Focal contacts: transmembrane links between the extracellular matrix and the cytoskeleton

The sites of tightest adhesion that form between cells and substrate surfaces in tissue culture are termed focal contacts. The external faces of focal contacts include specific receptors, belonging to the integrin family of proteins, for fibronectin and vitronectin, two common components of extracellular matrices. On the internal (cytoplasmic) side of focal contacts, several proteins, including talin and vinculin, mediate interactions with the actin filament bundles of the cytoskeleton. The changes that occur in focal contacts as a result of viral transformation are discussed.     

The adhesion plaque protein, talin, is phosphorylated in vivo in chicken embryo fibroblasts exposed to a tumor-promoting phorbol ester.

Talin is a high molecular weight phosphoprotein that is localized at adhesion plaques. We have found that talin phosphorylation increases 3.0-fold upon exposure of chicken embryo fibroblasts to the tumor-promoting phorbol ester, phorbol 12-myristate 13-acetate. Talin isolated from tumor promoter-treated cells is phosphorylated on serine and threonine residues. Vinculin, a 130 kDa talin-binding protein, also exhibits increased phosphorylation in vivo in response to tumor promoter, but to a lesser degree than does talin. Because tumor-promoting phorbol esters augment protein kinase C activity, we have compared the ability of purified protein kinase C to phosphorylate talin and vinculin in vitro. Both talin and vinculin were found to be substrates for protein kinase C; however, talin was phosphorylated to a greater extent than was vinculin. Cleavage of protein kinase C-phosphorylated talin by the calcium-dependent protease (Type II) revealed that while both the resulting 190-200 and 46 kDa proteolytic peptides were phosphorylated, the majority of label was contained within the 46-kDa fragment. Although incubation of chicken embryo fibroblasts with tumor-promoting phorbol ester induces a dramatic increase in talin phosphorylation, we detected no change in the organization of stress fibers and focal contacts in these cells. Exposure of the cells to tumor promoter did, however, result in a loss of actin and talin-rich cell surface elaborations that resemble focal contact precursor structures.     

Preliminary characterization of cell surface-extracellular matrix linkage complexes in cultured retinal pigmented epithelial cells

In this report, we describe the relative distribution of vinculin, talin, and fibronectin in cultured retinal pigmented epithelial cells from chick embryo eyes. We show that in these cells vinculin is present in both focal cell-substratum and cell-cell contacts, whereas talin is present only in the cell-substratum contacts. When cells are double-labeled for talin and fibronectin and viewed at the substratum level, fibronectin is not detectable and talin is concentrated in plaques corresponding to focal contacts. However, when the same cells are viewed at the apical level, both talin and fibronectin are present in a fibrillar pattern. In addition to fibrils which are both talin- and fibronectin-positive, there are areas which are either talin-positive and fibronectin-negative or, vice versa, talin-negative and fibronectin-positive. These observations indicate an interesting variability in the composition of transmembrane linkages in retinal pigmented epithelial cells in vitro.     

The coordinate organization of vinculin and of actin filaments during the early stages of fibroblast spreading on a substratum

Cultured normal fibroblasts adhere to their support essentially through the focal adhesion plaques which are greatly enriched with the 130 000 dalton protein, vinculin, along with the newly described 215 000 dalton protein, talin, and at which actin bundles terminate. In order to explore a role for vinculin in the formation of the adhesion plaques and of the actin bundles, we have studied and compared the development of these two cellular structures during the spreading of trypsinized and replated chicken embryonic fibroblasts. The techniques used were double indirect immunofluorescence and interference reflection microscopy. At the earliest stage of cell spreading observed, vinculin distributes into small patches that are located along actin filaments and at the basis of the ruffling membrane. At later spreading stage, vinculin markedly redistributes into larger striations which coincide with focal contacts. Some of these vinculin striations are associated with the ends of microfilaments while the others are not. These observations would suggest that two types of focal contacts can form simultaneously in early cell spreading. Hypotheses are made concerning the role of vinculin in the formation of the adhesive cell structures in the light of these new data and of previous reports on the subject.     

