THE ROLE OF DIHYDROPYRIDINE-SENSITIVE CA2+ CHANNELS IN STIMULUS-EVOKED CATECHOLAMINE RELEASE FROM CHEMORECEPTOR CELLS OF THE CAROTID-BODY

The present study utilized an in vitro preparation of the rabbit carotid body, with tissue catecholamine stores labeled by incubation with H-3-tyrosine. The goal was to characterize pharmacologically the voltage-dependent Ca2+ channels present in the type I (glomus) cells of this arterial chemoreceptor organ, and to elucidate their role as pathways for Ca2+ entry. We found that release of H-3-dopamine induced by high external potassium was over 95% dependent on external calcium concentration and that this release was 90-100% inhibited by the dihydropyridine antagonists, nisoldipine and nitrendipine, and was potentiated by the dihydropyridine agonist, BayK 8644. Therefore, any stimulus-induced, calcium-dependent release of H-3-dopamine that was inhibited by nisoldipine and potentiated by BayK 8644, was considered to be supported by Ca2+ entry into the cells via voltage-dependent Ca2+ channels. Significant differences were observed in the release of H-3-dopamine induced by 75 vs 25 mM K+. On prolonged stimulation, release induced by 75 mM K+ was large and transient, whilst that induced by 25 mM K+, although more moderate, was sustained. The release elicited by 75 mM K+ was inhibited approximately 90% by 1.5 mM Co2+ or 625 nM nisoldipine, while release by 25 mM K+ was completely blocked by 0.6 mM Co2+ or 125 nM nisoldipine. Low PO2-induced release of H-3-dopamine was 95% dependent on Ca2+, and was inhibited by nisoldipine (625 nM) in a manner inversely proportional to the intensity of hypoxic stimulation, i.e. 79% inhibition at a PO2 of 49 Torr, and 20% inhibition at PO2 of 0 Torr. BayK 8644 potentiated the release induced by moderate hypoxic stimuli. Release elicited by high PCO2/low pH, or by Na+-propionate or dinitrophenol-containing solutions, was approximately 80% Ca2+-dependent, and the dihydropyridines failed to modify this release. It is concluded that type I cells possess voltage-dependent Ca2+ channels sensitive to the dihydropyridines, which in agreement with previous electrophysiological data should be defined as L-type Ca2+ channels. Calcium entry which supports the release of H-3-dopamine elicited by moderate hypoxia should occur mainly through these channels while the release induced by strong hypoxic stimuli will be served by Ca2+ entry which occurs in part via voltage-dependent Ca2+ channels, and in part through an additional pathway, probably a Na+/Ca2+ exchanger. The insensitivity to dihydropyridines of the release of H-3-dopamine induced by high PCO2/low pH, Na+-propionate and dinitrophenol may indicate a complete loss of efficacy of the drugs to modulate Ca2+ channels under these conditions or more likely, that other mechanisms are activated, probably the Na+-Ca2+ exchanger.