Mutation of amino acids in pp60c-src that are phosphorylated by protein kinases C and A.

The product of the c-src proto-oncogene, pp60c-src, is phosphorylated at Ser-17 by cyclic AMP-dependent protein kinase A and at Ser-12 by calcium-phospholipid-dependent protein kinase C (when stimulated by 12-O-tetradecanoyl phorbol acetate). We tested the effects of Ser----Ala and Ser----Glu mutations at these sites in pp60c-src and in pp60c-src(F527) (a mutant whose transforming activities are enhanced by Tyr-527----Phe mutation) by transfecting single-, double-, and triple-mutant src expression plasmids into NIH 3T3 cells. Tryptic phosphopeptide analyses of the mutant proteins confirmed prior biochemical identifications of the phosphorylation sites and showed that neither separate nor coordinate mutations at Ser-12 and Ser-17 affected Tyr-416, Tyr-527, or Ser-48 phosphorylation or prevented mitosis-specific phosphorylations of either pp60c-src or pp60c-src(F527). Ser-12 mutation did not affect phosphorylation of the Ser-17-containing peptide, but mutation of Ser-17 significantly increased phosphorylation at Ser-12. Specific kinase activities (both with and without in vivo 12-O-tetradecanoyl phorbol acetate treatment) and the abilities of pp60c-src and pp60c-src(F527) to induce foci, transformed morphologies, and anchorage-independent growth were unaffected by any of the serine mutations. Thus, pp60c-src transforming activity in NIH 3T3 cells is relatively insensitive to phosphorylation at these sites, but there is a suggestion that Ser-17 phosphorylation may have a subtle regulatory effect.     

Biological and biochemical properties of the c-src+ gene product overexpressed in chicken embryo fibroblasts.

The c-src protein isolated from neuronal cells (pp60c-src+) displays a higher level of protein kinase activity than does pp60c-src from nonneural tissues. There are two structural alterations present in the amino-terminal half of pp60c-src+ expressed in neurons which could contribute to the enhanced activity of this form of pp60c-src: (i) a hexapeptide insert located at amino acid 114 of avian pp60c-src+ and (ii) a novel site(s) of serine phosphorylation. We characterized pp60c-src+ expressed in a nonneuronal cell type to identify factors that regulate the activity of the c-src+ protein and the importance of the neuronal environment on this regulation. The c-src+ protein overexpressed in chicken embryo fibroblasts (CEFs) displayed higher kinase activity than did pp60c-src. The major sites of phosphorylation of the c-src+ protein were Ser-17 and Tyr-527. The unique site(s) of serine phosphorylation originally identified in pp60c-src+ expressed in neurons was not detected in the c-src+ protein overexpressed in CEFs. Therefore, the hexapeptide insert is sufficient to cause an elevation in the tyrosine protein kinase activity of pp60c-src+. Our data also indicate that CEFs infected with the Rous sarcoma virus (RSV)c-src+ display phenotypic changes that distinguish them from cultures producing pp60c-src and that pp60c-src+-expressing cells are better able to grow in an anchorage-independent manner. The level of total cellular tyrosine phosphorylation in RSVc-src+-infected cultures was moderately higher than the level observed in cultures infected with RSVc-src. This level was not as pronounced as that observed in cells infected with RSVv-src or oncogenic variants of RSVc-src. Thus, pp60c-src+ could be considered a partially activated c-src variant protein much like other c-src proteins that contain mutations in the amino-terminal domain.     

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.     

Alterations in pp60c-src accompany differentiation of neurons from rat embryo striatum.

Cultured neurons from rat embryo striatum were found to contain two structurally distinct forms of pp60c-src. The 60-kilodalton (kDa) form appeared similar to pp60c-src from cultured rat fibroblasts or astrocytes. The 61-kDa form was specific to neurons and differed in the NH2-terminal 18 kDa of the molecule. In undifferentiated neurons the predominant phosphorylated species of pp60c-src was the fibroblast form. Upon differentiation, a second phosphorylated form of pp60c-src was detected. This form had two or more additional sites of serine phosphorylation within the NH2-terminal 18-kDa region of the molecule, one of which was Ser-12. The specific protein-tyrosine kinase activity of the total pp60c-src population increased 14-fold, as measured by autophosphorylation, or 7-fold, as measured by phosphorylation of an exogenous substrate, as striatal neurons differentiated. This elevation in protein kinase activity occurred without a detectable decrease in Tyr-527 phosphorylation or increase in Tyr-416 phosphorylation. Our results support the idea that the expression of the neuron-specific form of pp60c-src and the increase in specific protein kinase activity may be important for neuronal differentiation.     

pp60c-src variants containing lesions that affect phosphorylation at tyrosines 416 and 527.

