Altered sites of tyrosine phosphorylation in pp60c-src associated with polyomavirus middle tumor antigen.

We characterized the tyrosine phosphorylation sites of free pp60c-src and of pp60c-src associated with the polyomavirus middle tumor antigen (mT) in transformed avian and rodent cells. The sites of tyrosine phosphorylation in the two populations of pp60c-src were different, both in vitro and in vivo. Free pp60c-src was phosphorylated in vitro at a single site, tyrosine 416. pp60c-src associated with mT was phosphorylated in vitro on tyrosine 416 and on one or more additional tyrosine residues located in the amino-terminal region of the molecule. Free pp60c-src in polyomavirus mT-transformed cells was phosphorylated in vivo on tyrosine 527. In contrast, pp60c-src associated with mT was phosphorylated in vivo on tyrosine 416 and not detectably on tyrosine 527. Thus, the in vivo phosphorylation sites of pp60c-src associated with mT in transformed cells are identical to those of pp60v-src, the Rous sarcoma virus transforming protein. The results suggest that altered phosphorylation of pp60c-src associated with mT may play a role in the enhancement of the pp60c-src protein kinase activity and in cell transformation by polyomavirus.     

Forms of pp60v-src isolated from Rous sarcoma virus-transformed cells.

It has previously been shown that an electrophoretic variant form of the Rous sarcoma virus transforming protein, pp60v-src, exists in src-transformed cells. This variant, which was readily observed in vanadate-treated cells, was characterized as possessing extensive amino-terminal domain phosphotyrosine modification. Its appearance was further correlated with increased src-specific protein kinase activity. In this study, we used a src-specific monoclonal antibody (MAb) to resolve immunologic forms of pp60v-src. The MAb was able to distinguish between two populations of typical lower-band pp60v-src and was unreactive with the electrophoretic variant upper-band pp60v-src species. Using serial immunoprecipitations, we resolved four populations of pp60v-src: src protein either immunoreactive or unreactive with the MAb from both untreated and vanadate-treated transformed cells. The pp60v-src in each fraction displayed a distinct phosphoamino acid composition and tryptic phosphopeptide profile. However, analysis of their tyrosyl kinase specific activities showed that the immunologically resolved populations of pp60v-src from a given culture did not differ. Both pp60v-src fractions from vanadate-treated cells exhibited similar kinase specific activities, which were greatly enhanced over those of enzyme preparations from untreated cells. Since the MAb-reactive pp60v-src fraction from vanadate-treated cells lacked the electrophoretic variant upper-band pp60v-src species yet still possessed enhanced enzymatic specific activity, the initially stated correlation between the appearance of the electrophoretic variant src form and increased src kinase activity breaks down. These results suggest that yet to be defined modifications of the src protein may be involved in its functional regulation.     

Requirement of phosphatidylinositol-3 kinase modification for its association with p60src.

When purified p60v-src was mixed with lysates of chicken embryo fibroblasts and immunoprecipitated with anti-Src antibody, phosphatidylinositol (PI)-3 kinase activity was found to be present in the Src protein immunoprecipitates. The level of bound PI-3 kinase activity was 5 to 10 times higher in lysates obtained from cells transformed by the src, fps, or yes oncogene than in lysates of uninfected cells. This increase in associated PI-3 kinase activity appears to be due to increased binding of this enzyme to p60v-src. This change most likely resulted from tyrosine phosphorylation of PI-3 kinase or an associated protein, since the PI-3 kinase activity that can bind to p60v-src was depleted by antiphosphotyrosine antibody. Binding of PI-3 kinase did not require either p60src protein kinase activity or autophosphorylation of p60v-src tyrosine residues. Furthermore, binding was markedly decreased by deletions in the N-terminal SH2 region but unchanged by deletion of the C-terminal half of p60v-src containing the catalytic domain. Taking these data together, it appears that PI-3 kinase or its associated protein is phosphorylated on tyrosine and that the phosphorylated form can bind to the N-terminal half of p60v-src, which contains the SH2 domain.     

Phosphorylation and activation of epidermal growth factor receptors in cells transformed by the src oncogene.

