Binding of the Src SH2 domain to phosphopeptides is determined by residues in both the SH2 domain and the phosphopeptides.

Src homology 2 (SH2) domains are found in a variety of signaling proteins and bind phosphotyrosine-containing peptide sequences. To explore the binding properties of the SH2 domain of the Src protein kinase, we used immobilized phosphopeptides to bind purified glutathione S-transferase-Src SH2 fusion proteins. With this assay, as well as a free-peptide competition assay, we have estimated the affinities of the Src SH2 domain for various phosphopeptides relative to a Src SH2-phosphopeptide interaction whose Kd has been determined previously (YEEI-P; Kd = 4 nM). Two Src-derived phosphopeptides, one containing the regulatory C-terminal Tyr-527 and another containing the autophosphorylation site Tyr-416, bind the Src SH2 domain in a specific though low-affinity manner (with about 10(4)-lower affinity than the YEEI-P peptide). A platelet-derived growth factor receptor (PDGF-R) phosphopeptide containing Tyr-857 does not bind appreciably to the Src SH2 domain, suggesting it is not the PDGF-R binding site for Src as previously reported. However, another PDGF-R-derived phosphopeptide containing Tyr-751 does bind the Src SH2 domain (with an affinity approximately 2 orders of magnitude lower than that of YEEI-P). All of the phosphopeptides which bind to the Src SH2 domain contain a glutamic acid at position -3 or -4 with respect to phosphotyrosine; changing this residue to alanine greatly diminishes binding. We have also tested Src SH2 mutants for their binding properties and have interpreted our results in light of the recent crystal structure solution for the Src SH2 domain. Mutations in various conserved and nonconserved residues (R155A, R155K, N198E, H201R, and H201L) cause slight reductions in binding, while two mutations cause severe reductions. The W148E mutant domain, which alters the invariant tryptophan that marks the N-terminal border of the SH2 domain, binds poorly to phosphopeptides. Inclusion of the SH3 domain in the fusion protein partially restores the binding by the W148E mutant. A change in the invariant arginine that coordinates twice with phosphotyrosine in the peptide (R175L) results in a nearly complete loss of binding. The R175L mutant does display high affinity for the PDGF-R peptide containing Tyr-751, via an interaction that is at least partly phosphotyrosine independent. We have used this interaction to show that the R175L mutation also disrupts the intramolecular interaction between the Src SH2 domain and the phosphorylated C terminus within the context of the entire Src protein; thus, the binding properties observed for mutant domains in an in vitro assay appear to mimic those that occur in vivo.     

Role of electrostatic interactions in SH2 domain recognition: salt-dependence of tyrosyl-phosphorylated peptide binding to the tandem SH2 domain of the Syk kinase and the single SH2 domain of the Src kinase

SH2 domains are small protein domains that bind specifically to tyrosyl-phosphorylated sequences. Because phosphorylation contributes a large part of the binding free energy, it has been postulated that electrostatic interactions may play an important role in SH2 domain recognition. To test this hypothesis, we have examined the salt dependence of the interaction between tyrosyl-phosphorylated peptides and SH2 domains. The dependence of the binding constant, K(obs), on [NaCl] was shown to be strong for binding of the tandem SH2 domain of the Syk kinase (Syk-tSH2) to doubly phosphorylated peptides derived from immune-receptor tyrosine activation motifs (dpITAMs): the slopes of plots of log(K(obs)) versus log [NaCl], designated SK(obs), ranged from -2.6 +/- 0.1 to -3.1 +/- 0.2. Binding of the single SH2 domain of the Src kinase to its consensus singly phosphorylated peptide (sequence pYEEI where pY indicates a phosphotyrosine) was also highly dependent on [NaCl] with a SK(obs) value of -2.4 +/- 0.1. The ability of salt to disrupt the interactions between Syk-tSH2 and dpITAM peptides was shown to be anion-dependent with the inhibitory effect following the order: phosphate > Cl(-) > F(-). For the Syk-tSH2 system, interactions in the pY-binding pockets were shown to be responsible for a large portion of the total salt dependence: removal of either phosphate from the dpITAM peptide reduced the magnitude of SK(obs) by 40-60% and weakened binding by 2-3 orders of magnitude. Consistent with this finding, binding of the single amino acid Ac-pY-NH(2) was characterized by a large salt dependence of binding and was also dependent on the identity of the perturbing anion. The role of peptide residues C-terminal to the pY, which are implicated in determining the specificity of the phosphopeptide-SH2 domain interaction, was next probed by comparing the binding of the Src SH2 domain to a peptide containing the pYEEI sequence with that of a lower affinity variant pYAAI peptide: the magnitude of SK(obs) for the variant peptide was reduced to -1.3 +/- 0.1 as compared to -2.4 +/- 0.1 for the pYEEI peptide, indicating that in addition to pY, residues conferring peptide binding specificity contribute significantly to the salt dependence of SH2 domain binding. This study shows that electrostatic interactions play important roles not only in mediating pY recognition and binding but also in contributing to the specificity of the interactions between tyrosyl phosphopeptides and SH2 domains.     

