Affinity of integrins for damaged extracellular matrix: alpha v beta 3 binds to denatured collagen type I through RGD sites.

Cellular adhesion receptors termed integrins play an important role in the interaction of cells with extracellular matrix (ECM) during wound healing, development and tumorigenesis. During such events, ECM may become modified or damaged which could alter the types of adhesive signals presented to cells. In this study, cell adhesion and affinity chromatography experiments were performed to determine whether different integrins interact with denatured versus native ECM molecules. Human melanoma cells were found to adhere to denatured versus native type I collagen through different integrins. The cells adhere to denatured collagen through the alpha v beta 3 integrin and this interaction is inhibited by an RGD containing peptide but not by a control peptide. In contrast, adhesion to native type I collagen appears to be mediated by several beta 1 integrins and thus, is not inhibited by either alpha v beta 3 antibodies or the RGD peptide. Affinity chromatography reveals a marked increase in the quantity of alpha v beta 3 isolated on denatured collagen versus native collagen-sepharose. These results suggest that RGD sites in type I collagen may be masked and that they become exposed upon denaturation of the molecule. Wounding of extracellular matrix may, thus, expose RGD sites in collagens that facilitate the interaction of cells with damaged extracellular matrix through RGD binding integrins.     

Integrins

Integrins are cell adhesion receptors that are evolutionary old and that play important roles during developmental and pathological processes. The integrin family is composed of 24 αβ heterodimeric members that mediate the attachment of cells to the extracellular matrix (ECM) but that also take part in specialized cell-cell interactions. Only a subset of integrins (8 out of 24) recognizes the RGD sequence in the native ligands. In some ECM molecules, such as collagen and certain laminin isoforms, the RGD sequences are exposed upon denaturation or proteolytic cleavage, allowing cells to bind these ligands by using RGD-binding receptors. Proteolytic cleavage of ECM proteins might also generate fragments with novel biological activity such as endostatin, tumstatin, and endorepellin. Nine integrin chains contain an αI domain, including the collagen-binding integrins α1β1, α2β1, α10β1, and α11β1. The collagen-binding integrins recognize the triple-helical GFOGER sequence in the major collagens, but their ability to recognize these sequences in vivo is dependent on the fibrillar status and accessibility of the interactive domains in the fibrillar collagens. The current review summarizes some basic facts about the integrin family including a historical perspective, their structure, and their ligand-binding properties.     

Neurite outgrowth,RGD-dependent,and RGD-independent adhesion of identified molluscan motoneurons on selected substrates

The extracellular matrix (ECM) provides structural support to cells and tissues and is involved in the regulation of various essential physiological processes, including neurite outgrowth. Most of the adhesive interactions between cells and ECM proteins are mediated by integrins. Integrins typically recognize short linear amino acid sequences in ECM proteins, one of the most common being Arginine-Glycine-Aspartate (RGD). The present study investigated neurite outgrowth and adhesion of identified molluscan neurons on a selection of substrates in vitro. Involvement of RGD binding sites in adhesion to the different substrates was investigated using soluble synthetic RGD peptides. The cells adhered to native (i.e., nondenatured) laminin and type IV collagen, but not to native plasma fibronectin. Denaturation of fibronectin dramatically enhanced cell adhesion. Only the adhesion to denatured fibronectin was inhibited by RGD peptides, indicating that denaturation uncovers a RGD binding site in the protein. Laminin as well as denatured fibronectin, but not type IV collagen, induced neurite outgrowth from a percentage of the RPA neurons. These results demonstrate that molluscan neurons can attach to various substrates using both RGD-dependent and RGD-independent adhesion mechanisms. This suggests that at least two different cell adhesion receptors, possibly belonging to the integrin family, are expressed in these neurons. Moreover, the results show that vertebrate ECM proteins can induce outgrowth from these neurons, suggesting that the mechanisms involved in adhesion as well as outgrowth promoting are evolutionarily well conserved. © 1998 John Wiley & Sons, Inc. J Neurobiol 35: 37–52, 1998     

Discoidin Domain Receptors Promote α1β1- and α2β1-Integrin Mediated Cell Adhesion to Collagen by Enhancing Integrin Activation

