Substrate-attached serum and cell proteins in adhesion of mouse fibroblasts.

The effects of serum and coatings of substrate-attached material (SAM, which remains tightly adherent to the substrate after EGTA-mediated removal of cells) on the kinetics of attachment of DNA-radiolabeled BALB/c 3T3. SV40-transformed 3T3, and concanavalin A-selected revertant cells to glass coverlips were studied. The presence of serum in the medium of attaching cells had a marked effect on (1) the initial time lag before stable attachment of cells, (2) the maximum level of attached cells, (3) the stability of attachment, and (4) pseudopodial spread of the cell over the substrate. These serum effects could be mimicked by measuring attachment in medium without serum and with use of serum-preadsorbed or 3T3 SAM-coated coverslips. Enzymatic treatment of serumpreadsorbed substrates indicated that the factor(s) in serum which affects attachment is very trypsin-sensitive. Serum preadsorption of substrates stimulated attachment of SVT2 cells in medium with serum in a manner very similar to the effects of 3T3 SAM coating, while attachment of 3T3 SAM coating, while attachment of 3T3 or revertant cells was unaffected. Slab gel electrophoretic analysis (PAGE-SDS gels) identified eight major serum proteins by Coomassie blue staining (a) which bind to the substrate in the absence of cells and (b) which persist on the substrate after growth to confluence of 3T3 or SVT2 cells; this suggests that major breakdown or serum-adsorbed components does not occur during growth of normal or transformed cells. Seven radioactive SAM proteins were detected by autoradiography in 3T3 or SVT2 SAM electropherograms -- two of which are high molecular weight components which correspond to the glucosamine-radiolabeled hyaluronate proteoglycans observed previously; the remaining five are newly-identified proteins in SAM (one of these proteins appears to be actin). 3T3 and SVT2 cells have unique proportions of these seven components. The data are consistent with the idea that normal or virus-transformed cells do not attach directly to the culture substrate, but to specific classes of substrate-adsorbed serum proteins via deposition of specific classes of cell surface proteins and polysaccharides.     

Tyrosine phosphorylation and cytoskeletal tension regulate the release of fibroblast adhesions

We have investigated the mechanisms by which fibroblasts release their adhesions to the extracellular matrix substrata using a permeabilized cell system in which the adhesions remain relatively stable. A large number of different molecules were assayed for their effect on focal adhesion stability using immunofluorescence with antibodies against different focal adhesion constituents. ATP uniquely stimulates a rapid breakdown of focal adhesions, and at high ATP concentrations (> 5 mM), many cells are released from the dish. The remaining cells appear contracted with talin, alpha-actinin, and vinculin localized diffusely throughout the cell. Integrin containing tracks of variable intensity outline the regions where cells had resided before they detached from the substratum. At lower ATP concentrations (0.5-5 mM) the cells remain spread; however the focal adhesion components, including integrin, show an array of phenotypes ranging from diffusely localized throughout the cell to a localization in small, thin focal adhesions. Okadaic acid, a serine, threonine phosphatase inhibitor, enhances the contracted phenotype, even at low concentrations (0.5 mM) of ATP. The localization of focal adhesion components is different in okadaic acid-treated cells. In highly contracted cells, integrin is present in tracks where the cells resided before the contraction; however focal adhesions are no longer apparent. Talin, vinculin, and alpha-actinin localize in trabecular networks toward the periphery of the cell. Interestingly, phosphotyrosine staining as well as nascent, intracellular integrin precedes the recruitment of focal adhesion constituents into the trabecular network. The ATP-stimulated focal adhesion breakdown appears to operate through two mechanisms. First, ATP stimulates the tyrosine phosphorylation of several cytoskeletally associated proteins. These tyrosine phosphorylations correlated well with focal adhesion breakdown. Furthermore, addition of a recombinant, constitutively active tyrosine phosphatase inhibits both the tyrosine phosphorylations and the breakdown of the focal adhesions. None of the major tyrosine phosphoproteins are FAK, integrin, tensin, paxillin, or other phosphoproteins implicated in focal adhesion assembly. The second mechanism is cell contraction. High ATP concentrations, or lower ATP concentrations in the presence of okadaic acid induce cell contraction. Inhibiting the contraction by addition of a heptapeptide IRICRKG, which blocks the actin-myosin interaction, also inhibits focal adhesion breakdown. Neither the peptide nor the phosphatase inhibits focal adhesion breakdown under all conditions suggesting that both tension and tyrosine phosphorylations mediate the release of adhesions.     

