SRChing for the substrates of Src.

By the mid 1980's, it was clear that the transforming activity of oncogenic Src was linked to the activity of its tyrosine kinase domain and attention turned to identifying substrates, the putative next level of control in the pathway to transformation. Among the first to recognize the potential of phosphotyrosine-specific antibodies, Parsons and colleagues launched a risky shotgun-based approach that led ultimately to the cDNA cloning and functional characterization of many of today's best-known Src substrates (for example, p85-Cortactin, p110-AFAP1, p130Cas, p125FAK and p120-catenin). Two decades and over 6000 citations later, the original goals of the project may be seen as secondary to the enormous impact of these protein substrates in many areas of biology. At the request of the editors, this review is not restricted to the current status of the substrates, but reflects also on the anatomy of the project itself and some of the challenges and decisions encountered along the way.

Ableson kinases negatively regulate invadopodia function and invasion in head and neck squamous cell carcinoma by inhibiting an HB-EGF autocrine loop.

Head and neck squamous cell carcinoma (HNSCC) has a proclivity for locoregional invasion. HNSCC mediates invasion in part through invadopodia-based proteolysis of the extracellular matrix (ECM). Activation of Src, Erk1/2, Abl and Arg downstream of epidermal growth factor receptor (EGFR) modulates invadopodia activity through phosphorylation of the actin regulatory protein cortactin. In MDA-MB-231 breast cancer cells, Abl and Arg function downstream of Src to phosphorylate cortactin, promoting invadopodia ECM degradation activity and thus assigning a pro-invasive role for Ableson kinases. We report that Abl kinases have an opposite, negative regulatory role in HNSCC where they suppress invadopodia and tumor invasion. Impairment of Abl expression or Abl kinase activity with imatinib mesylate enhanced HNSCC matrix degradation and 3D collagen invasion, functions that were impaired in MDA-MB-231. HNSCC lines with elevated EGFR and Src activation did not contain increased Abl or Arg kinase activity, suggesting that Src could bypass Abl/Arg to phosphorylate cortactin and promote invadopodia ECM degradation. Src-transformed Abl(-/-)/Arg(-/-) fibroblasts produced ECM degrading invadopodia containing pY421 cortactin, indicating that Abl/Arg are dispensable for invadopodia function in this system. Imatinib-treated HNSCC cells had increased EGFR, Erk1/2 and Src activation, enhancing cortactin pY421 and pS405/418 required for invadopodia function. Imatinib stimulated shedding of the EGFR ligand heparin-binding EGF-like growth factor (HB-EGF) from HNSCC cells, where soluble HB-EGF enhanced invadopodia ECM degradation in HNSCC but not in MDA-MB-231. HNSCC cells treated with inhibitors of the EGFR-invadopodia pathway indicated that EGFR and Src are required for invadopodia function. Collectively, our results indicate that Abl kinases negatively regulate HNSCC invasive processes through suppression of an HB-EGF autocrine loop responsible for activating a EGFR-Src-cortactin cascade, in contrast to the invasion promoting functions of Abl kinases in breast and other cancer types. Our results provide mechanistic support for recent failed HNSCC clinical trials utilizing imatinib.

Cortactin: coupling membrane dynamics to cortical actin assembly.

Exposure of cells to a variety of external signals causes rapid changes in plasma membrane morphology. Plasma membrane dynamics, including membrane ruffle and microspike formation, fusion or fission of intracellular vesicles, and the spatial organization of transmembrane proteins, is directly controlled by the dynamic reorganization of the underlying actin cytoskeleton. Two members of the Rho family of small GTPases, Cdc42 and Rac, have been well established as mediators of extracellular signaling events that impact cortical actin organization. Actin-based signaling through Cdc42 and Rac ultimately results in activation of the actin-related protein (Arp) 2/3 complex, which promotes the formation of branched actin networks. In addition, the activity of both receptor and non-receptor protein tyrosine kinases along with numerous actin binding proteins works in concert with Arp2/3-mediated actin polymerization in regulating the formation of dynamic cortical actin-associated structures. In this review we discuss the structure and role of the cortical actin binding protein cortactin in Rho GTPase and tyrosine kinase signaling events, with the emphasis on the roles cortactin plays in tyrosine phosphorylation-based signal transduction, regulating cortical actin assembly, transmembrane receptor organization and membrane dynamics. We also consider how aberrant regulation of cortactin levels contributes to tumor cell invasion and metastasis.

