Crystallographic structure of the SH3 domain of the human c-Yes tyrosine kinase: loop flexibility and amyloid aggregation

SH3 domains from the Src family of tyrosine kinases represent an interesting example of the delicate balance between promiscuity and specificity characteristic of proline-rich ligand recognition by SH3 domains. The development of inhibitors of therapeutic potential requires a good understanding of the molecular determinants of binding affinity and specificity and relies on the availability of high quality structural information. Here, we present the first high-resolution crystal structure of the SH3 domain of the c-Yes oncogen. Comparison with other SH3 domains from the Src family revealed significant deviations in the loop regions. In particular, the n-Src loop, highly flexible and partially disordered, is stabilized in an unusual conformation by the establishment of several intramolecular hydrogen bonds. Additionally, we present here the first report of amyloid aggregation by an SH3 domain from the Src family.     

Protein aggregation and amyloid fibril formation by an SH3 domain probed by limited proteolysis

The SH3 domains are small protein modules of 60-85 amino acid residues that are found in many proteins involved in intracellular signal transduction. The SH3 domain of the p85alpha subunit of bovine phosphatidylinositol 3'-kinase (PI3-SH3) under acidic solution adopts a compact denatured state from which amyloid fibrils are readily formed. This aggregation process has been found to be modulated substantially by solution conditions. Here, we have analyzed the conformational features of the native and acid denatured states of PI3-SH3 by limited proteolysis experiments using proteinase K and pepsin, respectively. Moreover, we have analyzed the propensity of PI3-SH3 to be hydrolyzed by pepsin at different stages in the process of aggregation and amyloid formation at pH 1.2 and 2.0 and compared the sites of proteolysis under these conditions with the conformational features of both native and aggregated PI3-SH3. The results demonstrate that the denatured state of PI3-SH3 formed at low pH is relatively resistant to proteolysis, indicating that it is partially folded. The long loop connecting beta-strands b and c in the native protein is the region in this structure most susceptible to proteolysis. Remarkably, aggregates of PI3-SH3 that are formed initially from this denatured state in acid solution display enhanced susceptibility to proteolysis of the long loop, suggesting that the protein becomes more unfolded in the early stages of aggregation. By contrast, the more defined amyloid fibrils that are formed over longer periods of time are completely resistant to proteolysis. We suggest that the protein aggregates formed initially are relatively dynamic species that are able readily to reorganize their interactions to enable formation of very well ordered fibrillar structures. In addition, the disordered and non-native character of the polypeptide chains in the early aggregates could be important in determining the high cytotoxicity that has been revealed in previous studies of these species.     

Identification of a Src kinase SH3 binding site in the C-terminal domain of the human ErbB2 receptor tyrosine kinase

Overexpression of the ErbB2 receptor tyrosine kinase is associated with most aggressive tumors in breast cancer patients and is thus one of the main investigated therapeutic targets. Human ErbB2 C-terminal domain is an unstructured anchor that recruits specific adaptors for signaling cascades resulting in cell growth, differentiation and migration. Herein, we report the presence of a SH3 binding motif in the proline rich unfolded ErbB2 C-terminal region. NMR analysis of this motif supports a PPII helix conformation and the binding to Fyn-SH3 domain. The interaction of a kinase of the Src family with ErbB2 C-terminal domain could contribute to synergistic intracellular signaling and enhanced oncogenesis.     

Solution structure of N-terminal SH3 domain of Vav and the recognition site for Grb2 C-terminal SH3 domain

The three-dimensional structure of the N-terminal SH3 domain (residues 583–660) of murine Vav, which contains a tetra-proline sequence (Pro 607-Pro 610), was determined by NMR. The solution structure of the SH3 domain shows a typical SH3 fold, but it exists in two conformations due to cis-trans isomerization at the Gly614-Pro615 bond. The NMR structure of the P615G mutant, where Pro615 is replaced by glycine, reveals that the tetra-proline region is inserted into the RT-loop and binds to its own SH3 structure. The C-terminal SH3 domain of Grb2 specifically binds to the trans form of the N-terminal SH3 domain of Vav. The surface of Vav N-terminal SH3 which binds to Grb2 C-terminal SH3 was elucidated by chemical shift mapping experiments using NMR. The surface does not involve the tetra-proline region but involves the region comprising the n-src loop, the N-terminal and the C-terminal regions. This surface is located opposite to the tetra-proline containing region, consistent with that of our previous mutagenesis studies.     

