Visualization of cellular focal contacts using a monoclonal antibody to 80 kD serum protein adsorbed on the substratum

We have obtained a monoclonal antibody to 80 kD protein of calf serum; this protein easily and uniformly adsorbs on glass from serum-containing media. Indirect immunofluorescence staining of chick and mouse embryo fibroblasts cultured in the presence of calf serum, fixed with formaldehyde and permeabilized with Triton X-100, revealed black non-fluorescent strips and dots under the ventral cell surface, whereas all other parts of the substratum under and between cells were highly fluorescent. The distribution of non-fluorescent regions coincided with the distributed of focal contacts of cells with the substratum, revealed by interference reflection microscopy, as well as with the distribution of vinculin-containing plaques. The dark regions were also associated with the ends of microfilament bundles revealed by immunofluorescence with an anti-actin antibody. Thus, non-fluorescent regions seen after anti-80 kD staining are parts of the substratum under the focal contacts. Visualization of focal contacts with anti-80 kD provides very contrasting and high resolution pictures. Evidence is presented that 80 kD protein is adsorbed to glass in the areas of focal contacts, but the antibodies used for staining cannot penetrate these contacts.     

Association of intermediate filaments with vinculin-containing adhesion plaques of fibroblasts

Double immunofluorescence staining of quail embryo fibroblasts with rabbit antibody to vinculin and mouse monoclonal antibody to vimentin revealed a coincidence between fluorescence patterns for cell-substrate focal contacts and intermediate filaments. Most of the vinculin-containing adhesion plaques coincided with the ends of vimentin-positive fibrils. This association was further corroborated by immunoelection microscopic observations of the cytoskeletons of quail and mouse fibroblasts using a platinum replica technique. The intermediate filaments were identified either by direct treatment with antivimentin IgM or by an indirect immunogold staining method. Colcemid treatment of the cells caused a collapse of intermediate filaments and destroyed their association with focal contacts. During the early stages of the colcemid-induced collapse of the intermediate filaments, single vimentin fibrils appeared to retain their association with focal contacts. The possible role of the intermediate filaments in the formation and maintenance of focal contacts is discussed.     

Association of fibronectin and vinculin with focal contacts and stress fibers in stationary hamster fibroblasts

We have recently observed a transmembrane association between extracellular fibronectin (FN) fibers and elongated focal patches or fibers of vinculin (VN) in G1-arrested stationary Nil 8 hamster fibroblasts, with double-label immunofluorescence microscopy (Singer and Paradiso, 1981, Cell. 24:481-492). We hypothesized that these FN-VN complexes might correspond to focal contacts, the membrane sites that are probably mainly responsible for attaching cells to their substrata, because vinculin is often localized in focal contacts. However, because fibronectin-vinculin associations may not be restricted to the substrate adhesive surface of the cell, it became necessary to determine whether some or all of the various kinds of FN-VN complexes which we described are in proximity to the substrate. Using interference reflection optics and double-label immunofluorescence microscopy for fibronectin and vinculin, many elongated (up to 38 micrometer) FN-VN associations were found to be strikingly coincident with focal contacts in the perinuclear area of extremely flattened arrested Nil 8 fibroblasts in 0.3% fetal bovine serum (FBS). In addition, the long FN-VN adhesion complexes were precisely aligned with the major phase-dense stress fibers observed at the ventral surfaces of these stationary cells with phase contrast microscopy. Fibronectin was neither associated with vinculin-containing focal contacts of Nil 8 cells cultured in medium with 5% FBS nor with vinculin-negative focal contacts located at the extreme edges of stationary cells arrested in 0.3 FBS. Our time-course experiments suggest that early FN-VN lacking- focal contacts, which form at the cellular margins, develop into mature substrate adhesion complexes containing both fibronectin and vinculin, localized in the major stress fibers at the centers of sessile fibroblasts.     

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.     

