Low level of cellular protein phosphorylation by nontransforming overproduced p60c-src.

We have previously found that Rous sarcoma virus variants in which the viral src (v-src) gene is replaced by the cellular src (c-src) gene have no transforming activity. In this study, we analyzed the basis for the inability of the p60c-src overproduced by these variants to transform cells. Phosphorylations of tyrosine residues in total cell protein or in cellular 34K protein are known to be markedly enhanced upon infection with wild-type Rous sarcoma virus. We found that these tyrosine phosphorylations were only slightly increased in the c-src-containing virus-infected cells, whereas both levels were significantly increased by infection with wild-type Rous sarcoma virus, or transforming mutant viruses which are derived from c-src-containing viruses by spontaneous mutation. Phosphorylation at tyrosine 416 of p60 itself was also extremely low in overproduced p60c-src and high in p60s of transforming mutant viruses. In immunoprecipitates with monoclonal antibody, the overproduced p60c-src had much lower casein tyrosine kinase activity than did p60v-src. We previously showed that p60 myristylation and plasma membrane localization may be required for cell transformation. p60c-src was similar to transforming p60s in these properties. These results strongly suggest that the low level of tyrosine phosphorylation by overproduced p60c-src accounts for its inability to transform cells.     

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.     

Phosphorylation of the transforming protein of Rous sarcoma virus: direct demonstration of phosphorylation of serine 17 and identification of an additional site of tyrosine phosphorylation in p60v-src of Prague Rous sarcoma virus.

We provide direct evidence that serine 17 is the major site of serine phosphorylation in p60v-src, the transforming protein of Rous sarcoma virus, and in its cellular homolog, p60c-src. The amino acid composition of the tryptic peptide containing the major site of serine phosphorylation in p60v-src was deduced by peptide map analysis of the protein labeled biosynthetically with a variety of radioactive amino acids. Manual Edman degradation revealed that the phosphorylated serine in this peptide was the amino terminal residue. These data are consistent only with the phosphorylation of serine 17. The major site of serine phosphorylation in chicken p60c-src, the cellular homolog of p60v-src, is contained in a tryptic peptide identical to that containing serine 17 in p60v-src of Schmidt Ruppin Rous sarcoma virus of subgroup A. Serine 17 is therefore also phosphorylated in p60c-src. The p60v-src protein encoded by Prague Rous sarcoma virus was found to contain two sites of tyrosine phosphorylation. The previously unrecognized site of tyrosine phosphorylation may be tyrosine 205 or possibly tyrosine 208. Treatment of Prague Rous sarcoma virus-infected cells with vanadyl ions stimulated the protein kinase activity of p60v-src and increased the phosphorylation of tyrosine 416 but not the phosphorylation of the additional site of tyrosine phosphorylation.     

Isolation and structural mapping of a human c-src gene homologous to the transforming gene (v-src) of Rous sarcoma virus.

We have utilized a lambda Charon 4A human genomic library to isolate recombinant clones harboring a highly conserved c-src locus containing nucleotide sequences homologous to the transforming gene of Rous sarcoma virus (v-src). Four overlapping clones spanning 24 kilobases of cellular DNA were analyzed by restriction endonuclease mapping. Human c-src sequences homologous to the entire v-src region are present in a 20-kilobase region that contains 11 exons as determined by restriction mapping studies utilizing hybridization to labeled DNA probes representing various subregions of the v-src gene and by preliminary DNA sequencing analyses. A considerable degree of similarity exists between the organization of the human c-src gene and that of the corresponding chicken c-src gene with respect to exon size and number. However, the human c-src locus is larger than the corresponding chicken c-src locus, because many human c-src introns are larger than those of chicken c-src. alu family repetitive sequences are present within several human c-src introns. This locus represents a highly conserved human c-src locus that is detectable in human cellular DNAs from various sources including placenta, HeLa cells, and WI-38 cells.     

Human cellular src gene: nucleotide sequence and derived amino acid sequence of the region coding for the carboxy-terminal two-thirds of pp60c-src.

