Tandem-pore K(+) channels display an uneven distribution in amphibian retina

Previous studies in retinal glial (Müller) cells have suggested that the dominant membrane currents are mediated by K(+) inward-rectifier (Kir) channels. After blockade of inwardly (Kir) and outwardly (KD and BK) conducting channels, a large K(+) conductance remains, but its nature has not been determined. Tandem-pore K(+) channels are likely candidates for this potassium conductance and the purpose of the present study was to determine, using immunocytochemistry, whether Müller cells express TASK-1, TASK-2, TREK-1 and/or TREK-2 potassium channel subunits. The results reveal that retinal glial cells express TASK-1 and TASK-2 subunits, but not TREK-1 or TREK-2 subunits. Furthermore, the distribution of TASK subunits differs from that of Kir channels and may contribute to the potassium conductance of Müller cells.     

Investigation via ion pore transplantation of the putative relationship between glutamate receptors and K+ channels

The pore domains of ionotropic glutamate receptors (iGluRs) and potassium channels (K(+) channels) show several structural similarities. To test for functional compatibility, we transferred pore regions from prokaryotic, invertebrate, and vertebrate K(+) channels into pharmacologically representative iGluRs and vice versa. Although the chimeric proteins were expressed on the cell surface, only one of 45 pore chimeras showed ion channel function: The kainate receptor subunit GluR6, carrying the pore loop plus adjacent transmembrane domains of the prokaryotic, glutamate-gated, K(+)-selective GluR0, adopted several electrophysiological properties of the donor pore upon pore transplantation. This suggests that, despite structural similarities between iGluR and K(+) channel pores, there is a lack of functional compatibility so that K(+) channel pores cannot be gated by the iGluR gating machinery, and vice versa. However, K(+)-selective pores can be gated in an iGluR sequence environment, given a similar signal transduction mechanism as appears to be present in GluR0.     

Leak K⁺ channel mRNAs in dorsal root ganglia: relation to inflammation and spontaneous pain behaviour

Two pore domain potassium (K2P) channels (KCNKx.x) cause K + leak currents and are major contributors to resting membrane potential. Their roles in dorsal root ganglion (DRG) neurons normally, and in pathological pain models, are poorly understood. Therefore, we examined mRNA levels for 10 K2P channels in L4 and L5 rat DRGs normally, and 1 day and 4 days after unilateral cutaneous inflammation, induced by intradermal complete Freund's adjuvant (CFA) injections. Spontaneous foot lifting (SFL) duration (spontaneous pain behaviour) was measured in 1 day and 4 day rats < 1 h before DRG harvest. mRNA levels for KCNK channels and Kv1.4 relative to GAPDH (n = 4-6 rats/group) were determined with real-time RT-PCR. This study is the first to demonstrate expression of THIK1, THIK2 and TWIK2 mRNA in DRGs. Abundance in normal DRGs was, in descending order:Kv1.4 > TRESK(KCNK18) > TRAAK(KCNK4) > TREK2(KCNK10) = TWIK2(KCNK6) > TREK1 (KCNK2) = THIK2(KCNK12) > TASK1(KCNK3) > TASK2(KCNK5) > THIK1(KCNK13) = TASK3(KCNK9).During inflammation, the main differences from normal in DRG mRNA levels were bilateral, suggesting systemic regulation, although some channels showed evidence of ipsilateral modulation. By 1 day, bilateral K2P mRNA levels had decreased (THIK1) or increased (TASK1, THIK2) but by 4 days they were consistently decreased (TASK2, TASK3) or tended to decrease (excluding TRAAK). The decreased TASK2 mRNA was mirrored by decreased protein (TASK2-immunoreactivity) at 4 days. Ipsilateral mRNA levels at 4 days compared with 1 day were lower (TRESK, TASK1, TASK3, TASK2 and THIK2) or higher (THIK1). Ipsilateral SFL duration during inflammation was positively correlated with ipsilateral TASK1 and TASK3 mRNAs, and contralateral TASK1, TRESK and TASK2 mRNAs. Thus changes in K2P mRNA levels occurred during inflammation and for 4 K2P channels were associated with spontaneous pain behaviour (SFL). K2P channels and their altered expression are therefore associated with inflammation-induced pain.     

