Activation and inactivation of the bursting potassium channel from fused Torpedo synaptosomes.

Abstract

1. The voltage dependence of the bursting potassium channel in fused synaptosomes from Torpedo electric organ was studied in vitro, using the inside-out and the cell-attached configurations of the patch clamp technique. 2. The patch of membrane was held at various holding potentials (-140 to -50 mV) and then stepped to test potentials (-50 to +40 mV) for periods ranging from 5 to 300 ms. Each potential step was repeated 200-600 times. After subtraction of the capacitative transients and the leakage currents, an ensemble-averaged current was obtained. This ensemble current showed a marked activation upon depolarization, followed by an inactivation. 3. The activation of the bursting potassium channel is markedly dependent on the voltage step. Activation was detected at voltages positive to -50 mV. The peak of the ensemble current increases with the degree of depolarization, while the time to the peak decreases. With progressively larger depolarization, there is a shortening in the delay between the onset of the voltage step and the opening of the bursting potassium channels. 4. The inactivation phase of the ensemble current could be described adequately in most of the experiments, as a single exponential decay to a steady-state inactivation level. The time constant of inactivation was not markedly voltage dependent. 5. Single channel analysis of the inactivation reveals that it is due to a reduction in the number of channel openings and not due to changes in single channel current amplitude or channel mean open time along the pulse. 6. The holding potential has a marked effect on the peak amplitude of the ensemble current, indicating that hyperpolarization removes inactivation and depolarization induces it. The peak amplitude vs. voltage relation was fitted by the Boltzmann equation. The half-maximal inactivation was -105.2 +/- 5.8 mV (mean +/- S.E.M.), suggesting that at the resting potential a substantial fraction of the bursting potassium channels is in an inactivated state. 7. Two-pulse experiments show that the recovery from inactivation is a slow process which lasts well over 1 s. 8. High-frequency stimulation (20-66.7 Hz) by 5 ms pulses produces a progressive decline in the peak ensemble current amplitude. The decline is larger at higher stimulation frequencies.(ABSTRACT TRUNCATED AT 400 WORDS)