The discoidin domain receptors, DDR1 and DDR2, are receptor tyrosine kinases that bind to and are activated by collagens. Similar to collagen-binding β1 integrins, the DDRs bind to specific motifs within the collagen triple helix. However, these two types of collagen receptors recognize distinct collagen sequences. While GVMGFO (O is hydroxyproline) functions as a major DDR binding motif in fibrillar collagens, integrins bind to sequences containing Gxx’GEx”. The DDRs are thought to regulate cell adhesion, but their roles have hitherto only been studied indirectly. In this study we used synthetic triple-helical collagen-derived peptides that incorporate either the DDR-selective GVMGFO motif or integrin-selective motifs, such as GxOGER and GLOGEN, in order to selectively target either type of receptor and resolve their contributions to cell adhesion. Our data using HEK293 cells show that while cell adhesion to collagen I was completely inhibited by anti-integrin blocking antibodies, the DDRs could mediate cell attachment to the GVMGFO motif in an integrin-independent manner. Cell binding to GVMGFO was independent of DDR receptor signalling and occurred with limited cell spreading, indicating that the DDRs do not mediate firm adhesion. However, blocking the interaction of DDR-expressing cells with collagen I via the GVMGFO site diminished cell adhesion, suggesting that the DDRs positively modulate integrin-mediated cell adhesion. Indeed, overexpression of the DDRs or activation of the DDRs by the GVMGFO ligand promoted α1β1 and α2β1 integrin-mediated cell adhesion to medium- and low-affinity integrin ligands without regulating the cell surface expression levels of α1β1 or α2β1. Our data thus demonstrate an adhesion-promoting role of the DDRs, whereby overexpression and/or activation of the DDRs leads to enhanced integrin-mediated cell adhesion as a result of higher integrin activation state.     

Cell attachment properties of collagen type VI and arg-gly-asp dependent binding to its α2(VI) and α3(VI) chains

Twelve of sixteen different cell types including fibroblasts and tumor cells were able to attach and spread on substrates of pepsin-solubilized or intact collagen VI, and on its triple helical domain. Attachment and spreading were independent of soluble mediator proteins (fibronectin, laminin) and collagen VI was distinct from collagens I, IV and V in the cells with which it interacted. Many of the same cells bound and spread on substrates prepared from unfolded α2(VI) and α3(VI) chains but not on the α1(VI) chain. The interactions with the chains were inhibited by low concentrations (10–100 μM) of synthetic RGDS and RGDT but not RGES peptides while the binding of cells to pepsin-solubilized collagen VI was more than 20-fold less sensitive to these peptides. The data incidate that cells have the ability to bind to collagen VI in a specific manner suggesting a similar function for collagen VI in situ.     

Amino-acid sequence and cell-adhesion activity of a fibril-forming collagen from the tube worm Riftia pachyptila living at deep sea hydrothermal vents.

We have determined the amino acid sequence of the alpha chain of a fibril-forming collagen from the body wall of the marine invertebrate Riftia pachyptila (vestimentifera) by Edman degradation. The pepsin-solubilized collagen chain consists of a 1011-residue triple-helical domain and short remnants of N- and C-telopeptides. The triple-helical sequence showed one imperfection of the collagen Gly-Xaa-Yaa triplet repeat structure due to a Gly-->Ala substitution. This imperfection is correlated to a prominent kink in the molecule observed by electron microscopy. No strong sequence similarity was found with the fibril-forming vertebrate collagen types I-III, V and XI except for the invariant Gly residues. However, one of the two consensus cross-linking sequences was well conserved. The Riftia collagen shared with the vertebrate collagens many post-translational modifications. About 50% of the Pro and Lys residues are found in the Yaa position and were extensively hydroxylated to 4-hydroxyproline (4Hyp) and hydroxylysine (Hyl). A few proline residues in Xaa position were partially hydroxylated to either 4Hyp or 3Hyp. Despite the low sequence similarity, Riftia collagen was a potent adhesion substrate for two human cell lines. Cell adhesion could be inhibited by antibodies against the integrin beta 1 subunit but not by RGD peptides. This biological activity is apparently conserved in fibril-forming collagens of distantly related species but does not require the two RGD sequences present in Riftia collagen.     

Adhesion and Activation of Human Neutrophils onto Collagen Chains Separated by Electrophoresis

After separation of the various α chains of the collagens by SDS-PAGE, the binding of polymorphonuclear neutrophils (PMN) to these chains was detected by a double-antibody technique and the activation of PMN by nitro blue tetrazolium. All of the α chains tested were able to bind PMNs. The α1 chain of type I collagen activated the PMN when it had not been treated with pepsin. Pepsinized types II and VI collagens did not activate PMN. The pepsinized α1 (III) chains and all three α chains from pepsinized type V collagen were able to activate PMN.     