Dynamic molecular modeling of pathogenic mutations in the spectrin self-association domain.

Disruption of spectrin self-association underlies many inherited hemolytic disorders. Using dynamic modeling and energy minimization, the 3-dimensional structure of the self-association domain has been estimated in human erythrocyte spectrin and the structural consequences of 17 elliptogenic mutations determined. The predicted structure of the normal self-association domain was remarkably similar to the crystal structure of the Drosophila alpha-spectrin 14th repeat unit, despite replacement in the human sequence of over 70% of the amino acids relative to fly spectrin, including 2 prolines in the human sequence that appear in helical regions of the fly structure. The predicted structure placed all hydrophilic residues at the surface and identified 4 salt bridges, 9 hydrophobic interactions, and 4 H-bonds that stabilize the native self-association unit. Remarkably, every pathologic point mutation, including seemingly conservative substitutions such as G for A, A for V, or K for R (single-letter amino acid codes), led to conformational rearrangements in the predicted structure. The degree of structural disruption, as measured by root-mean-square deviation of the predicted backbone structure from the Drosophila structure, correlated strongly with the severity of clinical disease associated with each mutation. This approach thus enables an accurate prediction, from the primary sequence, of the clinical consequences of specific point mutations in spectrin. The 3-dimensional structure of the self-association domain derived here is likely to be accurate. It provides a powerful heuristic model for understanding how point mutations disrupt cytoskeletal function in a variety of hemolytic disorders.

Cortactin promotes and stabilizes Arp2/3-induced actin filament network formation.

Cortactin is a c-src substrate associated with sites of dynamic actin assembly at the leading edge of migrating cells. We previously showed that cortactin binds to Arp2/3 complex, the essential molecular machine for nucleating actin filament assembly. In this study, we demonstrate that cortactin activates Arp2/3 complex based on direct visualization of filament networks and pyrene actin assays. Strikingly, cortactin potently inhibited the debranching of filament networks. When cortactin was added in combination with the active VCA fragment of N-WASp, they synergistically enhanced Arp2/3-induced actin filament branching. The N-terminal acidic and F-actin binding domains of cortactin were both necessary to activate Arp2/3 complex. These results support a model in which cortactin modulates actin filament dendritic nucleation by two mechanisms, (1) direct activation of Arp2/3 complex and (2) stabilization of newly generated filament branch points. By these mechanisms, cortactin may promote the formation and stabilization of the actin network that drives protrusion at the leading edge of migrating cells.

Focal adhesion kinase: a regulator of focal adhesion dynamics and cell movement.

Engagement of integrin receptors with extracellular ligands gives rise to the formation of complex multiprotein structures that link the ECM to the cytoplasmic actin cytoskeleton. These adhesive complexes are dynamic, often heterogeneous structures, varying in size and organization. In motile cells, sites of adhesion within filopodia and lamellipodia are relatively small and transient and are referred to as 'focal complexes,' whereas adhesions underlying the body of the cell and localized to the ends of actin stress fibers are referred to as 'focal adhesions'. Signal transduction through focal complexes and focal adhesions has been implicated in the regulation of a number of key cellular processes, including growth factor induced mitogenic signals, cell survival and cell locomotion. The formation and remodeling of focal contacts is a dynamic process under the regulation of protein tyrosine kinases and small GTPases of the Rho family. In this review, we consider the role of the focal complex associated protein tyrosine kinase, Focal Adhesion Kinase (FAK), in the regulation of cell movement with the emphasis on how FAK regulates the flow of signals from the ECM to the actin cytoskeleton.

