Leukocyte migration to sites of inflammation is regulated by several endothelial adhesion molecules. Vascular adhesion protein-1 (VAP-1) is unique among the homing-associated molecules as it is both an enzyme that oxidizes primary amines and an adhesin. Although granulocytes can bind to endothelium via a VAP-1-dependent manner, the counter-receptor(s) on this leukocyte population is(are) not known. Here we used a phage display approach and identified Siglec-9 as a candidate ligand on granulocytes. The binding between Siglec-9 and VAP-1 was confirmed by in vitro and ex vivo adhesion assays. The interaction sites between VAP-1 and Siglec-9 were identified by molecular modeling and confirmed by further binding assays with mutated proteins. Although the binding takes place in the enzymatic groove of VAP-1, it is only partially dependent on the enzymatic activity of VAP-1. In positron emission tomography, the 68 Gallium-labeled peptide of Siglec-9 specifically detected VAP-1 in vasculature at sites of inflammation and cancer. Thus, the peptide binding to the enzymatic groove of VAP-1 can be used for imaging conditions, such as inflammation and cancer. (Blood. 2011;118(13):3725-3733) IntroductionLeukocyte migration from the blood into the nonlymphoid tissues is a hallmark of inflammation. Several molecules on the endothelial cell surface and their counter-receptors on leukocytes mediate a multistep adhesion cascade featuring tethering, rolling, activation, adhesion, crawling, and transmigration phases. 1,2 Vascular adhesion protein-1 (VAP-1/AOC3) is an endothelial cell molecule that is rapidly translocated from the intracellular storage granules to the endothelial cell surface on inflammation. It contributes to several steps in the extravasation cascade and controls trafficking of lymphocytes, granulocytes, and monocytes to sites of inflammation. VAP-1 has unique features distinct from other conventional adhesion molecules because, besides being an adhesin, it is also an enzyme. It catalyzes oxidative deamination of primary amines and produces hydrogen peroxide, aldehyde, and ammonium. 3 The end products of the enzymatic activity are highly potent inflammatory mediators and can up-regulate other adhesion molecules, such as E-and P-selectin, ICAM-1, and VCAM-1. 4,5 We recently found the first lymphocyte ligand for VAP-1, Siglec-10. 6 It is expressed on B cells, monocytes, and eosinophils but is absent from granulocytes. 7 However, VAP-1 is also involved in granulocyte migration to sites of inflammation. This has been demonstrated in studies with acute inflammation models (peritonitis, lung, and air pouch inflammation) in mouse. In these studies, significant reduction in granulocyte migration to sites of inflammation was obtained with a function blocking anti-VAP-1 antibody and a small molecular inhibitor against VAP-1. [8][9][10] Contribution of VAP-1 both at the rolling and transmigration steps during leukocyte extravasation has been demonstrated, and the enzymatic activity of VAP-1 seems to be important in these proc...
Human membrane primary amine oxidase (hAOC3; also known as vascular adhesion protein-1, VAP-1) is expressed upon inflammation in most tissues, where its enzymatic activity plays a crucial role in leukocyte trafficking. We have determined two new structures of a soluble, proteolytically cleaved form of hAOC3 (sAOC3), which was extracted from human plasma. In the 2.6 Å sAOC3 structure, an imidazole molecule is hydrogen bonded to the topaquinone (TPQ) cofactor, which is in an inactive on-copper conformation, while in the 2.95 Å structure, an imidazole molecule is covalently bound to the active off-copper conformation of TPQ. A second imidazole bound by Tyr394 and Thr212 was identified in the substrate channel. We furthermore demonstrated that imidazole has an inhibitory role at high concentrations used in crystallization. A triple mutant (Met211Val/Tyr394Asn/Leu469Gly) of hAOC3 was previously reported to change substrate preferences toward those of hAOC2, another human copper-containing monoamine oxidase. We now mutated these three residues and Thr212 individually to study their distinct role in the substrate specificity of hAOC3. Using enzyme activity assays, the effect of the four single mutations was tested with four different substrates (methylamine, benzylamine, 2-phenylethylamine, and p-tyramine), and their binding modes were predicted by docking studies. As a result, Met211 and Leu469 were shown to be key residues for substrate specificity. The native structures of sAOC3 and the mutational data presented in this study will aid the design of hAOC3 specific inhibitors.
Background:The integrin ␣I domain undergoes a conformational change during activation. Results: The crystal structure of an activated ␣I domain is different from the reported open and closed states. Conclusion: Our structure mimics the state where the Arg 287 -Glu 317 ion pair is just broken during the activation process. Significance: The activation mechanism of the collagen receptor integrins differs from the other integrins.
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