Regina Preisig‐Müller scite author profile

Tandem pore domain acid-sensitive K ؉ channel 3 (TASK-3) is a new member of the tandem pore domain potassium channel family. A cDNA encoding a 365-amino acid polypeptide with four putative transmembrane segments and two pore regions was isolated from guinea pig brain. An orthologous sequence was cloned from a human genomic library. Although TASK-3 is 62% identical to TASK-1, the cytosolic C-terminal sequence is only weakly conserved. Analysis of the gene structure identified an intron within the conserved GYG motif of the first pore region. Reverse transcriptase-polymerase chain reaction analysis showed strong expression in brain but very weak mRNA levels in other tissues. Cellattached patch-clamp recordings of TASK-3 expressed in HEK293 cells showed that the single channel currentvoltage relation was inwardly rectifying, and open probability increased markedly with depolarization. Removal of external divalent cations increased the mean single channel current measured at ؊100 mV from ؊2.3 to ؊5.8 pA. Expression of TASK-3 in Xenopus oocytes revealed an outwardly rectifying K ؉ current that was strongly decreased in the presence of lower extracellular pH. Substitution of the histidine residue His-98 by asparagine or tyrosine abolished pH sensitivity. This histidine, which is located at the outer part of the pore adjacent to the selectivity filter, may be an essential component of the extracellular pH sensor.

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THIK-1 and THIK-2, a Novel Subfamily of Tandem Pore Domain K+ Channels

Rajan¹,

Wischmeyer

Karschin

et al. 2001

Journal of Biological Chemistry

167

171

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Two cDNAs encoding novel K؉ channels, THIK-1 and THIK-2 (tandem pore domain halothane inhibited K ؉ channel), were isolated from rat brain. The proteins of 405 and 430 amino acids were 58% identical to each other. Homology analysis showed that the novel channels form a separate subfamily among tandem pore domain K ؉ channels. The genes of the human orthologs were identified as human genomic data base entries. They possess one intron each and were assigned to chromosomal region 14q24.1-14q24.3 (human (h) THIK-1) and 2p22-2p21 (hTHIK-2). In rat (r), THIK-1 (rTHIK-1) is expressed ubiquitously; rTHIK-2 expression was found in several tissues including brain and kidney. In situ hybridization of brain slices showed that rTHIK-2 is strongly expressed in most brain regions, whereas rTHIK-1 expression is more restricted. Heterologous expression of rTHIK-1 in Xenopus oocytes revealed a K ؉ channel displaying weak inward rectification in symmetrical K ؉ solution. The current was enhanced by arachidonic acid and inhibited by halothane. rTHIK-2 did not functionally express. Confocal microscopy of oocytes injected with green fluorescent protein-tagged rTHIK-1 or rTHIK-2 showed that both channel subunits are targeted to the outer membrane. However, coinjection of rTHIK-2 did not affect the currents induced by rTHIK-1, indicating that the two channel subunits do not form heteromers.

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Interaction with 14‐3‐3 proteins promotes functional expression of the potassium channels TASK‐1 and TASK‐3

Rajan

Preisig‐Müller

Wischmeyer

et al. 2002

The Journal of Physiology

140

166

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The two-pore-domain potassium channels TASK-1, TASK-3 and TASK-5 possess a conserved C-terminal motif of five amino acids. Truncation of the C-terminus of TASK-1 strongly reduced the currents measured after heterologous expression in Xenopus oocytes or HEK293 cells and decreased surface membrane expression of GFP-tagged channel proteins. Two-hybrid analysis showed that the C-terminal domain of TASK-1, TASK-3 and TASK-5, but not TASK-4, interacts with isoforms of the adapter protein 14-3-3. A pentapeptide motif at the extreme C-terminus of TASK-1, RRx(S/T)x, was found to be sufficient for weak but significant interaction with 14-3-3, whereas the last 40 amino acids of TASK-1 were required for strong binding. Deletion of a single amino acid at the C-terminal end of TASK-1 or TASK-3 abolished binding of 14-3-3 and strongly reduced the macroscopic currents observed in Xenopus oocytes. TASK-1 mutants that failed to interact with 14-3-3 isoforms (V411*, S410A, S410D) also produced only very weak macroscopic currents. In contrast, the mutant TASK-1 S409A, which interacts with 14-3-3-like wild-type channels, displayed normal macroscopic currents. Co-injection of 14-3-3z cRNA increased TASK-1 current in Xenopus oocytes by about 70 %. After co-transfection in HEK293 cells, TASK-1 and 14-3-3z (but not TASK-1DC5 and 14-3-3z) could be co-immunoprecipitated. Furthermore, TASK-1 and 14-3-3 could be coimmunoprecipitated in synaptic membrane extracts and postsynaptic density membranes. Our findings suggest that interaction of 14-3-3 with TASK-1 or TASK-3 may promote the trafficking of the channels to the surface membrane.

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Comparison of cloned Kir2 channels with native inward rectifier K⁺ channels from guinea‐pig cardiomyocytes

Liu

Derst

Schlichthörl

et al. 2001

The Journal of Physiology

149

158

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The aim of the study was to compare the properties of cloned Kir2 channels with the properties of native rectifier channels in guinea‐pig (gp) cardiac muscle. The cDNAs of gpKir2.1, gpKir2.2, gpKir2.3 and gpKir2.4 were obtained by screening a cDNA library from guinea‐pig cardiac ventricle. A partial genomic structure of all gpKir2 genes was deduced by comparison of the cDNAs with the nucleotide sequences derived from a guinea‐pig genomic library. The cell‐specific expression of Kir2 channel subunits was studied in isolated cardiomyocytes using a multi‐cell RT‐PCR approach. It was found that gpKir2.1, gpKir2.2 and gpKir2.3, but not gpKir2.4, are expressed in cardiomyocytes. Immunocytochemical analysis with polyclonal antibodies showed that expression of Kir2.4 is restricted to neuronal cells in the heart. After transfection in human embryonic kidney cells (HEK293) the mean single‐channel conductance with symmetrical K+ was found to be 30.6 pS for gpKir2.1, 40.0 pS for gpKir2.2 and 14.2 pS for Kir2.3. Cell‐attached measurements in isolated guinea‐pig cardiomyocytes (n= 351) revealed three populations of inwardly rectifying K+ channels with mean conductances of 34.0, 23.8 and 10.7 pS. Expression of the gpKir2 subunits in Xenopus oocytes showed inwardly rectifying currents. The Ba2+ concentrations required for half‐maximum block at ‐100 mV were 3.24 μm for gpKir2.1, 0.51 μm for gpKir2.2, 10.26 μm for gpKir2.3 and 235 μm for gpKir2.4. Ba2+ block of inward rectifier channels of cardiomyocytes was studied in cell‐attached recordings. The concentration and voltage dependence of Ba2+ block of the large‐conductance inward rectifier channels was virtually identical to that of gpKir2.2 expressed in Xenopus oocytes. Our results suggest that the large‐conductance inward rectifier channels found in guinea‐pig cardiomyocytes (34.0 pS) correspond to gpKir2.2. The intermediate‐conductance (23.8 pS) and low‐conductance (10.7 pS) channels described here may correspond to gpKir2.1 and gpKir2.3, respectively.

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Heteromerization of Kir2.x potassium channels contributes to the phenotype of Andersen's syndrome

Preisig‐Müller

Schlichthörl²,

Goerge³

et al. 2002

Proc. Natl. Acad. Sci. U.S.A.

197

161

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