Extracellular matrix fibers containing fibronectin and basement membrane heparan sulfate proteoglycan coalign with focal contacts and microfilament bundles in stationary fibroblasts

Double-label immunofluorescence microscopy and immunoelectron microscopy were performed on stationary cultures of Nil 8 fibroblasts to determine if fibronectin and basement membrane heparan sulfate proteoglycans play coordinated roles in cell-to-substrate adhesion. Relationships between subcellular matrix fibers containing fibronectin plus proteoglycan, and focal contacts associated with microfilament bundles, were studied simultaneously using interference reflection microscopy, differential interference contrast microscopy, and immunofluorescence microscopy. Cells maintained in 0.3% FBS were doubly stained with monospecific anti-fibronectin IgG and antibodies against a basement membrane proteoglycan purified from the EHS (Engelbreth-Holm-Swarm) tumor. Coincident patterns of fibronectin and proteoglycan-containing fibers were found to codistribute with focal contacts and microfilament bundles in both early (6-h) and late (24-h) cultures. The early cells showed doubly-stained fibers colinear with substrate adhesion sites in 43% of the sample, while 100% of the later cells exhibited these coaligned matrix-cytoskeletal attachment complexes. Immunoelectron microscopy showed that both of these antigens were situated in the same type of extracellular matrix fiber that appeared to be loosely associated with the cell surface membrane. We hypothesize that the appearance of proteoglycan in subcellular matrix fibers of these fibroblasts might stabilize fibronectin-containing cell-to-substrate contacts.     

A new protein of adhesion plaques and ruffling membranes

A protein with a molecular weight on SDS polyacrylamide gels of 215,000 (referred to here as 215K) was purified from chicken gizzard smooth muscle. Antibodies against this protein localized it in fibroblasts to adhesion plaques (focal contacts), to regions underlying cell surface fibronectin, and to ruffling membranes. In the first two distributions it was similar to vinculin in cellular location, and this was confirmed by double-label immunofluorescence microscopy, but the concentration of 215K in membrane ruffles distinguished it from vinculin. There was no cross-reaction of the antibody against 215K with vinculin, and immunoprecipitation and antibody staining of SDS gels of whole cells revealed a single cross-reactive component with a molecular weight of 215,000. Immunoprecipitation from cultures labeled with [32P]phosphate revealed 215K to be a phosphoprotein. Transformation of rat or chicken fibroblasts by Rous sarcoma virus resulted in a reorganization of 215K, in some cases into complex intracellular structures. The localization of 215K where microfilament bundles terminate as well as in close relation to cell surface fibronectin and in membrane ruffles suggests that the protein has some function in the organization of actin filaments at or close to regions of actin-membrane attachment.     

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.     

Association of type 3 protein kinase C with focal contacts in rat embryo fibroblasts

We have used immunocytofluorescence techniques to determine the subcellular distribution of the Ca2+, phospholipid-dependent protein kinase, protein kinase C (PKC). Using monoclonal antibodies that are specific for Type 3 (alpha) PKC, we have determined that there are least two pools of PKC in normal rat embryo fibroblasts (REF52 cells): diffuse cytoplasmic and fiber-associated. Extraction with chelators and detergent before fixing and staining removes the cytoplasmic PKC. The fiber-associated staining remains in these cytoskeleton preparations. The cytoskeleton Type 3 PKC staining closely resembles that of the focal contact protein vinculin and colocalizes with another focal contact protein, talin. Cytochalasin, but not colchicine, coordinately disrupts the staining pattern of vinculin and PKC. Activation of PKC by treatment with phorbol esters causes depolymerization of microfilaments and reorganization of vinculin staining. We propose that Type 3 PKC is a modulatory component of the focal contact and has a primary role in regulation of the association of microfilament bundles with the plasma membrane.     

Antibody mapping of functional domains in vinculin.

We have analyzed the functional domain structure of vinculin, a protein involved in linking microfilaments to the cytoplasmic face of cell membranes in animal cells. For this purpose, we used several monoclonal antibodies raised against chicken gizzard vinculin whose epitopes could be assigned to discrete regions in the vinculin sequence by immunoblotting of proteolytic fragments combined with N-terminal amino acid sequencing. Two of these antibodies induced the disruption of stress fibers and changed the number of morphology of focal contacts after microinjection in chicken embryo fibroblasts. Based on the location of its epitope in comparison with vinculin domains previously identified by other groups, we propose that one of these antibodies (15B7) interferes with the binding of vinculin to talin, the most peripheral of the microfilament proteins. The second antibody (14C10) binds within a region comprising three internal repeats and might therefore distort the inner architecture of vinculin. A third antibody (As3) inhibited the binding of F-actin to vinculin in an in vitro assay but had no effect on the microfilament system in cells. These data emphasize the role of vinculin as a key protein in microfilament-membrane linkage and support previous work on a direct interaction between vinculin and actin.     