Platelet-reactive sites in collagens type I and type III. Evidence for separate adhesion and aggregatory sites.

The adhesion of human and rabbit platelets to collagens and collagen-derived fragments immobilized on plastic was investigated. Adhesion appeared to be independent of collagen conformation, since similar attachment occurred to collagen (type I) in monomeric form, as fibres or in denatured state. The adhesion of human platelets was stimulated to a variable degree by Mg2+, but rabbit platelet adhesion showed little if any dependence on this cation. Collagens type I, III, V and VI were all able to support adhesion, although that to collagen type V (native) was lower than that to the other collagens. Adhesion to a series of peptides derived from collagens I and III was measured. Attachment did not require the presence of peptides in triple-helical configuration. The extent of adhesion ranged from relatively high, as good as to the intact parent collagen molecule, to little if any adhesive activity beyond the non-specific (background) level. The existence of very different degrees of activity suggests that platelet adhesion is associated with specific structural sites in the collagen molecule. Adhesion in many instances was essentially in accord with the known platelet-aggregatory activity of individual peptides. However, two peptides, alpha 1(I)CB3 and alpha 1(III)CB1,8,10,2, exhibited good adhesive activity although possessing little if any aggregatory activity. Of particular interest, despite its near-total lack of aggregatory activity, adhesion to peptide alpha 1(I)CB3 was as good as that to the structurally homologous peptide alpha 1(III)CB4, in which is located a highly reactive aggregatory site. This implies that platelet adhesion to collagen may involve sites in the collagen molecule distinct from those more directly associated with aggregation.     

An Activating Mutation Reveals a Second Binding Mode of the Integrin α2 I Domain to the GFOGER Motif in Collagens

The GFOGER motif in collagens (O denotes hydroxyproline) represents a high-affinity binding site for all collagen-binding integrins. Other GxOGER motifs require integrin activation for maximal binding. The E318W mutant of the integrin α2β1 I domain displays a relaxed collagen specificity, typical of an active state. E318W binds more strongly than the wild-type α2 I domain to GMOGER, and forms a 2:1 complex with a homotrimeric, collagen-like, GFOGER peptide. Crystal structure analysis of this complex reveals two E318W I domains, A and B, bound to a single triple helix. The E318W I domains are virtually identical to the collagen-bound wild-type I domain, suggesting that the E318W mutation activates the I domain by destabilising the unligated conformation. E318W I domain A interacts with two collagen chains similarly to wild-type I domain (high-affinity mode). E318W I domain B makes favourable interactions with only one collagen chain (low-affinity mode). This observation suggests that single GxOGER motifs in the heterotrimeric collagens V and IX may support binding of activated integrins.     

Glucosylation of galactosylhydroxylysyl residues in collagen in vitro by collagen glucosyltransferase. Inhibition by triple-helical conformation of the substrate.

Glucosylation of galactosylhydroxylysyl residues in various collagen polypeptide chains and in small peptides prepared from collagen was studied in vitro using collagen glucosyltransferase purified about 200 to 500-fold from extract prepared from chick embryos. When various denatured polypeptide or peptide chains were compared as substrates for the enzyme, no significant differences were found between citrate-soluble collagens from normal or lathyritic rats and isolated alpha1 and alpha2 chains. In contrast, gelatinized insoluble calf skin collagen, and peptides prepared from collagen and having an average molecular weight of about 500 were clearly less effective substrates as judged from their Km and V values. A marked difference was found between native and heat-denatured citrate-soluble collagen in that no synthesis of glucosylgalactosylhydroxylysine was observed with the native collagen when the reaction was studied at 30 degrees C with different times, enzyme concentrations, and substrate concentrations. When the reaction was studied as a function of temperature, little glucosylation of native collagen was observed below 37 degrees C, but there was a sharp transition in the rate of glucosylation of native collagen at temperatures above 37 degrees C, similar to that observable in the melting curve of collagen. The data suggest that triple-helical conformation of collagen prevents that glucosylation of galactosylhydroxylysyl residues.     