The nucleotide sequence of the 3' two-thirds of a highly conserved, molecularly cloned human cellular src gene (c-src) has been determined. This region of the c-src gene encodes the tyrosine kinase domain of the cellular src protein (pp60c-src) and corresponds to exons 6 through 12 of the chicken c-src gene, as well as nucleotides 545 to 1542 of the Rous sarcoma virus src gene (v-src). The human c-src sequence is very strongly conserved with respect to both the chicken c-src and the Rous sarcoma virus v-src genes, with nearly 90% nucleotide homology observed in this region. Amino acid sequence conservation in this region is even greater; 98% of the amino acids are conserved between human and chicken c-src. Furthermore, the exon sizes and the locations of the exon-intron boundaries are identical in the human and chicken c-src genes. However, sequences within the introns have not been conserved, and the introns within the human c-src gene are significantly larger than the corresponding introns within the chicken c-src gene. The strong amino acid conservation between the carboxy-terminal two-thirds of pp60c-src of species as divergent as humans and chickens suggests that this portion of the pp60c-src protein specifies one or more functional domains that are of great importance to some aspect of normal cellular growth or differentiation.     

5''-flanking sequences that inhibit in vitro transcription of a xenopus laevis tRNA gene

We determined the nucleotide sequences of all coding regions and a significant part of the flanking regions of the chicken c-src gene, which is a cellular homolog of the v-src gene of Rous sarcoma virus. The c-src gene consists of 12 exons; the boundaries of the exons were determined by assuming that the amino acid sequence of its product, pp60c-src, is basically the same as that of pp60v-src. The deduced amino acid sequence of pp60c-src was very similar to that of pp60v-src, but the last 19 carboxy-terminal amino acids of pp60c-src were replaced by a new set of 12 amino acids of pp60v-src. The sequence encoding the carboxy-terminal sequence of pp60v-src was found 900 bp downstream from the termination codon of the c-src gene. We suggest that the c-src sequence was captured by a virus through recombination at both sides of the c-src gene, and that the recombinations occurred at the level of proviral DNA.     

Activation of protein serine/threonine kinases p42, p63, and p87 in Rous sarcoma virus-transformed cells: signal transduction/transformation-dependent MBP kinases.

We have used myelin basic protein immobilized in sodium dodecyl sulfate-polyacrylamide gels to identify protein kinases after gel electrophoresis, followed by protein kinase reactions. This technique has permitted us to detect three protein kinases in serum-deprived cells transformed by p60src. On induction of cellular transformation by a temperature-sensitive v-src, a p87 protein kinase is activated within 30 min and remains activated in fully transformed cells. The p63 protein kinase is not fully activated until 24 h but remains activated in transformed cells. The commonly studied p42MBPK is rapidly activated within 30 min, and its kinase activity decreases significantly by 24 h, when the p63 enzyme is fully activated. The p42MBPK, as well as the p63 and p87 enzymes, are stimulated by transforming p60c-src mutants but not normal c-src or nonmyristylated p60c-src. In addition, the kinase activity of p63 enzyme, but not of p42MBPK, can be induced in okadaic acid-treated chicken embryo fibroblasts, indicating that phosphatase 2A and/or phosphatase 1 may be involved in the regulation of its activity. Additional data indicate that either p42MBPK or p63 activity correlates with the stimulation of the protein kinase p90RSK. Thus, there may be two independent pathways leading to the activation of the RSK gene product.     

Protein kinase C phosphorylates pp60src at a novel site

The transforming protein of Rous sarcoma virus (pp60v-src) and its normal cellular homolog (pp60c-src) are demonstrated to be phosphorylated at serine 12 in vivo under certain conditions. We propose that protein kinase C is responsible for this modification based on the following evidence. First, the tumor promoters, 12-O-tetradecanoylphorbol-13-acetate and teleocidin, and synthetic diacylglycerol, known activators of protein kinase C in vivo, cause nearly complete phosphorylation of pp60src at serine 12. Second, among five purified serine/threonine-specific protein kinases tested, only protein kinase C phosphorylates pp60c-src and pp60v-src in vitro at serine 12. Third, purified protein kinase C phosphorylates a synthetic peptide corresponding to the N-terminal 20 amino acids of pp60c-src at serine 12. The physiological significance of this novel phosphorylation is discussed.     

Binding of pp60v-src to membranes: evidence for multiple membrane interactions.