Src homology domains of v-Src stabilize an active conformation of the tyrosine kinase catalytic domain

To examine the interactions between Src homology,domains and the tyrosine kinase catalytic domain of v-Src, various combinations of domains have been expressed in bacteria as fusion proteins. Constructs containing the isolated catalytic domain, SH2 + catalytic domain, and SH3 + SH2 + catalytic domains were active in autophosphorylation assays. For the catalytic domain of v-Src, but not for v-Abl, addition of exogenous Src SH3-SH2 domains stimulated the autophosphorylation activity. In contrast to results for autophosphorylation, constructs containing Src homology domains were more active towards a synthetic peptide substrate than the isolated catalytic domain. The ability of the SH2 and SH3 domains of v-Src to stabilize an active enzyme conformation was also confirmed by refolding after denaturation in guanidinium hydrochloride. Collectively the data suggest that, in addition to their roles in intermolecular protein-protein interactions, the Src homology regions of v-Src exert a positive influence on tyrosine kinase function, potentially by maintaining an active conformation of the catalytic domain.     

Nucleation and the transition state of the SH3 domain

We present a verified computational model of the SH3 domain transition state (TS) ensemble. This model was built for three separate SH3 domains using experimental phi-values as structural constraints in all-atom protein folding simulations. While averaging over all conformations incorrectly considers non-TS conformations as transition states, quantifying structures as pre-TS, TS, and post-TS by measurement of their transmission coefficient ("probability to fold", or p(fold)) allows for rigorous conclusions regarding the structure of the folding nucleus and a full mechanistic analysis of the folding process. Through analysis of the TS, we observe a highly polarized nucleus in which many residues are solvent-exposed. Mechanistic analysis suggests the hydrophobic core forms largely after an early nucleation step. SH3 presents an ideal system for studying the nucleation-condensation mechanism and highlights the synergistic relationship between experiment and simulation in the study of protein folding.     

Determination of the solution structure of the SH3 domain of human p56 Lck tyrosine kinase

Summary The solution structure of the SH3 domain of human p56 Lck tyrosine kinase (Lck-SH3) has been determined by multidimensional heteronuclear NMR spectroscopy. The structure was calculated from a total of 935 experimental restraints comprising 785 distance restraints derived from 1017 assigned NOE cross peaks and 150 dihedral angle restraints derived from 160 vicinal coupling constants. A novel combination of the constant-time ¹H–¹³C NMR correlation experiment recorded with various delays of the constant-time refocusing delays and a fractionally ¹³C-labelled sample was exploited for the stereo-specific assignment of prochiral methyl groups. Additionally, 28 restraints of 14 identified hydrogen bonds were included. A family of 25 conformers was selected to characterize the solution structure. The average root-mean-square deviations of the backbone atoms (N, C, C, O) among the 25 conformers is 0.42 Å for residues 7 to 63. The N- and C-terminal residues, 1 to 6 and 64 to 81, are disordered, while the well-converged residues 7 to 63 correspond to the conserved sequences of other SH3 domains. The topology of the SH3 structure comprises five anti-parallel -strands arranged to form two perpendicular -sheets, which are concave and twisted in the middle part. The overall secondary structure and the backbone conformation of the core -strands are almost identical to the X-ray structure of the fragment containing the SH2-SH3 domains of p56 Lck [Eck et al. (1994) Nature, 368, 764–769]. The X-ray structure of the SH3 domain in the tandem SH2-SH3 fragment is spatially included within the ensemble of the 25 NMR conformers, except for the segment of residues 14 to 18, which makes intermolecular contacts with an adjacent SH2 molecule and the phosphopeptide ligand in the crystal lattice. Local structural differences from other known SH3 domains are also observed, the most prominent of which is the absence in Lck-SH3 of the two additional short -strands in the regions Ser¹⁵ to Glu¹⁷ and Gly²⁵ to Glu²⁷ flanking the so-called RT-Src loop. This loop (residues Glu¹⁷ to Leu²⁴), together with the n-Src loop (residues Gln³⁷ to Ser⁴⁶) confines the ligand interaction site which is formed by a shallow patch of hydrophobic amino acids (His¹⁴, Tyr¹⁶, Trp⁴¹, Phe⁵⁴ and Phe⁵⁹). Both loops are flexible and belong to the most mobile regions of the protein, which is assessed by the heteronuclear ¹⁵N,¹H-NOE values characterizing the degree of internal backbone motions. The aromatic residues of the ligand binding site are arranged such that they form three pockets for interactions with the polyproline ligand.Abbreviations CT constant time - HSQC heteronuclear single-quantum coherence - NOE nuclear Overhauser enhancement - NOESY nuclear Overhauser enhancement spectroscopy - SH2 Src homology domain 2 - SH3 Src homology domain 3     

