Tracking Voltage-dependent Conformational Changes in Skeletal Muscle Sodium Channel during Activation

doi:10.1085/jgp.20028679

Published 29 October 2002. doi:10.1085/jgp.20028679

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© Rockefeller University Press, 0022-1295/2002/11/629/ $5.00
Journal of General Physiology, Volume 120, Number 5, November 2002 629-645
Tracking Voltage-dependent Conformational Changes in Skeletal Muscle Sodium Channel during Activation

Baron Chanda and Francisco Bezanilla

Department of Physiology and Department of Anesthesiology, David Geffen School of Medicine at UCLA, Los Angeles, CA 90095

Address correspondence to Dr. Francisco Bezanilla, Department of Physiology, David Geffen School of Medicine at UCLA, 10833 LeConte Ave., Los Angeles, CA 90095. Fax: (310) 794-9612; E-mail: fbezanil{at}ucla.edu

The primary voltage sensor of the sodium channel is comprisedof four positively charged S4 segments that mainly differ inthe number of charged residues and are expected to contributedifferentially to the gating process. To understand their kineticand steady-state behavior, the fluorescence signals from thesites proximal to each of the four S4 segments of a rat skeletalmuscle sodium channel were monitored simultaneously with eithergating or ionic currents. At least one of the kinetic componentsof fluorescence from every S4 segment correlates with movementof gating charge. The fast kinetic component of fluorescencefrom sites S216C (S4 domain I), S660C (S4 domain II), and L1115C(S4 domain III) is comparable to the fast component of gatingcurrents. In contrast, the fast component of fluorescence fromthe site S1436C (S4 domain IV) correlates with the slow componentof gating. In all the cases, the slow component of fluorescencedoes not have any apparent correlation with charge movement.The fluorescence signals from sites reflecting the movementof S4s in the first three domains initiate simultaneously, whereasthe fluorescence signals from the site S1436C exhibit a lagphase. These results suggest that the voltage-dependent movementof S4 domain IV is a later step in the activation sequence.Analysis of equilibrium and kinetic properties of fluorescenceover activation voltage range indicate that S4 domain III islikely to move at most hyperpolarized potentials, whereas theS4s in domain I and domain II move at more depolarized potentials.The kinetics of fluorescence changes from sites near S4-DIVare slower than the activation time constants, suggesting thatthe voltage-dependent movement of S4-DIV may not be a prerequisitefor channel opening. These experiments allow us to map structuralfeatures onto the kinetic landscape of a sodium channel duringactivation.

Key Words: conformational changes • fluorescence • gating currents • sodium channel

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