Alexandre de Hemptinne

Chemically, mechanically, and hyperosmolarity-induced calcium responses of rat cortical capillary endothelial cells in culture.

Abstract The purpose of the present work was to characterize calcium responses of brain-capillary endothelial cells (BCEC), the cells forming the blood-brain barrier, to chemical, hyperosmolar and mechanical stimulation. Confluent BCEC cultures were grown from capillary fragments isolated from rat cerebral cortex. Intracellular free calcium ([Ca2+]i) was measured using fura-2 and digital imaging. Our experiments show large endothelial calcium responses to substance P and ATP, up to a peak value of approximately 1000 and 600 nM, respectively, and these responses were observed in 2/3 of the cells. Calcium responses to bradykinin, histamine, and hyperosmolar sucrose or mannitol were smaller, attaining a peak in the range 180–340 nM, and were observed in a smaller fraction of the cells. No calcium responses were observed to high-potassium, l-glutamate, serotonin, carbachol, noradrenalin, and nitric-oxide donors. Consecutive superfusion of the cultures with ATP, bradykinin, and histamin showed that cells with a certain response pattern were spatially grouped; the response pattern itself varied widely between experiments. Mechanical stimulation of a single cell caused a calcium response in the stimulated cell in primary cultures and triggered an intercellularly propagating calcium wave in passaged cultures. Given the important effect of endothelial [Ca2+]i on blood-brain barrier permeability and transport, we conclude that substance P and ATP are potential modulators of blood-brain barrier function. Hyperosmolarity-induced blood-brain barrier opening is probably not mediated through endothelial [Ca2+]i.

Effects of flunarizine on induced calcium transients as measured in fura-2 loaded neurons of the rat dorsal root ganglion

SummaryThe effect of the calcium entry blocker flunarizine on a high-potassium induced increase of intracellular free calcium was studied. The experiments were done with neurons isolated from rat dorsal root ganglia and loaded with the calcium-sensitive dye fura-2. The increase of calcium induced by 60 mmol/1 potassium was abolished after removal of extracellular calcium, was reversibly reduced by 50 μmol/l cadmium (76% inhibition), 50 μmol/1 nickel (25% inhibition) and 10 μmol/1 nifedipine (18°10 inhibition), and reversibly increased after removal of extracellular sodium (26% increase). The potassium induced increase of intracellular calcium is, therefore, mediated by transmembrane calcium influx, probably to a large extent through cadmium-sensitive calcium channels. Flunarizine (5 min incubation followed 1 min wash-out) reduced the amplitude of the high-potassium induced calcium increase in a dose-dependent manner (Kd = 370 ± 100 nmol/l; mean ± SEM; n = 8), causing complete inhibition at a concentration of 10 μmol/1 in the majority of cells. Flunarizine (≥ 1 μmol/1) caused a reversible increase of the resting level of intracellular calcium in some cells, an effect which disappeared in the absence of extracellular calcium. The drug (1 μmol/1 had no influence on the time course of recovery of intracellular calcium subsequent to a rise induced by high-potassium or by the calcium ionophore A23187. It is concluded that flunarizine acts as an inhibitor of depolarization-mediated calcium influx. At a concentration of 1 μmol/1, the drug presumably has no effect on cellular calcium extrusion and/or sequestration mechanisms.