Cloning, localisation and functional expression of a novel human, cerebellum specific, two pore domain potassium channel

We have isolated, by degenerate PCR, a complementary DNA encoding a novel two pore domain potassium channel. This is the 7th functional member of the human tandem pore domain potassium channel family to be reported. It has an open reading frame of 1.125 kb and encodes a 374 amino acid protein which shows 62% identity to the human TASK-1 gene: identity to other human members of the family is 31-35% at the amino acid level. We believe this gene to be human TASK-3, the ortholog of the recently reported rat TASK-3 gene: amino acid identity between the two is 74%. 'Taqman' mRNA analysis demonstrated a very specific tissue distribution pattern, showing human TASK-3 mRNA to be localised largely in the cerebellum, in contrast rat TASK-3 was reported to be widely distributed. We have shown by radiation hybrid mapping that human TASK-3 can be assigned to chromosome 8q24.3. Human TASK-3 was demonstrated to endow Xenopus oocytes with a negative resting membrane potential through the presence of a large K(+) selective conductance. TASK-3 is inhibited by extracellular acidosis with a mid-point of inhibition around pH 6. 5, supporting the predictions from the sequence data that this is a third human TASK (TWIK-related acid sensitive K(+) channel) gene.     

Involvement of leak K~+ channels in neurological disorders

TWIK-related acid-sensitive K+(TASK) channels give rise to leak K+ currents which influence the resting membrane potential and input resistance. The wide expression of TASK1 and TASK3 channels in the central nervous system suggests that these channels are critically involved in neurological disorders. It has become apparent in the past decade that TASK channels play critical roles for the development of various neurological disorders. In this review, I describe evidence for their roles in ischemia, epilepsy, learning/memory/cognition and apoptosis.     

The TASK background K2P channels: chemo- and nutrient sensors

Specialized chemo- and nutrient-sensing cells share a common electrophysiological mechanism by transducing low O(2), high CO(2) and low glucose stimuli into a compensatory cellular response: the closing of background K(+) channels encoded by the K(2P) subunits. Inhibition of the TASK K(2P) channels by extracellular acidosis leads to an increased excitability of brainstem respiratory neurons. Moreover, hypoxic down-modulation of TASK channels is implicated in the activation of glomus cells in the carotid body. Stimulation of both types of cell leads to an enhanced ventilation and to cardiocirculatory adjustments. Differential modulation of TASK channels by acidosis and high glucose alters excitability of the hypothalamic orexin neurons, which influence arousal, food seeking and breathing. These recent results shed light on the role of TASK channels in sensing physiological stimuli.     

BK channels in human glioma cells have enhanced calcium sensitivity

We have previously demonstrated the expression of large-conductance, calcium-activated potassium (BK) channels in human glioma cells. In the present study, we characterized the calcium sensitivity of glioma BK channels in excised membrane patches. Channels in inside-out patches were activated at -60 mV by 2.1 x 10(-6) M cytosolic Ca(2+), were highly K(+)-selective, and had a slope conductance of approximately iqual 210 pS. We characterized the Ca(2+) sensitivity of these channels in detail by isolating BK currents in outside-out patches with different free [Ca(2+)](i). The half-maximal voltage for channel activation, V(0.5), of glioma BK currents in outside-out patches was +138 mV with 0 Ca(2+)/10 EGTA. V(0.5) was shifted to +81 mV and -14 mV with free [Ca(2+)](i) of 1.5 x 10(-7) M and 2.1 x 10(-6) M, respectively. These results suggest that glioma BK channels have a higher Ca(2+) sensitivity than that described in many other human preparations. Data obtained from a cloned BK channel (hbr5) expressed in HEK cells support the conclusion that glioma BK channels have an unusually high sensitivity to calcium. In addition, the sensitivity of glioma BK channels to the BK inhibitor tetrandrine suggests the expression of BK channel auxiliary beta-subunits by glioma cells. Expression of the auxiliary beta-subunit of BK channels by glioma cells may relate to the high Ca(2+) sensitivity of glioma BK channels.     

