Charged Residues between the Selectivity Filter and S6 Segments Contribute to the Permeation Phenotype of the Sodium Channel

doi:10.1085/jgp.115.1.81

Published 1 January 2000. doi:10.1085/jgp.115.1.81

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Original Article

Charged Residues between the Selectivity Filter and S6 Segments Contribute to the Permeation Phenotype of the Sodium Channel

Ronald A. Li^a, Patricio Vélez^a, Nipavan Chiamvimonvat^a, Gordon F. Tomaselli^a, and Eduardo Marbán^a

^a From the Institute of Molecular Cardiobiology, The Johns Hopkins University School of Medicine, Baltimore, Maryland 21205
Institute of Molecular Cardiobiology, The Johns Hopkins University School of Medicine, 720 Rutland Avenue/Ross 844, Baltimore, MD 21205.410-955-7953

marban{at}jhmi.edu

The deep regions of the Na⁺ channel pore around the selectivityfilter have been studied extensively; however, little is knownabout the adjacent linkers between the P loops and S6. The presenceof conserved charged residues, including five in a row in domainIII (D-III), hints that these linkers may play a role in permeation.To characterize the structural topology and function of theselinkers, we neutralized the charged residues (from position411 in D-I and its homologues in D-II, -III, and -IV to theputative start sites of S6) individually by cysteine substitution.Several cysteine mutants displayed enhanced sensitivities toCd²⁺ block relative to wild-type and/or were modifiable by externalsulfhydryl-specific methanethiosulfonate reagents when expressedin TSA-201 cells, indicating that these amino acids reside inthe permeation pathway. While neutralization of positive chargesdid not alter single-channel conductance, negative charge neutralizationsgenerally reduced conductance, suggesting that such chargesfacilitate ion permeation. The electrical distances for Cd²⁺binding to these residues reveal a secondary "dip" into themembrane field of the linkers in domains II and IV. Our findingsdemonstrate significant functional roles and surprising structuralfeatures of these previously unexplored external charged residues.

Key Words: sodium channel • outer pore • cysteine mutagenesis • sulfhydryl modification • single-channel recording

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