Membrane association of pp60v-src, the myristylated transforming protein of Rous sarcoma virus, has been shown to be a receptor-mediated process, which is inhibited by myristylated src peptides containing the N-terminal 11 amino acids of the v-src sequence (MGYsrc). By cross-linking radiolabelled MGYsrc peptide to fibroblast membranes, a 32-kilodalton membrane protein was identified as a candidate src receptor. To elucidate the potential role of p32 in binding pp60v-src, we studied the relationship between binding of MGYsrc peptide and pp60v-src polypeptide to cellular membranes. The subcellular membrane distribution of p32 was distinct from that of pp60v-src in transformed cells. Moreover, under certain defined in vitro conditions, it was possible to inhibit peptide cross-linking to p32 without significantly affecting pp60v-src membrane binding. However, when internal sequences were removed from pp60v-src, the binding characteristics of the src deletion polypeptide and MGYsrc peptide became identical. These data indicate that the presence of internal membrane binding domains influences the interaction of myristylated N-terminal src sequences with p32, and suggest that accessory binding factors might be involved in establishing stable contact between pp60v-src and the membrane phospholipid bilayer.     

Deletions within the amino-terminal half of the c-src gene product that alter the functional activity of the protein.

To examine how amino acid sequences outside of the catalytic domain of pp60c-src influence the functional activity of this protein, we have introduced deletion mutations within the amino-terminal half of pp60c-src. These mutations caused distinct changes in the biochemical properties of the c-src gene products and in the properties of cells infected with retroviruses carrying these mutant c-src genes. Cells expressing the c-srcNX protein, which contains a deletion of amino acids 15 to 89, displayed a refractile, spindle-shaped morphology, formed intermediate-sized, tightly packed colonies in soft agar, and contained elevated levels of cellular phosphotyrosine-containing proteins. Thus, deletion of amino acids 15 to 89 can activate the kinase activity and transforming potential of the c-src gene product. Deletion of amino acids 112 to 225, however, did not increase the kinase activity or transforming ability of pp60c-src; indeed, deletion of these sequences in c-srcHP suppressed phenotypic alterations induced by pp60c-src. Cells expressing the c-srcNP or c-srcBS gene products (containing deletions of amino acids 15 to 225 and 55 to 169, respectively) displayed a fusiform, refractile morphology and formed diffuse colonies in soft agar; the mutant proteins displayed an increased in vitro protein-tyrosine kinase activity. However, only a few cellular proteins contained elevated levels of phosphotyrosine in vivo. Thus, deletions downstream of amino acid 89 severely restricted the ability of c-src to phosphorylate cellular substrates in vivo without affecting the intrinsic tyrosine kinase activity of the c-src gene product. These results suggest the existence of at least two modulatory regions within the amino-terminal half of pp60c-src that are important for the regulation of tyrosine kinase activity and for the interaction of pp60c-src with cellular substrates.     

Deletions in the SH2 domain of p60v-src prevent association with the detergent-insoluble cellular matrix.

p60v-src has been shown to associate with a detergent-insoluble cellular matrix containing cytoskeletal proteins, but p60c-src does not bind to this matrix. We analyzed the association of mutant src proteins with the matrix and found that mutants which lack an amino-terminal portion (residues 149 to 169) of the SH2 domain cannot bind to the matrix. Neither the SH3 region nor other portions of the SH2 region were required for association. We also tested protein kinase-defective mutants and chimeras of p60v-src and p60c-src. We found a strong correlation between the kinase activity of p60src and its association with the detergent-insoluble matrix. Double infection of kinase-defective and kinase-active mutants did not result in matrix binding of the kinase-defective src proteins. We also found that Tyr-416, the major site of autophosphorylation in p60v-src, was not required for matrix association.     

Characterization of partially activated p60c-src in chicken embryo fibroblasts.

Previous studies identified the amino acid changes involved in the activation of p60c-src and revealed that the activation accompanies an alteration of its tyrosine-phosphorylation site. We show here that p60c-src that had been converted to transforming protein by amino acid substitution of the c-src gene either at position 63, 95 and 96, or 338 (J. Kato, T. Takeya, C. Grandori, H. Iba, J. B. Levy, and H. Hanafusa, Mol. Cell. Biol. 6:4155-4160, 1986) and encoded in a Rous sarcoma virus variant was phosphorylated on both Tyr-416 and Tyr-527 in chicken embryo fibroblasts. The results obtained from protease V8 analysis, tryptic peptide mapping, and fractionation with nonionic detergent indicated that the p60 of each variant was present in two forms in the population of the virus-infected cells; one was phosphorylated on Tyr-416, and the other was phosphorylated on Tyr-527. On the other hand, colonies isolated in soft agar contained exclusively p60 of which only Tyr-416 was phosphorylated. These results implied that the limited population of p60 was activated in these Rous sarcoma virus variant-infected chicken embryo fibroblasts and that the activated p60 was concentrated in transformed cells. Furthermore, these two forms of p60 differed in their affinity for the detergent-insoluble cellular matrix in spite of their identical primary amino acid sequences, suggesting that the effect of alteration of the tyrosine phosphorylation site was coupled with the degree of stability of this association.     