The use of Rous sarcoma virus transformation mutants with differing tyrosine kinase activities to study the relationships between vinculin phosphorylation, pp60v-src location and adhesion plaque integrity

Tyrosine-specific phosphorylation of cellular proteins has been implicated in the neoplastic transformation of cells by Rous sarcoma virus (RSV). One of the putative substrates for the src gene product (pp60v-src) of RSV is the cytoskeletal protein vinculin, giving rise to the hypothesis that tyrosine-specific phosphorylation of vinculin disrupts adhesion plaque integrity, leading to the characteristic rounded morphology of RSV-transformed cells. We have investigated this hypothesis by analysing the properties of fibroblasts transformed by conditional and non-conditional mutants of RSV which confer different morphologies on infected cells, with respect to formation of microfilament bundles, formation of vinculin-containing adhesion plaques, the deposition of a fibronectin-containing extracellular matrix, the localization of pp60v-src and the tyrosine-specific phosphorylation of vinculin. Cells transformed by the temperature-sensitive (ts) RSV mutant LA32 cultured at 41 degrees C were morphologically normal, and contained prominent microfilament bundles and well-developed adhesion plaques. However, these cells had a fully active pp60v-src kinase, had pp60v-src concentrated in their adhesion plaques and contained vinculin which was heavily phosphorylated on tyrosine residues. Cells transformed by a recovered avian sarcoma virus, rASV 2234.3 exhibited a markedly fusiform morphology with pp60v-src concentrated in well-developed adhesion plaques and an elevation of the phosphotyrosine content of vinculin. Cells transformed by LA32 at restrictive temperature comprise morphologically normal cells, indistinguishable from untransformed CEF, yet which contain tyrosine-phosphorylated vinculin and suggest that neither tyrosine-specific phosphorylation of vinculin nor pp60v-src concentration in adhesion plaques is sufficient for the rounded morphology of RSV-transformed cells.     

Structure and function of a vimentin-associated matrix adhesion in endothelial cells

The alpha4 laminin subunit is a component of endothelial cell basement membranes. An antibody (2A3) against the alpha4 laminin G domain stains focal contact-like structures in transformed and primary microvascular endothelial cells (TrHBMECs and HMVECs, respectively), provided the latter cells are activated with growth factors. The 2A3 antibody staining colocalizes with that generated by alphav and beta3 integrin antibodies and, consistent with this localization, TrHBMECs and HMVECs adhere to the alpha4 laminin subunit G domain in an alphavbeta3-integrin-dependent manner. The alphavbeta3 integrin/2A3 antibody positively stained focal contacts are recognized by vinculin antibodies as well as by antibodies against plectin. Unusually, vimentin intermediate filaments, in addition to microfilament bundles, interact with many of the alphavbeta3 integrin-positive focal contacts. We have investigated the function of alpha4-laminin and alphavbeta3-integrin, which are at the core of these focal contacts, in cultured endothelial cells. Antibodies against these proteins inhibit branching morphogenesis of TrHBMECs and HMVECs in vitro, as well as their ability to repopulate in vitro wounds. Thus, we have characterized an endothelial cell matrix adhesion, which shows complex cytoskeletal interactions and whose assembly is regulated by growth factors. Our data indicate that this adhesion structure may play a role in angiogenesis.     

Identification of two distinct functional domains on vinculin involved in its association with focal contacts

We report here on the identification of two distinct functional domains on chicken vinculin molecule, which can, independently, mediate its interaction with focal contacts in living cells. These findings were obtained by immunofluorescent labeling of COS cells transfected with a series of chicken vinculin-specific cDNA constructs derived from clones cVin1 and cVin5 (Bendori, R., D. Salomon, and B. Geiger. 1987. EMBO [Eur. Mol. Biol. Organ.] J. 6:2897-2905). These included a chimeric construct consisting of 5' sequences of cVin1 attached to the complementary 3' region of cVin5, as well as several constructs of either cVin1 or cVin5 from which 3' or 5' sequences were deleted. We show here that the products of both cVin1 and cVin5, and of the cVin1/cVin5 chimera, readily associated with focal contacts in transfected COS cells. Furthermore, 78 and 45 kD NH2-terminal fragments encoded by a deleted cVin1 and the 78-kD COOH-terminal portion of vinculin encoded by cVin5 were capable of binding specifically to focal contact areas. In contrast 3'-deletion mutants prepared from clone cVin5 and a 5'-deletion mutant of cVin1, lacking both NH2- and COOH-terminal sequences, failed to associate with focal contacts in transfected cells. The loss of binding was accompanied by an overall disarray of the microfilament system. These results, together with previous in vitro binding studies, suggest that vinculin contains at least two independent sites for binding to focal contacts; the NH2-terminal domain may contain the talin binding site while the COOH-terminal domain may mediate vinculin-vinculin interaction. Moreover, the disruptive effect of the double-deleted molecule (lacking the two focal-contact binding sites) on the organization of actin suggests that a distinct region involved in the binding of vinculin to the microfilament system is present in the NH2-terminal 45-kD region of the molecule.     

