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.     

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.     

Development of anti-pp60src serum with antigen produced in Escherichia coli

We have purified p60^src from bacterial recombinants which direct the synthesis of the Rous sarcoma virus transforming gene (src) product. This protein was injected into rabbits, and they produced a highly cross-reactive serum which can recognize the src protein from many different strains of Rous sarcoma virus.     

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 Major Site of Phosphorylation within the Rous Sarcoma Virus MA Protein Is Not Required for Replication

About one-third of the MA protein in Rous sarcoma virus (RSV) is phosphorylated. Previous analyses of this fraction have suggested that serine residues 68 and 106 are the major sites of phosphorylation. As a follow-up to that study, we have characterized mutants which have these putative phosphorylation sites changed to alanine, either separately or together. None of the substitutions (S68A, S106A, or S68/106A) had an effect on the budding efficiency or infectivity of the virus. Upon examination of the ³²P-labeled viral proteins, we found that the S68A substitution did not affect phosphorylation in vivo at all. In contrast, the S106A substitution prevented all detectable phosphorylation of MA, suggesting that there is only one major site of phosphorylation in MA. We also found that the RSV MA protein is phosphorylated on tyrosine, but the amount was low and detectable only with large numbers of virions and an antibody specific for phosphotyrosine.     

Localization of N6-methyladenosine in the Rous sarcoma virus genome.

The 10,000-nucleotide RNA genome of the Prague strain, subgroup B (PR-B) of Rous sarcoma virus, was found to contain 11.6 ± 0.5 residues of m⁶Ap by quantitative analysis of ³²P-labeled virion RNA after complete RNAase digestion. Approximately ten of the m⁶Ap residues are located, without obvious clustering, in that region of the genome between 500 and 4000 nucleotides from the 3′ poly(A) end. The src gene, which is required for transformation, and part of the env gene, which codes for the major viral envelope glycoprotein, have previously been mapped in this region of the viral genome. A transformation-defective deletion mutant of PR-B Rous sarcoma virus, which lacks the src gene, has 7.0 ± 0.2 m⁶Ap residues per RNA subunit. This supports our mapping of a portion of the m⁶A residues in src and suggests that this methylation is specific to certain regions of the genome. The possible significance of this result for Rous sarcoma virus RNA processing and translation is discussed.     

Molecular events leading to enhanced glucose transport in Rous sarcoma virus-transformed cells

Transformation by Rous sarcoma virus results in a dramatic increase in the rate at which the transformed cells transport glucose across the cell membrane. The increased transport rate is a consequence of an increased number of transporters in the transformed cells. Utilizing antibody raised against the purified human erythrocyte glucose transporter, we have identified the glucose transporter as a membrane glycoprotein with a monomer Mr of approximately 41,000. The increased rate of glucose transport is dependent on the activity of pp60src, the transforming protein of Rous sarcoma virus. This protein has been shown to be a protein kinase that phosphorylates on tyrosine residues. We have examined the tyrosine phosphorylation of a major cellular protein of Mr 36,000 in cells infected with a panel of partially transforming mutants of Rous sarcoma virus. One of these mutants (CU2) increases the rate of glucose transport only slightly and does not render the infected cells fully anchorage independent or tumorigenic (although other transformation parameters are fully induced). Cells infected with this mutant display a 36,000-dalton protein that is phosphorylated to a considerably lesser extent than cells infected with wild-type virus. Analyses of this sort may help to identify the cellular targets of pp60src whose phosphorylation is necessary for the increased glucose transport rate.     

Phosphorylation of talin at tyrosine in Rous sarcoma virus-transformed cells.

The cytoskeletal protein talin was found to undergo enhanced phosphorylation at tyrosine residues in chicken embryo fibroblasts following transformation by Rous sarcoma virus. An increase in the tyrosine phosphorylation of talin was also observed within 6 h in cells infected by the temperature-sensitive mutant tsNY68 after a shift from the nonpermissive to the permissive temperature. The overall extent of phosphorylation was 0.07 mol of phosphate per mol of talin and was not appreciably altered by transformation. In uninfected cells talin was shown to be phosphorylated at multiple sites by tryptic peptide mapping. Following transformation most of these sites remained phosphorylated, to the same or to a lesser extent, while novel, phosphotyrosine-containing phosphopeptides appeared. Talin was phosphorylated at tyrosine in cells infected by Rous sarcoma virus mutants which induce altered or partial transformation morphologies; thus the increased phosphorylation of talin at tyrosine occurred irrespective of the morphology induced. Transformation by Y73 also induced elevated levels of phosphotyrosine in talin, whereas transformation by the avian erythroblastosis and Fujinami sarcoma viruses did not.     