The biological and biochemical properties of pp60c-src are regulated, in part, by phosphorylation at Tyr-416 and Tyr-527. The tyrosine kinase and transforming activities of pp60c-src are suppressed by phosphorylation at Tyr-527, whereas full activation of pp60c-src requires phosphorylation at Tyr-416. To test specifically the significance of the negatively charged phosphate moieties on these tyrosine residues, we have substituted the codons for both residues with codons for either Glu or Gln. A negatively charged Glu at position 527 was unable to mimic a phosphorylated Tyr at this position, and, in consequence, the mutated pp60c-src was activated and transforming. Similarly, substitution of Tyr-416 with Glu was unable to stimulate the activities of the enzyme. However, mutagenesis of Tyr-416 to Gln (to form the mutant 416Q) activated the kinase activity approximately twofold over that observed for wild-type pp60c-src. When introduced into the mutant 527F (containing Phe-527 instead of Tyr), the double mutant 416Q-527F exhibited weak transforming activity. This is in contrast to the other double mutants 416E-527F and 416F-527F, which were nontransforming. The biochemical basis by which 416Q activates pp60c-src is not understood but probably involves some local conformational perturbation. Deletion of residues 519 to 524 (RH5), a region previously shown to be necessary for association with middle-T antigen, led to loss of phosphorylation at Tyr-527 and activation of the enzymatic and focus-forming activities of pp60c-src. Hence, the sequences necessary for complex formation with middle-T antigen may also be required by the kinase(s) which phosphorylates Tyr-527 in vivo. This suggests that normal cells contain cellular proteins which are analogous to middle-T antigen and whose action regulates the activity of pp60c-src by controlling phosphorylation or dephosphorylation at residue 527.     

Enzymatically inactive p60c-src mutant with altered ATP-binding site is fully phosphorylated in its carboxy-terminal regulatory region

Cellular src protein, p60c-src, is phosphorylated on tyrosine 527 in chicken embryo fibroblasts, and this phosphorylation is implicated in suppressing the protein-tyrosine kinase activity and transforming potential of p60c-src. To determine whether tyrosine 527 phosphorylation is dependent on p60c-src kinase activity, the ATP-binding site of chicken p60c-src was destroyed by substitution of lysine 295 with methionine. The resultant protein, p60c-src(M295), expressed either in chicken cells or in yeast, lacked detectable kinase activity. Nevertheless, tyrosine and serine phosphorylation of p60c-src(M295) overproduced in chicken cells were indistinguishable from that of authentic p60c-src. By contrast, p60c-src(M295) was not phosphorylated on tyrosine in yeast. These results suggest that a protein kinase present in chicken cells but not in yeast phosphorylates tyrosine 527 in trans, and are consistent with the possibility that this kinase is distinct from p60c-src.     

The carboxy terminus of pp60c-src is a regulatory domain and is involved in complex formation with the middle-T antigen of polyomavirus.