Intertwined dimeric structure for the SH3 domain of the c-Src tyrosine kinase induced by polyethylene glycol binding

Here we report the first crystal structure of the SH3 domain of the cellular Src tyrosine kinase (c-Src-SH3) domain on its own. In the crystal two molecules of c-Src-SH3 exchange their -RT loops generating an intertwined dimer, in which the two SH3 units, preserving the binding site configuration, are oriented to allow simultaneous binding of two ligand molecules. The dimerization of c-Src-SH3 is induced, both in the crystal and in solution, by the binding of a PEG molecule at the dimer interface, indicating that this type of conformations are energetically close to the native structure. These results have important implications respect to in vivo oligomerization and amyloid aggregation.     

The SH3 domain of postsynaptic density 95 mediates inflammatory pain through phosphatidylinositol‐3‐kinase recruitment

Sensitization to inflammatory pain is a pathological form of neuronal plasticity that is poorly understood and treated. Here we examine the role of the SH3 domain of postsynaptic density 95 (PSD95) by using mice that carry a single amino‐acid substitution in the polyproline‐binding site. Testing multiple forms of plasticity we found sensitization to inflammation was specifically attenuated. The inflammatory response required recruitment of phosphatidylinositol‐3‐kinase‐C2α to the SH3‐binding site of PSD95. In wild‐type mice, wortmannin or peptide competition attenuated the sensitization. These results show that different types of behavioural plasticity are mediated by specific domains of PSD95 and suggest novel therapeutic avenues for reducing inflammatory pain.     

Design and structural thermodynamic studies of the chimeric protein derived from spectrin SH3 domain

A number of the chimeric constructs with spectrin SH3 domain were designed for structural and thermodynamic studies of protein self-assembly and protein-ligand interactions. SH3 domains, components of many regulatory proteins, operate through weak interactions with proline-rich regions of polypeptide chains. The recombinant construct (WT-CIIA) studied in this work was constructed by linking the peptide ligand PPPVPPYSAG to the domain C-terminus via a long 12-residue linker to increase the affinity of this ligand for the spectrin domain, thereby ensuring a stable positioning of the polyproline helix to the conserved ligand-binding site in orientation II, which is regarded as untypical of the interaction between this domain and oligopeptides. A comparison of fluorescence spectra of the initial domain and the recombinant protein WT-CIIA suggests that the ligand sticks to the conservative binding site. However, analysis of the equilibrium urea-induced unfolding has demonstrated that this is an unstable contact, which leads to a two-stage unfolding of the chimeric protein. The protein WT-CIIA was crystallized; a set of X-ray diffraction data with a resolution of 1.75 Å was recorded from individual crystals. A preliminary analysis of these diffraction data has demonstrated that the crystals belong to space group P32 with the following unit cell parameters: a = b = 36.39, c = 112.17 Å, a = β = 90.0, and γ = 120.0.     