FAK is required for tension-dependent organization of collective cell movements in Xenopus mesendoderm

Collective cell movements are integral to biological processes such as embryonic development and wound healing and also have a prominent role in some metastatic cancers. In migrating Xenopus mesendoderm, traction forces are generated by cells through integrin-based adhesions and tension transmitted across cadherin adhesions. This is accompanied by assembly of a mechanoresponsive cadherin adhesion complex containing keratin intermediate filaments and the catenin-family member plakoglobin. We demonstrate that focal adhesion kinase (FAK), a major component of integrin adhesion complexes, is required for normal morphogenesis at gastrulation, closure of the anterior neural tube, axial elongation and somitogenesis. Depletion of zygotically expressed FAK results in disruption of mesendoderm tissue polarity similar to that observed when expression of keratin or plakoglobin is inhibited. Both individual and collective migrations of mesendoderm cells from FAK depleted embryos are slowed, cell protrusions are disordered, and cell spreading and traction forces are decreased. Additionally, keratin filaments fail to organize at the rear of cells in the tissue and association of plakoglobin with cadherin is diminished. These findings suggest that FAK is required for the tension-dependent assembly of the cadherin adhesion complex that guides collective mesendoderm migration, perhaps by modulating the dynamic balance of substrate traction forces and cell cohesion needed to establish cell polarity.     

Adhesion of glycosaminoglycan-deficient chinese hamster ovary cell mutants to fibronectin substrata

We have examined the role of cell surface glycosaminoglycans in fibronectin-mediated cell adhesion by analyzing the adhesive properties of Chinese hamster ovary cell mutants deficient in glycosaminoglycans. The results of our study suggest that the absence of glycosaminoglycans does not affect the initial attachment and subsequent spreading of these cells on substrata composed of intact fibronectin or a fibronectin fragment containing the primary cell-binding domain. However, in contrast to wild-type cells, the glycosaminoglycan- deficient cells did not attach to substrate composed of a heparin- binding fibronectin fragment. Furthermore, the wild-type but not the glycosaminoglycan-deficient cells formed F-actin-containing stress fibers and focal adhesions on substrata composed of intact fibronectin. We propose, therefore, that cell surface proteoglycan(s) participate in the transmembrane linking of intracellular cytoskeletal components to extracellular matrix components which occurs in focal adhesions.     

Partial characterization of nervous system-specific cell surface antigen(s) NS-2.

Partial biochemical characterization of several neural tissue specific antigens isolated from a murine glioblastoma cell line was accomplished by means of radioiodination of intact cells followed by immunoprecipitation of the cell lysate with a rabbit serum specific for neural tissue antigens. Polyacrylamide gel electrophoresis of the immunoprecipitate in sodium dodecyl sulfate resolved the labeled antigens into several major components: two proteins (or glycoproteins) having apparent m.w.'s of 84,000 and 120,000 and lipid associated components which may be heterogeneous. The protein and lipid associated components apparently possess independent antigenicity because after chloroformmethanol extraction the protein components can be immunoprecipitated from the aqueous phase and the lipid associated component can be immunoprecipitated from the organic phase. Despite their independent antigenicity it is not known whether the components may be noncovalently associated on the cell surface. Although some of these antigens can be isolated from brain or glioma cells (a related tumor), non can be demonstrated in lymphoid tissues or C1300 neuroblastoma cells using identical methods. Therefore, these studies confirm our previous findings concerning the specificity of the anti-NS-2 antiserum by using cytotoxicity tests.     

Preferential Localization of Tyrosine-Phosphorylated Paxillin in Focal Adhesions

Focal adhesions are sites for integrin-mediated attachment of cultured cells to the extracellular matrix. Localization studies have shown that focal adhesions can be stained by antiphosphotyrosine antibodies, but the role of tyrosine-phosphorylated proteins in focal adhesions is not known. By using ventral plasma membranes prepared from chicken embryo fibroblasts spread on the substrate, we present evidence for the preferential localization of a minor pool of tyrosine-phosphorylated paxillin in focal adhesions. Ventral plasma membranes showed an enrichment in β1-integrins, and in several tyrosine-phosphorylated polypeptides, while focal adhesion proteins like vinculin and paxillin, although localized to focal adhesions in ventral plasma membranes, were not particularly enriched in these preparations compared to whole cell lysates. Biochemical and morphological analysis of ventral plasma membranes showed a dramatic increase in the level of tyrosine-phosphorylation of the pool of paxillin localized to the adhesive sites, when compared to the paxillin present in whole cell lysates. The observed preferential localization of tyrosine-phosphorylated paxillin to focal adhesions may represent a general mechanism to compartmentalize focal adhesion components from large non-phosphorylated, cytosolic pools.     