A large number of mutations were introduced into the carboxy-terminal domain of pp60c-src. The level of phosphorylation on Tyr-416 and Tyr-527, the transforming activity (as measured by focus formation on NIH 3T3 cells), kinase activity, and the ability of the mutant pp60c-src to associate with the middle-T antigen of polyomavirus were examined. The results indicate that Tyr-527 is a major carboxy-terminal element responsible for regulating pp60c-src in vivo. A good but not perfect correlation exists between lack of phosphorylation at Tyr-527 and increased phosphorylation at Tyr-416, between elevated phosphorylation on Tyr-416 and activated kinase activity, and between activated kinase activity and transforming activity. Phosphorylation of Tyr-527 was insensitive to the mutation of adjacent residues, indicating that the primary sequence only has a minor role in recognition by kinases or phosphatases which regulate it in vivo. Three mutants which have in common a modified Glu-524 residue were phosphorylated on Tyr-416 and Tyr-527 and were weakly transforming. This suggests that other mechanisms besides complete dephosphorylation of Tyr-527 can lead to increased phosphorylation of Tyr-416 and activation of the transforming activity of pp60c-src. Furthermore, the residues between Asp-518 and Pro-525 were required to form a stable complex with middle-T antigen. The proximity of these sequences to Tyr-527 suggests a model in which middle-T activates pp60c-src by binding directly to this region of the molecular and thereby preventing phosphorylation of Tyr-527. Alternatively, middle-T binding may mediate a conformational change in this region, which in turn induces an alteration in the level of phosphorylation at Tyr-527 and Tyr-416.     

Regulation of the oncogenic activity of the cellular src protein requires the correct spacing between the kinase domain and the C-terminal phosphorylated tyrosine (Tyr-527).

Repression of the tyrosine kinase activity of the cellular src protein (pp60c-src) depends on the phosphorylation of a tyrosine residue (Tyr-527) near the carboxy terminus. Tyr-527 is located 11 residues C terminal from the genetically defined end of the kinase domain (Leu-516) and is therefore in a negative regulatory region. Because the precise sequence of amino acids surrounding Tyr-527 appears to be unimportant for regulation, we hypothesized that the conformational constraints induced by phosphorylated Tyr-527 may require the correct spacing between the kinase domain (Leu-516) and Tyr-527. In this report, we show that deletions at residue 518 of two, four, or seven amino acids or insertions at this residue of two or four amino acids activated the kinase activity and thus the transforming potential of pp60c-src. As is the case for the prototype transforming variant, pp60527F, activation caused by these deletions or insertions was abolished when Tyr-416 (the autophosphorylation site) was changed to phenylalanine. In comparison with wild-type pp60c-src, the src proteins containing the alterations at residue 518 showed a lower phosphorylation state at Tyr-527 regardless of whether residue 416 was a tyrosine or a phenylalanine. Mechanisms dealing with the importance of spacing between the kinase domain and Tyr-527 are discussed.     

Dephosphorylation or antibody binding to the carboxy terminus stimulates pp60c-src.

Phosphorylation of pp60c-src at Tyr-527, six residues from the carboxy terminus, has been implicated in regulation of the protein-tyrosine kinase activity of pp60c-src. Here we show that dephosphorylation of pp60c-src by phosphatase treatment in vitro caused a 10- to 20-fold increase in pp60c-src protein-tyrosine kinase activity. Binding of specific antibody to the region of pp60c-src which contains phosphotyrosine-527 also increased kinase activity. Each treatment increased phosphorylation of added substrates and of Tyr-416 within pp60c-src by a similar mechanism that involved altered interactions with ATP and increased catalytic rate. We suggest that the phosphorylated carboxy terminus acts as an inhibitor of the protein kinase domain of pp60c-src, unless its conformation is altered by either dephosphorylation or antibody binding. The antibody additionally stimulated the phosphorylation of forms of pp60c-src that had reduced gel mobility, much like those phosphorylated in kinase reactions containing pp60c-src activated by polyomavirus medium tumor antigen. These in vitro experiments provide models for the activation of pp60c-src in cells transformed by polyomavirus. We also show that autophosphorylation of pp60c-src at Tyr-527 occurs only to a very limited extent in vitro, even when Tyr-527 is made available for phosphorylation by treatment with phosphatase. This suggests that other protein-tyrosine kinases may normally phosphorylate Tyr-527 and regulate pp60c-src in the cell.     

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.     

Regulation of pp60c-src and its interaction with polyomavirus middle T antigen in insect cells.