Protein folding kinetics beyond the phi value: using multiple amino acid substitutions to investigate the structure of the SH3 domain folding transition state

The SH3 domain folding transition state structure contains two well-ordered turn regions, known as the diverging turn and the distal loop. In the Src SH3 domain transition state, these regions are stabilized by a hydrogen bond between Glu30 in the diverging turn and Ser47 in the distal loop. We have examined the effects on folding kinetics of amino acid substitutions at the homologous positions (Glu24 and Ser41) in the Fyn SH3 domain. In contrast to most other folding kinetics studies which have focused primarily on non-disruptive substitutions with Ala or Gly, here we have examined the effects of substitutions with diverse amino acid residues. Using this approach, we demonstrate that the transition state structure is generally tolerant to amino acid substitutions. We also uncover a unique role for Ser at position 41 in facilitating folding of the distal loop, which can only be replicated by Asp at the same position. Both these residues appear to accelerate folding through the formation of short-range side-chain to backbone hydrogen bonds. The folding of the diverging turn region is shown to be driven primarily by local interactions. The diverging turn and distal loop regions are found to interact in the transition state structure, but only in the context of particular mutant backgrounds. This work demonstrates that studying the effects of a variety of amino acid substitutions on protein folding kinetics can provide unique insights into folding mechanisms which cannot be obtained by standard Phi value analysis.     

The helically extended SH3 domain of the T cell adaptor protein ADAP is a novel lipid interaction domain

Adhesion and degranulation-promoting adapter protein (ADAP) is critically involved in downstream signalling events triggered by the activation of the T cell receptor. Cytokine production, proliferation and integrin clustering of T cells are dependent on ADAP function, but the molecular basis for these processes is poorly understood. We now show the hSH3 domain of ADAP to be a lipid-interaction module that binds to acidic lipids, including phosphatidylinositides. Positively charged surface patches of the domain preferentially bind to polyvalent acidic lipids such as PIP2 or PIP3 over the monovalent PS phospholipid and this interaction is dependent on the N-terminal helix of the hSH3 domain fold. Basic amino acid side-chains from the SH3 scaffold also contribute to lipid binding. In the context of T cell signalling, our findings suggest that ADAP, upon recruitment to the cell-cell junction as part of a multiprotein complex, directly interacts with phosphoinositide-enriched regions of the plasma membrane. Furthermore, the ADAP lipid interaction defines the helically extended SH3 scaffold as a novel member of membrane interaction domains.     

A thermodynamic and kinetic analysis of the folding pathway of an SH3 domain entropically stabilised by a redesigned hydrophobic core

The folding thermodynamics and kinetics of the alpha-spectrin SH3 domain with a redesigned hydrophobic core have been studied. The introduction of five replacements, A11V, V23L, M25V, V44I and V58L, resulted in an increase of 16% in the overall volume of the side-chains forming the hydrophobic core but caused no remarkable changes to the positions of the backbone atoms. Judging by the scanning calorimetry data, the increased stability of the folded structure of the new SH3-variant is caused by entropic factors, since the changes in heat capacity and enthalpy upon the unfolding of the wild-type and mutant proteins were identical at 298 K. It appears that the design process resulted in an increase in burying both the hydrophobic and hydrophilic surfaces, which resulted in a compensatory effect upon the changes in heat capacity and enthalpy. Kinetic analysis shows that both the folding and unfolding rate constants are higher for the new variant, suggesting that its transition state becomes more stable compared to the folded and unfolded states. The phi(double dagger-U) values found for a number of side-chains are slightly lower than those of the wild-type protein, indicating that although the transition state ensemble (TSE) did not change overall, it has moved towards a more denatured conformation, in accordance with Hammond's postulate. Thus, the acceleration of the folding-unfolding reactions is caused mainly by an improvement in the specific and/or non-specific hydrophobic interactions within the TSE rather than by changes in the contact order. Experimental evidence showing that the TSE changes globally according to its hydrophobic content suggests that hydrophobicity may modulate the kinetic behaviour and also the folding pathway of a protein.     