Molecular heterogeneity of adherens junctions

We describe here the subcellular distributions of three junctional proteins in different adherens-type contacts. The proteins examined include vinculin, talin, and a recently described 135-kD protein (Volk, T., and B. Geiger, 1984, EMBO (Eur. Mol. Biol. Organ.) J., 10:2249-2260). Immunofluorescent localization of the three proteins indicated that while vinculin was ubiquitously present in all adherens junctions, the other two showed selective and mutually exclusive association with either cell-substrate or cell-cell adhesions. Talin was abundant in focal contacts and in dense plaques of smooth muscle, but was essentially absent from intercellular junctions such as intercalated disks or adherens junctions of lens fibers. The 135-kD protein, on the other hand, was present in the latter two loci and was apparently absent from membrane-bound plaques of gizzard or from focal contacts. Radioimmunoassay of tissue extracts and immunolabeling of cultured chick lens cells indicated that the selective presence of talin and of the 135-kD protein in different cell contacts is spatially regulated within individual cells. On the basis of these findings it was concluded that adherens junctions are molecularly heterogeneous and consist of at least two major subgroups. Contacts with noncellular substrates contain talin and vinculin but not the 135-kD protein, whereas their intercellular counterparts contain the latter two proteins and are devoid of talin. The significance of these results and their possible relationships to contact-induced regulation of cell behavior are discussed.     

Purification of a 190 kDa protein from smooth muscle: relationship to talin

Several studies of vinculin-binding proteins have described a 190 kDa protein in chicken gizzard smooth muscle which binds radioiodinated vinculin. We have purified and studied the 190 kDa protein from chicken gizzard smooth muscle. By indirect immunofluorescence, an antiserum raised against the 190 kDa protein stains adhesion plaques (focal contacts), ruffling membranes, and fibrillar streaks on the dorsal and ventral surfaces of fibroblasts. Both the binding to vinculin and the location of the protein in fibroblasts are properties shared with talin, a 215 kDa protein in smooth muscle and fibroblasts. Because antisera against talin and the 190 kDa cross-react the relationship of these two proteins has been investigated further. Upon prolonged storage at 4 degrees C, purified talin degrades into a 190 kDa fragment. A 190 kDa fragment is also generated from talin by the Staphylococcus aureus V-8 proteinase and by trypsin. Comparison of partial peptide maps of talin and the 190 kDa protein reveal that the proteins are very similar and when the 190 kDa fragment of talin is compared with the purified 190 kDa protein by partial proteolytic digestion no differences are found in the pattern of peptides generated. In addition, the amount of 190 kDa protein detected in muscle tissues excised from chick embryos can be drastically reduced if proteinase inhibitors are added to the tissue homogenates. We conclude that the purified 190 kDa dalton protein is a proteolytic fragment of talin. Although markedly reduced by proteinase inhibitors, detection of the 190 kDa protein is not completely abolished, suggesting that some talin may already be cleaved within living cells.     

Dissecting focal adhesions in cells differentially expressing calreticulin: a microscopy study

