K Channel Subconductance Levels Result from Heteromeric Pore Conformations

doi:10.1085/jgp.200509253

Axon Instruments microelectrode amplifiers

Published online Jul 25 2005. doi:10.1085/jgp.200509253
The Rockefeller University Press, 0022-1295 $8.00
JGP, Volume 126, Number 2, 87-103

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ARTICLE

K Channel Subconductance Levels Result from Heteromeric Pore Conformations

Mark L. Chapman and Antonius M.J. VanDongen

Department of Pharmacology and Cancer Biology, Duke University Medical Center, Durham, NC 27710

Correspondence to A.M.J. VanDongen: vando005{at}mc.duke.edu

Voltage-gated K channels assemble from four identical subunitssymmetrically arranged around a central permeation pathway.Each subunit harbors a voltage-sensing domain. The sigmoidalnature of the activation kinetics suggests that multiple sensorsneed to undergo a conformational change before the channel canopen. Following activation, individual K channels alternatestochastically between two main permeation states, open andclosed. This binary character of single channel behavior suggeststhe presence of a structure in the permeation pathway that canexist in only two conformations. However, single channel analysisof drk1 (K_v2.1) K channels demonstrated the existence of fouradditional, intermediate conductance levels. These short-livedsubconductance levels are visited when the channel gate movesbetween the closed and fully open state. We have proposed thatthese sublevels arise from transient heteromeric pore conformations,in which some, but not all, subunits are in the "open" state.A minimal model based on this hypothesis relates specific subconductancestates with the number of activated subunits (Chapman et al.,1997). To stringently test this hypothesis, we constructed atandem dimer that links two K channel subunits with differentactivation thresholds. Activation of this dimer by strong depolarizationsresulted in the characteristic binary open–close behavior.However, depolarizations to membrane potentials in between theactivation thresholds of the two parents elicited highly unusualsingle channel gating, displaying frequent visits to two subconductancelevels. The voltage dependence and kinetics of the small andlarge sublevels associate them with the activation of one andtwo subunits, respectively. The data therefore support the hypothesisthat subconductance levels result from heteromeric pore conformations.In this model, both sensor movement and channel opening havea subunit basis and these processes are allosterically coupled.

M.L. Chapman's present address is Icagen, Inc., 4222 EmperorBlvd., Durham, NC 27703.

Abbreviations used in this paper: COP, conditional open probability;FL, first latency; Po, open probability.

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