Movement and Crevices Around a Sodium Channel S3 Segment

doi:10.1085/jgp.20028636

Published 26 August 2002. doi:10.1085/jgp.20028636

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© Rockefeller University Press, 0022-1295/2002/9/419/ $5.00
Journal of General Physiology, Volume 120, Number 3, September 2002 419-436
Movement and Crevices Around a Sodium Channel S3 Segment

Thao P. Nguyen¹^,2 and Richard Horn¹

¹ Department of Physiology, Jefferson Medical College, Philadelphia, PA 19107
² Institute of Neurological Sciences, University of Pennsylvania, Philadelphia, PA 19104

Address correspondence to Dr. Richard Horn, Department of Physiology, Jefferson Medical College, 1020 Locust St., Philadelphia, PA 19107. Fax: (215) 503-2073; E-mail: Richard.Horn{at}TJU.edu

Voltage sensing is due mainly to the movement of positivelycharged S4 segments through the membrane electric field duringchanges of membrane potential. The roles of other transmembranesegments are under study. The S3 segment of domain 4 (D4/S3)in the sodium channel Na_v1.4 carries two negatively chargedresidues and has been implicated in voltage-dependent gating.We substituted cysteines into nine putative "high impact" sitesalong the complete length of D4/S3 and evaluated their accessibilitiesto extracellular sulfhydryl reagents. Only the four outermostsubstituted cysteines (L1433C, L1431C, G1430C, and S1427C) areaccessible to extracellular sulfhydryl reagents. We measuredthe voltage-dependent modification rates of the two cysteinessituated at the extreme ends of this accessible region, L1433Cand S1427C. Independent of the charge on the sulfhydryl reagents,depolarization increases the reactivity of both of these residues.Thus, the direction of the voltage dependence is opposite tothat expected for a negatively charged voltage sensor, namelyan inward translational movement in response to depolarization.Intrinsic electrostatic potentials were probed by charged sulfhydrylreagents and were either negative or positive, respectively,near L1433C and S1427C. The magnitude of the electrostatic potentialnear S1427C decreases with depolarization, suggesting that theextracellular crevice next to it widens during depolarization.S1427C experiences 44% of the electric field, as probed by chargedcysteine reagents. To further explore movements around D4/S3,we labeled cysteines with the photoactivatable cross-linkingreagent benzophenone-4-carboxamidocysteine methanethiosulfonateand examined the effects of UV irradiation on channel gating.After labeling with this reagent, all accessible cysteine mutantsshow altered gating upon brief UV irradiation. In each case,the apparent insertion efficiency of the photoactivated benzophenoneincreases with depolarization, indicating voltage-dependentmovement near the extracellular end of D4/S3.

Key Words: cysteine accessibility • photocross-linking • benzophenone • voltage-dependent movement • electrostatic potential

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