Structural basis for specificity switching of the Src SH2 domain

The Src SH2 domain binds pYEEI-containing phosphopeptides in an extended conformation with a hydrophobic pocket, which includes ThrEF1, binding Ile(pY +3). Mutating ThrEF1 to tryptophan switches specificity to an Asn(pY +2) requirement, yielding a biological mimic of the Grb2 SH2 domain. Here we show that the Src ThrEF1Trp SH2 domain mutant binds pYVNV phosphopeptides in a beta turn conformation, which, despite differing conformations of the interacting tryptophan, closely resembles the native Grb2/pYVNV cognate peptide binding mode. The ThrEF1Trp substitution therefore switches specificity by physically occluding the pTyr +3 binding pocket and by providing additional interaction surface area for Asn(pY +2). This demonstrates structurally how novel SH2 domain specificities may rapidly evolve through single amino acid substitutions and suggests how new signaling pathways may develop.     

Copper dipicolinates as peptidomimetic ligands for the Src SH2 domain

The introduction of copper chelates into peptide mimetics creates the Src SH2 binding ligands and paramagnetic complexes suitable for EPR studies of peptide protein interactions. The dipicolinic acid was attached to SH2 domain targeting fragments by two different linkers.     

Solid-phase binding assays of peptides using EGFP-Src SH2 domain fusion protein and biotinylated Src SH2 domain

Two solid-phase binding assays were designed and evaluated for their potential use in comparing the affinity of peptides to the Src SH2 domain. Resin beads attached to peptides were incubated with the enhanced green fluorescence protein(EGFP)-Src SH2 domain fusion protein or the biotinylated Src SH2 domain and extensively washed. The beads-attached tetrapeptides with high affinities to the EGFP-Src SH2 domain showed more fluorescence intensity than those beads containing tetrapeptides with weak binding affinities, as shown by fluorescence microscopy and fluorescence imaging system. Only the beads attached to pYEEI produced a dark purple color on incubation of the beads, respectively, with the biotinylated Src kinases SH2 domain, alkaline phosphatase-coupled streptavidin, and BCIP/NBT. These solid-phase binding assays may have potential applications for the screening of peptides for the Src kinases SH2 domains.     

Design of tetrapeptide ligands as inhibitors of the Src SH2 domain

Src homology-2 (SH2) domains are noncatalytic motifs containing approximately 100 amino acid residues that are involved in intracellular signal transduction. The phosphotyrosine-containing tetrapeptide pTyr-Glu-Glu-Ile (pYEEI) binds to Src SH2 domain with high affinity (K(d)=100 nM). The development of five classes of tetrapeptides as inhibitors for the Src SH2 domain is described. Peptides were prepared via solid-phase peptide synthesis and tested for affinity to Src SH2 domain using a fluorescence polarization based assay. All of the N-terminal substituted pYEEI derivatives (class II) presented binding affinity (IC(50)=of 2.7-8.6 microM) comparable to pYEEI (IC(50)=6.5 microM) in this assay. C-Terminal substituted pYEEI derivatives (class III) showed a lower binding affinity with IC(50) values of 34-41 microM. Amino-substituted phenylalanine derivatives (class IV) showed weak binding affinities (IC(50)=16-153 microM). Other substitutions on phenyl ring (class I) or the replacement of the phenyl ring with other cyclic groups (class V) dramatically decreased the binding of tetrapeptides to Src SH2 (IC(50)>100 microM). The ability of pYEEI and several of the tetrapeptides to inhibit the growth of cancer cells were assessed in a cell-based proliferation assay in human embryonic kidney (HEK) 293 tumor cells. The binding affinity of several of tested compounds against Src SH2 domain correlates with antiproliferative activity in 293T cells. None of the compounds showed any significant antifungal activity against Candida albicans ATCC 14053 at the maximum tested concentration of 10 microM. Overall, these results provided the structure-activity relationships for some FEEI and YEEI derivatives designed as Src SH2 domain inhibitors.     