Because functionally significant substrates for the tyrosyl protein kinase activity of pp60v-src are likely to include membrane-associated proteins involved in normal growth control, we have tested the hypothesis that pp60v-src could phosphorylate and alter the signaling activity of transmembrane growth factor receptors. We have found that the epidermal growth factor (EGF) receptor becomes constitutively phosphorylated on tyrosine in cells transformed by the src oncogene and in addition displays elevated levels of phosphoserine and phosphothreonine. High-performance liquid chromatography phosphopeptide mapping revealed two predominant sites of tyrosine phosphorylation, both of which differed from the major sites of receptor autophosphorylation; thus, the src-induced phosphorylation is unlikely to occur via an autocrine mechanism. To determine whether pp60v-src altered the signaling activity of the EGF receptor, we analyzed the tyrosine phosphorylation of phospholipase C-gamma, since phosphorylation of this enzyme occurs in response to activation of the EGF receptor but not in response to pp60v-src alone. We found that in cells coexpressing pp60v-src and the EGF receptor, phospholipase C-gamma was constitutively phosphorylated, a result we interpret as indicating that the signaling activity of the EGF receptor was altered in the src-transformed cells. These findings suggest that pp60v-src-induced alterations in phosphorylation and function of growth regulatory receptors could play an important role in generating the phenotypic changes associated with malignant transformation.     

The action of v-src on gap junctional permeability is modulated by pH

The product of the viral src gene (v-src) is the protein tyrosine kinase pp60v-src. Among the known consequences of pp60v-src activity is the reduction in permeability of gap junctions, an effect that is counteracted by the calcium antagonist TMB-8 (8-N,N-[diethylamino]octyl-3,4,5-trimethoxybenzoate). We show here that a decrease in intracellular pH (pHi) also counteracts the v-src effect: junctional permeability of cells containing active v-src kinase rose with decreasing pHi in the range 7.15 to 6.75, whereas junctional permeability of cells containing inactive v-src kinase or no v-src at all was insensitive to pH in that range. Low pH also counteracted the known action of diacylglycerol on junction, but only when pp60v-src kinase was inactive. Immunoblots of whole-cell lysates using an antibody against phosphotyrosine show that phosphorylation on tyrosine of at least one cellular protein, specific for pp60v-src kinase activity, was reduced by low pH but not by TMB-8. These results suggest that TMB-8 does not inhibit v-src action on junctional permeability by interfering with tyrosine phosphorylation of a protein crucial for closure of gap junction channels, but that the inhibition by low pH may be via this mechanism.     

Stable association of activated pp60src with two tyrosine-phosphorylated cellular proteins.

We have identified two phosphotyrosine-containing cellular proteins with relative molecular masses of 130,000 (pp130) and 110,000 (pp110) daltons in chicken embryo cells that coimmunoprecipitated with pp60v-src and activated forms of chicken pp60c-src (pp60(527)F). Most if not all of the tyrosine-phosphorylated forms of pp130 and pp110 could be immunoprecipitated from lysates with any of several src protein-specific monoclonal antibodies directed against at least three spatially distinct epitopes. Consequently, of the more than 15 prominent phosphoproteins detected on immunoblots with phosphotyrosine-specific antibodies, pp130 and pp110 were selectively removed by src protein-specific immunoprecipitation, and their presence in the immunoprecipitates appears to have been due to a direct interaction with activated src proteins. src protein variants that induce different morphological phenotypes were altered in their ability to form detergent-stable complexes with pp130 and pp110 or with pp110 alone. Mutant src proteins, defective for myristylation, showed increased tyrosine phosphorylation of and association with pp110. Expression of src variants with mutations in the A box (pp60dl92/527F) or B box (pp60dl155/527F) of the src homology region induced differences in phosphorylation of pp130 and pp110, as well as changes in their association with variant src proteins. Sequences within the B-box region appeared to be necessary for stable complex formation with pp130 and pp110 and may be involved in the interaction of activated src proteins with cellular substrates.     

In vivo effect of sodium orthovanadate on pp60c-src kinase.