Neurotensin inhibits background K+ channels and facilitates glutamatergic transmission in rat spinal cord dorsal horn

Neurotensin (NT) is a neuropeptide involved in the modulation of nociception. We have investigated the actions of NT on cultured postnatal rat spinal cord dorsal horn (DH) neurons. NT induced an inward current associated with a decrease in membrane conductance in 46% of the neurons and increased the frequency of glutamatergic miniature excitatory synaptic currents in 37% of the neurons. Similar effects were observed in acute slices. Both effects of NT were reproduced by the selective NTS1 agonist JMV449 and blocked by the NTS1 antagonist SR48692 and the NTS1/NTS2 antagonist SR142948A. The NTS2 agonist levocabastine had no effect. The actions of NT persisted after inactivation of G(i/o) proteins by pertussis toxin but were absent after inactivation of protein kinase C (PKC) by chelerythrine or inhibition of the MAPK (ERK1/2) pathway by PD98059. Pre- and postsynaptic effects of NT were insensitive to classical voltage- and Ca(2+) -dependent K(+) channel blockers. The K(+) conductance inhibited by NT was blocked by Ba(2+) and displayed no or little inward rectification, despite the presence of strongly rectifying Ba(2+) -sensitive K(+) conductance in these neurons. This suggested that NT blocked two-pore domain (K2P) background K(+) -channels rather than inwardly rectifying K(+) channels. Zn(2+) ions, which inhibit TRESK and TASK-3 K2P channels, decreased NT-induced current. Our results indicate that in DH neurons NT activates NTS1 receptors which, via the PKC-dependent activation of the MAPK (ERK1/2) pathway, depolarize the postsynaptic neuron and increase the synaptic release of glutamate. These actions of NT might modulate the transfer and the integration of somatosensory information in the DH.     

Deletion of TASK1 and TASK3 channels disrupts intrinsic excitability but does not abolish glucose or pH responses of orexin/hypocretin neurons

The firing of hypothalamic hypocretin/orexin neurons is vital for normal sleep–wake transitions, but its molecular determinants are not well understood. It was recently proposed that TASK (TWIK-related acid-sensitive potassium) channels [TASK1 (K_2P3.1) and/or TASK3 (K_2P9.1)] regulate neuronal firing and may contribute to the specialized responses of orexin neurons to glucose and pH. Here we tested these theories by performing patch-clamp recordings from orexin neurons directly identified by targeted green fluorescent protein labelling in brain slices from TASK1/3 double-knockout mice. The deletion of TASK1/3 channels significantly reduced the ability of orexin cells to generate high-frequency firing. Consistent with reduced excitability, individual action potentials from knockout cells had lower rates of rise, higher thresholds and more depolarized after-hyperpolarizations. However, orexin neurons from TASK1/3 knockout mice retained typical responses to glucose and pH, and the knockout animals showed normal food-anticipatory locomotor activity. Our results support a novel role for TASK genes in enhancing neuronal excitability and promoting high-frequency firing, but suggest that TASK1/3 subunits are not essential for orexin cell responses to glucose and pH.     

A novel KCNA1 mutation in a patient with paroxysmal ataxia,myokymia, painful contractures and metabolic dysfunctions

Episodic ataxia type 1 (EA1) is a human dominant neurological syndrome characterized by continuous myokymia, episodic attacks of ataxic gait and spastic contractions of skeletal muscles that can be triggered by emotional stress and fatigue. This rare disease is caused by missense mutations in the KCNA1 gene coding for the neuronal voltage gated potassium channel Kv1.1, which contributes to nerve cell excitability in the cerebellum, hippocampus, cortex and peripheral nervous system. We identified a novel KCNA1 mutation, E283K, in an Italian proband presenting with paroxysmal ataxia and myokymia aggravated by painful contractures and metabolic dysfunctions. The E283K mutation is located in the S3–S4 extracellular linker belonging to the voltage sensor domain of Kv channels. In order to test whether the E283K mutation affects Kv1.1 biophysical properties we transfected HEK293 cells with WT or mutant cDNAs alone or in a 1:1 combination, and recorded relative potassium currents in the whole-cell configuration of patch-clamp. Mutant E283K channels display voltage-dependent activation shifted by 10 mV toward positive potentials and kinetics of activation slowed by ~ 2 fold compared to WT channels. Potassium currents resulting from heteromeric WT/E283K channels show voltage-dependent gating and kinetics of activation intermediate between WT and mutant homomeric channels. Based on homology modeling studies of the mutant E283K, we propose a molecular explanation for the reduced voltage sensitivity and slow channel opening. Overall, our results suggest that the replacement of a negatively charged residue with a positively charged lysine at position 283 in Kv1.1 causes a drop of potassium current that likely accounts for EA-1 symptoms in the heterozygous carrier.     

