Voltage-dependent Gating Rearrangements in the Intracellular T1-T1 Interface of a K+ Channel

doi:10.1085/jgp.200509442

Published online 13 March 2006 doi:10.1085/jgp.200509442
The Rockefeller University Press, 0022-1295 $8.00
JGP, Volume 127, Number 4, 391-400

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Voltage-dependent Gating Rearrangements in the Intracellular T1–T1 Interface of a K⁺ Channel

Guangyu Wang and Manuel Covarrubias

Department of Pathology, Anatomy, and Cell Biology, Jefferson Medical College of Thomas Jefferson University, Philadelphia, PA 19107

Correspondence to Manuel Covarrubias: manuel.covarrubias{at}jefferson.edu

The intracellular tetramerization domain (T1) of most eukaryoticvoltage-gated potassium channels (Kv channels) exists as a "hanginggondola" below the transmembrane regions that directly controlactivation gating via the electromechanical coupling betweenthe S4 voltage sensor and the main S6 gate. However, much lessis known about the putative contribution of the T1 domain toKv channel gating. This possibility is mechanistically intriguingbecause the T1–S1 linker connects the T1 domain to thevoltage-sensing domain. Previously, we demonstrated that thiol-specificreagents inhibit Kv4.1 channels by reacting in a state-dependentmanner with native Zn²⁺ site thiolate groups in the T1–T1interface; therefore, we concluded that the T1–T1 interfaceis functionally active and not protected by Zn²⁺ (Wang, G.,M. Shahidullah, C.A. Rocha, C. Strang, P.J. Pfaffinger, andM. Covarrubias. 2005. J. Gen. Physiol. 126:55–69). Here,we co-expressed Kv4.1 channels and auxiliary subunits (KChIP-1and DPPX-S) to investigate the state and voltage dependenceof the accessibility of MTSET to the three interfacial cysteinesin the T1 domain. The results showed that the average MTSETmodification rate constant (k_MTSET) is dramatically enhancedin the activated state relative to the resting and inactivatedstates ( $~$ 260- and $~$ 47-fold, respectively). Crucially, under threeseparate conditions that produce distinct activation profiles,k_MTSET is steeply voltage dependent in a manner that is preciselycorrelated with the peak conductance–voltage relations.These observations strongly suggest that Kv4 channel gatingis tightly coupled to voltage-dependent accessibility changesof native T1 cysteines in the intersubunit Zn²⁺ site. Furthermore,cross-linking of cysteine pairs across the T1–T1 interfaceinduced substantial inhibition of the channel, which supportsthe functionally dynamic role of T1 in channel gating. Therefore,we conclude that the complex voltage-dependent gating rearrangementsof eukaryotic Kv channels are not limited to the membrane-spanningcore but must include the intracellular T1–T1 interface.Oxidative stress in excitable tissues may perturb this interfaceto modulate Kv4 channel function.

Abbreviations used in this paper: DTT, dithiothretiol; Kv, voltage-dependentpotassium; MTSET, 2-trimethylammonium-ethyl-methane-thiosulfonatebromide.

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