The integrin ␣ 9 subunit forms a single heterodimer, ␣ 9  1 that mediates cell adhesion to a site within the third fibronectin type III repeat of tenascin-C (TNfn3). In contrast to at least 3 other integrins that bind to this region of tenascin-C, ␣ 9  1 does not recognize the common integrin recognition motif, Arg-Gly-Asp (RGD). In this report, we have used substitution mutagenesis to identify a unique ligand recognition sequence in TNfn3. We introduced mutations substituting alanine for each of the acidic residues in or adjacent to each of the exposed loops predicted from the solved crystal structure. Most of these mutations had little or no effect on adhesion of ␣ 9 -transfected SW480 colon carcinoma cells, but mutations of either of two acidic residues in the B-C loop region markedly reduced attachment of these cells. In contrast, cells expressing the integrin ␣ v  3 , previously reported to bind to the RGD sequence in the adjacent F-G loop, attached to all mutant fragments except one in which the RGD site was mutated to RAA. The peptide, AEIDGIEL, based on the sequence of human tenascin-C in this region blocked the binding of ␣ 9 -transfected cells, but not  3 -transfected cells to wild type TNfn3. This sequence contains a tripeptide, IDG, homologous to the sequences LDV, IDA, and LDA in fibronectin and IDS in VCAM-1 recognized by the closely related integrin ␣ 4  1 . These findings support the idea that this tripeptide motif serves as a ligand binding site for the ␣ 4 /␣ 9 subfamily of integrins.Integrins are cell surface heterodimers that play roles in essential biological processes including development and tissue remodeling (1-4). Ligand binding specificity depends in large part on the specific ␣ and  subunit present in each heterodimer. To date, extracellular matrix proteins, cell surface immunoglobulin superfamily molecules, and cadherins have been identified as ligands for integrins. In most cases where the crystal structure of integrin ligands have been solved, the ligand binding site includes at least one acidic residue, generally displayed in an exposed peptide loop (5-7). The first short peptide sequence identified as an integrin recognition sequence was the tripeptide, Arg-Gly-Asp (RGD) (8), initially identified as a cell-recognition sequence in the large extracellular matrix protein, fibronectin (9, 10). Subsequently, this RGD sequence was found to be present in several integrin ligands and to serve as a recognition sequence for several different integrins (11). As the sequences of multiple integrin ␣ subunits were solved, it became clear that these sequences could be divided into 3 subfamilies based on sequence homology (1). One family includes ␣ subunits with a characteristic disulfide-linked cleavage site. A subset of these form heterodimers that recognize RGD-containing ligands. Another includes ␣ subunits that contain an inserted domain close to the N terminus but no cleavage site. These integrins generally do not recognize RGD-containing ligands. Finally, a third family, including o...