Synthetic heterotrimeric collagen peptides as mimics of cell adhesion sites of the basement membrane

Collagen type IV forms a network in the basement membrane into which other constituents of the tissue are incorporated. It also provides cell-adhesion sites that are specifically recognized by cell-surface receptors, i.e., the integrins. Different from the ubiquitous sequential RGD adhesion motif found in most of the matrix proteins, in collagen type IV, the responsible binding sites for alpha1beta1 integrin have been identified as Asp461 of the two alpha1 chains and Arg461 of the alpha2 chain. Because of the heterotrimeric character of this collagen, the spatial geometry of the binding epitope depends not only on the triple-helical fold, but decisively even on the stagger of the chains. To investigate the effects of chain registration on the conformational properties and binding affinities of this adhesion epitope, two synthetic heterotrimeric collagen peptides consisting of the identical three chains were assembled by an artificial cystine knot in two different registers, i.e., in the most plausible alpha2alpha1alpha1' and less probable alpha1alpha2alpha1' chain alignment. A detailed conformational characterization of both trimers allowed to correlate their different binding affinities for alpha1beta1 integrin with the degree of local plasticity of the two different triple helices. Optimal local breathing of the rod-shaped collagens is apparently crucial for selective recognition by proteins interacting with these main components of the extracellular matrix.     

Glycosylation Modulates Melanoma Cell α2β1 and α3β1 Integrin Interactions with Type IV Collagen

Although type IV collagen is heavily glycosylated, the influence of this post-translational modification on integrin binding has not been investigated. In the present study, galactosylated and nongalactosylated triple-helical peptides have been constructed containing the α1(IV)382–393 and α1(IV)531–543 sequences, which are binding sites for the α2β1 and α3β1 integrins, respectively. All peptides had triple-helical stabilities of 37 °C or greater. The galactosylation of Hyl³⁹³ in α1(IV)382–393 and Hyl⁵⁴⁰ and Hyl⁵⁴³ in α1(IV)531–543 had a dose-dependent influence on melanoma cell adhesion that was much more pronounced in the case of α3β1 integrin binding. Molecular modeling indicated that galactosylation occurred on the periphery of α2β1 integrin interaction with α1(IV)382–393 but right in the middle of α3β1 integrin interaction with α1(IV)531–543. The possibility of extracellular deglycosylation of type IV collagen was investigated, but no β-galactosidase-like activity capable of collagen modification was found. Thus, glycosylation of collagen can modulate integrin binding, and levels of glycosylation could be altered by reduction in expression of glycosylation enzymes but most likely not by extracellular deglycosylation activity.     

Regulation of Tenascin-C, a Vascular Smooth Muscle Cell Survival Factor that Interacts with the αvβ3 Integrin to Promote Epidermal Growth Factor Receptor Phosphorylation and Growth

Tenascin-C (TN-C) is induced in pulmonary vascular disease, where it colocalizes with proliferating smooth muscle cells (SMCs) and epidermal growth factor (EGF). Furthermore, cultured SMCs require TN-C for EGF-dependent growth on type I collagen. In this study, we explore the regulation and function of TN-C in SMCs. We show that a matix metalloproteinase (MMP) inhibitor (GM6001) suppresses SMC TN-C expression on native collagen, whereas denatured collagen promotes TN-C expression in a β3 integrin– dependent manner, independent of MMPs. Floating type I collagen gel also suppresses SMC MMP activity and TN-C protein synthesis and induces apoptosis, in the presence of EGF. Addition of exogenous TN-C to SMCs on floating collagen, or to SMCs treated with GM6001, restores the EGF growth response and “rescues” cells from apoptosis. The mechanism by which TN-C facilitates EGF-dependent survival and growth was then investigated. We show that TN-C interactions with α_vβ₃ integrins modify SMC shape, and EGF- dependent growth. These features are associated with redistribution of filamentous actin to focal adhesion complexes, which colocalize with clusters of EGF-Rs, tyrosine-phosphorylated proteins, and increased activation of EGF-Rs after addition of EGF. Cross-linking SMC β₃ integrins replicates the effect of TN-C on EGF-R clustering and tyrosine phosphorylation. Together, these studies represent a functional paradigm for ECM-dependent cell survival whereby MMPs upregulate TN-C by generating β₃ integrin ligands in type I collagen. In turn, α_vβ₃ interactions with TN-C alter SMC shape and increase EGF-R clustering and EGF-dependent growth. Conversely, suppression of MMPs downregulates TN-C and induces apoptosis.     