Cortactin localization to sites of actin assembly in lamellipodia requires interactions with F-actin and the Arp2/3 complex.

Cortactin is an actin-binding protein that is enriched within the lamellipodia of motile cells and in neuronal growth cones. Here, we report that cortactin is localized with the actin-related protein (Arp) 2/3 complex at sites of actin polymerization within the lamellipodia. Two distinct sequence motifs of cortactin contribute to its interaction with the cortical actin network: the fourth of six tandem repeats and the amino-terminal acidic region (NTA). Cortactin variants lacking either the fourth tandem repeat or the NTA failed to localize at the cell periphery. Tandem repeat four was necessary for cortactin to stably bind F-actin in vitro. The NTA region interacts directly with the Arp2/3 complex based on affinity chromatography, immunoprecipitation assays, and binding assays using purified components. Cortactin variants containing the NTA region were inefficient at promoting Arp2/3 actin nucleation activity. These data provide strong evidence that cortactin is specifically localized to sites of dynamic cortical actin assembly via simultaneous interaction with F-actin and the Arp2/3 complex. Cortactin interacts via its Src homology 3 (SH3) domain with ZO-1 and the SHANK family of postsynaptic density 95/dlg/ZO-1 homology (PDZ) domain-containing proteins, suggesting that cortactin contributes to the spatial organization of sites of actin polymerization coupled to selected cell surface transmembrane receptor complexes.

Regulation of c-SRC activity and function by the adapter protein CAS.

SRC family kinases play essential roles in a variety of cellular functions, including proliferation, survival, differentiation, and apoptosis. The activities of these kinases are regulated by intramolecular interactions and by heterologous binding partners that modulate the transition between active and inactive structural conformations. p130(CAS) (CAS) binds directly to both the SH2 and SH3 domains of c-SRC and therefore has the potential to structurally alter and activate this kinase. In this report, we demonstrate that overexpression of full-length CAS in COS-1 cells induces c-SRC-dependent tyrosine phosphorylation of multiple endogenous cellular proteins. A carboxy-terminal fragment of CAS (CAS-CT), which contains the c-SRC binding site, was sufficient to induce c-SRC-dependent protein tyrosine kinase activity, as measured by tyrosine phosphorylation of cortactin, paxillin, and, to a lesser extent, focal adhesion kinase. A single amino acid substitution located in the binding site for the SRC SH3 domain of CAS-CT disrupted CAS-CT's interaction with c-SRC and inhibited its ability to induce tyrosine phosphorylation of cortactin and paxillin. Murine C3H10T1/2 fibroblasts that expressed elevated levels of tyrosine phosphorylated CAS and c-SRC-CAS complexes exhibited an enhanced ability to form colonies in soft agar and to proliferate in the absence of serum or growth factors. CAS-CT fully substituted for CAS in mediating growth in soft agar but was less effective in promoting serum-independent growth. These data suggest that CAS plays an important role in regulating specific signaling pathways governing cell growth and/or survival, in part through its ability to interact with and modulate the activity of c-SRC.

Identification of a novel cortactin SH3 domain-binding protein and its localization to growth cones of cultured neurons.

