BACKGROUND AND PURPOSE: Neuronal ion channels are key targets of general anaesthetics and alcohol, and binding of these drugs to pre-existing and relatively specific sites is thought to alter channel gating. However, the underlying molecular mechanisms of this action are still poorly understood. Here, we investigated the neuronal Shaw2 voltage-gated K(+) (K(v)) channel to ask whether the inhalational anaesthetic halothane and n-alcohols share a binding site near the activation gate of the channel. EXPERIMENTAL APPROACH: Focusing on activation gate mutations that affect channel modulation by n-alcohols, we investigated n-alcohol-sensitive and n-alcohol-resistant K(v) channels heterologously expressed in Xenopus oocytes to probe the functional modulation by externally applied halothane using two-electrode voltage clamping and a gas-tight perfusion system. KEY RESULTS: Shaw2 K(v) channels are reversibly inhibited by halothane in a dose-dependent and saturable manner (K(0.5)= 400 microM; n(H)= 1.2). Also, discrete mutations in the channel's S4S5 linker are sufficient to reduce or confer inhibition by halothane (Shaw2-T330L and K(v)3.4-G371I/T378A respectively). Furthermore, a point mutation in the S6 segment of Shaw2 (P410A) converted the halothane-induced inhibition into halothane-induced potentiation. Lastly, the inhibition resulting from the co-application of n-butanol and halothane is consistent with the presence of overlapping binding sites for these drugs and weak binding cooperativity. CONCLUSIONS AND IMPLICATIONS: These observations strongly support a molecular model of a general anaesthetic binding site in the Shaw2 K(v) channel. This site may involve the amphiphilic interface between the S4S5 linker and the S6 segment, which plays a pivotal role in K(v) channel activation.
BACKGROUND AND PURPOSE: Neuronal ion channels are key targets of general anaesthetics and alcohol, and binding of these drugs to pre-existing and relatively specific sites is thought to alter channel gating. However, the underlying molecular mechanisms of this action are still poorly understood. Here, we investigated the neuronal Shaw2 voltage-gated K(+) (K(v)) channel to ask whether the inhalational anaesthetic halothane and n-alcohols share a binding site near the activation gate of the channel. EXPERIMENTAL APPROACH: Focusing on activation gate mutations that affect channel modulation by n-alcohols, we investigated n-alcohol-sensitive and n-alcohol-resistant K(v) channels heterologously expressed in Xenopus oocytes to probe the functional modulation by externally applied halothane using two-electrode voltage clamping and a gas-tight perfusion system. KEY RESULTS: Shaw2 K(v) channels are reversibly inhibited by halothane in a dose-dependent and saturable manner (K(0.5)= 400 microM; n(H)= 1.2). Also, discrete mutations in the channel's S4S5 linker are sufficient to reduce or confer inhibition by halothane (Shaw2-T330L and K(v)3.4-G371I/T378A respectively). Furthermore, a point mutation in the S6 segment of Shaw2 (P410A) converted the halothane-induced inhibition into halothane-induced potentiation. Lastly, the inhibition resulting from the co-application of n-butanol and halothane is consistent with the presence of overlapping binding sites for these drugs and weak binding cooperativity. CONCLUSIONS AND IMPLICATIONS: These observations strongly support a molecular model of a general anaesthetic binding site in the Shaw2 K(v) channel. This site may involve the amphiphilic interface between the S4S5 linker and the S6 segment, which plays a pivotal role in K(v) channel activation.
Authors: Hugh C Hemmings; Myles H Akabas; Peter A Goldstein; James R Trudell; Beverley A Orser; Neil L Harrison Journal: Trends Pharmacol Sci Date: 2005-10 Impact factor: 14.819
Authors: Maria I Lioudyno; Alexandra M Birch; Brian S Tanaka; Yuri Sokolov; Alan L Goldin; K George Chandy; James E Hall; Michael T Alkire Journal: J Neurosci Date: 2013-10-09 Impact factor: 6.167
Authors: Qiansheng Liang; Warren D Anderson; Shelly T Jones; Caio S Souza; Juliana M Hosoume; Werner Treptow; Manuel Covarrubias Journal: PLoS One Date: 2015-11-24 Impact factor: 3.240