Adhesiveness and distribution of vinculin and spectrin in retinal pigmented epithelial cells during growth and differentiation in vitro

Colonies of chick retinal pigmented epithelial (RPE) cells offer an excellent model system for studying the organization of cytoskeleton in sheets of differentiating epithelial cells. The cells occupying the center of the colony resemble RPE cells in vivo and are cuboidal, pigmented, and relatively nonadherent while those toward the periphery gradually become flatter, nonpigmented, motile, and strongly adherent to the substratum. Immunofluorescence microscopy with antiserum against chicken erythrocyte alpha-spectrin reveals that this protein is present in the cortex of RPE cells in all parts of the colony. It is neither concentrated in, nor excluded from the regions occupied by the major microfilament bundles, and its distribution is not related to the adhesion patterns visualized by surface reflection interference microscopy. In contrast, the distribution of vinculin is closely correlated with the adhesiveness of RPE cells in different parts of the colony. Immunofluorescence microscopy reveals that in the RPE cells vinculin may be diffusely distributed in the cytoplasm; present in a cortical band outlining the cell borders; and present in focal contacts and adhesions. The distribution of vinculin is affected by the length of time the colonies grow in culture, by the degree of cell packing and by the adhesiveness of cells to the substratum. In RPE cells grown in vitro for short periods (less than or equal to 3 days) vinculin is found in focal contacts and adhesions in both the undifferentiated, well spread peripheral cells as well as in the differentiated, polygonally packed central cells of the colony. In RPE cells cultured for longer periods (greater than or equal to 14 days) vinculin is present in focal contacts and adhesions only in strongly adherent, undifferentiated cells at the edge of the colony. In packed central cells of both short- and long-term cultures vinculin is found in the cortical band which circumscribes the apical ends of cells at the level of the adherens type intercellular junctions. Its appearance in the cortical bands does not depend on the length of time the colonies are grown in vitro but on the presence of cell-cell contacts resulting from an increased degree of cell packing within the central part of the colony. These results are discussed in relation to the development and the role of extracellular matrix in determining the adhesiveness of RPE cells in vitro.     

Immunolocalization of the intermediate filament-associated protein plectin at focal contacts and actin stress fibers.

The distribution of plectin in the cytoplasm of Rat1 and glioma C6 cells was examined using a combination of double and triple immunofluorescence microscopy and interference reflection microscopy. In cells examined shortly after subcultivation (less than 48 h), filamentous networks of plectin structures, resembling and partially colocalizing with vimentin filaments, were observed as reported in previous studies. In cells kept attached to the substrate without growth for periods of 72 h to 8 days (stationary cultures), thick fibrillary plectin structures were observed. These structures were located at the end of actin filament bundles and showed co-distribution with adhesion plaques (focal contacts), vinculin, and vimentin. Only relatively large adhesion plaques (dash-like contacts) were decorated by antibodies to plectin, smaller dot-like contacts at the cell edges remained undecorated. Moreover, in stationary Rat1 cells plectin structures were found to be predominantly colocalized with actin stress fibers. However, after treatment of such cells with colcemid, plectin's distribution changed dramatically. The protein was no longer associated with actin structures, but was distributed diffusely throughout the cytoplasm. After a similar treatment with cytochalasin B, plectin's association with stress fibers again was completely abolished, although stress fibers were still present. The association of plectin with focal contact-associated intermediate filaments was demonstrated also by immunogold electron microscopy of quick-frozen, deep-etched replicas of rat embryo fibroblasts. These data confirm previous reports suggesting a relationship between intermediate filaments on the one hand, and actin stress fibers and their associated plasma membrane junctional complexes, on the other. Furthermore, the data establish plectin as a novel component of focal contact complexes and suggest that plectin plays a role as mediator between intermediate filaments and actin filaments.     

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.     

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.     

