The Slack Sodium-Activated Potassium Channel Provides a Major Outward Current in Olfactory Neurons of Kv1.3−/− Super-Smeller Mice

Abstract: Lu S, Das P, Fadool DA, Kaczmarek LK. The Slack sodium-activated potassium channel provides a major outward current in olfactory neurons of Kv1.3Ϫ/Ϫ super-smeller mice.

“…In neuronal simulations, K Na channels caused firing accommodation Brown et al, 2008). These findings are congruent with the fact that K Na channels are a prominent rectifying K ϩ current in neurons (Dale, 1993;Hess et al, 2007;Budelli et al, 2009;Lu et al, 2010). However, direct empirical evidence for K Na channel contribution to neuronal excitability has been lacking.…”

“…We would argue that our experimental approach is the most physiological and accurately reflects the inhibition of I K by PKA. Moreover, because K Na is a prominent rectifying current in different neurons (Dale, 1993;Hess et al, 2007;Budelli et al, 2009;Lu et al, 2010), we propose that any modulation studies of I K in neurons should always be conducted in Na ϩ -containing external solutions.…”

PKA-Induced Internalization of Slack K_NaChannels Produces Dorsal Root Ganglion Neuron Hyperexcitability

“…In neuronal simulations, K Na channels caused firing accommodation Brown et al, 2008). These findings are congruent with the fact that K Na channels are a prominent rectifying K ϩ current in neurons (Dale, 1993;Hess et al, 2007;Budelli et al, 2009;Lu et al, 2010). However, direct empirical evidence for K Na channel contribution to neuronal excitability has been lacking.…”

“…We would argue that our experimental approach is the most physiological and accurately reflects the inhibition of I K by PKA. Moreover, because K Na is a prominent rectifying current in different neurons (Dale, 1993;Hess et al, 2007;Budelli et al, 2009;Lu et al, 2010), we propose that any modulation studies of I K in neurons should always be conducted in Na ϩ -containing external solutions.…”

PKA-Induced Internalization of Slack K_NaChannels Produces Dorsal Root Ganglion Neuron Hyperexcitability

“…Suppression of K Na 1.1 expression using RNAi techniques indicates that this subunit accounts for a substantial component of sustained K + current in several types of neurons, including cortical pyramidal cell, medium spiny neuron of the striatum and mitral cell of the olfactory bulb (Budelli et al, 2009;Lu et al, 2010). The channel is also expressed at high levels in nociceptive neurons within the dorsal root ganglion, and suppression of current using several approaches, including deletion of the gene for K Na 1.1, enhances neuronal excitability and produces hypersensitivity of animals to several pain-inducing stimuli (Gao et al, 2008;Tamsett et al, 2009;Nuwer et al, 2010;Huang et al, 2013;Lu et al, 2015;Martinez-Espinosa et al, 2015).…”

International Union of Basic and Clinical Pharmacology. C. Nomenclature and Properties of Calcium-Activated and Sodium-Activated Potassium Channels

“…Channel-forming proteins similar to slo1 are encoded by the Slo2.1 (Slick), Slo2.2 (Slack), and Slo3 genes, their protein products rendering a basic phenotype shared with slo1: high conductance for K 1 and dual regulation of gating by transmembrane voltage and ion recognition (Xia et al, 2004;Salkoff et al, 2006). Although the tissue expression and functional role of the slo2 and slo3 channels have been significantly elucidated (Dryer, 1994;Schreiber et al, 1998;Salkoff et al, 2006;Santi et al, 2006;Yang et al, 2007;Lu et al, 2010;Wojtovich et al, 2011), it remains unknown whether the unique ethanol sensitivity of slo1 channels extends to the other members of the Slo family.…”

Distinct Sensitivity of Slo1 Channel Proteins to Ethanol