Characterization of protein kinase activity associated with the transforming gene product of Fujinami sarcoma virus

Fujinami sarcoma virus (FSV), a newly characterized avian sarcoma virus, produces a protein of 140,000 daltons (p140) in infected cells. p140 is the product of a fused gene consisting of a part of the gag gene of avian retrovirus and FSV-unique sequences which are not related to the src sequences of Rous sarcoma virus. In vivo, p140 was found to be phosphorylated at both serine and tyrosine residues. Immunoprecipitates of p140 with antiserum against gag gene-coded proteins had a cyclic nucleotide-independent protein kinase activity which phosphorylated p140 itself, rabbit IgG of the immune complex and alpha-casein, an externally added soluble protein substrate. The phosphorylation was specific to tyrosine of the substrate proteins. p140 was phosphorylated in vitro at the same two tyrosine residues that were phosphorylated in vivo. The phosphate transferred to tyrosine residues of p140 forms a stable bond: it does not turn over during the kinase reaction, and the 32P-phosphate of p140 labeled in vitro or in vivo is not transferred to alpha-casein. FSV-p140 differs from p60src, the transforming protein of Rous sarcoma virus, in its marked preference of Mn2+ to Mg2+ ions, and in its inability to use GTP instead of ATP as the donor of gamma-phosphate.     

Nucleotide sequence of Fujinami sarcoma virus: evolutionary relationship of its transforming gene with transforming genes of other sarcoma viruses

We determined the entire nucleotide sequence of the molecularly cloned DNA of Fujinami sarcoma virus (FSV). The sequence of 1182 amino acids was deduced for the FSV transforming protein P130, the product of the FSV gag-fps fused gene. The P130 sequence was highly homologous to the amino acid sequence obtained for the gag-fes protein of feline sarcoma virus, supporting the view that fps and fes were derived from a cognate cellular gene in avian and mammalian species. In addition, FSV P130 and p60^src of Rous sarcoma virus were 40% homologous in the region of the carboxyterminal 280 amino acids, which includes the phosphoacceptor tyrosine residue. These results strongly suggest that the 3′ region of fps/fes and src originated from a common progenitor sequence. A portion (the U3 region) of the long terminal repeat of FSV DNA appears to be unusual among avian retroviruses in its close similarity in sequence and overall organization to the same region of the endogenous viral ev1 DNA.     

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.     

Phosphorylation of a 36,000 Mr cellular protein in cells infected with partial transformation mutants of rous sarcoma virus.

We have isolated and characterized mutants of Rous sarcoma virus which induce some parameters of transformation but fail to fully induce other parameters. We believe these mutants code for a pp60src which phosphorylates some targets well but phosphorylates others poorly. Using these mutants, we examined the phosphorylation of a 36,000 Mr protein which is phosphorylated on a tyrosine in cells transformed by Rous sarcoma virus, in an attempt to correlate this phosphorylation with the expression of specific transformation parameters. We found that phosphorylation of the 36,000 Mr protein was neither necessary nor sufficient for loss of fibronectin or for loss of density-dependent inhibition of growth. Phosphorylation of the protein was not sufficient for morphological alterations, increased hexose transport, or loss of adhesiveness. For the parameters measured, the best correlation was with increased plasminogen activator. In addition, it is noteworthy that cells infected with the mutant CU2 displayed low levels of phosphorylation of the 36,000 Mr protein and also were deficient in anchorage-independent growth and tumorigenicity, raising the possibility that the phosphorylation of the 35,000 Mr protein may be required for malignant growth properties.     

A glycoprotein in the plasma membrane matrix as a major potential substrate of p60v-src.