Thermodynamics and folding kinetics analysis of the SH3 domain form discrete molecular dynamics

We perform a detailed analysis of the thermodynamics and folding kinetics of the SH3 domain fold with discrete molecular dynamic simulations. We propose a protein model that reproduces some of the experimentally observed thermodynamic and folding kinetic properties of proteins. Specifically, we use our model to study the transition state ensemble of the SH3 fold family of proteins, a set of unstable conformations that fold to the protein native state with probability 1/2. We analyze the participation of each secondary structure element formed at the transition state ensemble. We also identify the folding nucleus of the SH3 fold and test extensively its importance for folding kinetics. We predict that a set of amino acid contacts between the RT-loop and the distal hairpin are the critical folding nucleus of the SH3 fold and propose a hypothesis that explains this result.     

Interaction of nebulin SH3 domain with titin PEVK and myopalladin: implications for the signaling and assembly role of titin and nebulin

Skeletal muscle nebulin is thought to determine thin filament length and regulate actomyosin interaction in a calcium/calmodulin or S100 sensitive manner. We have investigated the binding of nebulin SH3 with proline-rich peptides derived from the 28-mer PEVK modules of titin and the Z-line protein myopalladin, using fluorescence, circular dichroism and nuclear magnetic resonance techniques. Of the six peptides studied, PR2 of titin (VPEKKAPVAPPK) and myopalladin MyoP2 (646VKEPPPVLAKPK657) bind to nebulin SH3 with micromolar affinity (approximately 31 and 3.4 microM, respectively), whereas the other four peptides bind weakly (>100 microM). Sequence analysis of titins reveals numerous SH3 binding motifs that are highly enriched in the PEVK segments of titin isoforms. Our findings suggest that titin PEVK and myopalladin may play signaling roles in targeting and orientating nebulin to the Z-line during sarcomere assembly.     

The high resolution NMR structure of the third SH3 domain of CD2AP

CD2 associated protein (CD2AP) is an adaptor protein that plays an important role in cell to cell union needed for the kidney function. CD2AP interacts, as an adaptor protein, with different natural targets, such as CD2, nefrin, c-Cbl and podocin. These proteins are believed to interact to one of the three SH3 domains that are positioned in the N-terminal region of CD2AP. To understand the network of interactions between the natural targets and the three SH3 domains (SH3-A, B and C), we have started to determine the structures of the individual SH3 domains. Here we present the high-resolution structure of the SH3-C domain derived from NMR data. Full backbone and side-chain assignments were obtained from triple-resonance spectra. The structure was determined from distance restraints derived from high-resolution 600 and 800 MHz NOESY spectra, together with phi and psi torsion angle restraints based on the analysis of ¹HN, ¹⁵N, ¹Hα, ¹³Cα, ¹³CO and ¹³Cβ chemical shifts. Structures were calculated using CYANA and refined in water using RECOORD. The three-dimensional structure of CD2AP SH3-C contains all the features that are typically found in other SH3 domains, including the general binding site for the recognition of polyproline sequences.     

Construction of a non-redundant human SH2 domain database

Domain database is essential for domain property research. Eliminating redundant information in database query is very important for database quality. Here we report the manual construction of a non-redundant human SH2 domain database. There are 119 human SH2 domains in 110 SH2-containing proteins. Human SH2s were aligned with ClustalX, and a homologous tree was generated. In this tree, proteins with similar known function were classified into the same group. Some proteins in the same group have been reported to have similar binding motifs experimentally. The tree might provide clues about possible functions of hypothetical proteins for further experimental verification.     

