THE INTRINSIC FLEXIBILITY OF THE KV VOLTAGE SENSOR AND ITS IMPLICATIONS FOR CHANNEL GATING

doi:10.1529/biophysj.105.072199

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Biophys. J. BioFAST: First Published December 2, 2005. doi:10.1529/biophysj.105.072199
© 2005 by the Biophysical Society.

A more recent version of this article appeared on March 1, 2006.

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CHANNELS, RECEPTORS, AND ELECTRICAL SIGNALING

THE INTRINSIC FLEXIBILITY OF THE KV VOLTAGE SENSOR AND ITS IMPLICATIONS FOR CHANNEL GATING

Zara A Sands ¹, Alessandro Grottesi ² and Mark S. Sansom ²^*

¹ Univ of Oxford
² University of Oxford

^* To whom correspondence should be addressed. E-mail: mark{at}biop.ox.ac.uk.

Submitted on August 5, 2005
Revised on September 13, 2005
Accepted on 9 November 2005

Abstract
Analysis of the crystal structures of the intact voltage sensitivepotassium channel KvAP (from Aeropyrum pernix) and Kv1.2 (fromrat brain), along with the isolated voltage sensor (VS) domainfrom KvAP, raises the question of the exact nature of the voltage-sensingconformational change that triggers activation of Kv and relatedvoltage gated channels. Molecular dynamics simulations of theisolated VS of KvAP in a detergent micelle environment at twodifferent temperatures (300 K and 368 K) have been used to probethe intrinsic flexibility of this domain on a tens-of-nanosecondstimescale. The VS contains a positively charged (S4) helix whichis packed against a more hydrophobic S3 helix. The simulationsat elevated temperature reveal an intrinsic flexibility/conformationalinstability of the S3a region (i.e. the C-terminus of the S3helix). It is also evident that the S4 helix undergoes hingebending and swivelling about its central I130 residue. The conformationalinstability of the S3a region facilitates the motion of theN-terminal segment of S4 (i.e. S4a). These simulations thussupport a gating model in which, in response to depolarization,an S3b-S4a 'paddle' may move relative to the rest of the VSdomain. The flexible S3a region may in turn act to help restorethe paddle to its initial conformation upon re-polarization.

Key Words: molecular dynamics, potassium channel, simulation, voltage sensor

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