Detection of constitutive homomeric associations of the integrins Mac-1 subunits by fluorescence resonance energy transfer in living cells

Integrins alpha(M)beta(2) plays important role on leukocytes, such as adhesion, migration, phagocytosis, and apoptosis. It was hypothesized that homomeric associations of integrin subunits provide a driving force for integrins activation, and simultaneously inducing the formation of integrins clusters. However, experimental reports on homomeric associations between integrin subunits are still controversial. Here, we proved the homomeric associations of the isolated Mac-1 subunits in living cells using three-channel fluorescence resonance energy transfer (FRET) microscopy and FRET spectra methods. We found that the extent of homomeric associations between beta(2) subunits is higher than alpha(M) subunits. Furthermore, FRET imaging indicated that the extent of homomeric associations of the Mac-1 subunits is higher along the plasma membrane than in the cytoplasm. Finally, we suggested that homomeric associations of the transmembrane domains or/and cytoplasmic domains may provide the driving force for the formation of constitutive homomeric associations between alpha(M) or beta(2) subunits.     

Purification and characterization of mammalian integrins expressed by a rat neuronal cell line (PC12): evidence that they function as alpha/beta heterodimeric receptors for laminin and type IV collagen

Cells of the rat neuronal line, PC12, adhere well to substrates coated with laminin and type IV collagen, but attach poorly to fibronectin. Adhesion and neurite extension in response to these extracellular matrix proteins are inhibited by Fab fragments of an antiserum (anti-ECMR) that recognizes PC12 cell surface integrin subunits of Mr 120,000, 140,000, and 180,000 (Tomaselli, K. J., C. H. Damsky, and L. F. Reichardt. 1987. J. Cell Biol. 105:2347-2358). Here we extend our study of integrin structure and function in PC12 cells using integrin subunit-specific antibodies prepared against synthetic peptides corresponding to the cytoplasmic domains of the human integrin beta 1 and the fibronectin receptor alpha (alpha FN) subunits. Anti-integrin beta 1 immunoprecipitated a 120-kD beta 1 subunit and two noncovalently associated integrin alpha subunits of 140 and 180 kD from detergent extracts of surface-labeled PC12 cells. Immunodepletion studies using anti-integrin beta 1 demonstrated that these two putative alpha/beta heterodimers are identical to those recognized by the adhesion-perturbing ECMR antiserum. Anti-alpha FN immunoprecipitated fibronectin receptor heterodimers in human and rat fibroblastic cells, but not in PC12 cells. Thus, low levels of expression of the integrin alpha FN subunit can explain the poor attachment of PC12 cells to FN. The PC12 cell integrins were purified using a combination of lectin and ECMR antibody affinity chromatography. The purified integrins: (a) completely neutralize the ability of the anti-ECMR serum to inhibit PC12 cell adhesion to laminin and collagen IV; (b) have hydrodynamic properties that are very similar to those of previously characterized integrin alpha/beta heterodimeric receptors for ECM proteins; and (c) can be incorporated into phosphatidylcholine vesicles that then bind specifically to substrates coated with laminin or collagen IV but not fibronectin. Thus, the ligand-binding specificity of the liposomes containing the purified PC12 integrins closely parallels the substrate-binding preference of intact PC12 cells. These results demonstrate that mammalian integrins purified from a neuronal cell line can, when incorporated into lipid vesicles, function as receptors for laminin and type IV collagen.     

Cytoplasmic and transmembrane domains of integrin beta 1 and beta 3 subunits are functionally interchangeable

Integrin beta subunits combine with specific sets of alpha subunits to form functional adhesion receptors. The structure and binding properties of integrins suggest the presence of domains controlling at least three major functions: subunit association, ligand binding, and cytoskeletal interactions. To more carefully define structure/function relationships, a cDNA construct consisting of the extracellular domain of the avian beta 1 subunit and the cytoplasmic and transmembrane domains of the human beta 3 subunit was prepared and expressed in murine 3T3 cells. The resulting chimeric beta 1/3 subunit formed heterodimers with alpha subunits from the beta 1 subfamily, could not interact with alpha IIb from the beta 3 subfamily, was targeted to focal contacts, and formed functional complexes within the focal contacts. A second cDNA construct was prepared that coded for an avian beta 1 subunit without a transmembrane or cytoplasmic domain. This subunit was not found in association with an accompanying alpha subunit, nor was it found expressed on the cell surface. Instead, it accumulated in vesicles within the cytoplasm and was eventually shed from the cell. The results from studies of the behavior of these two cDNA constructs demonstrate that the transmembrane and cytoplasmic domains play no role in alpha subunit selection, that the cytoplasmic domain of beta 3 is capable of functioning in the context of alpha subunits with which it is not normally paired, and that both integrin subunits must be membrane associated for normal assembly and transport to cell surface adhesive structures.     