Cortactin is an actin-binding protein that contains several potential signaling motifs including a Src homology 3 (SH3) domain at the distal C terminus. Translocation of cortactin to specific cortical actin structures and hyperphosphorylation of cortactin on tyrosine have been associated with the cortical cytoskeleton reorganization induced by a variety of cellular stimuli. The function of cortactin in these processes is largely unknown in part due to the lack of information about cellular binding partners for cortactin. Here we report the identification of a novel cortactin-binding protein of approximately 180 kDa by yeast two-hybrid interaction screening. The interaction of cortactin with this 180-kDa protein was confirmed by both in vitro and in vivo methods, and the SH3 domain of cortactin was found to direct this interaction. Since this protein represents the first reported natural ligand for the cortactin SH3 domain, we designated it CortBP1 for cortactin-binding protein 1. CortBP1 contains two recognizable sequence motifs within its C-terminal region, including a consensus sequence for cortactin SH3 domain-binding peptides and a sterile alpha motif. Northern and Western blot analysis indicated that CortBP1 is expressed predominately in brain tissue. Immunofluorescence studies revealed colocalization of CortBP1 with cortactin and cortical actin filaments in lamellipodia and membrane ruffles in fibroblasts expressing CortBP1. Colocalization of endogenous CortBP1 and cortactin was also observed in growth cones of developing hippocampal neurons, implicating CortBP1 and cortactin in cytoskeleton reorganization during neurite outgrowth.

Translocation of cortactin to the cell periphery is mediated by the small GTPase Rac1.

Small GTPases of the Rho family regulate signaling pathways that control actin cytoskeletal structures. In Swiss 3T3 cells, RhoA activation leads to stress fiber and focal adhesion formation, Rac1 to lamellipoda and membrane ruffles, and Cdc42 to microspikes and filopodia. Several downstream molecules mediating these effects have been recently identified. In this report we provide evidence that the intracellular localization of the actin binding protein cortactin, a Src kinase substrate, is regulated by the activation of Rac1. Cortactin redistributes from the cytoplasm into membrane ruffles as a result of growth factor-induced Rac1 activation, and this translocation is blocked by expression of dominant negative Rac1N17. Expression of constitutively active Rac1L61 evoked the translocation of cortactin from cytoplasmic pools into peripheral membrane ruffles. Expression of mutant forms of the serine/threonine kinase PAK1, a downstream effector of Rac1 and Cdc42 recently demonstrated to trigger cortical actin polymerization and membrane ruffling, also led to the translocation of cortactin to the cell cortex, although this was effectively blocked by coexpression of Rac1N17. Collectively these data provide evidence for cortactin as a putative target of Rac1-induced signal transduction events involved in membrane ruffling and lamellipodia formation.

Mutation of a highly conserved residue of betaI spectrin associated with fatal and near-fatal neonatal hemolytic anemia.

We studied an infant with severe nonimmune hemolytic anemia and hydrops fetalis at birth. His neonatal course was marked by ongoing hemolysis of undetermined etiology requiring repeated erythrocyte transfusions. He has remained transfusion-dependent for more than 2 yr. A previous sibling born with hemolytic anemia and hydrops fetalis died on the second day of life. Peripheral blood smears from the parents revealed rare elliptocytes. Examination of their erythrocyte membranes revealed abnormal mechanical stability as well as structural and functional abnormalities in spectrin. Genetic studies revealed that the proband and his deceased sister were homozygous for a mutation of betaIsigma1 spectrin, L2025R, in a region of spectrin that is critical for normal function. The importance of leucine in this position of the proposed triple helical model of spectrin repeats is highlighted by its evolutionary conservation in all beta spectrins from Drosophila to humans. Molecular modeling demonstrated the disruption of hydrophobic interactions in the interior of the triple helix critical for spectrin function caused by the replacement of the hydrophobic, uncharged leucine by a hydrophilic, positively charged arginine. This mutation must also be expressed in the betaIsigma2 spectrin found in muscle, yet pathologic and immunohistochemical examination of skeletal muscle from the deceased sibling was unremarkable.

The lethal hemolytic mutation in beta I sigma 2 spectrin Providence yields a null phenotype in neonatal skeletal muscle.