High yields of soluble, biologically active pp60c-src and middle t antigen (MTAg) of polyomavirus were produced in insect cells, using a baculovirus expression system. In mammalian cells, pp60c-src undergoes a regulatory phosphorylation on Tyr-527 in vivo and is autophosphorylated on Tyr-416 in vitro. In insect cells, pp60c-src was phosphorylated primarily on Tyr-416, although Tyr-527 was detectable at a low level. A kinase-negative mutant of pp60c-src was not phosphorylated on either Tyr-527 or Tyr-416 in insect cells and thus is an excellent biochemical reagent to search for the regulatory kinase that usually phosphorylates Tyr-527 in mammalian cells. MTAg synthesized in insect cells was not phosphorylated on tyrosine residues in vivo or in vitro, suggesting that it did not associate with any endogenous tyrosine kinases. However, MTAg isolated from cells coinfected with viruses encoding both MTAg and pp60c-src was phosphorylated on tyrosine residues both in vivo and in vitro.     

Platelet tyrosine-specific protein phosphorylation is regulated by thrombin.

Intact human platelets, terminally differentiated cells with no growth potential, were found to possess unusually high levels of tyrosine-specific protein phosphorylation. The physiological platelet activator thrombin transiently elevated platelet phosphotyrosine content, apparently through stimulation of one or more tyrosine-specific protein kinases. Immunoblotting with antiphosphotyrosine antiserum showed that thrombin caused dramatic changes in the tyrosine phosphorylation of a number of individual protein bands and that these changes occurred in three distinct temporal waves. Most but not all of the protein bands phosphorylated at tyrosine in response to thrombin were also tyrosine phosphorylated in response to chilling or the combination of ionophore A23187 and tetradecanoylphorbol acetate. Thrombin stimulated the phosphorylation of the tyrosine kinase pp60c-src, primarily at Ser-12 and Tyr-527, although the effects of these phosphorylations on platelet pp60c-src function were not apparent. Together, these results suggest that tyrosine-specific protein kinases of uncertain identity are involved in signal transduction in platelets.     

Cell transformation by pp60c-src mutated in the carboxy-terminal regulatory domain

We introduced two mutations into the carboxy-terminal regulatory region of chicken pp60c-src. One, F527, replaces tyrosine 527 with phenylalanine. The other, Am517, produces a truncated pp60c-src protein lacking the 17 carboxy-terminal amino acids. Both mutant proteins were phosphorylated at tyrosine 416 in vivo. The specific activity of the Am517 mutant protein kinase was similar to that of wild-type pp60c-src whereas that of the F527 mutant was 5- to 10-fold higher. Both mutant c-src genes induced focus formation on NIH 3T3 cells, but the foci appeared at lower frequency, and were smaller than foci induced by polyoma middle tumor antigen (mT). The wild-type or F527 pp60c-src formed a complex with mT, whereas the Am517 pp60c-src did not. The results suggest that one, inability to phosphorylate tyrosine 527 increases pp60c-src protein kinase activity and transforming ability; two, transformation by mT involves other events besides lack of phosphorylation at tyrosine 527 of pp60c-src; three, activation of the pp60c-src protein kinase may not be required for transformation by the Am517 mutant; and four, the carboxyl terminus of pp60c-src appears to be required for association with mT.     

Characterization of purified pp60c-src protein tyrosine kinase from human platelets.

Intact pp60c-src, the cellular homologue of the transforming protein of Rous sarcoma virus, was purified from human platelets. The purified fractions also contained small amounts of a 54-kDa proteolytic degradation product of pp60c-src. We investigated some of the biochemical and kinetic properties of pp60c-src protein tyrosine kinase. Maximum kinase activity occurred at pH 6.5 and required a mixture of 2 mM Mn2+/Mg2+ as divalent cations. The enzyme most strongly phosphorylated casein, followed by enolase and alcohol dehydrogenase. The Km value for ATP was 4 microM for substrate phosphorylation and for autophosphorylation. Using casein, we determined a Vmax for substrate phosphorylation by pp60c-src in the range of 1.9-3.4 nmol.min-1.mg-1. Since the Vmax value for the purified 54-kDa fragment of pp60c-src was also included in this value, we conclude that proteolytic degradation of a 6-kDa fragment from the N-terminus of pp60c-src did not affect its kinase activity. Tryptic phosphopeptide analysis identified Tyr-416 as the major autophosphorylation site. Preincubation of purified pp60c-src with ATP increased the amount of autophosphorylation accompanied by an increase in Vmax, whereas the Km values were not altered. Our data directly demonstrate that autophosphorylation at Tyr-416 exerts, in contrast to phosphorylation at Tyr-527, a positive regulatory effect on the pp60c-src kinase activity.     