Cooperative interactions and a non-native buried Trp in the unfolded state of an SH3 domain

The presence of residual structure in the unfolded state of the N-terminal SH3 domain of Drosophila drk (drkN SH3 domain) has been investigated using far- and near-UV circular dichroism (CD), fluorescence, and NMR spectroscopy. The unfolded (U(exch)) state of the drkN SH3 domain is significantly populated and exists in equilibrium with the folded (F(exch)) state under non-denaturing conditions near physiological pH. Denaturation experiments have been performed on the drkN SH3 domain in order to monitor the change in ellipticity, fluorescence intensity, and chemical shift between the U(exch) state and chemically or thermally denatured states. Differences between the unfolded and chemically or thermally denatured states highlight specific areas of residual structure in the unfolded state that are cooperatively disrupted upon denaturation. Results provide evidence for cooperative interactions in the unfolded state involving residues of the central beta-sheet, particularly the beta4 strand. Denaturation as well as hydrogen-exchange experiments demonstrate a non-native burial of the Trp ring within this "cooperative" core of the unfolded state. These findings support the presence of non-native hydrophobic clusters, organised by Trp rings, within disordered states.     

A lack of peptide binding and decreased thermostability suggests that the CASKIN2 scaffolding protein SH3 domain may be vestigial

Background

CASKIN2 is a neuronal signaling scaffolding protein comprised of multiple ankyrin repeats, two SAM domains, and one SH3 domain. The CASKIN2 SH3 domain for an NMR structural determination because its peptide-binding cleft appeared to deviate from the repertoire of aromatic enriched amino acids that typically bind polyproline-rich sequences.

Results

The structure demonstrated that two non-canonical basic amino acids (K290/R319) in the binding cleft were accommodated well in the SH3 fold. An K290Y/R319W double mutant restoring the typical aromatic amino acids found in the binding cleft resulted in a 20 °C relative increase in the thermal stability. Considering the reduced stability, we speculated that the CASKIN2 SH3 could be a nonfunctional remnant in this scaffolding protein.

Conclusions

While the NMR structure demonstrates that the CASKIN2 SH3 domain is folded, its cleft has suffered two substitutions that prevent it from binding typical polyproline ligands. This observation led us to additionally survey and describe other SH3 domains in the Protein Data Bank that may have similarly lost their ability to promote protein-protein interactions.

     

Crystal structure of the SH3 domain of betaPIX in complex with a high affinity peptide from PAK2

The p21-activated kinases (PAKs) are important effector proteins of the small GTPases Cdc42 and Rac and control cytoskeletal rearrangements and cell proliferation. The direct interaction of PAKs with guanine nucleotide exchange factors from the PIX/Cool family, which is responsible for the localization of PAK kinases to focal complexes in the cell, is mediated by a 24-residue peptide segment in PAKs and an N-terminal src homology 3 (SH3) domain in PIX/Cool. The SH3-binding segment of PAK contains the atypical consensus-binding motif PxxxPR, which is required for unusually high affinity binding. In order to understand the structural basis for the high affinity and specificity of the PIX-PAK interaction, we solved crystal structures for the N-terminal SH3 domain of betaPIX and for the complex of the atypical binding segment of PAK2 with the N-terminal SH3 domain of betaPIX at 0.92 A and 1.3A resolution, respectively. The asymmetric unit of the crystal contains two SH3 domains and two peptide ligands. The bound peptide adopts a conformation that allows for intimate contacts with three grooves on the surface of the SH3 domain that lie between the n-Src and RT-loops. Most notably, the arginine residue of the PxxxPR motif forms a salt-bridge and is tightly coordinated by a number of residues in the SH3 domain. This arginine-specific interaction appears to be the key determinant for the high affinity binding of PAK peptides. Furthermore, C-terminal residues of the peptide engage in additional interactions with the surface of the RT-loop, which significantly increases binding specificity. Compared to a recent NMR structure of a similar complex, our crystal structure reveals an alternate binding mode. Finally, we compare our crystal structure with the recently published betaPIX/Cbl-b complex structure, and suggest the existence of a molecular switch.