Point mutations in beta I sigma 1 spectrin that impair the self-association of spectrin alpha beta heterodimers cause mild to severe hemolytic disease and erythrocyte shape abnormalities. Most such mutations act in a dominant negative fashion. One mutation that is particularly devastating is found in beta spectrin Providence. The Providence mutation replaces serine2019 with proline. Heterozygotes display microcytic and fragile erythrocytes; homozygotes die in the neonatal period. It has recently been determined that an alternative transcript of the same beta I sigma 1 spectrin gene expressed in erythroid lineage cells is the major spectrin in skeletal and cardiac muscle and in some neurons. Because the site of the Providence mutation is common to both beta I sigma 1 and beta I sigma 2 spectrin, defective protein must also be expressed in these tissues. Yet the impact of this or any other beta I spectrin mutation outside of the red cell is unexplored. To address this question with respect to skeletal muscle, we have examined the effects of the Providence mutation in cultured muscle cells, after adoptive gene transfer to adult mice, and in two infants homozygous for spectrin Providence. Transfection of the FLAG epitope tagged wild-type beta I sigma 2 or Providence beta I sigma 2 cDNA constructs into C2C12 myoblasts demonstrated by sedimentation velocity analysis that spectrin beta I sigma 2 Providence formed alpha II/-beta I sigma 2 heterodimers in muscle cells but not heterotetramers. Correspondingly, wild-type beta I sigma 2 spectrin formed both alpha II/beta I sigma 1 dimers and heterotetramers, although the proportion of dimers was surprisingly high, which suggested some limitation on self-association in the muscle environment. After adoptive gene transfer into adult mouse skeletal muscle in vivo, both the wild-type and mutant beta I sigma 2 spectrins assembled into a subsarcolemmal complex in a pattern indistinguishable from the native spectrin skeleton. Skeletal muscle taken at autopsy from two infants homozygous for spectrin Providence was normal histologically, as was the intracellular distribution of beta I sigma 2 spectrin as measured by immunoperoxidase staining. These patients also revealed no clinical evidence of myopathy or muscle wasting. It is unknown if they would have experienced dystrophic or myopathic changes if they had lived longer, although we believe that this is unlikely based on the absence of clinical myopathies in patients with other (albeit less severe) beta I spectrin self-association defects. Collectively, these observations indicate that the spectrin mutations that impact tetramer and oligomer formation, even those with a severe hemolytic phenotype, do not impact skeletal muscle function primarily because skeletal muscle does not use the oligomerizing feature of the spectrin skeleton to the same degree as erythrocytes.

Recurrent fatal hydrops fetalis associated with a nucleotide substitution in the erythrocyte beta-spectrin gene.

We studied a kindred in which four third-trimester fetal losses occurred, associated with severe Coombs-negative hemolytic anemia and hydrops fetalis. Postmortem examination of two infants revealed extensive extramedullary erythropoiesis. Studies of erythrocytes and erythrocyte membranes from the parents revealed abnormal erythrocyte membrane mechanical stability as well as structural and functional abnormalities in spectrin, the principal structural protein of the erythrocyte membrane. Genetic studies identified a point mutation of the beta-spectrin gene, S2019P, in a region of beta spectrin that is critical for normal spectrin function. Both parents and two living children were heterozygous for this mutation; three infants dying of hydrops fetalis were homozygous for this mutation. In an in vitro assay using recombinant peptides, the mutant beta-spectrin peptide demonstrated a significant abnormality in its ability to interact with alpha spectrin. This is the first description of a molecular defect of the erythrocyte membrane associated with hydrops fetalis.

Beta II-spectrin (fodrin) and beta I epsilon 2-spectrin (muscle) contain NH2- and COOH-terminal membrane association domains (MAD1 and MAD2).