SH3-SH2 domain orientation in Src kinases: NMR studies of Fyn

The regulatory domains of Src family kinases SH3 and SH2 suppress Src activity when bound to the catalytic domain. Here, the isolated SH3-SH2 fragment from the Src family member Fyn (FynSH32) is studied by NMR. The properties of this fragment are expected to be similar to the domains in the active state, where they are dissociated from the catalytic domain. Crosscommunication between SH3 and SH2 of FynSH32, measured by chemical shift perturbation, was found to be small. Diffusion and alignment anisotropy measurements showed that SH3 and SH2 of peptide-bound FynSH32 are significantly coupled but still exhibit some interdomain flexibility. The observed average domain orientation indicates that a large SH3-SH2 domain closure is required to reach the inactive state. The implications of these results for Src regulation are discussed.     

Structure-based design of novel nonpeptide inhibitors of the Src SH2 domain:phosphotyrosine mimetics exploiting multifunctional group replacement chemistry

A series of novel nonpeptide inhibitors of the pp60(c-Src) (Src) SH2 domain is described that exploit multifunctional group replacement of the phenylphosphate moiety of phosphotyrosine (pTyr). Relative to an x-ray structure of citrate complexed to the pTyr binding site of the Src SH2 domain, these nonpeptide ligands illustrate the systematic replacement of the phosphate group by multiple nonhydrolyzable, mono- or dianionic functionalities. Specifically, several phenylalanine (Phe) analogs incorporating key 4' and 3' substituents were synthesized and incorporated into a bicyclic benzamide template previously reported (W. C. Shakespeare et al., Proceedings of the National Academy of Science USA, 2000, Vol. 97, pp. 9373-9378). These pTyr mimetics included 4',3'-diphosphono-Phe (Dpp), 4',3'-dicarboxymethyloxy-Phe (Dcp), and 4'-phosphono-3'-carboxymethyloxy-Phe (Cpp). Noteworthy were nonpeptide inhibitors 8-11 that were 5- to 10-fold more potent than the cognate tetrapeptide ligand Ac-pTyr-Glu-Glu-Ile-NH(2) in binding to the Src SH2 domain.     

Mutational investigation of the specificity determining region of the Src SH2 domain

SH2 domains are protein modules which bind tyrosine phosphorylated sequences in many signaling pathways. These domains contain two regions with specialized functions: residues in one region form a deep pocket into which the phosphotyrosine of the target inserts, while the other region contains the so-called "specificity determining residues" which interact with the three residues C-terminal to the phosphotyrosine in the target. Here, titration calorimetry and site-directed mutagenesis have been used to probe the importance of eight specificity determining residues of the SH2 domain of the Src kinase involved in contacts with its tyrosine phosphorylated consensus peptide target (sequence pYEEI where pY indicates a phosphotyrosine). Mutating six of these eight residues to Ala individually, resulted in a threefold or less loss in binding affinity; hence the majority of the residues in the specificity determining region are by themselves of minimal importance for binding. Two residues were found to have significant effects on binding: Tyr betaD5 and Lys betaD3. Tyr betaD5 was the most crucial residue as evidenced by the 30-fold loss in affinity when Tyr betaD5 is mutated to Ile. However, while this mutation eliminated the specificity of the Src SH2 domain for the pYEEI peptide sequence, it was not sufficient to switch the specificity of the Src SH2 domain to that of a related SH2 domain which has an Ile at the betaD5 position. Mutation of Lys betaD3 to an Ala residue resulted in a modest reduction in binding affinity (sevenfold). It is interesting that this mutation resulted in a change of specificity affecting the selection of the +1 position residue C-terminal to the phosphotyrosine. Except for the Lys betaD3-+1 Glu interaction which is significantly coupled, only weak energetic coupling was observed across the binding interface, as assessed using double mutant cycles. The results of this study suggest that interactions involving the specificity determining region of SH2 domains may be insufficient by themselves to target single SH2 domains to particular phosphorylated sites.     

Investigation of phosphotyrosine recognition by the SH2 domain of the Src kinase.