Background information. Our previous studies have shown that calreticulin, a Ca²⁺‐binding chaperone located in the endoplasmic reticulum, affects cell—substratum adhesions via the induction of vinculin and N‐cadherin. Cells overexpressing calreticulin contain more vinculin than low expressers and make abundant contacts with the substratum. However, cells that express low levels of calreticulin exhibit a weak adhesive phenotype and make few, if any, focal adhesions. To date, the identity of the types of focal adhesions made by calreticulin overexpressing and low expressing cells has not been dissected. Results. The results of the present study show that calreticulin affects fibronectin matrix assembly in L fibroblast cell lines that differentially express the protein, and that these cells also differ profoundly in focal adhesion formation. Although the calreticulin overexpressing cells generate numerous interference‐reflection‐microscopy‐dark, vinculin‐ and paxillin‐containing classical focal contacts, as well as some fibrillar adhesions, the cells expressing low levels of calreticulin generate only a few weak focal adhesions. The fibronectin receptor was found to be clustered in calreticulin overexpressing cells, but diffusely distributed over the cell surface in low expressing cells. Plating L fibroblasts on fibronectin‐coated substrata induced extensive spreading in all cell lines tested. However, although calreticulin overexpressing cells were induced to form classical vinculin‐rich focal contacts, the low calreticulin expressing cells overcame their weak adhesive phenotype by induction of many tensin‐rich fibrillar adhesions, thus compensating for the low level of vinculin in these cells. Conclusions. We propose that calreticulin affects fibronectin production and, thereby, assembly, and it indirectly influences the formation and/or stability of focal contacts and fibrillar adhesions, both of which are instrumental in matrix assembly and remodelling.     

Organization of the cytoskeleton and the focal contacts of bovine aortic endothelial cells cultured on type I and III collagen.

We investigated the organization of the cytoskeleton and the focal contacts of bovine aortic endothelial cells cultured on type I and III collagen. The influence of these collagens on cell morphology and the distribution pattern of actin, vimentin, talin, and vinculin was analyzed by light microscopy, conventional electron microscopy, immunofluorescence, and immunogold labeling after lysis-squirting. Whereas the morphology of the endothelial cells is not markedly influenced, the structure of the cytoskeleton and the focal contacts of the cells are altered by the different collagen types. Stress fibers are more distinct in cells grown on type I collagen; cells on type III collagen show a more diffuse distribution of actin molecules. Intermediate filaments seem not to be affected by the collagens. The areas of focal contacts are larger in cells on type I collagen. Additionally, the labeling pattern of talin and vinculin is denser in focal contacts of cells grown on type I collagen. These results suggest an important role of the type of collagen in mediation of the organization of the microfilament system and the adhesion structures of bovine aortic endothelial cells in culture.     

Disruption of the Talin Gene Compromises Focal Adhesion Assembly in Undifferentiated but Not Differentiated Embryonic Stem Cells

We have used gene disruption to isolate two talin (−/−) ES cell mutants that contain no intact talin. The undifferentiated cells (a) were unable to spread on gelatin or laminin and grew as rounded colonies, although they were able to spread on fibronectin (b) showed reduced adhesion to laminin, but not fibronectin (c) expressed much reduced levels of β1 integrin, although levels of α5 and αV were wild-type (d) were less polarized with increased membrane protrusions compared with a vinculin (−/−) ES cell mutant (e) were unable to assemble vinculin or paxillin-containing focal adhesions or actin stress fibers on fibronectin, whereas vinculin (−/−) ES cells were able to assemble talin-containing focal adhesions. Both talin (−/−) ES cell mutants formed embryoid bodies, but differentiation was restricted to two morphologically distinct cell types. Interestingly, these differentiated talin (−/−) ES cells were able to spread and form focal adhesion-like structures containing vinculin and paxillin on fibronectin. Moreover, the levels of the β1 integrin subunit were comparable to those in wild-type ES cells. We conclude that talin is essential for β1 integrin expression and focal adhesion assembly in undifferentiated ES cells, but that a subset of differentiated cells are talin independent for both characteristics.     