Central to spectrin's function is its association with the plasma membrane. The linking proteins ankyrin and protein 4.1 partly mediate this association, and their interactions with spectrin are well understood. Both beta I (erythrocyte) and beta II (fodrin, beta G) spectrin also associate with unknown protein receptors in crude membrane preparations by ankyrin and protein 4.1 independent mechanisms. As a first step to understanding this interaction, kinetic and equilibrium assays have been used to monitor which regions of beta I and beta II spectrin inhibit the binding of purified 125I-labeled bovine brain spectrin to demyelinated and NaOH-stripped bovine brain membranes. A series of 19 recombinant proteins spanning the entire sequence of beta II spectrin, including an alternatively spliced NH2-terminal isoform (beta II epsilon 2 spectrin), were prepared as glutathione S-transferase fusion proteins. Also prepared were peptides representing the alternatively spliced COOH-terminal domain found in beta I epsilon 2 spectrin ("muscle spectrin"). Two distinct sequence motifs inhibited the binding of native brain spectrin. Membrane association domain 1 (MAD1) was represented in all fusion peptides that included spectrin repeat 1. These peptides slowed the kinetics of brain spectrin binding and inhibited up to 46% of the maximal binding under the conditions of these assays (apparent Ki < or = 0.2 microM). Peptides representative of repeats 2-17 of beta II spectrin were devoid of inhibitory activity. The second membrane association domain (MAD2) was identified in penultimate COOH-terminal sequences (domain III) of both beta II and beta I epsilon 2 spectrin. These sequences were absent in beta I epsilon 1 (erythrocyte) spectrin. MAD2 competitively inhibited over 80% of brain spectrin binding in these assays, with an apparent Ki < or = 0.1 microM. Direct binding studies confirmed that both MAD1 and MAD2 peptides associated with membranes with affinities comparable to their inhibition constants. Sequence comparisons suggest that MAD1 is created by the insertion of two non-homologous sequence motifs into repeat 1, extending it from 106 to 122 amino acids. Similarly, MAD2 encompasses a putative site of beta gamma-heterotrimeric G-protein binding called the pleckstrin homology domain, and MAD2 may in fact be the pleckstrin homology domain although this has not been rigorously proven. Collectively these studies identify two novel functional motifs in spectrin that mediate ankyrin independent association with membranes. We hypothesize that these motifs and their still to be discovered ligands play a primary role in the nascent assembly and stabilization of an ordered and polarized spectrin skeleton.

A partial structural repeat forms the heterodimer self-association site of all beta-spectrins.

The self-polymerization of alpha beta-spectrin heterodimers to form tetramers and higher oligomers is central to its role as a membrane stabilizer and organizer. Mutations near the amino terminus of alpha I sigma 1-spectrin or the COOH terminus of beta I sigma 1-spectrin often lead to profound impairment heterodimer polymerization and to hemolytic disease of varying severity. Previous studies using an 80-kDa univalent fragment of alpha I sigma 1-spectrin have established that the amino-terminal segment of alpha I sigma 1-spectrin mediates the association of the alpha subunit with either intact heterodimers or with isolated beta-spectrin (beta I sigma 1). However, the nature of the self-association site in beta-spectrin has remained unclear. In the present study, native beta-spectrin and recombinant beta-spectrin peptides representing COOH-terminal portions of two alternative transcripts of the gene on chromosome 2 (beta I sigma 1 or "erythrocyte" spectrin and beta I sigma 2 or "muscle" spectrin), and one transcript of the gene on chromosome 14 (beta II sigma 1 or "beta G-fodrin") have been examined for their ability to bind either intact alpha beta-spectrin or the alpha I-spectrin 80-kDa univalent fragment. Deletion of the nonhomologous beta-spectrin sequence downstream of repeat 17 (spectrin domain III) had no discernible effect on binding. Truncations proximal to codon 2085 of beta I sigma 1-spectrin demonstrated a precipitous loss of activity, accounted for by a loss of both binding affinity and capacity. Further truncations to repeat 16 (codon 1979) restored binding activity to levels approximating that of the intact molecule. Repeat 16/17 and 17/16 chimeras displayed reduced binding activity. Collectively, these data indicate that the beta-subunit self-association site is highly sensitive to conformation, involves widespread interactions within the 17th repeat unit, is largely independent of sequences in domain III, and can be recreated by the deletion of all residues distal to the COOH end (codon 1979) of the 16th and presumably other spectrin sequence repeat units. All beta-spectrins appear to use this binding motif, regardless of the nature of the nonhomologous sequence in domain III.