Integrin evolution: insights from ascidian and teleost fish genomes.

Integrins are a family of alphabeta heterodimeric receptors essential to cell adhesion in all metazoans. In humans, the family consists of 18 alpha and 8 beta subunits that combine to form 24 dimers. Here, we present phylogenetic reconstructions for the alpha and beta integrin subunits based on sequences from 24 invertebrate and vertebrate species, including the fully sequenced genomes of the ascidian Ciona intestinalis (a urochordate) and the pufferfish Takifugu rubripes (a teleost). Both genomes contain integrin alpha subunits that have the inserted alphaI domain. As for the one alphaI domain containing integrin alpha subunit discovered earlier from the ascidian Halocynthia roretzi, the Ciona alphaI domains are missing the distinctive characteristics of mammalian collagen receptors and segregate from all vertebrate alphaI domain integrins in a phylogenetic tree, forming a new subgroup of alpha subunits with alphaI domains. Each of the pufferfish alphaI domain sequences does have characteristics of the collagen receptor alphaI domains, but no leukocyte-specific alphaI domains were found in pufferfish. Comparative protein modeling suggests that several of these fish alphaI domains are structurally compatible with binding to a GFOGER sequence in a collagen triple helix.     

Selective recruitment of src family kinase Hck by leukocyte integrin alphaMbeta2 but not alphaLbeta2 or alphaXbeta2

Integrins are type I heterodimeric (alpha/beta) cell adhesion molecules. They trigger cell-signaling by recruiting cytosolic molecules to their cytoplasmic tails. Integrin alpha cytoplasmic tail contributes towards integrin function specificity, an important feature of integrins having different alpha subunits but sharing the same beta subunit. Herein, we show that the src family kinase Hck co-capped selectively with leukocyte integrin alpha(M)beta(2) but not alpha(L)beta(2) or alpha(X)beta(2). This was disrupted when the alpha(M) cytoplasmic tail was substituted with that of alpha(L) or alpha(X). Co-capping was recovered by alpha(L) or alpha(X) cytoplasmic tail truncation or forced separation of the alpha and beta cytoplasmic tails via salt-bridge disruption.     

The ability of integrin alpha(v)beta(3) To function as a receptor for foot-and-mouth disease virus is not dependent on the presence of complete subunit cytoplasmic domains

The integrin alpha(v)beta(3) has been shown to function as one of the integrin receptors on cultured cells for foot-and-mouth disease virus (FMDV), and high-efficiency utilization of the bovine homolog of this integrin is dependent on the cysteine-rich repeat region of the bovine beta(3) subunit. In this study we have examined the role of the cytoplasmic domains of the alpha(v) and beta(3) subunits in FMDV infection. We have found that truncations or extensions of these domains of either subunit, including deletions removing almost all of the cytoplasmic domains, had little or no effect on the ability of the integrin to function as a receptor for FMDV. The lysosomotropic agent monensin inhibited viral replication in cells transfected with either intact or cytoplasmic domain-truncated alpha(v)beta(3). In addition, viral replication in transfected cells was inhibited by an alpha(v)beta(3) function-blocking antibody but not by function-blocking antibodies to three other RGD-directed integrins, suggesting that these integrins are not involved in the infectious process. These results indicate that alterations to the cytoplasmic domains of either subunit, which lead to the inability of the integrin receptor to function normally, do not abolish the ability of the integrin to bind and internalize this viral ligand.     

A novel fibronectin receptor with an unexpected subunit composition (alpha v beta 1)

The integrins are a family of heterodimeric cell surface receptors for extracellular matrix molecules. An analysis of integrin subunits expressed by a number of cell lines identified a novel heterodimer. The alpha subunit of this integrin was immunologically and electrophoretically indistinguishable from the vitronectin receptor alpha subunit (alpha v) and the beta subunit was indistinguishable from beta 1. Affinity chromatography experiments and cell adhesion assays indicated that this receptor complex is a new fibronectin receptor. Its unexpected subunit composition demonstrates the importance of the beta subunit in determining the ligand specificity of integrins and suggests that the current integrin classification scheme needs revision.     

