Voltage-Activated Ionic Currents in Goldfish Pituitary Cells

Abstract

The release of gonadotropin and growth hormone from goldfish pituitary cells has been shown to be dependent on the entry of extracellular Ca2+ through voltage-sensitive Ca2+ channels by pharmacological studies. As a first step to further investigate the involvement of voltage-dependent ion channels in the regulation of anterior pituitary hormone release in the goldfish, cell excitability and voltage-dependent ion currents were characterized using tight-seal whole-cell recordings in dispersed goldfish pituitary cells. Cultured goldfish pituitary cells had an average membrane potential of -36 ± 3 mV. When held at membrane potentials more negative than -60 mV, these cells were excitable, responding to depolarizing current pulses or anode break with the firing of single action potentials. Results from total current voltage-clamp recordings suggested that all goldfish pituitary cells possess voltage-dependent Na+ , Ca2+, and K+ currents. These currents were further characterized independently under isolated current recording conditions. The rapid, transient Na+ current activated at voltages more positive than -40 mV and was sensitive to tetrodotoxin. The steady state inactivation of this Na+ current was also voltage-dependent; at the measured resting potential, ⩾50% of the Na+ current was not available for activation. The voltage-dependence and activation kinetics of the tetraethylammonium-sensitive K+ current resembled those of the delayed rectifier K+ current. The K+ current activated slowly at potentials more positive than -40 mV, and showed little inactivation over the duration of a 1-sec depolarizing pulse. Steady-state inactivation characteristics indicated that ≤50% of the K+ current was inactivated at resting potentials. Experiments with 4-aminopyridine indicated the presence of an early transient K+ current that activated in a similar voltage range as the delayed rectifier current. Using barium as the charge carrier to measure Ca2+ currents, a high-voltage activated, long-lasting Ca2+ current was revealed. This "L-type" Ca2+ current activated at potentials more positive than -30 mV and was inhibited by verapamil and nifedipine. This study indicates that goldfish pituitary cells possess the electrophysiological properties required for the participation of voltage-sensitive ion channels in the regulation of hormone release.