A Na+ Channel Mutation Linked to Hypokalemic Periodic Paralysis Exposes a Proton-selective Gating Pore

doi:10.1085/jgp.200709755

Published online June 25, 2007
doi:10.1085/jgp.200709755
The Journal of General Physiology, Vol. 130, No. 1, 11-20
The Rockefeller University Press, 0022-1295 $30.00
© 2007 Struyk et al.

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ARTICLE

A Na⁺ Channel Mutation Linked to Hypokalemic Periodic Paralysis Exposes a Proton-selective Gating Pore

Arie F. Struyk¹ and Stephen C. Cannon¹^,2

¹ Department of Neurology and ² Program in Neuroscience, University of Texas-Southwestern Medical Center, Dallas, TX 75390

Correspondence to Arie F. Struyk: arie.struyk{at}utsouthwestern.edu

The heritable muscle disorder hypokalemic periodic paralysis(HypoPP) is characterized by attacks of flaccid weakness, broughton by sustained sarcolemmal depolarization. HypoPP is geneticallylinked to missense mutations at charged residues in the S4 voltage-sensingsegments of either CaV1.1 (the skeletal muscle L-type Ca²⁺ channel)or NaV1.4 (the skeletal muscle voltage-gated Na⁺ channel). Althoughthese mutations alter the gating of both channels, these functionaldefects have proven insufficient to explain the sarcolemmaldepolarization in affected muscle. Recent insight into the topologyof the S4 voltage-sensing domain has aroused interest in analternative pathomechanism, wherein HypoPP mutations might generatean aberrant ionic leak conductance by unblocking the putativeaqueous crevice ("gating-pore") in which the S4 segment resides.We tested the rat isoform of NaV1.4 harboring the HypoPP mutationR663H (human R669H ortholog) at the outermost arginine of S4in domain II for a gating-pore conductance. We found that themutation R663H permits transmembrane permeation of protons,but not larger cations, similar to the conductance displayedby histidine substitution at Shaker K⁺ channel S4 sites. Theseresults are consistent with the notion that the outermost chargedresidue in the DIIS4 segment is simultaneously accessible tothe cytoplasmic and extracellular spaces when the voltage sensoris positioned inwardly. The predicted magnitude of this protonleak in mature skeletal muscle is small relative to the restingK⁺ and Cl^– conductances, and is thus not likely to fullyaccount for the aberrant sarcolemmal depolarization underlyingthe paralytic attacks. Rather, it is possible that a sustainedproton leak may contribute to instability of V_REST indirectly,for instance, by interfering with intracellular pH homeostasis.

Abbreviations used in this paper: HB, high-buffer; HypoPP, hypokalemicperiodic paralysis; WT, wild-type.

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