THE MECHANISM OF ADHESION OF CELLS TO GLASS : A Study by Interference Reflection Microscopy

An optical technique for measuring the thickness of thin films has been adapted and evaluated for studying the structure of the adhesion of cells to glass in tissue culture. This technique, which is termed interference reflection microscopy, has been used to study embryonic chick heart fibroblasts. These findings have been observed: in normal culture medium the closest approach of the cell surface to substrate in its adhesions is ca. 100 A, much of the cell surface lying farther away; chemical treatments which bring the cell surface to near its charge reversal point reduce the closest approach of adhesions to <50 A, probably to <30 A; chemical treatments which increase surface charge increase the nearest approach of cell and substrate in adhesions from ca. 100 A; high osmotic concentration of a non-polar substance, i.e. sucrose, does not affect the distance between cell and substrate in the adhesions. In addition, optical evidence indicates that there is no extracellular material between cell and glass in the adhesions. When cells de-adhere from glass, they appear not to leave fragments behind. The adhesive sites in these fibroblasts appear to be confined to the edge of the side of the cell facing the substrate and to the pseudopods. The significance of this is discussed in relation to the phenomenon of contact inhibition. Evidence is presented that the mechanism of cell adhesion does not involve calcium atoms binding cells to substrate by combining with carboxyl groups on cell surface, substrate, and with a cement substance. Osmium tetroxide fixation results in a final separation of 100 to 200 A between cell and substrate: there are reasons for thinking that this fairly close approach to the condition in life is produced as an artefact. The results can be accounted for only in terms of the action of electrostatic repulsive forces and an attractive force, probably the van der Waals—London forces. Biological arguments suggest that these results are equally applicable for cell-to-cell adhesions.     

Laminin alters cell shape and stimulates motility and proliferation of murine skeletal myoblasts

Proliferating skeletal myoblasts show multiple specific responses to laminin, one of the major glycoprotein components of basement membranes. Using MM14Dy myoblasts, a myogenic cell strain derived from a normal adult mouse skeletal muscle, we show in this study that substrate-bound laminin but not other matrix proteins such as collagens or fibronectin specifically and rapidly induces the outgrowth of cell processes, resulting in bipolar, spindle-shaped cells. This effect is independent from the presence of collagens or serum, and was also observed in primary cultures of fetal mouse skeletal myoblasts. The outgrowth of cell processes on laminin is associated with a dramatic stimulation of cell motility: MM14 myoblasts migrate about five times faster on laminin than on fibronectin. In another series of experiments the effect of laminin and fibronectin on thymidine uptake and proliferation of myoblasts was tested. On top of a type I collagen substrate which was provided to ensure complete adhesion even at low doses of laminin or fibronectin, laminin stimulated myoblast proliferation and incorporation of [3H]thymidine in a dose-dependent manner. The stimulation is two- to threefold higher than on dishes coated with equivalent amounts of fibronectin and is observed both in the presence and in the absence of serum. These results suggest that laminin, a major component of the muscle basal lamina, may be actively involved in the development and regeneration of skeletal muscle.     

Electrophoretic analysis of substrate-attached proteins from normal and virus-transformed cells.

