Leukocytes migrate from the blood into areas of inflammation by interacting with various adhesion molecules on endothelial cells. Vascular adhesion protein-1 (VAP-1) is a glycoprotein expressed on inflamed endothelium where it plays a dual role: it is both an enzyme that oxidizes primary amines and an adhesin that is involved in leukocyte trafficking to sites of inflammation. Although VAP-1 was identified more than 15 years ago, the counterreceptor(s) for VAP-1 on leukocytes has remained unknown. Here we have identified Siglec-10 as a leukocyte ligand for VAP-1 using phage display screenings. The binding between Siglec-10 and VAP-1 was verified by different adhesion assays, and this interaction was also consistent with molecular modeling. Moreover, the interaction between Siglec-10 and VAP-1 led to increased hydrogen peroxide production, indicating that Siglec-10 serves as a substrate for VAP-1. Thus, the Siglec-10-VAP-1 interaction seems to mediate lymphocyte adhesion to endothelium and has the potential to modify the inflammatory microenvironment via the enzymatic end products. IntroductionMaintenance of an adequate immune defense is largely dependent on migration of circulating leukocytes from the vasculature into the surrounding tissue. Extravasation of leukocytes from the blood into the tissues is controlled by a multistep cascade, which involves numerous adhesion and signaling molecules. First, leukocytes tether and roll on the vascular endothelium, after which they adhere more strongly, arrest, and finally diapedese through the vessel wall. 1,2 One of the endothelial molecules involved in this cascade is a 180-kDa homodimeric glycoprotein, vascular adhesion protein-1 (VAP-1). 3 VAP-1 is mainly expressed on vascular endothelium, on smooth muscle cells, and on adipocytes. 4 It is rapidly translocated to the endothelial cell surface on inflammation, where it supports recruitment of leukocytes. 5,6 VAP-1 is involved in the rolling, firm adhesion, and transmigration phases of the extravasation cascade. Besides being an adhesin, VAP-1 is also an enzyme (semicarbazide sensitive amine oxidase, SSAO) and catalyzes oxidative deamination of a primary amine to an aldehyde with concomitant release of hydrogen peroxide and ammonium. 4 We and others have shown that VAP-1 supports leukocyte recruitment to sites of inflammation via both enzyme-activity-dependent and enzyme-activity-independent ways. Monoclonal anti-VAP-1 antibodies, which do not block the enzymatic activity of VAP-1, still block the binding of leukocytes to the endothelium in vitro and in vivo, and inhibitors of the enzymatic function of VAP-1 are able to effectively prevent the interaction between leukocytes and endothelium in vitro and in vivo. 7,8 Moreover, it has been recently shown that the end products generated by the catalytic activity of VAP-1, especially hydrogen peroxide, play a role in the regulation of other homing-associated molecules and thus enhance the inflammatory response. 9,10 Although VAP-1 has been known already for a long time and ...
Our aim was to study the effects of hypoxia on the release of salmon cardiac peptide (sCP) from an isolated heart ventricle of trout during a constant mechanical load. Trout heart ventricles were studied in vitro. The ventricle was placed in an organ bath at 12 °C in which a constant mechanical load could be imposed on the ventricle while buffer solution was circulating. Ventricles were field-stimulated with a supramaximal voltage pulse at a rate of about 0.3 s⁻¹. Samples of 1 ml were collected at an interval of 10 min for 200 min from the organ bath and assessed with a radioimmunoassay for sCP. After a control period of 20 min, ventricles were exposed to hypoxia produced with N₂ gassing (n = 9) or to hypoxia with 20 mM BDM, a nonselective myosin ATPase inhibitor locking cross-bridges in a pre-power-stroke state inhibiting force production with normal electrical activity (n = 10). In this model and setup, hypoxia stimulated the release of sCP, but the interindividual variation in the response was large. At the end of hypoxia exposure, the concentration of sCP in the organ bath was about sixfold higher than at the start of the exposure (P < 0.05, one-way ANOVA for repeated measurements, followed by Dunnett's multiple comparison test). When BDM was introduced into the bath, the ventricle still secreted sCP but the hypoxic response was smaller than in the experiments without BDM. In the trout heart ventricle, there is a hypoxia-sensitive component in the release mechanism of sCP which is independent of contraction.
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