THE SUPPRESSION OF CA2+-DEPENDENT AND VOLTAGE-DEPENDENT K+ CURRENT DURING MACHR ACTIVATION IN RAT ADRENAL CHROMAFFIN CELLS

1. The mechanism by which muscarine, ionomycin or caffeine results in suppression of Ca2+- and voltage-dependent outward current in rat adrenal chromaffin cells was evaluated using both whole-cell voltage clamp and single channel recording. 2. The whole-cell current activated following the elevation of the cytosolic calcium concentration ([Ca2+](i)) by muscarine inactivates with a time course comparable to that of single Ca2+- and voltage-dependent potassium (BK) channels. 3. The whole-cell inactivating current is pharmacologically similar to BK current. 4. The voltage dependence of inactivation and rate of recovery from inactivation are qualitatively similar for both whole-cell current and ensemble averages of single BK channels. Furthermore, changes in the rate of whole-cell current inactivation track expected changes in submembrane [Ca2+]. 5. The suppression of outward current can be accounted for solely by inactivation of BK channels and does not depend on the means by which [Ca2+](i) is elevated. 6. Muscarinic acetylcholine receptor (mAChR) activation, changes in holding potential (-50 to -20 mV), and step depolarizations of different amplitude and duration were tested for their ability to elevate [Ca2+](i) and thereby regulate the availability of BK current for activation. 7. Following muscarine-induced elevation of [Ca2+](i) at holding potentials positive to -40 mV, the availability of BK current for activation was typically reduced by more than 50 %. 8. Holding potentials in the range of -50 to -20 mV produced only slight alterations in the availability of BK current for activation. 9. Step depolarizations that cause maximal rates of Ca2+ influx (0 to +10 mV) must exceed 200 ms to reduce the availability of BK current by approximately 50 %. 10. The results show that the muscarine-induced elevation of [Ca2+](i) produces a profound reduction in the availability of BK channels for activation at membrane potentials likely to be physiologically meaningful. Although depolarization-induced Ca2+ influx can inactivate BK current, we propose that short duration depolarizations that occur during normal electrical activity will not significantly alter BK channel availability.