The proteins which have been left tightly bound to the tissue culture substrate after ethylenebis (oxyethyl-enenitrilo) tetraacetic acid (EGTA)-mediated removal of normal, virus-transformed, and revertant mouse cells and which have been implicated in the substrate adhesion process have been analyzed by slab sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three size classes of hyaluronate proteoglycans were resolved in the 5% well gel; approximately half of the protein in the substrate-attached material coelectrophoresed with these polysaccharides-so-called glycosaminoglycan-associated protein(GAP). A portion of the GAP was shown to be highly heterogeneous and displaced from the polysaccharide by preincubation with calf histone before electrophoresis. The relative proportions of the proteoglycans varied in material deposited during a variety of cellular attachment and growth conditions. The remainder of the cellular protein in substrate-attached material was resolved as several major and distinct protein bands in 8 or 20% separating gels (a limited number of distinct serum proteins have also been identified as substrate bound). Protein C0 (molecular weight 220 000) was a prominent component in the material from a variety of normal and virus-transformed cells and resembled the so-called LETS or CSP glycoprotein in several respects; protein Ca was myosin-like in several respects; protein C2 was shown to be actin; and protein C1 (molecular weight 56 000) does not appear to be tubulin. Histones were also present in most preparations of substrate-attached material, particularly at high levels in transformed cell meterial, and may result from EGTA-mediated leakiness of the cell and subsequent binding to the negatively charged polysaccharide. These substrate-attached proteins were (a) prominent in substrate-attached material from many cell types in characteristic relative proportions, (b) deposited by EGTA-subcultured cells during the first hour of attachment to fresh substrate, (c) deposited by cells growing on plastic or glass substrates (three additional) components were also prominent in glass-attached material), and (d) deposited during long-term growth on or initial attachment to substrates coated wit 3T3 substrate-attached material. Pulse-chase analyses with radioactive leucine indicated that these proteins exhibit different turn-over behaviors. These results are discussed with regard to the possible involvement of these substrate-attached proteins in the substrate adhesion process, with particular interest in the interaction of cytoskeletal microfilaments with other surface membrane components and with regard to alteration of substrate adhesion by virus transformation.     

The serum dependence of baby hamster kidney cell attachment to a substratum

Normal attachment and spreading of baby hamster kidney cells onto a non-living substratum requires the presence of a specific serum component adsorbed to the substratum surface and Ca²⁺ ions in the medium. In the absence of the adsorbed serum factor or Ca²⁺ ions cells attach but do not spread. Thus, although the initial rate of BHK cell attachment is faster in serum-free medium than serum-containing medium, no cell spreading occurs in serum-free medium. Adsorption of serum onto the substratum results in a lag phase in the time course of cell attachment which can be eliminated by blocking the negatively charged groups of the serum components adsorbed to the substratum surface; blocking positively charged groups or free sulfhydryl groups of the adsorbed serum components is without effect. The requirement for serum components can be substituted for by adsorbing molecules such as concanavalin A or polycationic ferritin to the substratum surface; however, only ConA results in normal morphology of cell spreading. The data are discussed in terms of a non-electrostatic direct cell-substratum binding model of cell attachment.     

Initial studies of the molecular organization of the cell-substrate adhesion site

Using selective extraction reagents and non-penetrating probes, studies have been initiated on the molecular organization of substrate-attached material, adhesion sites which pinch off from the cell surface of normal Balb/c 3T3 or SV40-transformed Balb/c 3T3 (SVT2) cells and which remain bound to the serum-coated substrate during EGTA-mediated detachment of cells. Extraction of SVT2 adhesion sites with non-ionic detergents resulted in (a) only small amounts of leucine-radiolabeled protein and glucosamine-radiolabeled polysaccharide being solubilized; (b) selective solubilization of 80% of the adhesion site actin, and (c) solubilization of 95% of the phospholipid from these membranous pools. ATP in combination with potassium chloride extracted 60% of the actin. The 3T3 and SVT2 adhesion site proteins which are accessible to lactoperoxidase-catalyzed iodination were also determined. Many of the serum-derived proteins, bound to the substrate, were iodinated during iodination treatment of serum-coated or substrate-attached material-coated substrates, whereas the cellular proteins in the adhesion sites were not iodinated even though they were present in larger quantity as revealed by Coomassie blue staining. Iodination of cells, followed by their EGTA-mediated detachment and reattachment to fresh serum-coated substrates, indicated that the principal iodinated cell surface component deposited in new adhesion sites is the large external transformation-sensitive glycoprotein (even though large external transformation-sensitive glycoprotein is not the only principal iodinated cell surface component of these cells). These studies further establish the selective enrichment in this adhesive material of specific cell surface components and indicate that they are tenaciously bound at the interface between the serum coating and the undersurface of the adhesion site membranous pools.     