We have compared the tyrosine kinase activity of pp60c-src isolated from intact chicken embryo fibroblasts treated with micromolar sodium orthovanadate for 4 h and from untreated cells. We found an approximate 50% reduction in both autophosphorylation of pp60c-src and phosphorylation of casein when examined in the immune complex kinase assay. The reduction of in vitro enzymatic activity correlated with a vanadate-induced increase in in vivo phosphorylation of pp60c-src at the major site of tyrosine phosphorylation in the carboxyl-terminal half of the molecule and at serine in the amino-terminal half of the molecule. Our observations in vivo and those of Courtneidge in vitro (EMBO J. 4:1471-1477, 1985) suggest that vanadate may enhance a cellular regulatory mechanism that inhibits the activity of pp60c-src in normal cells. A likely candidate for this mechanism is phosphorylation at a tyrosine residue distinct from tyrosine 416, probably tyrosine 527 in the carboxyl-terminal sequence of amino acids unique to pp60c-src. The regulatory role, if any, of serine phosphorylation in pp60c-src remains unclear. The 36-kilodalton phosphoprotein, a substrate of pp60v-src, showed a significant phosphorylation at tyrosine after treatment of normal chicken embryo fibroblasts with vanadate. Assuming that pp60c-src is inhibited intracellularly by vanadate, either another tyrosine kinase is stimulated by vanadate (e.g., a growth factor receptor) or the 36-kilodalton phosphoprotein in normal cells is no longer rapidly dephosphorylated by a tyrosine phosphatase in the presence of vanadate.     

Structural and functional modification of pp60c-src associated with polyoma middle tumor antigen from infected or transformed cells.

The polyoma middle tumor antigen (MTAg) associates with the src proto-oncogene product pp60c-src in infected or transformed rodent cells. The tyrosine protein kinase activity of pp60c-src, as measured by in vitro phosphorylation of pp60c-src itself or the exogenous substrate enolase, was increased 10- to 20-fold in cells transformed or infected with transformation-competent polyoma virus compared with controls. pp60c-src associated with MTAg and precipitated with polyoma antitumor serum had a novel site(s) of in vitro tyrosine phosphorylation within its amino-terminal domain. These observations suggest that association of MTAg with pp60c-src alters the accessibility of pp60c-src tyrosine residues for phosphorylation in vitro and increases pp60c-src protein kinase activity. Several transformation-defective mutants of MTAg did not cause amino-terminal tyrosine phosphorylation of pp60c-src in vitro or enhance its protein kinase activity, suggesting that these properties correlate with the transforming ability of MTAg. However, one transformation-defective MTAg mutant, dl1015, did cause amino-terminal tyrosine phosphorylation of pp60c-src in vitro and did enhance its protein kinase activity. This suggests that properties of MTAg, in addition to modifying the structure and function of pp60c-src, may be important for transformation.     

Characterization of pp60src phosphorylation in vitro in Rous sarcoma virus-transformed cell membranes.

Phosphorylation of the src gene product pp60v-src was studied in plasma membrane fractions prepared from Rous sarcoma virus-transformed vole cells. Upon addition of [gamma-32P]ATP to isolated membrane vesicles, phosphate was incorporated into a 60,000-dalton polypeptide identified as pp60v-src. In the presence of vanadate, pp60v-src phosphorylation was stimulated ca. 30-fold. At low concentrations of ATP (1 microM), this reaction occurred almost exclusively on the carboxy-terminal 26,000-dalton region of pp60v-src. However, at higher ATP concentrations (100 microM), additional sites of phosphorylation were evident in the amino-terminal 34,000-dalton region. Kinetic analyses, performed under conditions in which ATP hydrolysis was minimal, revealed that the phosphorylation reaction at the carboxy terminus exhibited a higher Vmax and a lower Km for ATP than those occurring at the amino terminus. In addition, the amino-terminal region of pp60v-src was more rapidly dephosphorylated than the carboxy-terminal region. These results indicate that interaction of pp60v-src with the plasma membrane may limit the extent of amino-terminal phosphorylation by lowering the rate of the reaction and the affinity for the substrate while increasing its susceptibility to phosphoprotein phosphatases. We suggest that the use of transformed-cell membrane preparations provides a model system for studying the possible regulatory roles of phosphorylation and dephosphorylation on pp60v-src function.     

Intracellular localization and processing of pp60v-src proteins expressed by two distinct temperature-sensitive mutants of Rous sarcoma virus.

