The first seven amino acids encoded by the v-src oncogene act as a myristylation signal: lysine 7 is a critical determinant.

The transforming protein of Rous sarcoma virus, pp60v-src, is covalently coupled to myristic acid by an amide linkage to glycine 2. Myristylation promotes the association of pp60v-src with cellular membranes, and this subcellular location is essential for transforming activity. The findings presented here, in conjunction with the previous reports of others, imply that the seventh amino acid encoded by v-src might be important in the myristylation reaction. Replacement of lysine 7 by asparagine greatly reduced the myristylation, membrane association, and transforming activity of pp60v-src. In contrast, substitution of arginine at residue 7 had no effect on any of these properties of pp60v-src. Addition of amino acids 1 to 7 encoded by v-src was sufficient to cause myristylation of a src-pyruvate kinase fusion protein. We conclude that the recognition sequence for myristylation of pp60v-src comprises amino acids 1 to 7 and that lysine 7 is a critical component of this sequence.     

Association of the amino-terminal half of c-Src with focal adhesions alters their properties and is regulated by phosphorylation of tyrosine 527.

We have characterized the mechanism by which the subcellular distribution of c-Src is controlled by the phosphorylation of tyrosine 527. Mutation of this tyrosine dramatically redistributes c-Src from endosomal membranes to focal adhesions. Redistribution to focal adhesions occurs independently of kinase activity and cellular transformation. In cells lacking the regulatory kinase (CSK) that phosphorylates tyrosine 527, c-Src is also found predominantly in focal adhesions, confirming that phosphorylation of tyrosine 527 affects the location of c-Src inside the cell. The first 251 amino acids of c-Src are sufficient to allow association with focal adhesions, indicating that at least one signal for positioning c-Src in focal adhesions resides in the amino-terminal half. Point mutations and deletions in the first 251 amino acids of c-Src reveal that association with focal adhesions requires the myristylation site needed for membrane attachment, as well as the SH3 domain. Expression of the amino-terminal region alters both the structural and biochemical properties of focal adhesions. Focal adhesions containing this non-catalytic portion of c-Src are larger and exhibit increased levels of phosphotyrosine staining. Our results suggest that c-Src may regulate focal adhesions and cellular adhesion by a kinase-independent mechanism.     

Processing of p60v-src to its myristylated membrane-bound form.

p60src of wild-type Rous sarcoma virus is myristylated at its N-terminal glycine residue. We have shown previously that this myristylation is necessary for p60src membrane association and for cell transformation by using src mutants with alterations within the N-terminal 30 kilodaltons of p60src. In this study we analyzed the process of p60src myristylation in wild type- and mutant-infected cells. All myristylated src proteins examined lack the initiator methionine, but two mutant src proteins lacking the initiator methionine are not myristylated, indicating that removal of the initiator methionine and myristylation are not obligatorily coupled. Analysis of the kinetics of myristylation and the association of p60src with cellular proteins p50 and p90 indicated that myristylation occurs before p60src becomes membrane associated and that transient association with p50 and p90 occurs regardless of myristylation. Myristylation is required for stable association of p60src with the plasma membrane but is not sufficient for membrane association. A mutant with an src deletion of amino acids 169 through 264 has an src protein that is myristylated but not membrane bound, remaining stably associated with p50 and p90. This mutant is transformation defective. Several N-terminal deletion mutants possessing tyrosine kinase activity have myristylated and membrane-bound src proteins but are not fully active in cell transformation, suggesting that additional N-terminal functional domains exist.     

Palmitylation of an amino-terminal cysteine motif of protein tyrosine kinases p56lck and p59fyn mediates interaction with glycosyl-phosphatidylinositol-anchored proteins.