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.     

Altered phosphorylation and activation of pp60c-src during fibroblast mitosis

At least half the pp60c-src in NIH 3T3-derived c-src overexpresser cells in modified by novel threonine and, possibly, serine phosphorylation within its amino 16 kd region during mitosis. At the same time, the tryptic phosphopeptide containing Ser 17, the site of cyclic AMP-dependent phosphorylation, is either modified or dephosphorylated. While the amount of pp60c-src is not significantly altered, the in vitro-specific kinase activity of modified pp60c-src is enhanced 4- to 7-fold. Modified pp60c-src has the same tyrosine-containing tryptic phosphopeptides as pp60c-src from unsynchronized cells, indicating that activation is independent of Tyr 416/Tyr 527 phosphorylation. Electrophoretic mobility retardations indicated that endogenous pp60c-src and pp60v-src are similarly modified during mitosis. The modifications and enhanced activity disappear near the time of cell division. These results suggest that pp60c-src is regulated by and, in turn, may regulate mitosis-specific events in fibroblasts.     

A protein tyrosine kinase involved in regulation of pp60c-src function

We recently identified a novel protein tyrosine kinase that specifically phosphorylates truncated pp60c-src (Mr = 53,000) at a tyrosine residue(s) distinct from its autophosphorylation site. In this study, we examined whether this enzyme phosphorylates intact pp60c-src (Mr = 60,000) and determined its phosphorylation site. Non-neuronal and neuronal forms of intact pp60c-src were separately purified from the membrane fraction of neonatal rat brain by sequential column chromatographies. The novel kinase phosphorylated tyrosine residues of both forms of intact pp60c-src. The phosphorylation occurred in parallel with autophosphorylation of pp60c-src, and in both forms the final stoichiometry estimated was quite similar to that of autophosphorylation (about 5%). The enzyme also phosphorylated pp60c-src in which the kinase activity had been destroyed by an ATP analogue, p-fluorosulfonylbenzoyl 5'-adenosine. The phosphorylation site of the non-neuronal form was analyzed by sequential peptide mapping with tosylphenylalanyl chloromethyl ketone-treated trypsin and alpha-chymotrypsin. Tryptic digestion of the phosphorylated pp60c-src yielded a unique phosphopeptide that cross-reacted with an antibody specific for the carboxyl-terminal sequence of chicken pp60c-src. Digestion of the phosphopeptide with chymotrypsin yielded a product that comigrated with a synthetic phosphopeptide corresponding to the carboxyl-terminal 15 residues of chicken pp60c-src. These results clearly indicate that the carboxyl-terminal sequence of rat pp60c-src is identical to that of chicken pp60c-src, and a tyrosine residue corresponding to chicken Tyr527 is the phosphorylation site. This phosphorylation resulted in a decrease in the enolase phosphorylating activity of pp60c-src. Kinetic experiments indicated that this decrease in activity was due to a decrease in the Vmax value of pp60c-src. These findings support our previous proposal that the novel tyrosine kinase acts as a specific regulator of pp60c-src in cells.     

Activation of c-Src in cells bearing v-Crk and its suppression by Csk.

The protein product of the CT10 virus, p47gag-crk (v-Crk), which contains Src homology region 2 (SH2) and 3 (SH3) domains but lacks a kinase domain, is believed to cause an increase in cellular protein tyrosine phosphorylation. A candidate tyrosine kinase, Csk (C-terminal Src kinase), has been implicated in c-Src Tyr-527 phosphorylation, which negatively regulates the protein tyrosine kinase of pp60c-src (c-Src). To investigate how c-Src kinase activity is regulated in vivo, we first looked at whether v-Crk can activate c-Src kinase. We found that cooverexpression of v-Crk and c-Src caused elevation of c-Src kinase activity, resulting in an increase of tyrosine phosphorylation of cellular proteins and morphological transformation of rat 3Y1 fibroblasts. v-Crk and c-Src complexes were not detected, although v-Crk bound to a variety of tyrosine-phosphorylated proteins in cells overexpressing v-Crk and c-Src. Overexpression of Csk in these transformed cells caused reversion to normal phenotypes and also reduced the level of c-Src kinase activity. However, Csk did not cause reversion of cells transformed by v-Src or c-Src527F, in which Tyr-527 was changed to Phe. These results strongly suggest that Csk acts on Tyr-527 of c-Src and suppresses c-Src kinase activity in vivo. Because Csk can suppress transformation by cooverexpression of v-Crk and c-Src, we suggest that v-Crk causes activation of c-Src in vivo by altering the phosphorylation state of Tyr-527.     