Cell/substratum adhesions in RSV-transformed rat fibroblasts

Cell/substratum adhesions have been studied in rat fibroblasts transformed by a ts-mutant of Rous sarcoma virus (LA-29) using light and electron microscopy and a variety of preparative methods including immunolabeling. Cells were studied both during the process of transformation, i.e., shifting from 39 degrees to 35 degrees C, and in a fully transformed state (passaged at 35 degrees C continuously). The typical focal contacts observed at 39 degrees C (restrictive temperature) were replaced by "point-contacts" (100-200 per cell) which were classified by immunolabeling as podosome-like adhesions containing actin, beta 1 integrin subunit, vinculin, talin, alpha-actinin, and small membrane patches containing clathrin and integrin. Tyrosine-phosphorylated proteins and pp60src were found in association with groups of small particles on the protoplasmic surface of ventral membranes by gold immunolabeling. Both types of point-contacts were visualized by electron microscopy of ultrathin sections and shadowed replicas and characterized by gold immunolabeling wherever possible. The overall composition of podosome-like adhesions is similar to focal contacts but there are differences in the three-dimensional organization of the microfilaments and in the topography of vinculin which is associated more with actin filaments than with the plasma membrane. The presence of talin and extracellular matrix receptor in podosomes together with the adhesive properties of these actin-containing structures argues against the hypothesis that pp60src affects the interaction of actin with the plasma membrane by phosphorylating the fibronectin receptor and/or other associated proteins.     

Actin-independent association of vinculin with the cytoplasmic aspect of the plasma membrane in cell-contact areas

We investigated the mode of association of vinculin with areas of contact between the termini of microfilament bundles and the cell membrane in sites of focal contact with the substrate by selective removal of actin from these areas. Opened-up substrate-attached membranes of chick fibroblasts as well as detergent-permeabilized cells were treated with fragmin from Physarum in the presence of Ca+2. This treatment removed actin filaments from the cytoplasmic faces of the membranes, along with several actin-associated proteins (alpha-actinin, tropomyosin, myosin, and filamin). Vinculin distribution was not affected by treatment. Moreover, rhodamine- or fluorescein-conjugated vinculin, when added to these preparations, became specifically associated with the focal contacts regardless of whether the latter were pretreated with fragmin or not. We conclude that the association of vinculin with focal contacts is largely actin-independent. We discuss the implications of these findings in the molecular mechanisms of microfilament membrane association in areas of cell contact.     

Expression of α1-chimaerin (rac-1 GAP) alters the cytoskeletal and adhesive properties of fibroblasts

The small GTP-binding protein rac-1, a member of the ras gene superfamily of GTPases, is thought to be a key component of a signal transduction pathway that mediates cell membrane ruffling and actin stress fiber formation induced by growth factors. rac-1 protein is regulated by the interplay of several activities:proteins that enhance GDP dissociation (GDP Dissociation Stimulator, GDS), inhibit nucleotide exchange (GDP Dissociation Inhibitor, GDI), or accelerate GTP hydrolysis (GTPase Activating Protein, GAP). We have assessed the relative contribution of the rac-1/GAP interactions to the overall activity of rac-1 by expressing α¹-chimaerin, a rac-1-specific GAP, in fibroblasts. NIH 3T3 cells were transfected with (α₁)-chimaerin-expressing cells showed rac-1 GAP activity that was regulated by phosphatidylserine and phorbol ester. The cells expressing α₁-chimaerin showed a distinct phenotype. They had altered adhesive properties as measured by their ability to bind to a fibronection-coated glass surface, suggesting that the expression of a rac-1 GAP alters the assembly of integrin receptors, actin and cytoskeletal proteins such as vinculin and talin. Direct demonstration of this phenomenon was achieved by studying the organization of actin stress fiber and formation of focal adhesions in the α₁-chimaerin expressing cells following stimulation by growth factors. Mock transfected cells, upon serum or lysophospatidic acid stimulation, organize actin as a dense array of parallel fibers running the length of the cell. This process did not take place in the cells expressing rac-1 GAP. Similarly, the formation of focal adhesions as measured by the appearance of vinculin clusters was imparied in the α₁-chimaerin expressing cells. These results demonstrate that expression of a GAP for rac-1 in fibroblasts produces profound changes in the cytoskeletal organization and suggest that GAP activity negatively regulates rac-1 function.     