A potential substrate of p60v-src in Rous sarcoma virus-transformed cells was found to be a 130-kilodalton (kDa) glycoprotein which binds to lectin-Sepharose and can be immunoprecipitated by an anti-phosphotyrosine antibody. This glycoprotein was shown to be distinct from the fibronectin receptor and a cellular protein phosphorylated in p60v-src immune complexes. The protein was a transmembrane protein localized in the plasma membrane and resistant to extraction with Triton X-100. The 130-kDa protein was also highly phosphorylated in cells transformed by Fujinami sarcoma virus or Y73 but not in cells infected with Rous sarcoma virus mutants that encode p60v-src lacking myristoylated N termini. Phosphorylation of this glycoprotein was temperature dependent in cells infected with temperature-sensitive mutants. The good correlation between its phosphorylation and morphological transformation, together with its relative abundance among phosphorylated proteins and its subcellular localization, suggests that phosphorylation of the 130-kDa glycoprotein is one of the primary events important for cell transformation by p60v-src and related oncogene products.     

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.     

Phosphorylation and metabolism of the transforming protein of Rous sarcoma virus.

p60src, the transforming protein of Rous sarcoma virus, was found to contain 0.5 to 0.9 mol of total phosphate per mol of polypeptide. The protein is known to be phosphorylated at two sites, a serine in the amino-terminal domain and a tyrosine in the carboxy-terminal domain. Because our indirect analysis suggests that the serine is phosphorylated to approximately twice the extent of the tyrosine, we estimate that p60src contains approximately 0.3 to 0.6 mol of phosphoserine and 0.2 to 0.3 mol of phosphotyrosine per mol of polypeptide. p60src was found to represent approximately 0.02% of the total incorporated radioactivity in Rous sarcoma virus-transformed chick cells labeled with [35S]methionine for 48 h. This corresponds to approximately 500,000 molecules of p60src per cell. Pulse-chase experiments revealed that the half-life of p60src ranged from 2 to 7 h, depending on the strain of virus examined. The P60src of the Schmidt-Ruppin strain was significantly more stable than that of the Prague strain.     

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.     

Phosphotyrosine-containing proteins and expression of transformation parameters in cells infected with partial transformation mutants of Rous sarcoma virus.

We have examined the phosphorylation state of five proteins known to become phosphorylated on tyrosine during transformation by Rous sarcoma virus by using cells infected with a panel of partially transforming mutant viruses. Situations of viral mutant and growth temperature were found in which phosphorylation of some proteins occurred more extensively than that of others, indicating that mutations in the src gene had affected the specificity of pp60src for some of its substrates as well as affecting the activity of the enzyme. To obtain insight into the biological functions of these phosphorylations, comparisons were made between the degree of phosphorylation of these proteins and the expression of various indicators of the transformed phenotype. The data suggest that phosphorylation of proteins l, p, and q (Mr of 46,000, 39,000 and 28,000, respectively) is not sufficient to induce changes in adhesiveness, hexose transport or morphology. The phosphorylation of protein p or l or total phosphotyrosine content correlated well with the production of plasminogen activator, and the phosphorylation of proteins l and q correlated well with increased hexose transport. However, even when good correlations were observed, significant exceptions were sometimes noted. It thus remains possible that some phosphorylations on tyrosine observed in Rous sarcoma virus-transformed cells are not causally related to the expression of the measured parameters of transformation.     

Rous sarcoma virus transforming protein lacking myristic acid phosphorylates known polypeptide substrates without inducing transformation

Mutagenesis of glycine 2 of p60src, the transforming protein of Rous sarcoma virus (RSV), yields a protein that is neither myristylated nor bound to cellular membranes. Although these mutant viruses retain full tyrosine protein kinase activity, they are transformation-defective. We examined in detail tyrosine phosphorylation of cellular polypeptides and the phenotype induced by infection with two such viruses. Infection failed to cause growth in agar, cytoskeletal reorganization, or changes in fibronectin synthesis and protease secretion. Strikingly, tyrosine phosphorylation of the known substrates of p60src was extensive, and differed from that found in wild-type transformed cells only quantitatively. There was no apparent correlation between the extent to which any of eight known protein substrates of p60src were phosphorylated and the phenotype of infected cells. We suggest that the phosphorylation of as yet unidentified proteins, which are probably found in cellular membranes, is essential for transformation by RSV.     

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.