The cell adhesion domain of type XVII collagen promotes integrin-mediated cell spreading by a novel mechanism

Type XVII collagen (BP180) is a keratinocyte transmembrane protein that exists as the full-length protein in hemidesmosomes and as a 120-kDa shed ectodomain in the extracellular matrix. The largest collagenous domain of type XVII collagen, COL15, has been described previously as a cell adhesion domain (Tasanen, K., Eble, J. A., Aumailley, M., Schumann, H., Baetge, J, Tu, H., Bruckner, P., and Bruckner-Tuderman, L. (2000) J. Biol. Chem. 275, 3093-3099). In the present work, the integrin binding of triple helical, human recombinant COL15 was tested. Solid phase binding assays using recombinant integrin alpha(1)I, alpha(2)I, and alpha(10)I domains and cell spreading assays with alpha(1)beta(1)- and alpha(2)beta(1)-expressing Chinese hamster ovary cells showed that, unlike other collagens, COL15 was not recognized by the collagen receptors. Denaturation of the COL15 domain increased the spreading of human HaCaT keratinocytes, which could migrate on the denatured COL15 domain as effectively as on fibronectin. Spreading of HaCaT cells on the COL15 domain was mediated by alpha(5)beta(1) and alpha(V)beta(1) integrins, and it could be blocked by RGD peptides. The collagen alpha-chains in the COL15 domain do not contain RGD motifs but, instead, contain 12 closely related KGD motifs, four in each of the three alpha-chains. Twenty-two overlapping, synthetic peptides corresponding to the entire COL15 domain were tested; three peptides, all containing the KGD motif, inhibited the spreading of HaCaT cells on denatured COL15 domain. Furthermore, this effect was lost by mutation from D to E (KGE instead of KGD). We suggest that the COL15 domain of type XVII collagen represents a specific collagenous structure, unable to interact with the cellular receptors for other collagens. After being shed from the cell surface, it may support keratinocyte spreading and migration.     

Interaction of calf skin collagen with glycerol: linked function analysis

Glycerol stabilizes the triple-helical structure of solubilized calf skin collagen. The equilibrium melting temperature of the protein increased linearly from 38.0 degrees C in AS buffer (0.01 M NaOAc and 0.02 M NaCl, pH 4.0) to 43.0 degrees C in AS and 6 M glycerol buffer. To understand the thermodynamic basis of this effect on the equilibrium melting temperature and the glycerol inhibition of collagen self-association, the preferential interactions of native and denatured calf skin collagens in AS buffer containing 1.5, 3, and 4.5 M glycerol were measured with a precision densimeter. The results indicated that native collagen binds glycerol preferentially whereas denatured collagen neither binds nor repels glycerol. The preferential binding of glycerol by native collagen, when interpreted in terms of the three-component solution thermodynamics, suggests that the surface interaction of native collagen with glycerol is energetically more favorable than its interaction with water. By use of the Wyman linked function, the negative chemical potential change of collagen derived from its preferential binding of glycerol can account for both the glycerol stabilization of the triple-helical structure of collagen and the inhibition of in vitro self-association of monomers into fibrils.     

α2β1 Integrin Mediates Dermal Fibroblast Attachment to Type VII Collagen via a 158-Amino-Acid Segment of the NC1 Domain

Dermal fibroblasts are in apposition to type VII (anchoring fibril) collagen in both unwounded and wounded skin. The NC1 domain of type VII collagen contains multiple submodules with homology to known adhesive molecules, including fibronectin type III-like repeats and a potential RGD cell attachment site. We previously reported the structure and matrix binding properties of authentic and recombinant NC1. In this study, we examined the interaction between dermal fibroblasts and the NC1 domain of type VII collagen. We found that both recombinant and authentic NC1 vigorously promoted human fibroblast attachment. Adhesion of fibroblasts to NC1 was dose dependent, saturable, and abolished by both polyclonal and monoclonal antibodies to NC1. Cell adhesion to NC1 was divalent cation dependent and specifically inhibited by a monoclonal antibody directed against the α2 or β1 integrin subunits, but not by the presence of RGD peptides. Furthermore, the cell-binding activity of NC1 was not conformation dependent, since heat-denatured NC1 still promoted cell adhesion. Using a series of recombinant NC1 deletion mutant proteins, the cell binding site of NC1 was mapped to a 158-aa (residues 202–360) subdomain. We conclude that human dermal fibroblasts interact with the NC1 domain of type VII collagen and this cell–matrix interaction is mediated by the α2β1 integrin and is RGD independent.     