Modulation of Expression and Assembly of Vinculin duringin VitroFibrillar Collagen-Induced Angiogenesis and Its Reversal

A model of collagen-inducedin vitroangiogenesis was used to investigate the modulation of expression and assembly of focal adhesion plaque-associated proteins during the process of differentiation. Human umbilical vein endothelial cells (HUVEC), first attached on an adhesive substratum (gelatin-, fibronectin-, or laminin-coated dish) or adherent collagen gel and then covered by an overlaying collagen gel, organized within 3–4 days in tube-like structures (TLS). Removing the overlaying collagen gel from fully differentiated HUVEC induced a reversion of the process and HUVEC returned to a monolayer pattern. Modulations of focal adhesion-associated proteins occurring in HUVEC during thein vitrodifferentiation process and its reversal were investigated by Western blot analysis. A significant decrease of expression of vinculin, the integrin α₂subunit, talin, α-actinin, and actin was observed in TLS whereas the amount of FVIII-related antigen did not vary as compared to control monolayer cultures. During reversal, all the reduced proteins were markedly reexpressed. Human skin fibroblasts (HSF), submitted to the same experimental conditions, did not form TLS. Most of the focal adhesion proteins in HSF were similarly modulated by an overlaying collagen gel with the exception of vinculin, which was not modified. This particular protein was therefore more thoroughly investigated. In a nondifferentiated monolayer of HUVEC, a significant proportion of vinculin was organized into a detergent-resistant juxtamembranous structure (focal adhesion plaque) which disassembled early in TLS formation and reassembled during the reversal of the process. The reduction of vinculin during TLS formation was preceded by a downregulation of its mRNA while this mRNA was upregulated during reversal of the morphotype. These results suggest that the modulations of the cytoskeletal and focal adhesion proteins and more specifically of vinculin coupled to its subcellular redistribution are critical and early events in the cascade of mechanochemical signaling duringin vitroangiogenesis induced by fibrillar collagen.     

Functional studies of the domains of talin

The protein talin has two domains of approximately 200 and 47 kD, which can be cleaved apart by a variety of proteases. To examine the function of these two structural domains of talin, we have digested purified talin with a calcium-dependent protease and separated the resulting fragments chromatographically. Both fragments were radioiodinated and used to probe Western blots of whole fibroblasts and chicken gizzard extracts. The large talin fragment bound to vinculin and metavinculin. The small fragment did not demonstrate any binding in this assay. The fragments were labeled fluorescently and microinjected into fibroblasts in tissue culture. The large talin fragment incorporated quickly into focal adhesions where it remained stable for at least 14 h. The small fragment associated with focal adhesions of fibroblasts but was also distributed diffusely in the cytoplasm and the nucleus. These experiments suggest that talin has at least two sites that contribute to its localization in focal adhesions. Intact talin microinjected into Madin-Darby bovine kidney epithelial cells localized to the focal adhesions but was excluded from the zonulae adherentes, despite the localization of vinculin to both of these sites. In contrast, the large talin fragment, when microinjected into these epithelial cells, incorporated into both focal adhesions and zonulae adherentes. The difference in localization between the large talin fragment and intact talin seems to be due to the removal of the small domain. This difference in localization suggests that talin binding sites in zonulae adherentes have limited accessibility.     

Accumulation of talin in nodes at the edge of the lamellipodium and separate incorporation into adhesion plaques at focal contacts in fibroblasts

