SH3-mediated Hck tyrosine kinase activation and fibroblast transformation by the Nef protein of HIV-1

SH3-Domain binding function of HIV-1 Nef is required for association with a PAK-related kinase

HIV-1 Nef has previously been shown to bind to Src homology-3 (SH3) domains of a subset of Src family tyrosine kinases. In addition, Nef has been reported to coprecipitate with a serine/threonine kinase activity termed NAK (for Nef-associated kinase). The identity of NAK remains uncertain, but it has been suggested to represent a novel member of the p21-activated kinase (PAK) family. We report here that NAK autophosphorylation is increased not only by an activated form of the p21-family GTPase cdc42 but also by a plasma membrane-targeted fragment of the adapter protein Nck, thus providing further evidence that NAK is related to PAKs. A detailed structure-based mutational analysis of Nef revealed that all amino acid changes that inhibited the Nef/Hck-SH3 interaction, as measured by surface-plasmon resonance, also abolished coprecipitation of NAK. As PAK family proteins do not contain SH3 domains, these observations are best explained by a protein complex in which Nef, NAK, and an SH3-protein all contact each other. In addition, a number of conserved amino acids in Nef that are not involved in SH3 binding were also found to be crucial for association with NAK. Molecular modeling suggests that these residues are involved in formation of an adjacent binding surface for NAK or another critical component of the NAK/Nef complex.

RT loop flexibility enhances the specificity of Src family SH3 domains for HIV-1 Nef

Understanding the issue of specificity imposed in the interactions of SH3 domains has largely been addressed in studies investigating the interaction of proline-rich amino acid sequences derived from potential ligands for these domains. Although the interaction with this motif forms an essential platform in the binding of SH3 domains, in many cases little specificity is observed and the difference in affinity for so-called specific and nonspecific proline-rich sequences is not great. Furthermore, the binding interface between an SH3 domain and a protein ligand appears to encompass more interactions than are represented by that involving the proline-rich motif. Here we investigate the issue of specificity from the opposite point of view; namely, how does a ligand recognize different SH3 domains? We present the crystal structure of the unbound SH3 domain from hemopoietic cell kinase (Hck) which is a member of the Src family of tyrosine kinases. This structure reveals that, unlike the structures of other Src kinase SH3 domains, the RT loop region is highly mobile and lacks a network of hydrogen bonds that is elsewhere apparent. The RT loop has been shown to form a major part of the binding interface between SH3 domains and HIV-1 Nef. Thermodynamic data, derived from isothermal titration calorimetry, for the binding of Hck SH3 to HIV-1 Nef show that the binding of Hck (KD = 1.5 microM) is approximately an order of magnitude tighter than those of other Src family kinases that were investigated (Fyn, Lck, and Src). This increase in affinity is attributed to, among other effects, the inherent flexibility in the RT loop which does not require breaking the network of hydrogen bonds to adopt the conformation required for binding.

Structural similarity of two T cell signaling regulators suggests a conserved and interactive mechanism of immunosuppression

A primary structural element is identified which is present in the Nef protein of immunodeficiency viruses and in the cytoplasmic domain of a regulatory T cell protein, CTLA-4. In both proteins, conserved residues that lie within this element have been shown to be important for the regulation of cellular signaling and endocytic trafficking. The structural similarity identified suggests conserved and, possibly, interactive mechanisms for Nef- and CTLA-4-dependent modulation of T cell function.

Crystal structure of the abl-SH3 domain complexed with a designed high-affinity peptide ligand: implications for SH3-ligand interactions

The Abl-SH3 domain is implicated in negative regulation of the Abl kinase by mediating protein-protein interactions. High-affinity SH3 ligands could compete for these interactions and specifically activate the Abl kinase, providing control and a better understanding of the molecular interactions that underlie diseases where SH3 domains are involved. The p41 peptide (APSYSPPPPP) is a member of a group of peptide ligands designed to bind specifically the Abl-SH3 domain. It binds to Abl-SH3 with a Kd of 1.5 microM, whereas its affinity for the Fyn-SH3 domain is 273 microM. We have determined the crystal structure of the Abl-SH3 domain in complex with the high-affinity peptide ligand p41 at 1.6 A resolution. In the crystal structure, this peptide adopts a polyproline type II helix conformation through residue 5 to 10, and it binds in type I orientation to the Abl-SH3 domain. The tyrosine side-chain in position 4 of the peptide is hydrogen bonded to two residues in the RT-loop of the Abl-SH3 domain. The tight fit of this side-chain into the RT-loop pocket is enhanced by conformational adjustment of the main chain at position 5. The SH3 ligand peptides can be divided into two distinct parts. The N-terminal part binds to the SH3 domain in the region formed by the valley between the nSrc and RT-loops. It determines the specificity for different SH3 domains. The C-terminal part adopts a polyproline type II helix conformation. This binds to a well-conserved hydrophobic surface of the SH3 domain. Analysis of two "half"-peptides, corresponding to these ligand parts, shows that both are essential components for strong binding to the SH3 domains. The crystal structure of the Abl-SH3:p41 complex explains the high affinity and specificity of the p41 peptide towards the Abl-SH3 domain, and reveals principles that will be exploited for future design of small, high-affinity ligands to interfere efficiently with the in vivo regulation of Abl kinase activity.