A new type of substratum adhesion structure in NRK cells revealed by correlated interference reflection and electron microscopy

The substratum adherent membrane of NRK cells in vitro has been studied using correlated interference reflection and surface replica electron microscopy. Structures visualized by interference reflection microscopy were identified in the subsequently prepared platinum-carbon replicas of the adherent membranes. Substratum adherent membranes were prepared using a hypotonic shock/cell shearing technique (lysis-squirting). Typically 20% of the original ventral membrane surface area and 50% of the original focal adhesion number were retained. Microfilament bundle termini, clathrin-coated sheets and pits, cytotic vesicles having a ridged surface and groups of membrane associated particles were well preserved in the replicas. Two types of isolated adhesion structures were found after lysis-squirting. In addition to typical elongate focal adhesions containing actin and vinculin, we report the existence of adherent membrane patches lacking microfilament bundles and negative for vinculin labelling, but coated with clathrin and identifiable in interference reflection microscopy as less dark than focal adhesions and having dot, U- or sinusoidal shapes.     

Regulation of integrin-mediated adhesion at focal contacts by cyclic AMP

Cyclic AMP (cAMP) elevation causes diverse types of cultured cells to round partially and develop arborized cell processes. Renal glomerular mesangial cells are smooth, muscle-like cells and in culture contain abundant actin microfilament cables that insert into substratum focal contacts. cAMP elevation causes adhesion loss, microfilament cable fragmentation, and shape change in cultured mesangial cells. We investigated the roles of the classical vitronectin (αVβ3 integrin) and fibronectin (α5β1 integrin) receptors in these changes. Mesangial cells on vitronectin-rich substrata contained microfilament cables that terminated in focal contacts that stained with antibodies to vitronectin receptor. cAMP elevation caused loss of focal contact and associated vitronectin receptor. Both fibronectin and its receptor stained in a fibrillary pattern at the cell surface under control conditions but appeared aggregated along the cell processes after cAMP elevation. This suggested that cAMP elevation caused loss of adhesion mediated by vitronectin receptor but not by fibronectin receptor. We plated cells onto fibronectin-coated slides to test the effect of ligand immobilization on the cellular response to cAMP. On fibronectin-coated slides fibronectin receptor was observed in peripheral focal contacts where actin filaments terminated, as seen with vitronectin receptor on vitronectin-coated substrata, and in abundant linear arrays distributed along microfilaments as well. Substratum contacts mediated by fibronectin receptor along the length of actin filaments have been termed fibronexus contacts. After cAMP elevation, microfilaments fragmented and fibronectin receptor disappeared from peripheral focal contacts, but the more central contacts along residual microfilament fragments appeared intact. Also, substratum adhesion was maintained after cAMP elevation on fibronectin—but not on vitronectincoated surfaces. Although other types of extracellular matrix receptors may also be involved, our observations suggest that cAMP regulates adhesion at focal contacts but not at fibronexus-type extracellular matrix contacts. © 1993 Wiley-Liss, Inc.     

Ultrastructural localization of plasma membrane-associated urokinase- type plasminogen activator at focal contacts

We have recently shown that urokinase-type plasminogen activator (u-PA) and plasminogen activator inhibitor type 1 are both found extracellularly beneath cultured human skin fibroblasts and HT-1080 sarcoma cells, but in distinct localizations. Here, the ultrastructural distribution of u-PA was studied using immunoferritin electron microscopy. In HT-1080 cells, u-PA on the extracellular aspect of the plasma membrane was detected at sites of direct contact of the cell with the growth substratum beneath all parts of the ventral cell surface. The ferritin-labeled adhesion plaques, which were enriched in submembraneous microfilaments, were frequently seen at the leading lamellae of the cells as well as in lamellipodia and microspikes. Besides the cell-substratum adhesion plaques, ferritin label was detected at cell-cell contact sites. Double-label immunofluorescence showed a striking colocalization of u-PA and vinculin in both HT-1080 cells and WI-38 lung fibroblasts, which is consistent with u-PA being a focal contact component. The u-PA-containing focal contacts of WI-38 cells had no direct codistribution with fibronectin fibrils. In WI-38 cells made stationary by cultivation in a medium containing 0.5% FCS, vinculin plaques became highly elongated and more centrally located, whereas u-PA immunolabel disappeared from such focal adhesions. These findings show that plasma membrane-associated u-PA is an intrinsic component of focal contacts, where, we propose, it enables directional proteolysis for cell migration and invasion.