The binding of tyrosine phosphorylated targets by SH2 domains is required for propagation of many cellular signals in higher eukaryotes; however, the determinants of phosphotyrosine (pTyr) recognition by SH2 domains are not well understood. In order to identify the attributes of pTyr required for high affinity interaction with SH2 domains, the binding of the SH2 domain of the Src kinase (Src SH2 domain) to a dephosphorylated peptide, a phosphoserine-containing peptide, and the amino acid pTyr was studied using titration calorimetry and compared with the binding of a high affinity tyrosyl phosphopeptide. The dephosphorylated peptide and the phosphoserine containing peptide both bind extremely weakly to the Src SH2 domain (DeltaGo (dephosphorylated)=-3.6 kcal/mol, DeltaGo (phosphoserine) >-3.7 kcal/mol); however, the DeltaGo value of pTyr binding is more favorable (-4.7 kcal/mol, or 50 % of the entire binding free energy of a high affinity tyrosyl phosphopeptide). These results indicate that both the phosphate and the tyrosine ring of the pTyr are critical determinants of high affinity binding. Alanine mutagenesis was also used to evaluate the energetic contribution to binding of ten residues located in the pTyr-binding site. Mutation of the strictly conserved Arg betaB5 resulted in a large increase in DeltaGo (DeltaDeltaGo=3.2 kcal/mol) while elimination of the other examined residues each resulted in a significantly smaller (DeltaDeltaGo<1.4 kcal/mol) reduction in affinity, indicating that Arg betaB5 is the single most important determinant of pTyr recognition. However, mutation of Cys betaC3, a residue unique to the Src SH2 domain, surprisingly increased affinity by eightfold (DeltaDeltaGo=-1.1 kcal/mol). Using a double mutant cycle analysis, it was revealed that residues of the pTyr-binding pocket are not coupled to the peptide residues C-terminal to the pTyr. In addition, comparison of each residue's DeltaDeltaGo value upon mutation with that residue's sequence conservation among SH2 domains revealed only a modest correlation between a residue's energetic contribution to pTyr recognition and its conservation throughout evolution. The results of this investigation highlight the importance of a single critical interaction, the buried ionic bond between the phosphate of the pTyr and Arg betaB5 of the SH2 domain, driving the binding of SH2 domains to tyrosine phosphorylated targets.     

Native state energetics of the Src SH2 domain: evidence for a partially structured state in the denatured ensemble

We have defined the free-energy profile of the Src SH2 domain using a variety of biophysical techniques. Equilibrium and kinetic experiments monitored by tryptophan fluorescence show that Src SH2 is quite stable and folds rapidly by a two-state mechanism, without populating any intermediates. Native state hydrogen-deuterium exchange confirms this two-state behavior; we detect no cooperative partially unfolded forms in equilibrium with the native conformation under any conditions. Interestingly, the apparent stability of the protein from hydrogen exchange is 2 kcal/mol greater than the stability determined by both equilibrium and kinetic studies followed by fluorescence. Native-state proteolysis demonstrates that this "super protection" does not result from a deviation from the linear extrapolation model used to fit the fluorescence data. Instead, it likely arises from a notable compaction in the unfolded state under native conditions, resulting in an ensemble of conformations with substantial solvent exposure of side chains and flexible regions sensitive to proteolysis, but backbone amides that exchange with solvent approximately 30-fold slower than would be expected for a random coil. The apparently simple behavior of Src SH2 in traditional unfolding studies masks the significant complexity present in the denatured-state ensemble.     

Src kinase activity and SH2 domain regulate the dynamics of Src association with lipid and protein targets

Src functions depend on its association with the plasma membrane and with specific membrane-associated assemblies. Many aspects of these interactions are unclear. We investigated the functions of kinase, SH2, and SH3 domains in Src membrane interactions. We used FRAP beam-size analysis in live cells expressing a series of c-Src-GFP proteins with targeted mutations in specific domains together with biochemical experiments to determine whether the mutants can generate and bind to phosphotyrosyl proteins. Wild-type Src displays lipid-like membrane association, whereas constitutively active Src-Y527F interacts transiently with slower-diffusing membrane-associated proteins. These interactions require Src kinase activity and SH2 binding, but not SH3 binding. Furthermore, overexpression of paxillin, an Src substrate with a high cytoplasmic population, competes with membrane phosphotyrosyl protein targets for binding to activated Src. Our observations indicate that the interactions of Src with lipid and protein targets are dynamic and that the kinase and SH2 domain cooperate in the membrane targeting of Src.     