Cross-linking of glycosyl-phosphatidylinositol (GPI)-anchored membrane proteins on T cells can trigger cell activation. We and others have shown an association between GPI-anchored proteins and the protein tyrosine kinases (PTKs) p56lck and p59fyn, suggesting a pathway for signaling through GPI-anchored proteins. Studies of decay-accelerating factor (DAF) or CD59 in either the C32 cell line or the HeLa cell line transfected with PTK cDNA demonstrated that the GPI-anchored proteins associated noncovalently with p56lck and p59fyn but not with p60src. Nonmyristylated versions of p56lck and p59fyn also failed to associate with the GPI-anchored proteins. Mutational analysis of the PTK demonstrated that the association with the GPI-anchored proteins mapped to the unique amino-terminal domains of the PTK. A chimeric PTK consisting of the 10 amino-terminal residues of p56lck or p59fyn replacing the corresponding amino acids in p60src was sufficient for association with DAF, but the converse constructs containing the first 10 amino acids of p60src plus the remainder of p56lck or p59fyn did not associate with DAF. Mutation of cysteine to serine at positions 3 and 6 in p59fyn or positions 3 and 5 in p56lck abolished the association of these kinases with DAF. Mutation of serine to cysteine at positions 3 and 6 in p60src conferred on p60src the ability to associate with DAF. Direct labeling with [3H]palmitate demonstrated palmitylation of this amino-terminal cysteine motif in p56lck. Thus, palmitylation of the amino-terminal cysteine residue(s) together with myristylation of the amino-terminal glycine residue defines important motifs for the association of PTKs with GPI-anchored proteins.     

N-terminal deletions in Rous sarcoma virus p60src: effects on tyrosine kinase and biological activities and on recombination in tissue culture with the cellular src gene.

We have constructed deletions within the region of cloned Rous sarcoma virus DNA coding for the N-terminal 30 kilodaltons of p60src. Infectious virus was recovered after transfection. Deletions of amino acids 15 to 149, 15 to 169, or 149 to 169 attenuated but did not abolish transforming activity, as assayed by focus formation and anchorage-independent growth. These deletions also had only slight effects on the tyrosine kinase activity of the mutant src protein. Deletion of amino acids 169 to 264 or 15 to 264 completely abolished transforming activity, and src kinase activity was reduced at least 10-fold. However, these mutant viruses generated low levels of transforming virus by recombination with the cellular src gene. The results suggest that as well as previously identified functional domains for p60src myristylation and membrane binding (amino acids 1 to 14) and tyrosine kinase activity (amino acids 250 to 526), additional N-terminal sequences (particularly amino acids 82 to 169) can influence the transforming activity of the src protein.     

The amino-terminal 14 amino acids of v-src can functionally replace the extracellular and transmembrane domains of v-erbB.

The retroviral oncogene v-erbB encodes a truncated form of the receptor for epidermal growth factor, an integral membrane protein-tyrosine kinase. By contrast, the oncogene v-src encodes a protein-tyrosine kinase that is a peripheral membrane protein. The morphologies and spectra of cells transformed by these two oncogenes differ. In an effort to identify the functional determinant(s) of these differences, we constructed and tested first deletion mutants of v-erbB and then chimeras between v-src and v-erbB. As reported previously, the absence of any membrane anchorage eliminated transformation by v-erbB. Anchorage of the cytoplasmic kinase domain of v-erbB to membranes with amino-terminal portions of the v-src protein permitted transformation. The phenotype and spectrum of transformation were those expected for v-erbB rather than for v-src. The transforming chimeras lost their biological activity if the signal for myristylation at the amino terminus of v-src was compromised by mutation. Biochemical fractionations revealed a correlation between transforming activity and the association of chimeric gene products with the membrane fraction of the cell. For reasons not yet apparent, the combined presence of membrane anchorage domains of v-src, and the transmembrane domain of v-erbB in the same chimera typically (but not inevitably) impeded transformation. Our results suggest that the specificity of transformation by v-erbB resides in the selection of substrates by the cytoplasmic domain of the gene product. The protein retains access to those substrates even when anchored to the membrane in the manner of a peripheral rather than a transmembrane protein.     

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.     

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.     

The myristylation signal of p60v-src functionally complements the N-terminal fps-specific region of P130gag-fps.

The P130gag-fps protein-tyrosine kinase of Fujinami sarcoma virus contains an N-terminal fps-specific domain (Nfps) that is important for oncogenicity. The N-terminal 14 amino acids of p60v-src, which direct myristylation and membrane association, can replace the gag-Nfps sequences of P130gag-fps (residues 1 to 635), producing a highly transforming src-fps polypeptide. Conversely, gag-Nfps can restore modest transforming activity to a nonmyristylated v-src polypeptide. These results emphasize the modular construction of protein-tyrosine kinases and indicate that Nfps, possibly in conjunction with gag, functions in the subcellular localization of P130gag-fps.     

The amino terminus of polyomavirus middle T antigen is required for transformation.