The sites of phosphorylation by protein kinase C and an intact SH2 domain are required for the enhanced response to beta-adrenergic agonists in cells overexpressing c-src.

Previously we demonstrated that C3H10T1/2 murine fibroblasts overexpressing avian c-src exhibit elevated levels of cyclic AMP (cAMP) in response to beta-adrenergic agonists compared with that in control cells and that this enhanced response requires c-src kinase activity (W. A. Bushman, L. K. Wilson, D. K. Luttrell, J. S. Moyers, and S. J. Parsons, Proc. Natl. Acad. Sci. USA 87:7462-7466, 1990). However, it is not yet known which components of the beta-adrenergic receptor pathway, if any, interact with pp60c-src. It has recently been shown that immune complexes of pp60c-src phosphorylate recombinant G alpha proteins in vitro to stoichiometric levels, resulting in alterations of GTP binding and GTPase activity (W. P. Hausdorff, J. A. Pitcher, D. K. Luttrell, M. E. Linder, H. Kurose, S. J. Parsons, M. G. Caron, and R. J. Lefkowitz, Proc. Natl. Acad. Sci. USA 89:5720-5724, 1992), raising the possibility that the Gs alpha protein may be an in vivo target for the interaction with pp60c-src. To further characterize the involvement of pp60c-src in the beta-adrenergic signalling pathway, we have overexpressed, in 10T1/2 cells, pp60c-src containing mutations in several domains which are believed to be important for signalling processes. In this study we show that the sites of phosphorylation by protein kinase C (PKC) (Ser-12 and Ser-48) as well as the SH2 region of pp60c-src are required for the enhanced response of c-src overexpressors to beta-agonist stimulation. Mutation at the site of myristylation (Gly-2) results in a decrease in the enhanced response, while mutation at the site of phosphorylation by cAMP-dependent protein kinase (Ser-17) has no effect. Two-dimensional phosphotryptic analyses indicate that phosphorylation on Ser-12 and Ser-48 in unstimulated cells is associated with the ability of overexpressed pp60c-src to potentiate beta-adrenergic signalling. Cells overexpressing wild-type c-src also exhibit enhanced cAMP accumulation upon treatment with cholera toxin, an effect that is abated in cells overexpressing pp60c-src defective in the kinase or SH2 domains or altered at the sites of phosphorylation by PKC. These studies provide the first evidence for the physiological significance of the pp60c-src sites of PKC phosphorylation. In addition, they show that the SH2, Ser-12/48, and myristylation regions may be important for efficient interaction of pp60c-src with components of the beta-adrenergic pathway. Our data also support the possibility that the Gs alpha protein may be an in vivo target for alteration by pp60c-src.     

Activation and suppression of pp60c-src transforming ability by mutation of its primary sites of tyrosine phosphorylation

pp60c-src is phosphorylated in vivo at tyrosine 527, a residue not present in pp60v-src (its transforming homolog), and not at tyrosine 416, its site of in vitro autophosphorylation. To test the hypothesis that tyrosine phosphorylation regulates pp60c-src biological activity, we constructed and studied pp60c-src mutants in which Tyr 527 and Tyr 416 were separately or coordinately altered to phenylalanine. Tyr----Phe 527 mutation strongly activated pp60c-src transforming and kinase activities, whereas the additional introduction of a Tyr----Phe 416 mutation suppressed these activities. Tyr----Phe 416 mutation of normal pp60c-src eliminated its partial transforming activity, which suggests that transient or otherwise restricted phosphorylation of Tyr 416 is important for pp60c-src function even though stable phosphorylation is not observed in vivo.