Inhibition of "leak" potassium (K+) channels is a widespread CNS mechanism by which transmitters induce slow excitation. We show that TASK-1, a two pore domain K+ channel, provides a prominent leak K+ current and target for neurotransmitter modulation in hypoglossal motoneurons (HMs). TASK-1 mRNA is present at high levels in motoneurons, including HMs, which express a K+ current with pH- and voltage-dependent properties virtually identical to those of the cloned channel. This pH-sensitive K+ channel was fully inhibited by serotonin, norepinephrine, substance P, thyrotropin-releasing hormone, and 3,5-dihydroxyphenylglycine, a group I metabotropic glutamate receptor agonist. The neurotransmitter effect was entirely reconstituted in HEK 293 cells coexpressing TASK-1 and the TRH-R1 receptor. Given its expression patterns and the widespread prevalence of this neuromodulatory mechanism, TASK-1 also likely supports this action in other CNS neurons.
Despite widespread use of volatile general anesthetics for well over a century, the mechanisms by which they alter specific CNS functions remain unclear. Here, we present evidence implicating the two-pore domain, pH-sensitive TASK-1 channel as a target for specific, clinically important anesthetic effects in mammalian neurons. In rat somatic motoneurons and locus coeruleus cells, two populations of neurons that express TASK-1 mRNA, inhalation anesthetics activated a neuronal K ϩ conductance, causing membrane hyperpolarization and suppressing action potential discharge. These membrane effects occurred at clinically relevant anesthetic levels, with precisely the steep concentration dependence expected for anesthetic effects of these compounds. The native neuronal K ϩ current displayed voltage-and time-dependent properties that were identical to those mediated by the open-rectifier TASK-1 channel. Moreover, the neuronal K ϩ channel and heterologously expressed TASK-1 were similarly modulated by extracellular pH. The decreased cellular excitability associated with TASK-1 activation in these cell groups probably accounts for specific CNS effects of anesthetics: in motoneurons, it likely contributes to anesthetic-induced immobilization, whereas in the locus coeruleus, it may support analgesic and hypnotic actions attributed to inhibition of those neurons.
The recently described two-pore-domain K+ channels, TASK-1 and TASK-3, generate currents with a unique set of properties; specifically, the channels produce instantaneous open-rectifier (i.e., "leak") K+ currents that are modulated by extracellular pH and by clinically useful anesthetics. In this study, we used histochemical and in vitro electrophysiological approaches to determine that TASK channels are expressed in serotonergic raphe neurons and to show that they confer a pH and anesthetic sensitivity to these neurons. By combining in situ hybridization for TASK-1 or TASK-3 with immunohistochemical localization of tryptophan hydroxylase, we found that a majority of serotonergic neurons in both dorsal and caudal raphe cell groups contain TASK channel transcripts (approximately 70-90%). Whole-cell voltage-clamp recordings were obtained from raphe cells that responded to 5-HT in a manner characteristic of serotonergic neurons (i.e., with activation of an inwardly rectifying K+ current). In those cells, we isolated an endogenous K+ conductance that had properties expected of TASK channel currents; raphe neurons expressed a joint pH- and halothane-sensitive open-rectifier K+ current. The pH sensitivity of this current (pK approximately 7.0) was intermediate between that of TASK-1 and TASK-3, consistent with functional expression of both channel types. Together, these data indicate that TASK-1 and TASK-3 are expressed and functional in serotonergic raphe neurons. The pH-dependent inhibition of TASK channels in raphe neurons may contribute to ventilatory and arousal reflexes associated with extracellular acidosis; on the other hand, activation of raphe neuronal TASK channels by volatile anesthetics could play a role in their immobilizing and sedative-hypnotic effects.
Leak K+ currents contribute to the resting membrane potential and are important for modulation of neuronal excitability. Within the past few years, an entire family of genes has been described whose members form leak K+ channels, insofar as they generate potassium-selective currents with little voltage- and time-dependence. They are often referred to as "two-pore-domain" channels because of their predicted topology, which includes two pore-forming regions in each subunit. These channels are modulated by a host of different endogenous and clinical compounds such as neurotransmitters and anesthetics, and by physicochemical factors such as temperature, pH, oxygen tension, and osmolarity. They also are subject to long-term regulation by changes in gene expression. In this review, the authors describe multiple roles that modulation of leak K+ channels play in CNS function and discuss evidence that members of the two-pore-domain family are molecular substrates for these processes.