In polyomavirus-transformed cells, pp60c-src is activated by association with polyomavirus middle T antigen. These complexes have a higher tyrosine kinase activity compared with that of unassociated pp60c-src. Genetic analyses have revealed that the carboxy-terminal 15 amino acids of pp60c-src and the amino-terminal half of middle T antigen are required for this association and consequent activation of the tyrosine kinase. To define in greater detail the borders of the domain in middle T antigen required for activation of pp60c-src, we constructed a set of unidirectional amino-terminal deletion mutants of middle T antigen. Analysis of these mutants revealed that the first six amino acids of middle T antigen are required for it to activate the kinase activity of pp60c-src and to transform Rat-1 fibroblasts. Analysis of a series of insertion and substitution mutants confirmed these observations and further revealed that mutations affecting the first four amino acids of middle T antigen reduced or abolished its capacity to activate the kinase activity of pp60c-src and to transform Rat-1 cells in culture. Our results suggest that the first four amino acids of middle T antigen constitute part of a domain required for activation of the pp60c-src tyrosyl kinase activity and for consequent cellular transformation.     

Identification of platelet membrane proteins that interact with amino-terminal peptides of pp60c-src.

Platelets contain exceptionally high levels of pp60c-src and, thus, provide a convenient system for investigating the physiological function of this protein-tyrosine kinase. We have employed chemical cross-linking of myristylated amino-terminal peptides of pp60c-src to platelet membranes in order to identify platelet membrane components that interact with pp60c-src to regulate or mediate its activity. We detected specific binding of radioiodinated peptides to platelet membrane proteins of 32, 50, 92, and 105 kDa. The 32-kDa protein may be related to the putative src receptor component recently identified in fibroblast membranes. The most reactive platelet protein, however, is the 50-kDa protein, which is either absent or nonreactive in fibroblast membranes. Binding of src peptides to this protein was saturable, and we estimate the presence of approximately 1 x 10(6) of the 50-kDa binding sites per platelet. The specificity of the peptide binding to the 50- and 32-kDa platelet proteins was analyzed by competition with different peptides. The binding sites displayed an absolute requirement for an N-myristoyl moiety and a strong preference for pp60c-src amino-terminal sequences. The identification of these src-interacting proteins may help to decipher the biochemical pathways in which platelet pp60c-src is involved.     

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.     

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.     

A short sequence in the p60src N terminus is required for p60src myristylation and membrane association and for cell transformation.

We have constructed mutants by using linker insertion followed by deletion in the region of cloned Rous sarcoma virus DNA coding for the N-terminal 9 kilodaltons of the src protein. Previous work implicated this region in the membrane association of the protein. The mutations had little effect on src tyrosine kinase activity. Substitution of a tri- or tetrapeptide for amino acids 15 to 27, 15 to 49, or 15 to 81 had little effect on the in vitro transforming capacity of the virus. Like wild-type p60src, the src proteins of these mutants associated with plasma membranes and were labeled with [3H]myristic acid. In contrast, a mutant whose src protein had the dipeptide Asp-Leu substituted for amino acids 2 to 81 and a mutant with the tripeptide Asp-Leu-Gly substituted for amino acids 2 to 15 were transformation defective, and the mutant proteins did not associate with membranes and were not labeled with [3H]myristic acid. These results suggest that amino acids 2 to 15 serve as an attachment site for myristic acid and as a membrane anchor. Since deletions including this region prevent transformation, and since tyrosine kinase activity is not diminished by the deletions, these results imply that target recognition is impaired by mutations altering the very N terminus, perhaps through their effect on membrane association.     

Mutants of polyomavirus middle-T antigen

Polyomavirus middle-T antigen induces the transformation of established cell lines in culture and is known to interact with and/or modulate the activity of several enzymes (pp60c.src, protein kinase C and phosphatidylinositol kinase) in vitro. This review is a compilation of the reported mutants of middle-T antigen and their biochemical and biological properties as they relate to the transformation event. The mutants of polyomavirus middle-T antigen have been previously classified phenotypically. Given the now large number of mutants, the classification presented here is based upon the position within the molecule. A model of middle-T is presented in which the protein is considered as consisting of three domains: a hydrophobic domain (the putative membrane-binding domain), the amino-terminal half of the molecule (the putative pp60c.src-binding domain) and the intervening amino acids (the putative modulatory domain). A current model for the induction of transformation by polyomavirus middle-T is presented.     

In vitro synthesis of pp60v-src: myristylation in a cell-free system.