Tandem-pore domain potassium channels are functionally expressed in retinal (Müller) glial cells

Tandem-pore domain (2P-domain) K+-channels regulate neuronal excitability, but their function in glia, particularly, in retinal glial cells, is unclear. We have previously demonstrated the immunocytochemical localization of the 2P-domain K+ channels TASK-1 and TASK-2 in retinal Müller glial cells of amphibians. The purpose of the present study was to determine whether these channels were functional, by employing whole-cell recording from frog and mammalian (guinea pig, rat and mouse) Müller cells and confocal microscopy to monitor swelling in rat Müller cells. TASK-like immunolabel was localized in these cells. The currents mediated by 2P-domain channels were studied in isolation after blocking Kir, K(A), K(D), and BK channels. The remaining cell conductance was mostly outward and was depressed by acid pH, bupivacaine, methanandamide, quinine, and clofilium, and activated by alkaline pH in a manner consistent with that described for TASK channels. Arachidonic acid (an activator of TREK channels) had no effect on this conductance. Blockade of the conductance with bupivacaine depolarized the Müller cell membrane potential by about 50%. In slices of the rat retina, adenosine inhibited osmotic glial cell swelling via activation of A1 receptors and subsequent opening of 2P-domain K+ channels. The swelling was strongly increased by clofilium and quinine (inhibitors of 2P-domain K+ channels). These data suggest that 2P-domain K+ channels are involved in homeostasis of glial cell volume, in activity-dependent spatial K+ buffering and may play a role in maintenance of a hyperpolarized membrane potential especially in conditions where Kir channels are blocked or downregulated.     

A TASK-like pH- and amine-sensitive 'leak' K+ conductance regulates neonatal rat facial motoneuron excitability in vitro

A 'leak' potassium (K+) conductance (gK(Leak)) modulated by amine neurotransmitters is a major determinant of neonatal rat facial motoneuron excitability. Although the molecular identity of gK(Leak) is unknown, TASK-1 and TASK-3 channel mRNA is found in facial motoneurons. External pH, across the physiological range (pH 6-8), and noradrenaline (NA) modulated a conductance that displayed a relatively linear current/voltage relationship and reversed at the K+ equilibrium potential, consistent with inhibition of gK(Leak). The pH-sensitive current (I(pH)), was maximal around pH 8, fully inhibited near pH 6 and was described by a modified Hill equation with a pK of 7.1. The NA-induced current (I(NA)) was occluded at pH 6 and enhanced at pH 7.7. The TASK-1 selective inhibitor anandamide (10 microM), its stable analogue methanandamide (10 microM), the TASK-3 selective inhibitor ruthenium red (10 microM) and Zn2+ (100-300 microM) all failed to alter facial motoneuron membrane current or block I(NA) or I(pH). Isoflurane, a volatile anaesthetic that enhances heteromeric TASK-1/TASK-3 currents, increased gK(Leak). Ba2+, Cs+ and Rb+ blocked I(NA) and I(pH) voltage-dependently with maximal block at hyperpolarized potentials. 4-Aminopyridine (4-AP, 4 mM) voltage-independently blocked I(NA) and I(pH). In summary, gK(Leak) displays some of the properties of a TASK-like conductance. The linearity of gK(Leak) and an independence of activation on external [K+] suggests against pH-sensitive inwardly rectifying K+ channels. Our results argue against principal contributions to gK(Leak) by homomeric TASK-1 or TASK-3 channels, while the potentiation by isoflurane supports a predominant role for heterodimeric TASK-1/TASK-3 channels.     

