Time- and Voltage-Dependent Components of Kv4.3 Inactivation

doi:10.1529/biophysj.105.059378

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CHANNELS, RECEPTORS, AND ELECTRICAL SIGNALING

Time- and Voltage-Dependent Components of Kv4.3 Inactivation

Shimin Wang ¹, Vladimir E Bondarenko ¹, Yu-jie Qu ¹, Glenna CL Bett ¹, Michael J Morales ¹, Randall L Rasmusson ¹ and Harold C Strauss ¹^*

¹ UB, SUNY

^* To whom correspondence should be addressed. E-mail: hstrauss{at}buffalo.edu.

Submitted on January 11, 2005
Revised on April 5, 2005
Accepted on 15 July 2005

Abstract
Kv4.3 inactivation is a complex multi-exponential process, whichcan occur from both closed and open states. The fast componentof inactivation is modulated by the N-terminus, but the mechanismsmediating the other components of inactivation are controversial.We studied inactivation of Kv4.3 expressed in Xenopus laevisoocytes, using the two-electrode voltage-clamp technique. Inactivationduring 2000 ms pulses at potentials positive to the activationthreshold was described by three exponents (46 ± 3, 152± 13 and 930 ± 50 ms at +50 mV, n=7) whereas closed-stateinactivation (at potentials below threshold) was described bytwo exponents (1079 ± 119 and 3719 ± 307 ms at -40mV, n=9). The fast component of open-state inactivation wasdominant at potentials positive to -20 mV. Negative to -30 mV,the intermediate and slow components dominated inactivation. Inactivation properties were dependent on pulse duration. Recovery from inactivation was strongly dependent on voltageand pulse duration. We developed an 11 state Markov model ofKv4.3 gating that incorporated a direct transition from theopen-inactivated state to the closed-inactivated state. Simulationswith this model reproduced open- and closed-state inactivation,isochronal inactivation relationships, and reopening currents. Our data suggest that inactivation can proceed primarily fromthe open state and that multiple inactivation components canbe identified.

Key Words: Xenopus oocytes, inactivation kinetics, recovery from inactivation, voltage-gated K+ channels

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