Determination of N- and C-terminal borders of the transmembrane domain of integrin subunits

Previous studies on the membrane-cytoplasm interphase of human integrin subunits have shown that a conserved lysine in subunits alpha(2), alpha(5), beta(1), and beta(2) is embedded in the plasma membrane in the absence of interacting proteins (Armulik, A., Nilsson, I., von Heijne, G., and Johansson, S. (1999) in J. Biol. Chem. 274, 37030-37034). Using a glycosylation mapping technique, we here show that alpha(10) and beta(8), two subunits that deviate significantly from the integrin consensus sequences in the membrane-proximal region, were found to have the conserved lysine at a similar position in the lipid bilayer. Thus, this organization at the C-terminal end of the transmembrane (TM) domain seems likely to be general for all 24 integrin subunits. Furthermore, we have determined the N-terminal border of the TM domains of the alpha(2), alpha(5), alpha(10), beta(1), and beta(8) subunits. The TM domain of subunit beta(8) is found to be 22 amino acids long, with a second basic residue (Arg(684)) positioned just inside the membrane at the exoplasmic side, whereas the lipidembedded domains of the other subunits are longer, varying from 25 (alpha(2)) to 29 amino acids (alpha(10)). These numbers implicate that the TM region of the analyzed integrins (except beta(8)) would be tilted or bent in the membrane. Integrin signaling by transmembrane conformational change may involve alteration of the position of the segment adjacent to the conserved lysine. To test the proposed "piston" model for signaling, we forced this region at the C-terminal end of the alpha(5) and beta(1) TM domains out of the membrane into the cytosol by replacing Lys-Leu with Lys-Lys. The mutation was found to not alter the position of the N-terminal end of the TM domain in the membrane, indicating that the TM domain is not moving as a piston. Instead the shift results in a shorter and therefore less tilted or bent TM alpha-helix.     

Transmembrane and cytoplasmic domains in integrin activation and protein-protein interactions (review)

Integrins are heterodimeric membrane-spanning adhesion receptors that are essential for a wide range of biological functions. Control of integrin conformational states is required for bidirectional signalling across the membrane. Key components of this control mechanism are the transmembrane and cytoplasmic domains of the alpha and beta subunits. These domains are believed to interact, holding the integrin in the inactive state, while inside-out integrin activation is accompanied by domain separation. Although there are strong indications for domain interactions, the majority of evidence is insufficient to precisely define the interaction interface. The current best model of the complex, derived from computational calculations with experimental restraints, suggests that integrin activation by the cytoplasmic protein talin is accomplished by steric disruption of the alpha/beta interface. Better atomic-level resolution structures of the alpha/beta transmembrane/cytoplasmic domain complex are still required for the resting state integrin to corroborate this. Integrin activation is also controlled by competitive interactions involving the cytoplasmic domains, particularly the beta-tails. The concept of the beta integrin tail as a focal adhesion interaction 'hub' for interactions and regulation is discussed. Current efforts to define the structure and affinity of the various complexes formed by integrin tails, and how these interactions are controlled, e.g. by phosphorylation and localization, are described.     

Involvement of laminin binding integrins and laminin-5 in branching morphogenesis of the ureteric bud during kidney development.

Branching morphogenesis of the ureteric bud (UB) [induced by the metanephric mesenchyme (MM)] is necessary for normal kidney development. The role of integrins in this complex developmental process is not well understood. However, the recent advent of in vitro model systems to study branching of UB cells and isolated UB tissue makes possible a more detailed analysis of the integrins involved. We detected integrin subunits alpha3, alpha6, beta1, and beta4 in both the UB and cells derived from the early UB. Blocking the function of each of these integrin subunits individually markedly inhibited branching morphogenesis in cell culture models. However, inhibiting individual integrin function with blocking antibodies in whole kidney and isolated UB culture only partially inhibited UB branching morphogenesis, suggesting that, in these more complex in vitro systems, multiple integrins are involved in the branching program. In whole organ and isolated bud culture, marked retardation of UB branching was observed only when both alpha3 and alpha6 integrin subunits were inhibited. The alpha6 integrin subunit can be expressed as both alpha6beta1 and alpha6beta4, and both of these beta subunits are important for UB branching morphogenesis in both cell and organ culture. Furthermore, laminin-5, a common ligand for integrins alpha3beta1 and alpha6beta4, was detected in the developing UB and shown to be required for normal UB branching morphogenesis in whole embryonic kidney organ culture as well as isolated UB culture. Together, these data from UB cell culture, organ culture, and isolated UB culture models indicate that both integrin alpha3 and alpha6 subunits play a direct role in UB branching morphogenesis, as opposed to being modulators of the inductive effects of mesenchyme on UB development. Furthermore the data are consistent with a role for laminin-5, acting through its alpha3beta1 and/or alpha6beta4 integrin receptors, in UB branching during nephrogenesis. These data may help to partially explain the renal phenotype seen in integrin alpha3 and alpha3/alpha6 subunit-deficient animals.     