The transforming protein of Rous sarcoma virus, pp60v-src, is known to be a tyrosine protein kinase, but the mechanism of cell transformation remains unclear. In further investigating pp60v-src structure and function, we have analyzed two temperature-sensitive (ts) Rous sarcoma virus src gene mutants, tsLA29 and tsLA32. The mutations in tsLA29 and tsLA32 map in the carboxy-terminal region and the amino-terminal half of pp60v-src, respectively, and encode mutant proteins with either temperature-labile (tsLA29) or -stable (tsLA32) kinase activities. Here we examined the intracellular processing and localization of these pp60v-src mutants and extended our characterization of transformation parameters expressed by cells infected by the Rous sarcoma virus variants. No obvious defects in functional integrity of the tsLA32 pp60v-src could yet be demonstrated, whereas the tsLA29 pp60v-src was perturbed not only in kinase activity, but also in aspects of protein processing and localization. Analysis of transformation parameters expressed by infected cells demonstrated the complete temperature lability of both mutants.     

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.     

Polyamines are essential for cell transformation by pp60v-src: delineation of molecular events relevant for the transformed phenotype

Ornithine decarboxylase (ODC), the key enzyme of polyamine biosynthesis, becomes upregulated during cell proliferation and transformation. Here we show that intact ODC activity is needed for the acquisition of a transformed phenotype in rat 2R cells infected with a temperature-sensitive mutant of Rous sarcoma virus. Addition of the ODC inhibitor alpha-difluoromethyl ornithine (DFMO) to the cells (in polyamine-free medium) before shift to permissive temperature prevented the depolymerization of filamentous actin and morphological transformation. Polyamine supplementation restored the transforming potential of pp60v-src. DFMO did not interfere with the expression of pp60v-src or its in vitro tyrosine kinase activity. The tyrosine phosphorylation of most cellular proteins, including ras GAP, did not either display clear temperature- or DFMO-sensitive changes. A marked increase was, however, observed in the tyrosine phosphorylation of phosphatidylinositol 3-kinase and proteins of 33 and 36 kD upon the temperature shift, and these hyperphosphorylations were partially inhibited by DFMO. A DFMO-sensitive increase was also found in the total phosphorylation of calpactins I and II. The well-documented association of GAP with the phosphotyrosine-containing proteins p190 and p62 did not correlate with transformation, but a novel 42-kD tyrosine phosphorylated protein was complexed with GAP in a polyamine- and transformation-dependent manner. Further, tyrosine phosphorylated proteins of 130, 80/85, and 36 kD were found to coimmunoprecipitate with pp60v-src in a transformation-related manner. Altogether, this model offers a tool for sorting out the protein phosphorylations and associations critical for the transformed phenotype triggered by pp60v- src, and implicates a pivotal role for polyamines in cell transformation.     

Rous sarcoma virus variants that encode src proteins with an altered carboxy terminus are defective for cellular transformation.

The src gene of Rous sarcoma virus (v-src) and its cellular homolog, the c-src gene, share extensive sequence homology. The most notable differences between these genes reside in the region encoding the carboxy terminus of the src proteins. We constructed mutations within the 3' end of the v-src gene to determine the significance of this region to the transforming potential of the v-src protein, pp60v-src. The mutants CHdl300 and CHis1511 contain mutations that alter the last 23 amino acids of pp60v-src, whereas the mutant CHis1545-C contains a linker insertion that alters the last 11 amino acids of pp60v-src, and the mutant CHis1545-H contains a linker insertion that results in a 9-amino-acid insertion at position 415. Plasmids bearing each of these mutations were unable to transform chicken cells when introduced into these cells by DNA transfection. In addition, the structurally altered src proteins encoded by the mutants had much-reduced levels of tyrosine protein kinase activity in vivo, as measured by autophosphorylation and phosphorylation of the 34,000-Mr cellular protein, and in vitro, as determined by measuring the level of pp60src autophosphorylation. These data indicate that the carboxy-terminal amino acid sequences play an important role in maintaining the structure of the catalytic domain of pp60v-src. In contrast, the transfection of chicken cells with plasmid DNA containing a chimeric v-c-src gene resulted in morphological cell transformation and the synthesis of an enzymatically active hybrid protein. Therefore, the carboxy-terminal sequence alterations observed in the c-src protein do not alone serve to alter the functional activity of a hybrid v-c-src protein appreciably.     

A mutation at the ATP-binding site of pp60v-src abolishes kinase activity, transformation, and tumorigenicity.

