The three-dimensional structure of an N-terminal fragment comprising the first 51 amino acids from human plasma vitronectin, the somatomedin B (SMB) domain, has been determined by two-dimensional NMR approaches. An average structure was calculated, representing the overall fold from a set of 20 minimized structures. The core residues (18 -41) overlay with a root mean square deviation of 2.29 ؎ 0.62 Å. The N-and Cterminal segments exhibit higher root mean square deviations, reflecting more flexibility in solution and/or fewer long-range NOEs for these regions. Residues 26 -30 form a unique single-turn ␣-helix, the locus where plasminogen activator inhibitor type-1 (PAI-1) is bound. This structure of this helix is highly homologous with that of a recombinant SMB domain solved in a co-crystal with PAI-1 (Zhou, A., Huntington, J. A., Pannu, N. S., Carrell, R. W., and Read, R. J. (2003) Nat. Struct. Biol. 10, 541-544), although the remainder of the structure differs. Significantly, the pattern of disulfide cross-links observed in this material isolated from human plasma is altogether different from the disulfides proposed for recombinant forms. The NMR structure reveals the relative orientation of binding sites for cell surface receptors, including an integrin-binding site at residues 45-47, which was disordered and did not diffract in the co-crystal, and a site for the urokinase receptor, which overlaps with the PAI-1-binding site.Human vitronectin is a glycoprotein found in the circulation, where it contributes to hemostasis by regulating blood coagulation and fibrinolysis (1, 2). Vitronectin is also found in the ECM, 1 where it plays important roles in cell adhesion, pericellular proteolysis, tissue invasion, angiogenesis, and metastasis (3-7). The variety of functions of vitronectin in the two microenvironments is a manifestation of its ability to interact with numerous humoral and cellular proteins. An important binding partner for vitronectin is the serine protease inhibitor PAI-1, which also is found both in circulation and the ECM. Furthermore, it has different activities depending upon this localization; the anti-protease activity of PAI-1 that regulates thrombolysis in the circulation is targeted instead toward pericellular proteolysis when localized to the ECM or cell/matrix boundary. Vitronectin binds to PAI-1 with high affinity and stabilizes the inhibitor in its active conformation (8, 9). Vitronectin can also associate with PAI-1 and assemble to form higher order complexes (10) that exhibit altered adhesive functions (11). Key to the adhesive functions of vitronectin are its interactions with cell-surface receptors including integrins and uPAR.A widely accepted model suggests that vitronectin is organized into functional domains that provide the broad repertoire necessary for binding to target ligands (12)(13)(14). We recently used computational methods to predict the structure of the three domains comprising vitronectin (15). A threading algorithm gave high confidence predictions for the central domai...
