An in vitro study on the modulation of the neutrophil adhesive behavior by soluble fibrinogen.

Fibrinogen constitutes an important plasma glycoprotein involved in hemostasis and in inflammation. Previously, we have shown that at physiological concentrations, soluble fibrinogen is able to modulate the pattern of neutrophil activation. This led us to propose that under these conditions, fibrinogen could as well interfere with the adhesive behaviour of circulating neutrophils which is of utmost importance in their recruitment to the vascular wall during inflammatory processes. To address our working hypothesis, in vitro adhesion assays were here performed in a flow chamber by using primary cultures of human umbilical vein endothelial cells (HUVEC) and neutrophils isolated from peripheral venous blood of healthy human donors. In the presence of a physiological concentration of soluble fibrinogen (300 mg/dL), we observed that despite the number of neutrophils rolling on an activated endothelium was not affected, their rolling velocity was increased in comparison to that of non-activated neutrophils. Consequently as expected, the number of fibrinogen-treated neutrophils adhering to activated HUVEC monolayers was significantly diminished. Overall, we have here demonstrated that at least in vitro, soluble fibrinogen under physiological concentrations is able to modulate the interaction of neutrophils with the vascular endothelium. In vivo studies will enable us in the future to study the physiological relevance of these findings and further to understand the mechanisms underlying this function.

Differential effect of soluble fibrinogen as a neutrophil activator.

A fundamental paradigm involved in acute inflammatory responses to invading pathogens and tissue damage is the migration of specific leukocyte populations to the affected tissues to mount an initial innate response to the aggression. The recruitment of polymorphonuclear neutrophils (PMNs) from the blood is a central event in this respect. The aim of this study was to understand whether fibrinogen is able to modulate the pattern of neutrophil activation and thus contribute to neutrophil recruitment. We demonstrated that fibrinogen induces free radical production by neutrophils without modifying the activation status of Mac-1 (αMß2, CD11b/CD18), the previously identified neutrophil receptor for fibrinogen. This data indicates that fibrinogen must have an additional different binding site in the neutrophil membrane. Importantly, we propose that as Mac-1 activation was not affected by the binding of fibrinogen, activated neutrophils can further maintain their ability to marginate, roll and adhere to the endothelial walls.