Structure, dynamics, and binding thermodynamics of the v-Src SH2 domain: implications for drug design

SH2 domains provide fundamental recognition sites in tyrosine kinase-mediated signaling pathways which, when aberrant, give rise to disease states such as cancer, diabetes, and immune deficiency. Designing specific inhibitors that target the SH2 domain-binding site, however, have presented a major challenge. Despite well over a decade of intensive research, clinically useful SH2 domain inhibitors have yet to become available. A better understanding of the structural, dynamic, and thermodynamic contributions to ligand binding of individual SH2 domains will provide some insight as to whether inhibitor development is possible. We report the first high resolution solution structure of the apo-v-Src SH2 domain. This is accompanied by the analysis of backbone dynamics and pK(a) values within the apo- and peptide-bound states. Our results indicate that the phosphotyrosine (pY) pocket is tightly structured and hence not adaptable to exogenous ligands. On the other hand, the pocket which accommodates residues proximal and C-terminal of the pY (pY + 3) or so-called specificity determining region, is a large dynamic-binding surface. This appears to allow a high level of promiscuity in binding. Binding of a series of synthetic, phosphotyrosyl, peptidomimetic compounds designed to explore interactions in the pY + 3 pocket further demonstrates the ability of the SH2 domain to accommodate diverse ligands. The thermodynamic parameters of these interactions show dramatic enthalpy/entropy compensation. These data suggest that the v-Src SH2 domain does not have a highly specific secondary-binding site, which clearly presents a major hurdle to design selective inhibitors.     

Structure-based design and synthesis of a novel class of Src SH2 inhibitors.

The structure-based design and synthesis of a novel class of 2,4-disubstituted thiazoles as Src SH2 inhibitors is described. Initial results are presented, including the X-ray and NMR analysis of one thiazole inhibitor bound to Lck and Src SH2.     

Macrocyclization in the design of a conformationally constrained Grb2 SH2 domain inhibitor.

Grubbs' olefin metathesis reaction was utilized to prepare a macrocyclic variant of a linear Grb2 SH2 domain antagonist in an attempt to induce a beta-bend conformation known to be required for high affinity binding. In extracellular Grb2 SH2 domain binding assays, the macrocyclic analogue exhibited an approximate 100-fold enhancement in binding potency relative to its linear counterpart. The macrocycle was not as effective in whole cell binding assays as would be expected based on its extracellular binding potency.     

The SH3 domain of Src can downregulate its kinase activity in the absence of the SH2 domain-pY527 interaction

The contact between the SH2 domain and the C-terminal tail of c-Src inhibits its kinase activity via a complex network of interactions, including the SH3 domain. We examined the role of the SH3 domain in v-Src, where the C-terminal tail is mutated and unbound. We used the v-Src variants Prague C (PRC) and Schmidt-Ruppin A (SRA), which are of low and high kinase activities, respectively, to measure phosphorylation in vitro by immunoprecipitated kinases produced in Saccharomyces cerevisiae. Swapping the regulatory domains between SRA and PRC revealed that N117D, I96T, and V124L mutations in the n-src- and RT-loops of the SH3 domain of PRC are responsible for the low kinase activity of PRC. Moreover, introducing D117N, R95W, T96I, and L124V into activated c-Src(Y527F) caused a 2.5-fold increase in its activity. The mutations in the CD linker KP249,250DG and L255A, which were shown to activate c-Src, had no effect on the activity of the "SH2-activated" Src kinases. Together our data suggest that in the "SH2-activated" forms of Src, the SH3 domain continues to influence the kinase activity via the direct contacts of the n-src- and RT-loops with the kinase N-terminal lobe.     

Involvement of the SH3 domain in Ca2+-mediated regulation of Src family kinases

When cells are treated with Ca(2+) and Ca(2+)-ionophore, c-Src kinase activity increases, whereas c-Yes kinase activity decreases. This opposite modulation can be reproduced in an in vitro reconstitution assay and is dependent on Ca(2+) and on soluble factors present in cell lysates. Since c-Src and c-Yes share a high degree of homology, with the exception of their N-terminal "unique" domains, their activity was thought to be coordinately regulated. To assess the mechanism of regulation we generated stable cell lines expressing eight different constructs containing wild type c-Src and c-Yes, as well as swaps of the unique domain alone, unique and Src homology 3 (SH3) domains together and the SH3 domain alone. Swapping of the unique domains was not sufficient to reverse the regulation of the chimeric molecules. On the other hand, chimeras containing swaps of the unique plus the SH3 domains displayed reverse regulation, implicating both domains in the regulation of kinase activity by Ca(2+). To rule out the participation of the unique domain, we used chimeric molecules with swapped SH3 domains only and found that the SH3 domain is necessary and sufficient to confer Ca(2+)-mediated regulation of Src and Yes tyrosine kinases.     