The human immunodeficiency virus type 1 Nef protein binds the Src-related tyrosine kinase Lck SH2 domain through a novel phosphotyrosine independent mechanism

Primate lentiviruses encode for an unique nef gene with an essential function in both viral replication and pathogenicity in the host. The molecular basis for this function remains however poorly defined. Several Nef-binding cellular proteins are thought to be instrumental in its function. Indeed, Nef contains a proline-rich motif implicated in the binding to the Src-like tyrosine kinase Hck and also to a Ser/Thr kinase of molecular weight 62 kDa. The disruption of this motif affects the binding to both these kinases as well as viral replication. Whereas Hck is expressed in the myeloid lineage and hence may account for the nef function in infected monocytes, we and others have reported previously that Nef also interacts with the T-lymphocyte Src-kinase Lck, leading to specific cell signaling impairment. This interaction occurs through the binding of Nef to both Lck SH2 and SH3 domains. Both the proline motif and phosphorylation of Nef on tyrosine residue were proposed to account for these interactions. Here, we investigate the mechanism of Lck SH2 binding by HIV-1 Nef. Using recombinant fusion proteins to precipitate lysates, we show that although SH2 binding is dependent on phosphorylation events, it occurs in a tyrosine independent manner because it requires neither tyrosine residues in Nef nor the phosphotyrosine binding pocket from the Lck SH2 domain, hence suggesting a role for a phosphoserine or a phosphothreonine residue. Further, we show that Hck SH2 does not interact with Nef, indicating that Hck SH3 binding is sufficient for Nef binding, whereas Lck SH2 cooperate together with SH3 to allow Nef binding to a level similar to Hck SH3. Together, our results establish different mechanisms for Hck and Lck binding by HIV-1 Nef protein, and identify a novel mechanism for Src-like tyrosine kinase targeting by a viral protein.

Fibroblast transformation by Fps/Fes tyrosine kinases requires Ras, Rac, and Cdc42 and induces extracellular signal-regulated and c-Jun N-terminal kinase activation

The small GTP-binding proteins Ras, Rac, and Cdc42 link protein-tyrosine kinases with mitogen-activated protein kinase (MAPK) signaling cascades. Ras controls the activation of extracellular signal-regulated kinases (ERKs), while Rac and Cdc42 regulate the c-Jun N-terminal kinases (JNKs). In this study, we investigated whether small G protein/MAPK cascades contribute to signal transduction by transforming variants of c-Fes, a nonreceptor tyrosine kinase implicated in cytokine signaling and myeloid differentiation. First, we investigated the effects of dominant-negative small G proteins on Rat-2 fibroblast transformation by a retroviral homolog of c-Fes (v-Fps) and by c-Fes activated via N-terminal addition of the v-Src myristylation signal (Myr-Fes). We observed that dominant-negative Ras, Rac, and Cdc42 inhibited v-Fps- and Myr-Fes-induced growth of Rat-2 cells in soft agar, indicating that activation of these small GTP-binding proteins is required for fibroblast transformation by Fps/Fes tyrosine kinases. To determine whether MAPK pathways are activated downstream of these small G proteins, we measured ERK and JNK activity in the v-Fps- and Myr-Fes-transformed Rat-2 cells. Both ERK and JNK activities were elevated in the transformed cells, suggesting that these pathways are involved in cellular transformation. Dominant-negative mutants of Ras (but not Rac or Cdc42) specifically inhibited ERK activation by v-Fps and Myr-Fes, demonstrating that ERK activation occurs exclusively downstream of Ras. All three dominant-negative small G proteins inhibited JNK activation by v-Fps and Myr-Fes, indicating that JNK activation by these tyrosine kinases requires both Ras and Rho family GTPases. These data demonstrate that multiple small G protein/MAPK cascades are involved in downstream signal transduction by Fps/Fes tyrosine kinases.