The mesenchymal α11β1 integrin attenuates PDGF-BB-stimulated chemotaxis of embryonic fibroblasts on collagens

α11β1 constitutes the most recent addition to the integrin family and has been shown to display a binding preference for interstitial collagens found in mesenchymal tissues. We have previously observed that when α11β1 integrin is expressed in cells lacking endogenous collagen receptors, it can mediate PDGF-BB-dependent chemotaxis on collagen I in vitro. To determine in which cells PDGF and α11β1 might cooperate in regulating cell migration in vivo, we studied in detail the expression and distribution of α11 integrin chain in mouse embryos and tested the ability of PDGF isoforms to stimulate the α11β1-mediated cell migration of embryonic fibroblasts.Full-length mouse α11 cDNA was sequenced and antibodies were raised to deduced α11 integrin amino acid sequence. In the embryonic mouse head, α11 protein and RNA were localized to ectomesenchymally derived cells. In the periodontal ligament, α11β1 was expressed as the only detectable collagen-binding integrin, and α11β1 is thus a major receptor for cell migration and matrix organization in this cell population. In the remainder of the embryo, the α11 chain was expressed in a subset of mesenchymal cells including tendon/ligament fibroblasts, perichondrial cells, and intestinal villi fibroblasts. Most of the α11-expressing cells also expressed the α2 integrin chain, but no detectable overlap was found with the α1 integrin chain. In cells expressing multiple collagen receptors, these might function to promote a more stable cell adhesion and render the cells more resistant to chemotactic stimuli.Wild-type embryonic fibroblasts activated mainly the PDGF β receptor in response to PDGF-BB and migrated on collagens I, II, III, IV, V, and XI in response to PDGF-BB in vitro, whereas mutant fibroblasts that lacked α11β1 in their collagen receptor repertoire showed a stronger chemotactic response on collagens when stimulated with PDGF-BB. In the cellular context of embryonic fibroblasts, α11β1 is thus anti-migratory.We speculate that the PDGF BB-dependent cell migration of mesenchymal cells is tightly regulated by the collagen receptor repertoire, and disturbances of this repertoire might lead to unregulated cell migration that could affect normal embryonic development and tissue structure.     

Effects of Collagen IV on Neuroblastoma Cell Matrix-Related Functions

Integrin-mediated interactions with collagen IV and its domains were examined in a human neuroblastoma cell line (SK-N-SH). By adhesion assays we demonstrated that neuroblastoma cells bound to solid-phase intact collagen IV and synthetic cell-binding peptide HEP-III, derived from the collagenous part of the molecule, but not to the main noncollagenous NC1 domain or to the synthetic cell-binding peptide HEP-I, derived from this domain. Monoclonal antibodies against β1, α3, and αvβ3 integrins resulted in inhibition of cell binding to collagenous substrates by 95, 30, and 35%, respectively. By flow cytometry and immunoblotting it was shown that culture of SK-N-SH cells on collagen IV resulted in alteration in the expression of major neuroblastoma cell integrins. Binding to collagen IV induced the expression and activation of matrix metalloproteinases A and B (MMP-2, MMP-9), with a concomitant increase at the protein level of tissue-specific inhibitors of metalloproteinases (TIMP-1, TIMP-2). Finally, the expression of MMP-2 was significantly up-regulated by anti-α3β1 antibodies, whereas ligation of anti-αvβ3 antibodies resulted in a modest down-regulation of MMP-2. Our results indicate that the presence of collagen IV modulates the expression of integrins, which are used for binding to this glycoprotein, and MMP-2 secreted by SK-N-SH cells.     

The integrins

The integrins are a superfamily of cell adhesion receptors that bind to extracellular matrix ligands, cell-surface ligands, and soluble ligands. They are transmembrane αβ heterodimers and at least 18 α and eight β subunits are known in humans, generating 24 heterodimers. Members of this family have been found in mammals, chicken and zebrafish, as well as lower eukaryotes, including sponges, the nematode Caenorhabditis elegans (two α and one β subunits, generating two integrins) and the fruitfly Drosophila melanogaster (five α and one β, generating five integrins). The α and β subunits have distinct domain structures, with extracellular domains from each subunit contributing to the ligand-binding site of the heterodimer. The sequence arginine-glycine-aspartic acid (RGD) was identified as a general integrin-binding motif, but individual integrins are also specific for particular protein ligands. Immunologically important integrin ligands are the intercellular adhesion molecules (ICAMs), immunoglobulin superfamily members present on inflamed endothelium and antigen-presenting cells. On ligand binding, integrins transduce signals into the cell interior; they can also receive intracellular signals that regulate their ligand-binding affinity. Here we provide a brief overview that concentrates mostly on the organization, structure and function of mammalian integrins, which have been more extensively studied than integrins in other organisms.