Jararhagin-derived RKKH Peptides Induce Structural Changes in α1I Domain of Human Integrin α1β1*

Integrin α1β1 is one of four collagen-binding integrins in humans. Collagens bind to the αI domain and in the case of α2I collagen binding is competitively inhibited by peptides containing the RKKH sequence and derived from the metalloproteinase jararhagin of snake venom from Bothrops jararaca. In α2I, these peptides bind near the metal ion-dependent adhesion site (MIDAS), where a collagen (I)-like peptide is known to bind; magnesium is required for binding. Published structures of the ligand-bound “open” conformation of α2I differs significantly from the “closed” conformation seen in the structure of apo-α2I near MIDAS. Here we show that two peptides, CTRKKHDC and CARKKHDC, derived from jararhagin also bind to α1I and competitively inhibit collagen I binding. Furthermore, calorimetric and fluorimetric measurements show that the structure of the complex of α1I with Mg2+ and CTRKKHDC differs from structure in the absence of peptide. A comparison of the x-ray structure of apo-α1I (“closed” conformation) and a model structure of the α1I (“open” conformation) based on the closely related structure of α2I reveals that the binding site is partially blocked to ligands by Glu255 and Tyr285 in the “closed” structure, whereas in the “open” structure helix C is unwound and these residues are shifted, and the “RKKH” peptides fit well when docked. The “open” conformation of α2I resulting from binding a collagen (I)-like peptide leads to exposure of hydrophobic surface, also seen in the model of α1I and shown experimentally for α1I using a fluorescent hydrophobic probe.

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