The focal contact forms beneath F-actin-rich ribs, or cytoplasmic precursors, present in the lamellipodia of fibroblasts. The basal part of the precursor is retained at the contact as the initial adhesion plaque. We have examined the distribution of talin in the lamellipodia and adhesion plaques of chicken embryo fibroblasts relative to the process of focal contact formation. Motility of single cells was recorded with differential interference contrast or interference reflection microscopy before fixation and fluorescent staining for talin, F-actin, and vinculin. Talin is present along the extreme edge of the lamellipodium, where it is further concentrated into a series of nodes. The nodes of talin are present at the tips of both larger and finer F-actin-rich ribs and at small structural nodes at the edge of the lamellipodium. We suggest that the talin in the nodes functions, via a cross-linking activity, in the convergence of actin filaments at the membrane during development of the ribs. Talin accumulates de novo in the adhesion plaque, independent of that at the tip of the precursor, in response to contact with the substrate. This second accumulation of talin at the focal contact starts before vinculin, consistent with a sequential binding of talin at the membrane and of vinculin to talin. The results imply that talin functions independently at two steps during formation of the focal contact: the development of the F-actin-rich precursor of the contact; and development of the contact-associated adhesion plaque, both involving organization of F-actin at the membrane.     

The cytoskeletal protein talin contains at least two distinct vinculin binding domains

We have mapped the vinculin-binding sites in the cytoskeletal protein talin as well as those sequences which target the talin molecule to focal contacts. Using a series of overlapping talin-fusion proteins expressed in E. coli and 125I-vinculin in both gel-overlay and microtitre well binding assays, we present evidence for three separable binding sites for vinculin. All three are in the tail segment of talin (residues 434-2541) and are recognized by the same fragment of vinculin (residues 1-258). Two sites are adjacent to each other and span residues 498-950, and the third site is more than 700 residues distant in the primary sequence. Scatchard analysis of 125I-vinculin binding to talin also indicates three sites, each with a similar affinity (Kd = 2- 6 x 10(-7) M). We also detect a substoichiometric interaction of higher affinity (Kd = 3 x 10(-8) M) which remains unexplained. By expressing regions of the chicken talin molecule in heterologous cells, we have shown that the sequences required to target talin to focal contacts overlap those which bind vinculin.     

Molecular dynamics study of talin-vinculin binding

Cells can sense mechanical force in regulating focal adhesion assembly. One vivid example is the force-induced recruitment of vinculin to reinforce initial contacts between a cell and the extracellular matrix. Crystal structures of the unbound proteins and bound complex between the vinculin head subdomain (Vh1) and the talin vinculin binding site 1 (VBS1) indicate that vinculin undergoes a conformational change upon binding to talin. However, the molecular basis for this event and the precise nature of the binding pathway remain elusive. In this article, molecular dynamics is used to investigate the binding mechanism of Vh1 and VBS1 under minimal constraints to facilitate binding. One simulation demonstrates binding of the two molecules in the complete absence of external force. VBS1 makes early hydrophobic contact with Vh1 by positioning the critical hydrophobic residues (L608, L615, and L622) in the groove formed by helices 1 and 2 of Vh1. The solvent-exposed hydrophobic residues (V619 and L623) then gradually penetrate the hydrophobic core of Vh1, thus further separating helix 1 from helix 2. These critical residues are highly conserved as large hydrophobic side groups in other vinculin binding sites; studies also have demonstrated that these residues are essential in Vh1-VBS1 binding. Similar binding mechanisms are also demonstrated in separate molecular dynamics simulations of Vh1 binding to other vinculin binding sites both in talin and α-actinin.     

A conformational switch in vinculin drives formation and dynamics of a talin-vinculin complex at focal adhesions

