Identification of a novel recognition sequence for integrin alphaM beta2 within the gamma-chain of fibrinogen.

The interaction of leukocyte integrin alphaMbeta2 (CD11b/CD18, Mac-1) with fibrinogen has been implicated in the inflammatory response by contributing to leukocyte adhesion to the endothelium and subsequent transmigration. Previously, it has been demonstrated that a peptide, P1, corresponding to residues 190-202 in the gamma-chain of fibrinogen, binds to alphaM beta2 and blocks the interaction of fibrinogen with the receptor and that Asp199 within P1 is important to activity. We have demonstrated, however, that a double mutation of Asp199-Gly200 to Gly-Ala in the recombinant gamma-module of fibrinogen, spanning region 148-411, did not abrogate alphaM beta2 recognition and considered that other binding sites in the gamma-module may participate in the receptor recognition. We have found that synthetic peptide P2, duplicating gamma377-395, inhibited adhesion of alphaM beta2-transfected cells to immobilized D100 fragment of fibrinogen in a dose-dependent manner. In addition, immobilized P2 directly supported efficient adhesion of the alphaM beta2-expressing cells, including activated and non-activated monocytoid cells. The I domain of alphaM beta2 was implicated in recognition of P2, as the biotinylated recombinant alphaMI domain specifically bound to both P2 and P1 peptides. Analysis of overlapping peptides spanning P2 demonstrated that it may contain two functional sequences: gamma377-386 (P2-N) and gamma383-395 (P2-C), with the latter sequence being more active. In the three-dimensional structure of the gamma-module, gamma190-202 and gamma377-395 reside in close proximity, forming two antiparallel beta strands. The juxtapositioning of these two sequences may form an unique and complex binding site for alphaM beta2.