Thrombospondin modulates focal adhesions in endothelial cells

We examined the effects of thrombospondin (TSP) in the substrate adhesion of bovine aortic endothelial cells. The protein was tested both as a substrate for cell adhesion and as a modulator of the later stages of the cell adhesive process. TSP substrates supported the attachment of some BAE cells, but not cell spreading or the formation of focal adhesion plaques. In contrast, cells seeded on fibrinogen or fibronectin substrates were able to complete the adhesive process, as indicated by the formation of focal adhesion plaques. Incubation of cells in suspension with soluble TSP before or at the time of seeding onto fibronectin substrates resulted in an inhibition of focal adhesion formation. Furthermore, the addition of TSP to fully adherent cells in situ or prespread on fibronectin substrates caused a reduction in the number of cells, which were positive for focal adhesions, although there was no significant effect on cell spreading. In a dose-dependent manner, TSP reduced the number of cells with adhesion plaques to approximately 60% of control levels. The distribution of remaining adhesion plaques in TSP-treated cells was also altered: plaques were primarily limited to the periphery of cells and were not present in the central cell body, as in control cells treated with BSA. The observed effects were specific for TSP and were not observed with platelet factor 4, beta-thromboglobulin, or fibronectin. The TSP-mediated loss of adhesion plaques was neutralized by the addition of heparin, fucoidan, other heparin-binding proteins, and by a monoclonal antibody to the heparin binding domain of TSP, but not by antibodies to the core or carboxy-terminal regions of TSP. The interaction of the heparin- binding domain of TSP with cell-associated heparan sulfate appears to be an important mechanistic component for this activity of TSP. These data indicate that TSP may have a role in destabilizing cell adhesion through prevention of focal adhesion formation and by loss of preformed focal adhesions.     

Preferential Localization of Tyrosine-Phosphorylated Paxillin in Focal Adhesions

Focal adhesions are sites for integrin-mediated attachment of cultured cells to the extracellular matrix. Localization studies have shown that focal adhesions can be stained by antiphosphotyrosine antibodies, but the role of tyrosine-phosphorylated proteins in focal adhesions is not known. By using ventral plasma membranes prepared from chicken embryo fibroblasts spread on the substrate, we present evidence for the preferential localization of a minor pool of tyrosine-phosphorylated paxillin in focal adhesions. Ventral plasma membranes showed an enrichment in β1-integrins, and in several tyrosine-phosphorylated polypeptides, while focal adhesion proteins like vinculin and paxillin, although localized to focal adhesions in ventral plasma membranes, were not particularly enriched in these preparations compared to whole cell lysates. Biochemical and morphological analysis of ventral plasma membranes showed a dramatic increase in the level of tyrosine-phosphorylation of the pool of paxillin localized to the adhesive sites, when compared to the paxillin present in whole cell lysates. The observed preferential localization of tyrosine-phosphorylated paxillin to focal adhesions may represent a general mechanism to compartmentalize focal adhesion components from large non-phosphorylated, cytosolic pools.     

Epidermal growth factor: relationship between receptor down regulation in cultured NRK cells and epidermal growth factor enhancement of phosphorylation of a 170000 molecular weight membrane protein in vitro

Incubation of confluent nondividing NRK cells in serum-free media with unlabeled epidermal growth factor (EGF) leads to a reduction in the specific binding capacity for 125I-labeled EGF. This modulation of the binding capacity for 125I-labeled EGF by unlabeled EGF, termed receptor down regulation, was dependent on EGF concentration and time. Membranes from untreated NRK cells have a phosphorylating system which catalyzed in vitro the phosphorylation of numerous membrane components; this phosphorylating system was stimulated by EGF. Although EGF enhanced the phosphorylation of many membrane proteins, one major component with Mr 170K and a minor band of Mr 150K were primarily affected. A comparison of the membrane phosphoproteins of untreated and down-regulated cells by in vitro phosphorylation and NaDodSO4 gel electrophoresis revealed that down regulation of EGF receptors results in a specific decrease in 32P phosphorylation of the 170K- and 150K-dalton components to subsequent stimulation with EGF in vitro. We further characterized the modulation of phosphorylation of the 170K protein by down regulation with EGF and found it to be dependent on EGF concentration and time. These studies demonstrated a correlation between the loss of 125I-labeled EGF binding activity by the cells and the loss of the vitro EGF-dependent 32P phosphorylation of the 170K-dalton membrane protein. In addition, the results suggest that the major 170K Mr phosphoprotein band is a component of the receptor for EGF which is a substrate of the phosphorylation reaction.     

