Disruption of integrin-fibronectin complexes by allosteric but not ligand-mimetic inhibitors.

Failure of Arg-Gly-Asp (RGD)-based inhibitors to reverse integrin-ligand binding has been reported, but the prevalence of this phenomenon among integrin heterodimers is currently unknown. In the present study we have investigated the interaction of four different RGD-binding integrins (α5ß1, αVß1, αVß3 and αVß6) with fibronectin (FN) using surface plasmon resonance. The ability of inhibitors to reverse ligand binding was assessed by their capacity to increase the dissociation rate of pre-formed integrin-FN complexes. For all four receptors we showed that RGD-based inhibitors (such as cilengitide) were completely unable to increase the dissociation rate. Formation of the non-reversible state occurred very rapidly and did not rely on the time-dependent formation of a high-affinity state of the integrin, or the integrin leg regions. In contrast with RGD-based inhibitors, Ca2+ (but not Mg2+) was able to greatly increase the dissociation rate of integrin-FN complexes, with a half-maximal response at ~0.4 mM Ca2+ for αVß3-FN. The effect of Ca2+ was overcome by co-addition of Mn2+, but not Mg2+. A stimulatory anti-ß1 monoclonal antibody (mAb) abrogated the effect of Ca2+ on α5ß1-FN complexes; conversely, a function-blocking mAb mimicked the effect of Ca2+. These results imply that Ca2+ acts allosterically, probably through binding to the adjacent metal-ion-dependent adhesion site (ADMIDAS), and that the α1 helix in the ß subunit I domain is the key element affected by allosteric modulators. The data suggest an explanation for the limited clinical efficacy of RGD-based integrin antagonists, and we propose that allosteric antagonists could prove to be of greater therapeutic benefit.

Distinct biophysical mechanisms of focal adhesion kinase mechanoactivation by different extracellular matrix proteins.

Matrix mechanics controls cell fate by modulating the bonds between integrins and extracellular matrix (ECM) proteins. However, it remains unclear how fibronectin (FN), type 1 collagen, and their receptor integrin subtypes distinctly control force transmission to regulate focal adhesion kinase (FAK) activity, a crucial molecular signal governing cell adhesion/migration. Here we showed, using a genetically encoded FAK biosensor based on fluorescence resonance energy transfer, that FN-mediated FAK activation is dependent on the mechanical tension, which may expose its otherwise hidden FN synergy site to integrin α5. In sharp contrast, the ligation between the constitutively exposed binding motif of type 1 collagen and its receptor integrin α2 was surprisingly tension-independent to induce sufficient FAK activation. Although integrin α subunit determines mechanosensitivity, the ligation between α subunit and the ECM proteins converges at the integrin ß1 activation to induce FAK activation. We further discovered that the interaction of the N-terminal protein 4.1/ezrin/redixin/moesin basic patch with phosphatidylinositol 4,5-biphosphate is crucial during cell adhesion to maintain the FAK activation from the inhibitory effect of nearby protein 4.1/ezrin/redixin/moesin acidic sites. Therefore, different ECM proteins either can transmit or can shield from mechanical forces to regulate cellular functions, with the accessibility of ECM binding motifs by their specific integrin α subunits determining the biophysical mechanisms of FAK activation during mechanotransduction.

Activation of integrin alpha5beta1 delays apoptosis of Ntera2 neuronal cells.

Integrins are dynamic membrane proteins that mediate adhesion of cells to the extracellular matrix. Integrins initiate signal transduction, alone and cooperatively with growth factor receptors, and regulate many aspects of cell behavior. We report here that alpha5beta1-mediated adhesion of Ntera2 neuronal cells to fibronectin decreased apoptosis in response to serum withdrawal. Adhesion induced phosphorylation of FAK, and strongly increased the AKT phosphorylation induced by growth factors, demonstrating for the first time in neuronal cells that integrin-mediated adhesion and growth factors cooperate to regulate AKT activity. Integrins exist on cells in different activation states, and cell survival on fibronectin was enhanced by the antibody 12G10, that modulates the conformation of beta1 in favor of its active form. The antibody 12G10 specifically delayed loss of phosphorylation of AKT on serine 473, and GSK-3beta on serine 9, induced by serum withdrawal, suggesting that these kinases are critical sensors of integrin activation on neuronal cells.

Novel activating and inactivating mutations in the integrin beta1 subunit A domain.

The ligand-binding activity of integrins is regulated by shape changes that convert these receptors from a resting (or inactive) state to an active state. However, the precise conformational changes that take place in head region of integrins (the site of ligand binding) during activation are not well understood. The portion of the integrin beta subunit involved in ligand recognition contains a von Willebrand factor type A domain, which comprises a central beta-sheet surrounded by seven alpha helices (alpha1-alpha7). Using site-directed mutagenesis, we show here that point mutation of hydrophobic residues in the alpha1 and alpha7 helices (which would be predicted to increase the mobility of these helices) markedly increases the ligand-binding activity of both integrins alpha5beta1 and alpha4beta1. In contrast, mutation of a hydrophilic residue near the base of the alpha1 helix decreases activity and also suppresses exposure of activation epitopes on the underlying hybrid domain. Our results provide new evidence that shifts of the alpha1 and alpha7 helices are involved in activation of the A domain. Although these changes are grossly similar to those defined in the A domains found in some integrin alpha subunits, movement of the alpha1 helix appears to play a more prominent role in betaA domain activation.

E-cadherin is a ligand for integrin alpha2beta1.

E-cadherin is a 120-kDa transmembrane glycoprotein expressed mainly on the surface of epithelial cells. The best characterised function of E-cadherin is homotypic, calcium-dependent cell-cell adhesion; however, the observation that E-cadherin is also capable of interacting with the alphaEbeta7 integrin to mediate leukocyte cell-cell adhesion [Nature 372 (1994) 190] suggests that it also participates in heterotypic interactions. To investigate the possibility that E-cadherin may interact with integrins expressed on non-leukocytic cells, cell adhesion and solid-phase receptor-ligand binding experiments were performed using a pentameric E-cadherin construct designed to detect low affinity, high avidity interactions. HT1080 human fibrosarcoma cells specifically adhered to pentameric E-cadherin, and this adhesion was inhibited by anti-functional monoclonal antibodies directed against the integrin alpha2 and beta1 subunits, but not by a series of antibodies recognising other subunits. This suggested that the E-cadherin receptor was alpha2beta1, a previously characterised collagen/laminin receptor. Pentameric E-cadherin, but not monomeric E-cadherin, specifically bound, in a divalent cation-dependent manner, to both purified alpha2beta1 and to a recombinant form of the A-domain of the alpha2 subunit, which has been shown to be a major ligand-binding site within this and other integrins. These findings demonstrate that E-cadherin can interact with alpha2beta1 and suggest that heterotypic interactions between E-cadherin and integrins may be more common than originally thought.