Genetic Analyses of Integrin Signaling

The development of multicellular organisms, as well as maintenance of organ architecture and function, requires robust regulation of cell fates. This is in part achieved by conserved signaling pathways through which cells process extracellular information and translate this information into changes in proliferation, differentiation, migration, and cell shape. Gene deletion studies in higher eukaryotes have assigned critical roles for components of the extracellular matrix (ECM) and their cellular receptors in a vast number of developmental processes, indicating that a large proportion of this signaling is regulated by cell-ECM interactions. In addition, genetic alterations in components of this signaling axis play causative roles in several human diseases. This review will discuss what genetic analyses in mice and lower organisms have taught us about adhesion signaling in development and disease.Almost all cells in multicellular organisms are surrounded by a three-dimensional organized meshwork of macromolecules that constitute the extracellular matrix (ECM). The ECM is a dynamic structure that is generated and constantly remodeled by cells that secrete and manipulate its components into a precise configuration. It functions as a structural framework that provides cells with positional and environmental information, but also forms specialized structures such as cartilage, tendons, basement membranes (BM), bone, and teeth. In addition to its structural properties, the ECM acts as a signaling platform that regulates a large number of cellular functions. It is capable of binding growth factors, chemokines, and cytokines thereby modulating their bioavailability and activity. On the other hand, the ECM is recognized by multiple cell surface receptors that transmit information from the extracellular environment by propagating intracellular signals (for a review, see Hynes 2009).The major cell surface receptors that recognize and assemble the ECM are integrins. Integrins are heterodimeric transmembrane proteins composed of α and β subunits. Eighteen α subunits and eight β subunits can assemble in 24 different combinations with overlapping substrate specificity and cell-type-specific expression patterns (Hynes 2002; Humphries et al. 2006). This, together with the ability of different heterodimers to assemble specific intracellular signaling complexes, provides multiple layers of signaling specificity to these receptors. Conversely, the integrin expression profile of a given cell type determines which ECM components it can bind. Signals arising from integrins regulate virtually all aspects of cell behavior, including cell migration, survival, cell cycle progression, and differentiation.Genetics has proven to be a powerful tool to dissect the functions of ECM–cell interactions in complex organisms. To date, all of the integrin subunits and their major ligands have been deleted in mice. Given the large variety of cellular processes regulated by adhesion signaling, it is not surprising that a significant subset of these proteins has proven to be essential for embryonic development and/or tissue maintenance. However, in addition to underlining the importance of cell-ECM interactions in development, genetic studies also revealed critical roles for tissue- and cell-type-specific modes of adhesion signaling and provided important insights into human disease.