Mechanisms of sodium azide-induced changes in intracellular calcium concentration in rat primary cortical neurons.

Abstract An intracellular calcium ([Ca 2+ ] i ) increase is involved in sodium azide (NaN 3 )-induced neurotoxicity, an in vitro model of brain ischemia. In this study the questions of possible additional sources of calcium influx, besides glutamate receptor activation, and of the time-course of NaN 3 effects have been addressed by measuring [Ca 2+ ] i in rat primary cortical cultures with the FURA-2 method. Basal [Ca 2+ ] i of neuronal populations was concentration-dependently increased 30 min, but not 24 h, after a 10-min NaN 3 (3–30 mM) treatment; conversely, the net increase induced by electrical stimulation (10 Hz, 10 s) was consistently reduced. All the above effects depended on glutamate release and consequent NMDA receptor activation, since the NMDA antagonist MK-801 (1 μM) prevented them, and the spontaneous efflux of [ 3 H]- d -aspartate from superfused neurons was concentration-dependently increased by NaN 3 . In single neuronal cells, NaN 3 application progressively and concentration-dependently increased [Ca 2+ ] i (to 177 ± 5% and 249 ± 7% of the controls, 4 and 12 min after a 10 mM-treatment, respectively). EGTA (5 mM) pretreatment reduced the effect of 10 mM NaN 3 (to 118 ± 5% at 4 min, and to 148 ± 10% at 12 min, respectively), while 1 μM cyclosporin A did not. Both MK-801 and CNQX (a non-NMDA glutamate antagonist, 10 μM) prevented NaN 3 effect at 4 min (to 147 ± 8% and 153 ± 5%, respectively), but not at 12 min after NaN 3 treatment. Conversely, 10 μM verapamil and 0.1 μM ω-conotoxin (L- and N-type calcium channel blockers, respectively) significantly attenuated NaN 3 effects at 12 min (to 198 ± 8% and 164 ± 5%, respectively), but not at 4 min; the P/Q-type calcium channel blocker, agatoxin, 0.3 μM, was ineffective. These findings show that the predominant source of calcium increase induced by NaN 3 is extracellular, involving glutamate receptor activation in a first step and calcium channel (mainly of the N-type) opening in a second step.