We constructed a mutant, called RSV-SF2, at the ATP-binding site of pp60v-src. In this mutant, lysine-295 is replaced with methionine. SF2 pp60v-src was found to have a half-life similar to that of wild-type pp60v-src and was localized in the membranous fraction of the cell. Rat cells expressing SF2 pp60v-src were morphologically untransformed and do not form tumors. The SF2 pp60v-src isolated from these cells lacked kinase activity with either specific immunoglobulin or other substrates, and expression of SF2 pp60v-src failed to cause an increase of total phosphotyrosine in the proteins of infected cells. Wild-type pp60v-src was phosphorylated on serine and tyrosine in infected cells, and the analogous phosphorylations could also be carried out in vitro. Phosphorylation of serine was catalyzed by a cyclic AMP-dependent protein kinase, and phosphorylation of tyrosine was perhaps catalyzed by pp60v-src itself. By contrast, SF2 pp60v-src could not be phosphorylated on serine or tyrosine either in infected cells or in vitro. These findings strengthen the belief that the phosphotransferase activity of pp60v-src is required for neoplastic transformation by the protein and suggest that the binding of ATP to pp60v-src elicits an allosteric change required for phosphorylation of serine in the protein.     

Phosphorylation of tyrosine-416 is not required for the transforming properties and kinase activity of pp60v-src

A mutant in src, the oncogene of Rous sarcoma virus, has been constructed in which the major phosphorylated tyrosine (Tyr-416, located in the carboxy-terminal half of the protein) has been replaced by phenylalanine. Mouse cells transformed with this mutant src form foci and grow in soft agar, indicative of a transformed state. Also, the mutant protein retains the wild-type ability to phosphorylate proteins on tyrosine. Partial proteolysis revealed that the carboxy-terminal half of the mutant protein was still phosphorylated, although apparently to a lesser extent. Analysis indicated that this residual phosphorylation was on tyrosine. We conclude that the major tyrosine phosphorylation in pp60v-src is not required for two of the protein's notable properties--protein kinase activity and transformation of cultured cells.     

Inhibition of the tyrosine kinase activity of v-src, v-fgr, and v-yes gene products by a monoclonal antibody which binds both amino and carboxy peptide fragments of pp60v-src.

A monoclonal antibody, R2D2, raised to the src gene product of Rous sarcoma virus was found to inhibit the tyrosine protein kinase activity of pp60v-src in autophosphorylation reactions and in reactions involving exogenously added substrates, such as casein and histone. R2D2 also inhibited the enzymatic activity of two related viral transforming proteins, pp70gag-fgr and pp90gag-yes. The inhibitory ability of R2D2 was dependent upon immunoglobulin concentration and could be demonstrated in both immune complexes formed directly with R2D2 and preformed immune complexes to which R2D2 was added. Binding sites in both the amino-terminal 110 amino acid residues and the carboxy-terminal 240 amino acids of pp60v-src were identified for R2D2. These results indicate that at least part of the epitope recognized by R2D2 resides within a region of the src protein which is required for protein kinase activity. The localization of the R2D2 epitope to the amino- as well as to the carboxy-terminal portions of pp60v-src, together with results of studies analyzing the relative binding efficiencies of R2D2 to the intact protein and to V-8 proteolytic fragments of pp60v-src, are consistent with the view that the R2D2 epitope is conformational in nature and that it is assembled from residues contained within both N-terminal and C-terminal regions of the molecule.     

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.     

Biochemical properties of p60v-src mutants that induce different cell transformation parameters.

PA101 and PA104 are Rous sarcoma virus variants that are differentially temperature sensitive in cell transformation parameters, including stimulation of cell proliferation, morphological alteration, and anchorage independence. To investigate the biochemical basis for the differential expression of these parameters, the tyrosine kinase activity and subcellular localization of the mutant p60v-src proteins encoded in the variants were examined. Analysis of chimeric src proteins derived from the mutant proteins revealed that lesions in the kinase domain inhibit in vitro kinase activity and confer temperature sensitivity on tyrosine phosphorylation of cellular protein p34 in vivo. The amino-terminal portions of the mutant src proteins also influence tyrosine phosphorylation in vivo and in vitro, which is consistent with an interaction between an amino-terminal region and the kinase domain. Large proportions of the mutant src proteins exist in soluble complexes with cellular proteins p50 and p90, even though the src proteins are myristylated. The formation of these soluble complexes segregates with lesions in the kinase domain and is independent of temperature. Our results demonstrate that the transformation parameters examined correlate to a limited extent with p34 phosphorylation but not with the levels of in vitro kinase activity or soluble complex formation.