A computational model of transmembrane integrin clustering

The presented work describes a structural model for integrin homooligomerization, focusing on the transmembrane domains. The two noncovalently linked integrin subunits, alpha and beta, were previously shown to homodimerize or homotrimerize, respectively. Our work is based on published mutational work that induced homotrimerization of beta3 integrins. The mutations provided structural restraints for the creation of a structural model of the beta3 homotrimer by a computational search of the conformational space of homomeric interactions of the beta3 integrin. Additionally, we explored possible conformations of the alphaIIb integrin homodimer, for which no unique solution was found. Two possible models of signal transduction, involving two different alphaIIb conformations, are discussed. One of the possible homodimeric alphaIIb conformations is GpA like, which is in line with experimental evidence. Based on our here-presented structural models and on recent experiments, we will argue that most probably the heteromeric alpha/beta transmembrane complex separates in the course of clustering.     

Regulation of cell adhesion receptors by transforming growth factor-beta. Concomitant regulation of integrins that share a common beta 1 subunit

Cell adhesion to extracellular matrices is mediated by a set of heterodimeric cell surface receptors called integrins that might be the subject of regulation by growth and differentiation factors. We have examined the effect of transforming growth factor-beta 1 (TGF-beta 1) on the expression of the very late antigens or alpha beta 1 group of integrins in human cell lines. The six known members of this family share a common beta 1 subunit but have distinct alpha subunits that confer selective affinity toward type I collagen, fibronectin, laminin, and other as yet unknown cell adhesion proteins. Using a panel of specific antibodies and cDNA probes, we show that in WI-38 lung fibroblasts TGF-beta 1 elevates concomitantly the expression of alpha 1, alpha 2, alpha 3, alpha 5, and beta 1 integrin subunits at the protein and/or mRNA level, their assembly into the corresponding alpha beta 1 complexes, and their exposure on the cell surface. The rate of synthesis of total alpha subunits relative to beta 1 subunit is higher in TGF-beta 1-treated cells than in control cells. The characteristically slow (t1/2 approximately 10 h) rate of beta 1 conversion from precursor form to mature glycoprotein in untreated cells increases markedly (to t1/2 approximately 3 h) in response to TGF-beta 1. The results suggest that in WI-38 fibroblasts the beta 1 subunit is synthesized in excess over alpha subunits, and assembly of beta 1 subunits with rate-limiting alpha subunits is required for transit through the Golgi and exposure of alpha beta 1 complex on the cell surface. TGF-beta 1 does not induce the synthesis of integrin subunits that are not expressed in unstimulated cells, such as alpha 4 and alpha 6 subunits in WI-38 fibroblasts. However, alpha 4 and alpha 6 subunits can be regulated by TGF-beta in those cells that express them. The results suggest that TGF-beta regulates the expression of individual integrin subunits by parallel but independent mechanisms. By modifying the balance of individual alpha beta 1 integrins, TGF-beta 1 might modulate those aspects of cell migration, positioning, and development that are guided by adhesion to extracellular matrices.     

Expression of a soluble functional form of the integrin alpha4beta1 in mammalian cells

The integrin alpha4beta1(VLA4) has been expressed as a soluble, active, heterodimeric immunoglobulin fusion protein. cDNAs encoding the extracellular domains of the human alpha4 and beta1 subunits were fused to the genomic DNA encoding the human gamma1 immunoglobulin Fc domain and functional integrin fusion protein was expressed as a secreted, soluble molecule from a range of mammalian cell lines. Specific mutations were introduced into the Fc region of the molecules to promote alpha4beta1 heterodimer formation. The soluble alpha4beta1-Fc fusion protein exhibited divalent cation dependent binding to VCAM-1, which was blocked by the appropriate function blocking antibodies. The apparent Kd for VCAM-1 binding were similar for both the soluble and native forms of alpha4beta1. In addition, the integrin-Fc fusion was shown to stain cells expressing VCAM-1 on their surface by FACs analysis. This approach for expressing soluble alpha4beta1 should be generally applicable to a range of integrins.     

