Species Variants of the IsK Protein: Differences in Kinetics, Voltage Dependence, and La3+ Block of the Currents Expressed in Xenopus Oocytes

Overview

Journal Pflugers Arch

Specialty Physiology

Date 1994 Jan 1

PMID 8146016

Citations 5

Authors

R E Hice

K Folander

J J Salata

J S Smith

M C Sanguinetti

R Swanson

Affiliations

Soon will be listed here.

Abstract

We have compared the slowly activating K+ currents (IsK) resulting from the expression of the human, mouse, or rat IsK proteins in Xenopus oocytes, utilizing natural, species-dependent sequence variations to initiate structure-function studies of this channel. Differences were found between the human and rodent currents in their voltage dependence, kinetics, and sensitivity to external La3+. The current/voltage relationships of the human and rat IsK currents differed significantly, with greater depolarizations required for activation of the human channel. The first 30 s of activation during depolarizations to potentials between -10 and +40 mV was best described by a triexponential function for each of the three species variants. The activation rates were, however, significantly faster for the human current than for either of the rodent forms. Similarly, deactivation kinetics were best described as a biexponential decay for each of the species variants but the human currents deactivated more rapidly than the rodent currents. The human and the rodent forms of IsK were also differentially affected by external La3+. Low concentrations (10, 50 microM) rapidly and reversibly reduced the magnitude of the mouse and rat currents during a test depolarization and increased the deactivation rates of the tail currents. In contrast, the magnitude and deactivation rates of the human IsK currents were unaffected by 50 microM La3+.

Citing Articles

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Single-channel characteristics of wild-type IKs channels and channels formed with two minK mutants that cause long QT syndrome.

Sesti F, Goldstein S J Gen Physiol. 1998; 112(6):651-63.

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Differences between outward currents of human atrial and subepicardial ventricular myocytes.

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A slowly activating voltage-dependent K+ current in rat pituitary nerve terminals.

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