Cellular contractility changes are sufficient to drive epithelial scattering

Epithelial scattering occurs when cells disassemble cell–cell junctions, allowing individual epithelial cells to act in a solitary manner. Epithelial scattering occurs frequently in development, where it accompanies epithelial–mesenchymal transitions and is required for individual cells to migrate and invade. While migration and invasion have received extensive research focus, how cell–cell junctions are detached remains poorly understood. An open debate has been whether disruption of cell–cell interactions occurs by remodeling of cell–cell adhesions, increased traction forces through cell substrate adhesions, or some combination of both processes. Here we seek to examine how changes in adhesion and contractility are coupled to drive detachment of individual epithelial cells during hepatocyte growth factor (HGF)/scatter factor-induced EMT. We find that HGF signaling does not alter the strength of cell–cell adhesion between cells in suspension, suggesting that changes in cell–cell adhesion strength might not accompany epithelial scattering. Instead, cell–substrate adhesion seems to play a bigger role, as cell–substrate adhesions are stronger in cells treated with HGF and since rapid scattering in cells treated with HGF and TGFβ is associated with a dramatic increase in focal adhesions. Increases in the pliability of the substratum, reducing cells ability to generate traction on the substrate, alter cells? ability to scatter. Further consistent with changes in substrate adhesion being required for cell–cell detachment during EMT, scattering is impaired in cells expressing both active and inactive RhoA mutants, though in different ways. In addition to its roles in driving assembly of both stress fibers and focal adhesions, RhoA also generates myosin-based contractility in cells. We therefore sought to examine how RhoA-dependent contractility contributes to cell–cell detachment. Inhibition of Rho kinase or myosin II induces the same effect on cells, namely an inhibition of cell scattering following HGF treatment. Interestingly, restoration of myosin-based contractility in blebbistatin-treated cells results in cell scattering, including global actin rearrangements. Scattering is reminiscent of HGF-induced epithelial scattering without a concomitant increase in cell migration or decrease in adhesion strength. This scattering is dependent on RhoA, as blebbistatin-induced scattering is reduced in cells expressing dominant-negative RhoA mutants. This suggests that induction of myosin-based cellular contractility may be sufficient for cell–cell detachment during epithelial scattering.     

Suppression of tumorigenicity in transformed cells after transfection with vinculin cDNA

Transfection of chicken vinculin cDNA into two tumor cell lines expressing diminished levels of the endogenous protein, brought about a drastic suppression of their tumorigenic ability. The SV-40-transformed Balb/c 3T3 line (SVT2) contains four times less vinculin than the parental 3T3 cells, and the rat adenocarcinoma BSp73ASML has no detectable vinculin. Restoration of vinculin in these cells, up to the levels found in 3T3 cells, resulted in an apparent increase in substrate adhesiveness, a decrease in the ability to grow in soft agar, and suppression of their capacity to develop tumors after injection into syngeneic hosts or nude mice. These results suggest that vinculin, a cytoplasmic component of cell-matrix and cell-cell adhesions, may have a major suppressive effect on the transformed phenotype.     

Integrin-mediated adhesion regulates membrane order

The properties of cholesterol-dependent domains (lipid rafts) in cell membranes have been controversial. Because integrin-mediated cell adhesion and caveolin both regulate trafficking of raft components, we investigated the effects of adhesion and caveolin on membrane order. The fluorescent probe Laurdan and two-photon microscopy revealed that focal adhesions are highly ordered; in fact, they are more ordered than caveolae or domains that stain with cholera toxin subunit B (CtxB). Membrane order at focal adhesion depends partly on phosphorylation of caveolin1 at Tyr14, which localizes to focal adhesions. Detachment of cells from the substratum triggers a rapid, caveolin-independent decrease in membrane order, followed by a slower, caveolin-dependent decrease that correlates with internalization of CtxB-stained domains. Endocytosed CtxB domains also become more fluid. Thus, membrane order is highly dependent on caveolae and focal adhesions. These results show that lipid raft properties are conferred by assembly of specific protein complexes. The ordered state within focal adhesions may have important consequences for signaling at these sites.     