pp60c-src has less affinity for the detergent-insoluble cellular matrix than do pp60v-src and other viral protein-tyrosine kinases.

A difference in affinity for a Nonidet P-40-insoluble cellular matrix was observed between the products of the viral and cellular src genes. It has previously been demonstrated that pp60v-src is associated with a detergent-insoluble matrix containing the cellular cytoskeleton (J. G. Burr, G. Dreyfuss, S. Penman, and J. M. Buchanan, Proc. Natl. Acad. Sci. USA 77:3484-3488, 1980). We observed a similar association of the transforming proteins of Fujinami sarcoma virus (P130gag-fps) and Yamaguchi 73 avian sarcoma virus (P90gag-yes), both of which are tyrosine-specific protein kinases. However, we found that the endogenous c-src product, pp60c-src, was not tightly bound to the detergent-insoluble matrix. This does not appear to have been due to differences in the cytoskeleton between transformed and nontransformed cells since pp60c-src was also solubilized by nonionic detergent in cells transformed by Rous sarcoma virus. This difference in the affinities of the v-src and c-src products for cytoskeletal proteins may contribute to the inability of pp60c-src to transform cells.     

Features of the pp60v-src carboxyl terminus that are required for transformation.

Analysis of the biological and biochemical activities of pp60recombinant-src proteins encoded by 12 carboxyl-terminal mutants showed that a wide family of alternate src carboxyl termini permit complete transforming and kinase activities. src proteins having carboxyl termini which are up to 10 amino acids longer than that of pp60c-src (17 amino acids longer than that of pp60v-src) still permit transformation. Transformation-positive mutations preserve leucine-516, a residue which is highly conserved in protein-tyrosine kinase sequences; removal causes in vivo protein instability. Successive deletion mutants show that this residue is at the boundary of a region required for kinase activity. pp60src which is truncated just outside this point still transforms cells and binds both pp50 and pp90 cellular proteins.     

Antiserum specific for the carboxy terminus of the transforming protein of Rous sarcoma virus

An antiserum specific for the carboxy terminus of p60src, the transforming protein of Rous sarcoma virus, was produced by immunization of rabbits with a conjugate of bovine serum albumin and the synthetic peptide NH2-Tyr-Val-Leu-Glu-Val-Ala-Glu-COOH. The carboxy-terminal six amino acids of this peptide correspond in sequence to that deduced for the carboxy terminus of the p60src of the Schmidt-Ruppin strain of Rous sarcoma virus of subgroup A. The p60src proteins of the several strains of Rous sarcoma virus and the cellular homolog of the viral transforming protein, p60c-src, comprise a polymorphic family of polypeptides. The anticarboxy-terminal serum reacted readily with the p60src proteins of three different strains of Rous sarcoma virus. In contrast, no precipitation of cellular p60c-src could be detected with this serum. This suggests that the viral p60src proteins have identical carboxy termini and that the carboxy terminus of cellular p60c-src may be different from that of viral p60src. The anticarboxy-terminal serum reacted poorly with the subpopulation of viral p60src which is present in a complex with two cellular phosphoproteins. Apparently, the presence of the two cellular proteins interferes with the recognition of p60src by the anticarboxy-terminal serum. It seems likely, therefore, that these two cellular proteins bind to the carboxy-terminal domain of p60src.     

Suppression of src transformation by overexpression of full-length GTPase-activating protein (GAP) or of the GAP C terminus.