Identification and distribution of a two-pore domain potassium channel in the CNS of Aplysia californica

A cDNA encoding a potassium channel of the two-pore domain family (K2p) of leak channels was cloned from the CNS of the marine opisthobranch Aplysia californica. This is the first sequence of the K2p family identified in molluscs and has been named AcK2p1. The deduced amino acid sequence is homologous to channels of the mammalian two-pore domain halothane inhibited (THIK) subfamily, bearing 46% identity to THIK-1 (KCNK 13) and 48% to THIK-2 (KCNK12). We used in-situ hybridization to analyze the distribution of this class of channels in the CNS. AcK2p1 is specifically expressed in many central neurons of all major ganglia including the largest identified neurons MCC, R2 and LP1. The highest expression of AcK2p1 was detected in an asymmetrical and distinct cluster of up to 30 cells located at the dorsal-medial region of the right pleural ganglion. The neuron-specific distribution seen in the molluscan CNS is consistent with data from mammals that indicate THIK is only expressed in restricted neuronal populations, suggesting its involvement in both the maintenance of neuronal phenotype and in the specific functional role of these neurons in their respective networks.     

Anticonvulsant phenytoin affects voltage-gated potassium currents in cerebellar granule cells

The anticonvulsant drug phenytoin (diphenylhydantoin, DPH) was examined for its action on potassium currents in cerebellar granule cells using the whole-cell patch-clamp technique. Granular cells expressed two main types of voltage-dependent potassium currents: the first, sensitive to Tetraethylammonium ion (TEA), resembles a delayed rectifier K(+) channel (I(d)); the second shows biophysical and pharmacological properties similar to an I(A)-type potassium current. Phenytoin blocks the I(A) current in a dose-dependent manner, with an apparent dissociation constant K(d) of (73+/-7) microM. The drug shifts the steady-state inactivation curves towards a more negative potential, stabilizing the inactivated state, while the activation kinetics remain unaffected. The estimated K(d) when the cell is held to -100 mV (closed state of the channel) is 145+/-8 microM which decreases to 35+/-10 microM at -80 mV holding potential (partial inactivation of the channel). Phenytoin shows a discriminant behaviour between the two different types of potassium channels because at high concentration the effect of the drug on the delayed rectifier K(+) channel is negligible.     

Expression of ion channels and mutational effects in giant Drosophila neurons differentiated from cell division-arrested embryonic neuroblasts.

A culture system of "giant" Drosophila neurons derived from cytokinesis-arrested embryonic neuroblasts was developed to overcome the technical difficulties usually encountered in studying small Drosophila neurons. Cytochalasin B-treated neuroblasts differentiated into giant multinucleated cells that displayed neuronal morphology and neuron-specific markers (Wu et al., 1990). Here, we report that these giant neurons express different excitability patterns and membrane channels similar to those reported in excitable tissues of Drosophila. Individual neurons exhibited distinct all-or-none or graded voltage responses upon current injection. Both current- and voltage-clamp recordings could be performed on the same neuron because of the large cell size, thus making it possible to elucidate the functional role of the individual types of channels. By using pharmacological agents and ion substitution, the following currents were identified in these giant neurons: inward Na+ and Ca2+ currents and outward voltage-activated (the A-type and delayed rectifier) and Ca(2+)-activated K+ currents. In addition, we found a tetrodotoxin (TTX)-sensitive, Na(+)-dependent outward K+ current and a persistent component of an inward Na+ current, which have not been reported in Drosophila previously. This culture system can be used to analyze the mutational perturbations in ion channels and the resultant alterations in membrane excitability. Neurons from the mutant slowpoke (slo), which is known to lack a component of the Ca(2+)-activated K+ currents in muscles, exhibited prolonged action potentials associated with defects in the Ca(2+)-activated K+ current. This abnormality appeared to be more severe in the neurites than in the soma.     

Potassium channels are involved in zinc-induced apoptosis in MES23.5 cells

There is evidence that zinc may be involved in the pathogenesis of Parkinson's disease by an apoptotic pathway. However, the mechanisms underlying zinc-induced apoptosis are unknown. Previous studies showed that 6-hydroxydopamine (6-OHDA)-enhanced potassium channels are involved in apoptosis of dopaminergic neurons. Our study was designed to test whether zinc-induced apoptosis was mediated by potassium channels. First we demonstrated cell apoptosis with zinc treatment by Hoechst staining assay. The results showed that 13.38% +/- 0.6% of MES23.5 cells were apoptotic after 24 hr of incubation with 60 microM zinc sulfate. Then we observed that the tyrosine hydroxylase (TH) protein expression and the dopamine content decreased, as detected by Western blots and high-performance liquid chromatography-electrochemical detection (HPLC-ECD). We further elucidated the mechanism of cell apoptosis by using whole-cell patch clamp recording. The data demonstrated that MES23.5 cells exhibited a tetraethylammonium (TEA)-sensitive outward K(+) current with delayed rectifier characteristics. Increases of K(+) current density were recorded following the treatment with 60 microM zinc for 4-8 hr. After incubation with 20 mM TEA, the zinc-induced enhancement of K(+) currents was fully blocked. Furthermore, incubation with TEA blocked zinc-mediated caspase-3 activation and cell apoptosis. These data suggest that zinc-induced apoptosis of MES23.5 dopaminergic cells may due to the enhancement of TEA-sensitive K(+) channel activity.     