Urokinase-type plasminogen activator receptor induces conformational changes in the integrin alphaMbeta2 headpiece and reorientation of its transmembrane domains

The glycosylphosphatidylinositol-linked urokinase-type plasminogen activator receptor (uPAR) interacts with the heterodimer cell adhesion molecules integrins to modulate cell adhesion and migration. Devoid of a cytoplasmic domain, uPAR triggers intracellular signaling via its associated molecules that contain cytoplasmic domains. Interestingly, uPAR changes the ectodomain conformation of one of its partner molecules, integrin alpha(5)beta(1), and elicits cytoplasmic signaling. The separation or reorientation of integrin transmembrane domains and cytoplasmic tails are required for integrin outside-in signaling. However, there is a lack of direct evidence showing these conformational changes of an integrin that interacts with uPAR. In this investigation we used reporter monoclonal antibodies and fluorescence resonance energy transfer analyses to show conformational changes in the alpha(M)beta(2) headpiece and reorientation of its transmembrane domains when alpha(M)beta(2) interacts with uPAR.     

Structural requirements of MLD-containing disintegrins for functional interaction with alpha 4 beta 1 and alpha 9 beta1 integrins

Three non-RGD-containing disintegrins, VLO5, EO5, and EC3, belong to the heterodimeric family of these snake venom-derived proteins. They are potent inhibitors of certain leukocyte integrins such as alpha4beta1, alpha4beta7, and alpha9beta1, and act through the MLD motif present in one of their subunits. However, the selectivity of these disintegrins to interact with integrins is related to the amino acid composition of the integrin-binding loop in the MLD-containing subunit. The most important amino acid is that preceding the MLD motif. In vitro experiments in adhesion and ELISA assays revealed that the TMLD-containing disintegrins, VLO5 and EO5, appeared to be very potent inhibitors of human alpha4beta1 and alpha9beta1 and less effective in inhibition of the alpha4beta7 integrin. The reverse effect was observed for the AMLD-containing disintegrin, EC3. The data with native disintegrins were confirmed by experiments with synthetic peptides displaying TMLD and AMLD motifs. The MLD-containing disintegrins showed differential activities to inhibit human and murine alpha4beta1 integrin. EC3 was a weaker inhibitor of human integrin, whereas VLO5 and EO5 less actively inhibited murine alpha4beta1. These data describe a useful set of potent and selective integrin antagonists and suggest conformational requirements of human and mouse integrins for interaction with ligands.     

Association of the membrane proximal regions of the alpha and beta subunit cytoplasmic domains constrains an integrin in the inactive state

The adhesiveness of integrins is regulated through a process termed "inside-out" signaling. To understand the molecular mechanism of integrin inside-out signaling, we generated K562 stable cell lines that expressed LFA-1 (alpha(L)beta(2)) or Mac-1 (alpha(M)beta(2)) with mutations in the cytoplasmic domain. Complete truncation of the beta(2) cytoplasmic domain, but not a truncation that retained the membrane proximal eight residues, resulted in constitutive activation of alpha(L)beta(2) and alpha(M)beta(2), demonstrating the importance of this membrane proximal region in the regulation of integrin adhesive function. Furthermore, replacement of the alpha(L) and beta(2) cytoplasmic domains with acidic and basic peptides that form an alpha-helical coiled coil caused inactivation of alpha(L)beta(2). Association of these artificial cytoplasmic domains was directly demonstrated. By contrast, replacement of the alpha(L) and beta(2) cytoplasmic domains with two basic peptides that do not form an alpha-helical coiled coil activated alpha(L)beta(2). Induction of ligand binding by the activating cytoplasmic domain mutations correlated with the induction of activation epitopes in the extracellular domain. Our data demonstrate that cytoplasmic, membrane proximal association between integrin alpha and beta subunits, constrains an integrin in the inactive conformation.     

