Abstract
The bovine ether à go-go gene encodes a delayed rectifier potassium channel. In contrast to other delayed rectifiers, its activation kinetics is largely determined by the holding potential and the concentration of extracellular Mg2+, giving rise to slowly activating currents with a characteristic sigmoidal rising phase. Replacement of a single amino acid in the extracellular linker between transmembrane segments S3 and S4 (L322H) strongly reduced the prepulse dependence and accelerated activation by 1 order of magnitude. In addition, compared with the wild type, the half-activation voltage of this mutant was shifted by more than 30 mV to more negative potentials. We used dimeric and tetrameric constructs of the bovine eag1 gene to analyze channels with defined stoichiometry of mutated and wild-type subunits within the tetrameric channel complexes. With increasing numbers of mutated subunits, the channel activation was progressively accelerated, and the sigmoidicity of the current traces was reduced. Based on a quantitative analysis, we show that the slow gating, typical for EAG channels, is mediated by independent conformational transitions of individual subunits, which gain their voltage dependence from the S4 segment. At a given voltage, external Mg2+ increases the probability of a channel subunit to be in the slowly activating conformation, whereas mutation L322H strongly reduces this probability.
Highlights
Voltage-gated potassium channels (Kϩ channels) play major roles in the control of cellular resting potentials, and they are involved in the regulation of firing rate and shaping of action potentials in excitable cells [1]
Based on a quantitative analysis, we show that the slow gating, typical for EAG channels, is mediated by independent conformational transitions of individual subunits, which gain their voltage dependence from the S4 segment
Test pulses from potentials just below the activation threshold (e.g. Ϫ70 mV) lead to rapid activation, whereas hyperpolarizing prepulses result in very slow activation kinetics
Summary
Voltage-gated potassium channels (Kϩ channels) play major roles in the control of cellular resting potentials, and they are involved in the regulation of firing rate and shaping of action potentials in excitable cells [1]. Activation of channel constructs with only two or one wild-type subunit were described by this equation, assuming n ϭ 2 or 1, respectively. Parameters for the mutant are shown as closed symbols, B and C. p was generally much smaller than for the wild type, and the time constants for the activation of the slow gates did not depend on [Mg2ϩ].
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