We studied the effects of inhalation anaesthetics on the membrane properties of hypoglossal motoneurones in a neonatal rat brainstem slice preparation. In current clamp, halothane caused a membrane hyperpolarization that was invariably associated with decreased input resistance; in voltage clamp, halothane induced an outward current and increased input conductance. Qualitatively similar results were obtained with isoflurane and sevoflurane. The halothane current reversed near the predicted K+ equilibrium potential (EK) and was reduced in elevated extracellular K+ and in the presence of Ba2+ (2 mm). Moreover, the Ba2+‐sensitive component of halothane current was linear and reversed near EK. The halothane current was not sensitive to glibenclamide or thyrotropin‐releasing hormone (TRH). Therefore, the halothane current was mediated, in part, by activation of a Ba2+‐sensitive K+ current distinct from the ATP‐ and neurotransmitter‐sensitive K+ currents in hypoglossal motoneurones. Halothane also inhibited Ih, a hyperpolarization‐activated cationic current; this was primarily due to a decrease in the absolute amount of current, although halothane also caused a small, but statistically significant, shift in the voltage dependence of Ih activation. Extracellular Cs+ (3 mm) blocked Ih and a component of halothane‐sensitive current with properties reminiscent of Ih. A small component of halothane current, resistant to Ba2+ and Cs+, was observed in TTX‐containing solutions at potentials depolarized to ∼−70 mV. Partial Na+ substitution by N‐methyl‐D‐glucamine completely abolished this residual current, indicating that halothane also inhibited a TTX‐resistant Na+ current active near rest potentials. Thus, halothane activates a Ba2+‐sensitive, relatively voltage‐independent K+ current and inhibits both Ih and a TTX‐insensitive persistent Na+ current in hypoglossal motoneurones. These effects of halothane decrease motoneuronal excitability and may contribute to the immobilization that accompanies inhalation anaesthesia.
Neurotransmitters and volatile anaesthetics have opposing effects on motoneuronal excitability which appear to reflect contrasting modulation of two types of subthreshold currents. Neurotransmitters increase motoneuronal excitability by inhibiting TWIK‐related acid‐sensitive K+ channels (TASK) and shifting activation of a hyperpolarization‐activated cationic current (Ih) to more depolarized potentials; on the other hand, anaesthetics decrease excitability by activating a TASK‐like current and inducing a hyperpolarizing shift in Ih activation. Here, we used whole‐cell recording from motoneurones in brainstem slices to test if neurotransmitters (serotonin (5‐HT) and noradrenaline (NA)) and an anaesthetic (halothane) indeed compete for modulation of the same ion channels ‐ and we determined which prevails. When applied together under current clamp conditions, 5‐HT reversed anaesthetic‐induced membrane hyperpolarization and increased motoneuronal excitability. Under voltage clamp conditions, 5‐HT and NA overcame most, but not all, of the halothane‐induced current. When Ih was blocked with ZD 7288, the neurotransmitters completely inhibited the K+ current activated by halothane; the halothane‐sensitive neurotransmitter current reversed at the equilibrium potential for potassium (EK) and displayed properties expected of acid‐sensitive, open‐rectifier TASK channels. To characterize modulation of Ih in relative isolation, effects of 5‐HT and halothane were examined in acidified bath solutions that blocked TASK channels. Under these conditions, 5‐HT and halothane each caused their characteristic shift in voltage‐dependent gating of Ih. When tested concurrently, however, halothane decreased the neurotransmitter‐induced depolarizing shift in Ih activation. Thus, halothane and neurotransmitters converge on TASK and Ih channels with opposite effects; transmitter action prevailed over anaesthetic effects on TASK channels, but not over effects on Ih. These data suggest that anaesthetic actions resulting from effects on either TASK or hyperpolarization‐activated cyclic nucleotide‐gated (HCN) channels in motoneurones, and perhaps at other CNS sites, can be modulated by prevailing neurotransmitter tone.
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