Kir4.1 channels mediate a depolarization of hippocampal astrocytes under hyperammonemic conditions in situ

Increased ammonium (NH(4) (+) ) concentration in the brain is the prime candidate responsible for hepatic encephalopathy (HE), a serious neurological disorder caused by liver failure and characterized by disturbed glutamatergic neurotransmission and impaired glial function. We investigated the mechanisms of NH(4) (+) -induced depolarization of astrocytes in mouse hippocampal slices using whole-cell patch-clamp and potassium-selective microelectrodes. At postnatal days (P) 18-21, perfusion with 5 mM NH(4) (+) evoked a transient increase in the extracellular potassium concentration ([K(+) ](o) ) by about 1 mM. Astrocytes depolarized by on average 8 mV and then slowly repolarized to a plateau depolarization of 6 mV, which was maintained during NH(4) (+) perfusion. In voltage-clamped astrocytes, NH(4) (+) induced an inward current and a reduction in membrane resistance. Amplitudes of [K(+) ](o) transients and astrocyte depolarization/inward currents increased from P3-4 to P18-21. Perfusion with 100 μM Ba(2+) did not alter [K(+) ](o) transients but strongly reduced both astrocyte depolarization and inward currents. NH(4) (+) -induced depolarization and inward currents were also virtually absent in slices from Kir4.1 -/- mice, while [K(+) ](o) transients were unaltered. Blocking Na(+) /K(+) -ATPase with ouabain caused an immediate and complex increase in [K(+) ](o) . Taken together, our results are in agreement with the hypothesis that reduced uptake of K(+) by the Na(+) , K(+) -ATPase in the presence of NH(4) (+) disturbs the extracellular K(+) homeostasis. Furthermore, astrocytes depolarize in response to the increase in [K(+) ](o) and by influx of NH(4) (+) through Kir4.1 channels. The depolarization reduces the astrocytes' capacity for channel-mediated flux of K(+) and for uptake of glutamate and might hereby contribute to the pathology of HE.     

Electrical and neurotransmitter activity of mature neurons derived from mouse embryonic stem cells by Sox-1 lineage selection and directed differentiation

Sx1TV2/16C is a mouse embryonic stem (ES) cell line in which one copy of the Sox1 gene, an early neuroectodermal marker, has been targeted with a neomycin (G418) selection cassette. A combination of directed differentiation with retinoic acid and G418 selection results in an enriched neural stem cell population that can be further differentiated into neurons. After 6-7 days post-plating (D6-7PP) most neurons readily fired tetrodotoxin (TTX)-sensitive action potentials due to the expression of TTX-sensitive Na(+) and tetraethylammonium (TEA)-sensitive K(+) channels. Neurons reached their maximal cell capacitance after D6-7PP; however, ion channel expression continued until at least D21PP. The percentage of cells receiving spontaneous synaptic currents (s.s.c.) increased with days in culture until 100% of cells received a synaptic input by D20PP. Spontaneous synaptic currents were reduced in amplitude and frequency by TTX, or upon exposure to a Ca(2+)-free, 2.5 mm Mg(2+) saline. S.s.c. of rapid decay time constants were preferentially blocked by the nonNMDA glutamatergic receptor antagonists CNQX or NBQX. Ca(2+) levels within ES cell-derived neurons increased in response to glutamate receptor agonists l-glutamate, AMPA, N-methyl-d-aspartate (NMDA) and kainic acid and to acetylcholine, ATP and dopamine. ES cell-derived neurons also generated cationic and Cl(-)-selective currents in response to NMDA and glycine or GABA, respectively. It was concluded that ES-derived neurons fire action potentials, receive excitatory and inhibitory synaptic input and respond to various neurotransmitters in a manner akin to primary central neurons.