Foot-and-mouth disease virus receptors: comparison of bovine alpha(V) integrin utilization by type A and O viruses

Three members of the alpha(V) integrin family of cellular receptors, alpha(V)beta(1), alpha(V)beta(3), and alpha(V)beta(6), have been identified as receptors for foot-and-mouth disease virus (FMDV) in vitro. The virus interacts with these receptors via a highly conserved arginine-glycine-aspartic acid (RGD) amino acid sequence motif located within the betaG-betaH (G-H) loop of VP1. Other alpha(V) integrins, as well as several other integrins, recognize and bind to RGD motifs on their natural ligands and also may be candidate receptors for FMDV. To analyze the roles of the alpha(V) integrins from a susceptible species as viral receptors, we molecularly cloned the bovine beta(1), beta(5), and beta(6) integrin subunits. Using these subunits, along with previously cloned bovine alpha(V) and beta(3) subunits, in a transient expression assay system, we compared the efficiencies of infection mediated by alpha(V)beta(1), alpha(V)beta(3), alpha(V)beta(5), and alpha(V)beta(6) among three strains of FMDV serotype A and two strains of serotype O. While all the viruses could infect cells expressing these integrins, they exhibited different efficiencies of integrin utilization. All the type A viruses used alpha(V)beta(3) and alpha(V)beta(6) with relatively high efficiency, while only one virus utilized alpha(V)beta(1) with moderate efficiency. In contrast, both type O viruses utilized alpha(V)beta(6) and alpha(V)beta(1) with higher efficiency than alpha(V)beta(3). Only low levels of viral replication were detected in alpha(V)beta(5)-expressing cells infected with either serotype. Experiments in which the ligand-binding domains among the beta subunits were exchanged indicated that this region of the integrin subunit appears to contribute to the differences in integrin utilizations among strains. In contrast, the G-H loops of the different viruses do not appear to be involved in this phenomenon. Thus, the ability of the virus to utilize multiple integrins in vitro may be a reflection of the use of multiple receptors during the course of infection within the susceptible host.     

Role of the alpha1 and alpha2 integrin cytoplasmic domains in cell morphology, motility and responsiveness to stimulation by the protein kinase C pathway

The alpha1beta1 and alpha2beta1 integrins, extracellular matrix receptors for collagens and/or laminins, have similarities in structure and ligand binding. Recent studies suggest that the two receptors mediate distinct post-ligand binding events and are not simply redundant receptors. To discern the mechanisms by which the two receptors differ, we focused on the roles of the cytoplasmic domains of the alpha subunits. We expressed either full-length alpha1 integrin subunit cDNA (X1C1), full-length alpha2 integrin subunit cDNA (X2C2), chimeric cDNA composed of the extracellular and transmembrane domains of alpha2 subunit and the cytoplasmic domain of alpha1 (X2C1), chimeric cDNA composed of the extracellular and transmembrane domains of alpha1 subunit and the cytoplasmic domain of alpha2 (X1C2), alpha1 cDNA truncated after the GFFKR sequence (X1C0) or alpha2 cDNA truncated after the GFFKR sequence (X2C0) in K562 cells. Although the cytoplasmic domains of the alpha1 and alpha2 subunits were not required for adhesion, the extent of adhesion at low substrate density was enhanced by the presence of either the alpha1 or alpha2 cytoplasmic tail. Spreading was also influenced by the presence of an alpha subunit cytoplasmic tail. Activation of the protein kinase C pathway with phorbol dibutyrate-stimulated motility that was dependent upon the presence of the alpha2 cytoplasmic tail. Both the phosphatidylinosotide-3-OH kinase and the mitogen-activated protein kinase pathways were required for phorbol-activated, alpha2-cytoplasmic tail-dependent migration.     

Cholesterol alters the interaction of glycosphingolipid GM3 with alpha5beta1 integrin and increases integrin-mediated cell adhesion to fibronectin

Integrins bind to their ligand in the extracellular matrix (ECM), such as fibronectin (FN), through a specific interaction between the amino acid motifs in the ligand, and binding sites in the extracellular domains of the integrin molecule generated jointly by its alpha and beta subunits. It has been proposed that membrane cholesterol and glycosphingolipids (GSLs) can regulate integrin-ECM interactions and it has been demonstrated that increased membrane cholesterol leads to increased cell adhesion to FN. Here, we have shown that a specific glycosphingolipid GM3 binds directly to alpha5beta1 integrin and an increase in membrane cholesterol results in the redistribution of GM3-associated alpha5beta1 integrin molecules specifically on the surface that is in contact with the substratum. Our results suggest that GM3-associated alpha5beta1 integrins bind less avidly to FN than GM3-free integrins and that cholesterol and GM3 play an interdependent role in the distribution of alpha5beta1integrin molecules in the membrane and regulation of cell adhesion.