Anion permeation in human ClC-4 channels.
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Journal: 2003/December - Biophysical Journal
ISSN: 0006-3495
Abstract:
ClC-4 and ClC-5 are mammalian ClC isoforms with unique ion conduction and gating properties. Macroscopic current recordings in heterologous expression systems revealed very small currents at negative potentials, whereas a substantially larger instantaneous current amplitude and a subsequent activation were observed upon depolarization. Neither the functional basis nor the physiological impact of these channel features are currently understood. Here, we used whole-cell recordings to study pore properties of human ClC-4 channels heterologously expressed in tsA201 or HEK293 cells. Variance analysis demonstrated that the prominent rectification of the instantaneous macroscopic current amplitude is due to a voltage-dependent unitary current conductance. The single channel amplitudes are very small, i.e., 0.10 +/- 0.02 pA at +140 mV for external Cl(-) and internal I(-). Conductivity and permeability sequences were determined for various external and internal anions, and both values increase for anions with lower dehydration energies. ClC-4 exhibits pore properties that are distinct from other ClC isoforms. These differences can be explained by assuming differences in the size of the pore narrowing and the electrostatic potentials within the ion conduction pathways.
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Biophys J 84(4): 2306-2318
PMID: 12668439

Anion Permeation in Human ClC-4 Channels

RWTH Aachen, Institute of Physiology, Aachen, Germany; Centro de Estudios Cientificos, Valdivia, Chile; and Departamento de Biologia, Facultad de Ciencias, Universidad de Chile, Santiago, Chile
Address reprint requests to Christoph Fahlke, Institut für Physiologie, RWTH Aachen, Pauwelsstr. 30, D-52074 Aachen, Germany. Tel.: 49-241-80-88810; Fax: 49-241-80-82434; E-mail: ed.nehcaa-htwr.ygoloisyhp@eklhafhc.
Address reprint requests to Christoph Fahlke, Institut für Physiologie, RWTH Aachen, Pauwelsstr. 30, D-52074 Aachen, Germany. Tel.: 49-241-80-88810; Fax: 49-241-80-82434; E-mail: ed.nehcaa-htwr.ygoloisyhp@eklhafhc.
Received 2002 Sep 4; Accepted 2002 Nov 22.
Copyright © 2003, Biophysical Society

Abstract

ClC-4 and ClC-5 are mammalian ClC isoforms with unique ion conduction and gating properties. Macroscopic current recordings in heterologous expression systems revealed very small currents at negative potentials, whereas a substantially larger instantaneous current amplitude and a subsequent activation were observed upon depolarization. Neither the functional basis nor the physiological impact of these channel features are currently understood. Here, we used whole-cell recordings to study pore properties of human ClC-4 channels heterologously expressed in tsA201 or HEK293 cells. Variance analysis demonstrated that the prominent rectification of the instantaneous macroscopic current amplitude is due to a voltage-dependent unitary current conductance. The single channel amplitudes are very small, i.e., 0.10 ± 0.02 pA at +140 mV for external Cl and internal I. Conductivity and permeability sequences were determined for various external and internal anions, and both values increase for anions with lower dehydration energies. ClC-4 exhibits pore properties that are distinct from other ClC isoforms. These differences can be explained by assuming differences in the size of the pore narrowing and the electrostatic potentials within the ion conduction pathways.

Abstract

Acknowledgments

We thank Dr. Guy Droogmann for providing us with the simplex routine used for Fig. 9, Dr. Louis DeFelice for insightful discussions and moral support concerning the analysis shown in Fig. 2, Drs. Guy Droogmann, Al George, Criss Hartzell, J.P. Johnson, Bernd Nilius, and Carlos Vanoye for helpful discussions, and Luisa Soto for excellent technical assistance.

This work began during a three-month stay of C.F. as a “Heisenberg-Stipendiat der Deutschen Forschungsgemeinschaft” (Fa 301/3-1) in Santiago de Chile. C.F. was further supported by grants from the German Research Foundation (Fa301/4-1; TP3/FOR 450/1), the Muscular Dystrophy Association of the United States, and the American Heart Association. R.L. was supported by Chilean grants FONDECYT 1000-0890, Cátedra Presidencial, and a Human Frontiers in Science Program grant. The Centro de Estudios is a Millenium Institute.

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