Abstract
Extravasation of polymorphonuclear leukocytes (PMN) and associated plasma leakage are key events in the inflammatory process. The kinetics of PMN-induced changes in endothelial barrier function were studied by means of confluent monolayers of bovine aorta or human umbilical vein endothelial cells (EC), cultured on permeable membranes and mounted in a two-compartment diffusion chamber. The model permitted continuous measurement of transendothelial electrical resistance (TEER), and analysis of protein efflux and PMN migration across the EC monolayer.
Transendothelial chemotactic stimulation (fMLP or LTB4) of PMN resting on EC in the upper compartment induced a prompt decline in TEER, followed by an increase in protein flux and transmigration of PMN. Adding the chemoattractant together with PMN in the upper compartment provoked adhesion of PMN, fall in TEER and increase in protein permeability, but no transmigration of PMN, whereas inhibition of PMN adhesion to EC by pretreatment with anti-CD18 mAb prevented all responses to chemotactic stimulation.
Chemoattractant-induced adhesion of PMN to the EC monolayer induced a rapid rise in EC cytosolic free Ca2+, similar to that obtained by direct stimulation of EC with histamine, indicating an active response of EC to PMN activation and adhesion.
In summary, continuous recording of transendothelial electrical resistance in the in vitro model described permits rapid and sensitive analysis of leukocyte activation-induced effects on EC barrier function. The kinetics and specificity of the EC and PMN responses to chemoattractant stimulation suggest that activated PMN, via adhesion-dependent events, have a direct effect on EC junctional integrity independent of whether transmigration occurs or not.
Keywords: Inflammation, leukocyte extravasation, endothelial cells, vascular permeability, plasma leakage
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