Overexpression of the full-length GTPase-activating protein (GAP) has recently been shown to suppress c-ras transformation of NIH 3T3 cells but not v-ras transformation (36). Here, we show that focus formation induced by c-src was inhibited by approximately 80% when cotransfected with a plasmid encoding full-length GAP. In a similar assay, focus formation by the activated c-src (Tyr-527 to Phe) gene was inhibited by 33%. Cotransfection of the GAP C terminus coding sequences (which encode the GTPase-accelerating domain) with c-src or c-src527F inhibited transformation more efficiently than did the full-length GAP, while the GAP N terminus coding sequences had no effect on src transformation. When cells transformed by c-ras, c-src, c-src527F, or v-src were transfected with GAP or the GAP C terminus sequence in the presence of a selectable marker, 40 to 85% of the resistant colonies were found to be morphologically revertant. The GAP C terminus induced reversion of each src-transformed cell line more efficiently than the full-length GAP, but this was not the case for reversion of c-ras transformation. Biochemical analysis of v-src revertant subclones showed that the reversion correlated with overexpression of full-length GAP or the GAP C terminus. There was no decrease in the level of pp60src expression or the level of protein-tyrosine phosphorylation in vivo. We conclude that GAP can suppress transformation by src via inhibition of endogenous ras activity, without inhibiting in vivo tyrosine phosphorylation of cellular proteins induced by pp60src, and that src may negatively regulate GAP's inhibitory action on endogenous ras.     

Activation of the proto-oncogene p60c-src by point mutations in the SH2 domain.

To investigate the importance of a conserved region spanning residues 137 to 241 in the noncatalytic domain of p60c-src (SH2 region), we used oligonucleotide-directed mutagenesis to change residues that are highly conserved in this region. Chicken embryo fibroblasts infected with a p60c-src variant containing arginine instead of tryptophan at residue 148 (W148R) appeared more rounded than cells overexpressing a normal c-src gene, and they formed colonies in soft agar. p60c-src variants containing serine instead of arginine at residue 155 (R155S) or isoleucine instead of glycine at residue 170 (G170I) also appeared transformed and were anchorage independent, but to a lesser extent than W148R. Mutation of residue 201 from histidine to leucine (H201L) had no observable effect. The in vitro kinase activity of cells infected with W148R or G170I was elevated twofold. Expression of p60W148R (or, to a lesser extent, of p60G170I) increased the number of proteins phosphorylated on tyrosine in infected cells. All of the mutants were phosphorylated in vivo on Tyr-527, instead of Tyr-416 as observed for p60v-src. Immunoprecipitated p60W148R and p60G170I were found to be associated with a phosphatidylinositol kinase activity, a factor which appears to be necessary for transformation by tyrosine-specific protein kinases. These results show that a single point mutation in the SH2 region of the cellular src gene can activate its transforming potential. This type of activation is in a new category of alterations at the amino terminus that activate but do not cause a shift in phosphorylation at the carboxy terminus.     

Restriction of the in vitro and in vivo tyrosine protein kinase activities of pp60c-src relative to pp60v-src.

The tyrosine protein kinase activities of pp60c-src and pp60v-src were compared. The activities were qualitatively similar in vitro when the src proteins were bound in an immune complex with monoclonal antibody; both proteins utilized either ATP or GTP as phosphate donors, preferred Mn2+ to Mg2+, and had similar exogenous substrate specificities. The specific activity of pp60c-src was about 10-fold lower than that of pp60v-src for exogenous substrate phosphorylation but was only 1.1- to 2-fold lower than that of pp60v-src for autophosphorylation. Six glycolytic enzymes, including three not previously identified as substrates for pp60src phosphorylation, were phosphorylated by both pp60c-src and pp60v-src. Levels of pp60c-src fourfold higher than the amount of pp60v-src in src-plasmid-transformed cells did not detectably alter the level of phosphotyrosine in cellular proteins, but increasing the expression of pp60c-src another twofold (which induces cells to form foci in monolayer culture (P.J. Johnson, P.M. Coussens, A.V. Danko, and D. Shalloway, Mol. Cell. Biol. 5:1073-1083, 1985) resulted in a threefold increase in the level of cellular protein phosphotyrosine. Immunoprecipitation and analysis of the alkali-stable phosphoproteins by two-dimensional electrophoresis showed that, in contrast to pp60v-src-transformed cells, pp36 and enolase are only weakly phosphorylated in these high-level pp60c-src overexpresser cells. Even allowing for the in vitro differences in specific activities of phosphorylation, these results suggest that the pp60c-src tyrosine protein phosphorylating activity may be restricted relative to that of pp60v-src by additional in vivo mechanisms.