Rous sarcoma virus transforming protein, pp60v-src

Previous studies have shown that the avian progesterone receptor, when in the nontransformed 8 S state, is complexed to another cellular protein having a molecular weight of 90,000. In this report, we show that this receptor-binding protein is indistinguishable from the 90,000-dalton protein which associates in a complex with the Rous sarcoma virus transforming protein, pp60v-src. This identity was established by the following criteria. 1) Monoclonal antibodies directed against the pp60v-src-associated 90-kDa protein recognized the 90-kDa progesterone receptor binding protein in an immunoblot assay. Conversely, monoclonal antibodies that recognize the progesterone receptor binding protein bind to the 90-kDa protein which complexes with pp60v-src. 2) Peptide maps prepared from the 90-kDa proteins immunoprecipitated from chicken cells with monoclonal antibodies directed against either the 90-kDa receptor binding protein or the 90-kDa pp60v-src-associated protein were indistinguishable. 3) Preincubation of the progesterone receptor complex with monoclonal antibodies prepared against the pp60v-src-associated protein caused a shift in the sedimentation of the progesterone receptor. Previous studies have established that the pp60v-src-associated protein is indistinguishable from one of the major heat shock proteins which are induced under a variety of stress conditions in eukaryotic cells. These present studies implicate a new role for this 90-kDa protein in the action of steroid hormones.     

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.     

Half-life of the Rous sarcoma virus transforming protein pp60src and its associated kinase activity.

The half-life of metabolically labeled pp60src of the Prague A strain of Rous sarcoma virus and of several transformation-defective, temperature-sensitive mutants was investigated by pulse-labeling infected cells with [35S]methionine, chasing for different times, and immunoprecipitating pp60src with tumor-bearing rabbit serum. These experiments showed that pp60src has a short half-life of approximately 60 min under normal physiological conditions and that the mutant pp60src proteins have similar half-lives to the wild type, irrespective of whether the cells are kept at the nonpermissive (42 degrees C) or permissive (35 degrees C) temperature. The half-life of the pp60src -associated kinase activity was determined by monitoring its decay by the immunoglobulin G heavy chain assay after the cells had been treated with several inhibitors of protein synthesis. In these experiments the kinase half-life was much longer than expected from the half-life of pp60src. The apparent contradiction between the half-lives of the kinase activity and the [35S]methionine-labeled pp60src protein could be resolved by the observation that treatment of cells with inhibitors of protein synthesis stabilized pp60src, resulting in a greatly extended half-life. Inhibitors of protein synthesis also extended the half-life of the gag precursor polypeptide, Pr76, suggesting that a host factor(s) may be required for the efficient intracellular processing of this polypeptide to the gag proteins.     

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.     

Functional domains of the pp60v-src protein as revealed by analysis of temperature-sensitive Rous sarcoma virus mutants.

Four temperature-sensitive (ts) Rous sarcoma virus src gene mutants with lesions in different parts of the gene represent three classes of alteration in pp60src. These classes are composed of mutants with (i) heat-labile protein kinase activities both in vitro and in vivo (tsLA27 and tsLA29), (ii) heat-labile kinases in vivo but not in vitro (tsLA33), and (iii) neither in vivo nor in vitro heat-labile kinases (tsLA32). The latter class indicates the existence of structural or functional pp60src domains that are required for transformation but do not grossly affect tyrosine kinase activity.