Covalent attachment of myristic acid to pp60v-src, the transforming protein of Rous sarcoma virus, was studied in a cell-free system. Using a synthetic peptide containing the first 11 amino acids of the mature pp60v-src polypeptide sequence as a substrate, we probed lysates from a variety of cells and tissues for N-myristyl transferase (NMT) activity. Nearly every eucaryotic cell type tested contained NMT, including avian, mammalian, insect, and plant cells. Since NMT activity was detected in rabbit reticulocyte lysates, we took advantage of the translational capability of these lysates to determine the precise point during translation at which myristate is attached to pp60v-src. src mRNA, transcribed from cloned v-src DNA, was translated in reticulocyte lysates which had been depleted of endogenous myristate. Addition of [3H]myristate to lysates 10 min after the start of synchronized translation resulted in a dramatic decrease in the incorporation of radiolabeled myristate into pp60v-src polypeptide chains. These results imply that although myristate can be attached posttranslationally to synthetic peptide substrates, myristylation in vivo is apparently a very early cotranslational event which occurs before the first 100 amino acids of the nascent polypeptide chain are polymerized.     

Specific and saturable binding of pp60v-src to plasma membranes: evidence for a myristyl-src receptor

The molecular basis for membrane association of pp60v-src, the transforming protein of Rous sarcoma virus, was investigated in a cell-free system. Newly synthesized pp60v-src polypeptide, produced by in vitro translation of src mRNA, rapidly bound to plasma membranes. Binding was saturable and dependent on the presence of myristate at the amino terminus of pp60v-src. Prior treatment of membranes with heat or trypsin greatly decreased subsequent binding of pp60v-src. Membrane binding of pp60v-src was competed by a myristylated peptide containing the first 11 amino acids of the mature src sequence, but not by non-myristylated src peptide or other myristylated peptides. The specificity, saturability, and competitive nature of pp60v-src binding provide evidence for the existence of a src receptor in the plasma membrane.     

p59fyn tyrosine kinase associates with multiple T-cell receptor subunits through its unique amino-terminal domain.

Several lines of evidence link the protein tyrosine kinase p59fyn to the T-cell receptor. The molecular basis of this interaction has not been established. Here we show that the tyrosine kinase p59fyn can associate with chimeric proteins that contain the cytoplasmic domains of CD3 epsilon, gamma, zeta (zeta), and eta. Mutational analysis of the zeta cytoplasmic domain demonstrated that the membrane-proximal 41 residues of zeta are sufficient for p59fyn binding and that at least two p59fyn binding domains are present. The association of p59fyn with the zeta chain was specific, as two closely related Src family protein tyrosine kinases, p60src and p56lck, did not associate with a chimeric protein that contained the cytoplasmic domain of zeta. Mutational analysis of p59fyn revealed that a 10-amino-acid sequence in the unique amino-terminal domain of p59fyn was responsible for the association with zeta. These findings support evidence that p59fyn is functionally and structurally linked to the T-cell receptor. More importantly, these studies support a critical role for the unique amino-terminal domains of Src family kinases in the coupling of tyrosine kinases to the signalling pathways of cell surface receptors.     

The absence of myristic acid decreases membrane binding of p60src but does not affect tyrosine protein kinase activity.

We have constructed two point mutants of Rous sarcoma virus in which the amino-terminal glycine residue of the transforming protein, p60src, was changed to an alanine or a glutamic acid residue. Both mutant proteins failed to become myristylated and, more importantly, no longer transformed cells. The lack of transformation could not be attributed to defects in the catalytic activity of the mutant p60src proteins. In vitro phosphorylation of the peptide angiotensin or of the cellular substrate proteins enolase and p36 revealed no significant differences in the Km or specific activity of the mutant and wild-type p60src proteins. However, when cellular fractions were prepared, less than 12% of the nonmyristylated p60src proteins was bound to membranes. In contrast, more than 82% of the wild-type protein was associated with membranes. Wild-type p60src was phosphorylated by protein kinase C, a protein kinase which associates with membranes when activated. The mutant proteins were not. This finding supports the idea that within the intact cell the nonmyristylated p60src proteins are cytoplasmic and suggests that this apparent solubility is not an artifact of the cell fractionation procedure. The myristyl groups of p60src apparently encourages a tight association between protein and membranes and, by determining the cellular location of the enzyme, allows transformation to occur.