Fast and slow steps in the activation of sodium channels.
Open Access
- 1 December 1979
- journal article
- research article
- Published by Rockefeller University Press in The Journal of general physiology
- Vol. 74 (6), 691-711
- https://doi.org/10.1085/jgp.74.6.691
Abstract
Kinetic features of Na conductance (gNa) and associated gating current (Ig) were studied in voltage-clamped, internally perfused squid [Loligo pealei] axons. Following a step depolarization Ig ON has several kinetic components: a rapid, early phase largely preceding gNa turn-on; a delayed intermediate component developing as gNa increases; and a slow component continuing after gNa is fully activated. With small depolarizations the early phase shows a quick rise (< 40 .mu.s) and smooth decay; the slow component is not detectable. During large pulses all 3 components are present, and the earliest shows a rising phase or initial plateau lasting .apprx. 80 .mu.s. Steady-state and kinetic features of Ig are minimally influenced by control pulse currents, provided controls are restricted to a sufficiently negative voltage range. Ig OFF following a strong brief pulse also shows a rising phase. A depolarizing prepulse producing gNa inactivation and Ig immobilization eliminates the rising phase of Ig OFF. gNa, the immobilized portion of Ig ON, and the rising phase reappear with similar time-courses when tested with a second depolarizing pulse after varying periods of repolarization. 30 mM external ZnCl2 delays and slows gNa activation, prolongs the rising phase, and slows the subsequent decay of Ig ON. Zn does not affect the kinetics of gNa tails or Ig OFF as channels close. A sequential kinetic model of Na channel activation, which adequately describes the observations is presented. The rapid early phase of Ig ON is generated by a series of several fast steps, while the intermediate component reflects a subsequent step. The slow component is too slow to be clearly associated with gNa activation.This publication has 3 references indexed in Scilit:
- Inactivation of the sodium channel. I. Sodium current experiments.The Journal of general physiology, 1977
- Inactivation of the sodium channel. II. Gating current experiments.The Journal of general physiology, 1977
- Asymmetrical displacement current and its relation with the activation of sodium current in the membrane of frog myelinated nervePflügers Archiv - European Journal of Physiology, 1976