Paxillin: a new vinculin-binding protein present in focal adhesions

The 68-kD protein (paxillin) is a cytoskeletal component that localizes to the focal adhesions at the ends of actin stress fibers in chicken embryo fibroblasts. It is also present in the focal adhesions of Madin-Darby bovine kidney (MDBK) epithelial cells but is absent, like talin, from the cell-cell adherens junctions of these cells. Paxillin purified from chicken gizzard smooth muscle migrates as a diffuse band on SDS-PAGE gels with a molecular mass of 65-70 kD. It is a protein of multiple isoforms with pIs ranging from 6.31 to 6.85. Using purified paxillin, we have demonstrated a specific interaction in vitro with another focal adhesion protein, vinculin. Cleavage of vinculin with Staphylococcus aureus V8 protease results in the generation of two fragments of approximately 85 and 27 kD. Unlike talin, which binds to the large vinculin fragment, paxillin was found to bind to the small vinculin fragment, which represents the rod domain of the molecule. Together with the previous observation that paxillin is a major substrate of pp60src in Rous sarcoma virus-transformed cells (Glenney, J. R., and L. Zokas. 1989. J. Cell Biol. 108:2401-2408), this interaction with vinculin suggests paxillin may be a key component in the control of focal adhesion organization.     

Force and focal adhesion assembly: a close relationship studied using elastic micropatterned substrates

Mechanical forces play a major role in the regulation of cell adhesion and cytoskeletal organization. In order to explore the molecular mechanism underlying this regulation, we have investigated the relationship between local force applied by the cell to the substrate and the assembly of focal adhesions. A novel approach was developed for real-time, high-resolution measurements of forces applied by cells at single adhesion sites. This method combines micropatterning of elastomer substrates and fluorescence imaging of focal adhesions in live cells expressing GFP-tagged vinculin. Local forces are correlated with the orientation, total fluorescence intensity and area of the focal adhesions, indicating a constant stress of 5.5 +/- 2 nNmicrom(-2). The dynamics of the force-dependent modulation of focal adhesions were characterized by blocking actomyosin contractility and were found to be on a time scale of seconds. The results put clear constraints on the possible molecular mechanisms for the mechanosensory response of focal adhesions to applied force.     

Embryonal carcinoma cell adhesion: the role of surface galactosyltransferase and its 90K lactosaminoglycan substrate

Embryonal carcinoma (EC) cells possess a complex cell surface glycoconjugate called lactosaminoglycan, whose core structure is composed of repeating N-acetyllactosamine (Gal leads to GlcNAc) disaccharides. Recent studies suggest that the cell surface receptor for lactosaminoglycan is galactosyltransferase, which binds terminal GlcNAc residues on various side chains, thus anchoring the glycoconjugate to the cell surface (Shur, B. D. (1982). J. Biol. Chem. 257, 6871-6878.). The results described in this paper suggest that multivalent lactosaminoglycans mediate EC cell adhesions by binding to their surface galactosyltransferase receptors. In the presence of UDPgalactose, but not other sugar nucleotides, EC cell adhesion is reduced and preformed cell adhesions are dissociated. UDPgalactose interferes with EC cell adhesion by forcing the galactosyltransferase reaction to completion, thus dissociating the enzyme from its galactosylated substrate (i.e., lactosaminoglycan), and thereby dissociating EC cells from one another. Lactosaminoglycans purified from EC cell cultures rapidly agglutinate EC cells, and EC cells preferentially adhere to substrates irreversibly derivatized with protein- and lipid-free lactosaminoglycan side chains. Under identical conditions, EC cells do not adhere to either hyaluronate- or chondroitin sulfate-derivatized substrates, relative to underivatized control surfaces. EC cell adhesion to other cells and to lactosaminoglycan-derivatized surfaces can be inhibited by reagents that selectively interfere with surface galactosyltransferase activity. First, alpha-lactalbumin specifically reduces the galactosyltransferase's affinity for its lactosaminoglycan substrate and simultaneously inhibits adhesion. Similar levels of bovine serum albumin have no effect. Second, selective inhibition of surface galactosyltransferase with UDP-dialdehyde also inhibits adhesion, while similar levels of AMP-dialdehyde do not. Results show that 1 mM Ca2+ protects the surface galactosyltransferase activity from proteolysis, which suggests the galactosyltransferase is one of the Ca2+-dependent EC cell adhesion molecules. SDS-PAGE fluorography and gel chromatography analyses have determined that the principal lactosaminoglycan substrate for EC surface galactosyltransferase has an apparent molecular weight of 90K. Taken together, these results suggest that lactosaminoglycans participate in EC cell adhesion by binding to their surface galactosyltransferase receptors.