Dynamic interactions between the cytoskeleton and integrins control cell adhesion, but regulatory mechanisms remain largely undefined. Here, we tested the extent to which the autoinhibitory head-tail interaction (HTI) in vinculin regulates formation and lifetime of the talin-vinculin complex, a proposed mediator of integrin-cytoskeleton bonds. In an ectopic recruitment assay, mutational reduction of HTI drove assembly of talin-vinculin complexes, whereas ectopic complexes did not form between talin and wild-type vinculin. Moreover, reduction of HTI altered the dynamic assembly of vinculin and talin in focal adhesions. Using fluorescence recovery after photobleaching, we show that the focal adhesion residency time of vinculin was enhanced up to 3-fold by HTI mutations. The slow dynamics of vinculin correlated with exposure of its cryptic talin-binding site, and a talin-binding site mutation rescued the dynamics of activated vinculin. Significantly, HTI-deficient vinculin inhibited the focal adhesion dynamics of talin, but not paxillin or alpha-actinin. These data show that talin conformation in cells permits vinculin binding, whereas the autoinhibited conformation of vinculin constitutes the barrier to complex formation. Down-regulation of HTI in vinculin to Kd approximately 10(-7) is sufficient to induce talin binding, and HTI is essential to the dynamics of vinculin and talin at focal adhesions. We therefore conclude that vinculin conformation, as modulated by the strength of HTI, directly regulates the formation and lifetime of talin-vinculin complexes in cells.     

Coincidence of actin filaments and talin is required to activate vinculin

Vinculin regulates cell adhesion by strengthening contacts between extracellular matrix and the cytoskeleton. Binding of the integrin ligand, talin, to the head domain of vinculin and F-actin to its tail domain is a potential mechanism for this function, but vinculin is autoinhibited by intramolecular interactions between its head and tail domain and must be activated to bind talin and actin. Because autoinhibition of vinculin occurs by synergism between two head and tail interfaces, one hypothesis is that activation could occur by two ligands that coordinately disrupt both interfaces. To test this idea we use a fluorescence resonance energy transfer probe that reports directly on activation of vinculin. Neither talin rod, VBS3 (a talin peptide that mimics a postulated activated state of talin), nor F-actin alone can activate vinculin. But in the presence of F-actin either talin rod or VBS3 induces dose-dependent activation of vinculin. The activation data are supported by solution phase binding studies, which show that talin rod or VBS3 fails to bind vinculin, whereas the same two ligands bind tightly to vinculin head domain (K(d) approximately 100 nM). These data strongly support a combinatorial mechanism of vinculin activation; moreover, they are inconsistent with a model in which talin or activated talin is sufficient to activate vinculin. Combinatorial activation implies that at cell adhesion sites vinculin is a coincidence detector awaiting simultaneous signals from talin and actin polymerization to unleash its scaffolding activity.     

Reduced cell migration and disruption of the actin cytoskeleton in calpain-deficient embryonic fibroblasts

The physiological functions and substrates of the calcium-dependent protease calpain remain only partly understood. The mu- and m-calpains consist of a mu- or m-80-kDa large subunit (genes Capn1 and Capn2), and a common 28-kDa small subunit (Capn4). To assess the role of calpain in migration, we used fibroblasts obtained from Capn4(-/-) mouse embryos. The cells lacked calpain activity on casein zymography and did not generate the characteristic calpain-generated spectrin breakdown product that is observed in wild-type cells. Capn4(-/-) cells had decreased migration rates and abnormal organization of the actin cytoskeleton with a loss of central stress fibers. Interestingly, these cells extended numerous thin projections and displayed delayed retraction of membrane protrusions and filopodia. The number of focal adhesions was decreased in Capn4(-/-) cells, but the cells had prominent vinculin-containing focal complexes at the cell periphery. The levels of the focal adhesion proteins, alpha-actinin, focal adhesion kinase (FAK), spectrin, talin, and vinculin, were the same in Capn4(+/+) and Capn4(-/-) cells. FAK, alpha-actinin, and vinculin were not cleaved in either cell type plated on fibronectin. However, proteolysis of the focal complex component, talin, was detected in the wild-type cells but not in the Capn4(-/-) cells, suggesting that calpain cleavage of talin is important during cell migration. Moreover, talin cleavage was again observed when calpain activity was partially restored in Capn4(-/-) embryonic fibroblasts by stable transfection with a vector expressing the rat 28-kDa calpain small subunit. The results demonstrate unequivocally that calpain is a critical regulator of cell migration and of the organization of the actin cytoskeleton and focal adhesions.