Peter Newham

The structure of cell-adhesion molecules

In recent years, following the identification and molecular cloning of many key adhesion molecules, the three-dimensional structures of some of the domains that mediate adhesive interactions have been determined. This review discusses how these studies have helped explain the unique functional roles of the different families of adhesion molecules.

A specific α5β1-integrin conformation promotes directional integrin translocation and fibronectin matrix formation

Integrin adhesion receptors are structurally dynamic proteins that adopt a number of functionally relevant conformations. We have produced a conformation-dependent anti-α5 monoclonal antibody (SNAKA51) that converts α5β1 integrin into a ligand-competent form and promotes fibronectin binding. In adherent fibroblasts, SNAKA51 preferentially bound to integrins in fibrillar adhesions. Clustering of integrins expressing this activation epitope induced directional translocation of α5β1, mimicking fibrillar adhesion formation. Priming of α5β1 integrin by SNAKA51 increased the accumulation of detergent-resistant fibronectin in the extracellular matrix, thus identifying an integrin conformation that promotes matrix assembly. The SNAKA51 epitope was mapped to the calf-1/calf-2 domains. We propose that the action of the antibody causes the legs of the integrin to change conformation and thereby primes the integrin to bind ligand. These findings identify SNAKA51 as the first anti-integrin antibody to selectively recognize a subset of adhesion contacts, and they identify an integrin conformation associated with integrin translocation and fibronectin matrix formation.

Integrin adhesion receptors: structure, function and implications for biomedicine

Over the past decade, multi-disciplinary approaches have led to the discovery and characterization of several classes of adhesion molecules. Under normal conditions, these molecules provide support for cells, regulate cell migration and contain information that cells use when sensing their environment. In disease, adhesive function is frequently compromised and results in tissue disorder, aberrant cell migration and dysregulation of signalling pathways. The integrins are a major family of adhesion receptors produced by most cell types and are a means by which the cell senses its immediate environment and responds to changes in extracellular matrix composition. Recent years have seen major advances in our understanding of integrin-ligand interactions, and have revealed a structurally dynamic family of receptors capable of translating information into and out of the cell.

Alpha4 integrin binding interfaces on VCAM-1 and MAdCAM-1. Integrin binding footprints identify accessory binding sites that play a role in integrin specificity.

Integrins are a family of heterodimeric adhesion receptors that mediate cellular interactions with a range of matrix components and cell surface proteins. Vascular cell adhesion molecule-1 (VCAM-1) is an endothelial cell ligand for two leukocyte integrins (α4β1 and α4β7). A related CAM, mucosal addressin cell adhesion molecule-1 (MAdCAM-1) is recognized by α4β7 but is a poor ligand for α4β1. Previous studies have revealed that all α4 integrin-ligand interactions are dependent on a key acidic ligand motif centered on the CAM domain 1 C-D loop region. By generating VCAM-1/MAdCAM-1 chimeras and testing recombinant proteins in cell adhesion assays we have found that α4β1 binds to the MAdCAM-1 adhesion motif when present in VCAM-1, but not when the VCAM-1 motif was present in MAdCAM-1, suggesting that this region does not contain all of the information necessary to determine integrin binding specificity. To characterize integrin-CAM specificity further we measured α4β1 and α4β7 binding to a comprehensive set of mutant VCAM-1 constructs containing amino acid substitutions within the predicted integrin adhesion face. These data revealed the presence of key “regulatory residues” adjacent to integrin contact sites and an important difference in the “footprint” of α4β1 and α4β7 that was associated with an accessory binding site located in VCAM-1 Ig domain 2. The analogous region in MAdCAM-1 is markedly different in size and sequence and when mutated abolishes integrin binding activity.

Production of recombinant soluble human integrin α4β1

Integrin α4β1 is a major leukocyte adhesion receptor that is a key target for the development of anti‐inflammatory therapeutics. With the dual long‐term goals of developing a reagent for use in high‐throughput inhibitor screening assays and for crystallisation trials and subsequent structure determination, we have generated a recombinant soluble α4β1 receptor. Both subunits were truncated prior to the transmembrane domains by site‐directed mutagenesis and expressed using baculovirus infection of insect cells. The molecular weights of the recombinant subunits were as expected for post‐translationally unmodified protein. In addition, as observed for the native subunit, a proportion of the α4 subunit was proteolytically processed into two fragments. ELISA and solid phase ligand‐binding assays were performed to investigate the folding and functionality of the soluble integrin. The data suggest that the receptor was correctly folded and that it bound recombinant ligands with similar kinetics to the native molecule.