Self-association and backbone dynamics of the hck SH2 domain in the free and phosphopeptide-complexed forms

Decreased dynamic motion in the peptide backbone of proteins may accompany ligand binding and influence the thermodynamic and kinetic stability of the resulting complexes. We have investigated the diffusional behavior and backbone dynamics of the free and phosphopeptide (EPQpYEEIPIYL) complexed Hck SH2 domain using NMR spectroscopy. Both the free domain and its phosphopeptide complex self-associate at higher protein concentrations. Diffusional measurements and surface analysis indicate that charged side-chain groups are probably responsible for self-association. Higher order aggregation, such as trimer and tetramer, also occurs at elevated protein concentrations. Dynamic motion in the peptide backbone of Hck SH2 was determined from 15N relaxation data fit using extended model-free parameters. The rotational correlation time (taum) for uncomplexed Hck SH2 was 6.8 ns while taum for peptide-bound Hck SH2 was 7.6 ns. Generalized order parameters (S2) increased for most residues upon binding of the phosphopeptide, consistent with peptide binding restricting motion of the NH bond vectors on the picosecond time scale. These studies suggest that complexation increases internal order in Hck SH2 and that internal dynamic motions contribute to the activation of Src-family kinases in vivo.

Solution structure of the human Hck SH3 domain and identification of its ligand binding site

SH3 domains are protein binding domains that occur widely among signal transduction proteins. Here, we present the NMR-determined solution structure of the SH3 domain from the cytoplasmic protein tyrosine kinase, Hck. Hck is involved in a number of cell signal transduction pathways, frequently in pathways associated with immune response. SH3 domains bind proteins via a left-handed polyproline type II helix on the target protein. We have assessed the structural impact of binding to a ligand through addition of a peptide corresponding to a proline-rich region of a Hck target, the GTPase activating protein of the Ras pathway. Ligand binding effects small structural changes and stabilizes the SH3 domain structure. Also, we have compared the solution structure of the Hck SH3 domain to the crystal structure of Hck, in which the SH3 domain exhibits an intramolecular binding to an interdomain linker region. These structures are interpreted as the apo- and holo- forms of the Hck SH3 domain.

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.

Structures of Src-family tyrosine kinases

The crystal structures of three Src-family tyrosine kinases have been determined recently. The structure of the catalytic domain of Lck has been determined in the active autophosphorylated state. The structures of larger constructs of c-Src and Hck, containing the SH3, SH2 and catalytic domains, as well as a C-terminal regulatory tail, have been determined in the down-regulated state, phosphorylated in the C-terminal tail. A comparison of these structures leads to an unanticipated mechanism for the regulation of catalytic activity by cooperative interactions between the SH2, SH3 and catalytic domains.

Identification and localization of slow, natural, cooperative unfolding in the hematopoietic cell kinase SH3 domain by amide hydrogen exchange and mass spectrometry

Protein unfolding on a fast time scale (milliseconds-minutes) has been widely reported, but slower unfolding events (10 min-hours) have received less attention. Amide hydrogen exchange (HX) and mass spectrometry (MS) were used to investigate the unfolding dynamics of the hematopoietic cell kinase (Hck) SH3 domain. Analysis of mass spectra after deuterium exchange into intact Hck SH3 indicates a cooperative unfolding event involving 24-61% of the domain and occurring with a half-life of approximately 20 min under physiological conditions. To identify the unfolding region, SH3 was incubated in D2O and proteolytically fragmented into peptides that were analyzed by mass spectrometry. Correlation of HX rates and isotope patterns reveals cooperative unfolding in several regions, including the C-terminal half of the RT-loop and a beta-sheet flanking the binding site. Binding of a prolyl-rich segment from the HIV Nef protein slows unfolding by a factor of 3. Further analysis yields a KD of 25 microM for the Nef peptide. These results demonstrate that an inherent flexibility in the SH3 domain may assist interconversion of the closed, intramolecularly ligated state and the open, active state of Src family kinases. Furthermore, this type of previously undetectable, slow unfolding process may provide the basis for new mechanisms in which kinetics of local unfolding combines with thermodynamics to regulate enzymatic activity. The combination of hydrogen exchange and mass spectrometry appears to be the only general method capable of examining these slow unfolding processes.