Simultaneous assay of Src SH3 and SH2 domain binding using different wavelength fluorescence polarization probes.

pp60(c-src) is a prototypical nonreceptor tyrosine kinase and may play a role in diseases as diverse as cancer and osteoporosis. In Src, the SH3 domain (Src homology 3) binds proteins at specific, proline-rich sequences, while the SH2 domain (Src homology 2) binds phosphotyrosine-containing sequences. Inhibition of Src SH3 and SH2 domain function is of potential therapeutic value because of their importance in signaling pathways involved in disease states. We have developed dual-wavelength fluorescent peptide probes for both the Src SH3 and the Src SH2 domains, which allow the simultaneous measurement of compounds binding to each domain in assays based on the technique of fluorescence polarization. We demonstrate the utility of these probes in a dual-binding assay (suitable for high-throughput screening) to study the interactions of various peptides with these domains, including a sequence from the rat protein p130(CAS) which has been reported to bind simultaneously to both Src SH3 and SH2 domains. Utilizing this dual-binding assay, we confirm that sequences from p130(CAS) can simultaneously bind Src via both its SH3 and its SH2 domains. We also use the dual-binding assay as an internal control to identify substances which inhibit SH3 and SH2 binding via nonspecific mechanisms.     

Monocarboxylic-based phosphotyrosyl mimetics in the design of GRB2 SH2 domain inhibitors

Three monocarboxylic-containing analogues, O-carboxymethyltyrosine (cmT, 5), 4-(carboxymethyl)phenylalanine (cmF, 6), and 4-(carboxydifluoromethyl)phenylalanine (F2cmF, 7) were utilized as phosphotyrosyl (pTyr) replacements in a high affinity B-bend mimicking platform, where they exhibited IC50 values of 2.5 microM, 65 microM and 28 microM, respectively, in a Grb2 SH2 domain Biacore binding assay. When a terminal N(alpha)-oxalyl axillary was utilized to enhance ligand interactions with a critical SH2 domain Arg67 residue (alphaA-helix), binding potencies increased from 4- to 10-fold, resulting in submicromolar affinity for cmF (IC50 = 0.6 microM) and low micromolar affinity for F2cmF (IC50 = 2 microM). Cell lysate binding studies also showed inhibition of cognate Grb2 binding to the p185erbB-2 phosphoprotein in the same rank order of potency as observed in the Biacore assay. These results indicate the potential value of cmF and F2cmF residues as pTyr mimetics for the study of Grb2 SH2 domains and suggest new strategies for improvements in inhibitor design.     

The role of the linker between the SH2 domain and catalytic domain in the regulation and function of Src.

The crystal structures of the regulated Src and Hck tyrosine kinases show intramolecular interactions between the phosphorylated tail and the SH2 domain as well as between the SH3 domain, the SH2-catalytic domain linker (SH2-CD linker) and the catalytic domain. The relative contribution of these interactions to regulation of activity is poorly understood. Mutational analysis of Src and Lck revealed that interaction of the SH2-CD linker with the SH3 domain is crucial for regulation. Moreover, three sites of interaction of the linker with the catalytic domain, one at the beginning (Trp260) and two at the back of the small lobe, opposite the catalytic cleft (beta2/beta3 loop; alphaC/beta4 loop), impinge on Src activity. Other activating mutations map to the front of the catalytic domain in the loop preceding the alphaC-helix (beta3/alphaC loop). SH2-CD linker mutants are deregulated in mammalian cells but transform fibroblasts weakly, suggesting that the linker may bind cellular components. Interpretation of our results on the basis of the crystal structure of Src favours a model in which the correctly positioned SH2-CD linker exerts an inhibitory function on catalysis of Src family members by facilitating displacement of the alphaC-helix. This study may provide a template for the generation of deregulated versions of other protein kinases.