TASK-1, a two-pore domain K+ channel, is modulated by multiple neurotransmitters in motoneurons

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.     

TWIK-2, an inactivating 2P domain K+ channel

We cloned human and rat TWIK-2 and expressed this novel 2P domain K(+) channel in transiently transfected COS cells. TWIK-2 is highly expressed in the gastrointestinal tract, the vasculature, and the immune system. Rat TWIK-2 currents are about 15 times larger than human TWIK-2 currents, but both exhibit outward rectification in a physiological K(+) gradient and mild inward rectification in symmetrical K(+) conditions. TWIK-2 currents are inactivating at depolarized potentials, and the kinetic of inactivation is highly temperature-sensitive. TWIK-2 shows an extremely low conductance, which prevents the visualization of discrete single channel events. The inactivation and rectification are intrinsic properties of TWIK-2 channels. In a physiological K(+) gradient, TWIK-2 is half inhibited by 0.1 mm Ba(2+), quinine, and quinidine. Finally, cysteine 53 in the M1P1 external loop is required for functional expression of TWIK-2 but is not critical for subunit self-assembly. TWIK-2 is the first reported 2P domain K(+) channel that inactivates. The base-line, transient, and delayed activities of TWIK-2 suggest that this novel 2P domain K(+) channel may play an important functional role in cell electrogenesis.     

Activator-induced dynamic disorder and molecular memory in human two-pore domain hTREK1 K+ channel

Ion channels are fundamental molecules in the nervous system that catalyze the flux of ions across the cell membrane. Ion channel flux activity is comparable to the catalytic activity of enzyme molecules. Saturating concentrations of substrate induce “dynamic disorder” in the kinetic rate processes of single-enzyme molecules and consequently, develop correlative “memory” of the previous history of activities. Similarly, binding of ions as substrate alone or in presence of agonists affects the catalytic turnover of single-ion channels. Here, we investigated the possible existence of dynamic disorder and molecular memory in the single human-TREK1-channel due to binding of substrate/agonist using the excised inside–out patch-clamp technique. Our results suggest that the single-hTREK1-channel behaves as a typical Michaelis–Menten enzyme molecule with a high-affinity binding site for K⁺ ion as substrate. But, in contrast to enzyme, dynamic disorder in single-hTREK1-channel was not induced by substrate K⁺ binding, but required allosteric modification of the channel molecule by the agonist, trichloroethanol. In addition, interaction of trichloroethanol with hTREK1 induced strong correlation in the waiting time and flux intensity, exemplified by distinct mode-switching between high and low flux activities. This suggested the induction of molecular memory in the channel molecule by the agonist, which persisted for several decades in time. Our mathematical modeling studies identified the kinetic rate processes associated with dynamic disorder. It further revealed the presence of multiple populations of distinct conformations that contributed to the “heterogeneity” and consequently, to the molecular memory phenomenon that we observed.     

Modulation of the two-pore domain acid-sensitive K+ channel TASK-2 (KCNK5) by changes in cell volume

The molecular identity of K(+) channels involved in Ehrlich cell volume regulation is unknown. A background K(+) conductance is activated by cell swelling and is also modulated by extracellular pH. These characteristics are most similar to those of newly emerging TASK (TWIK-related acid-sensitive K(+) channels)-type of two pore-domain K(+) channels. mTASK-2, but not TASK-1 or -3, is present in Ehrlich cells and mouse kidney tissue from where the full coding sequences were obtained. Heterologous expression of mTASK-2 cDNA in HEK-293 cells generated K(+) currents in the absence intracellular Ca(2+). Exposure to hypotonicity enhanced mTASK-2 currents and osmotic cell shrinkage led to inhibition. This occurred without altering voltage dependence and with only slight decrease in pK(a) in hypotonicity but no change in hypertonicity. Replacement with other cations yields a permselectivity sequence for mTASK-2 of K(+) > Rb(+) Cs(+) > NH(4)(+) > Na(+) congruent with Li(+), similar to that for the native conductance (I(K, vol)). Clofilium, a quaternary ammonium blocker of I(K, vol), blocked the mTASK-2-mediated K(+) current with an IC(50) of 25 microm. The presence of mTASK-2 in Ehrlich cells, its functional similarities with I(K, vol), and its modulation by changes in cell volume suggest that this two-pore domain K(+) channel participates in the regulatory volume decrease phenomenon.     

Activation of protein kinase C epsilon inhibits the two-pore domain K+ channel, TASK-1, inducing repolarization abnormalities in cardiac ventricular myocytes

Activation of the platelet-activating factor (PAF) receptor leads to a decrease in outward current in murine ventricular myocytes by inhibiting the TASK-1 channel. TASK-1 carries a background or "leak" current and is a member of the two-pore domain potassium channel family. Its inhibition is sufficient to delay repolarization, causing prolongation of the action potential duration, and in some cases, early after depolarizations. We set out to determine the cellular mechanisms that control regulation of TASK-1 by PAF. Inhibition of TASK-1 via activation of the PAF receptor is protein kinase C (PKC)-dependent. Using isoform-specific PKC inhibitor or activator peptides in patch clamp experiments, we now demonstrate that activation of PKCepsilon is both necessary and sufficient to regulate murine TASK-1 current in a heterologous expression system and to induce repolarization abnormalities in isolated myocytes. Furthermore, site-directed mutagenesis studies have identified threonine 381, in the C-terminal tail of murine TASK-1, as a critical residue in this regulation.     

System-specific O2 sensitivity of the tandem pore domain K+ channel TASK-1

Hypoxic inhibition of TASK-1, a tandem pore domain background K⁺ channel, provides a critical link between reduced O₂ levels and physiological responses in various cell types. Here, we examined the expression and O₂ sensitivity of TASK-1 in immortalized adrenomedullary chromaffin (MAH) cells. In physiological (asymmetrical) K⁺ solutions, 3 µM anandamide or 300 µM Zn²⁺ inhibited a strongly pH-sensitive current. Under symmetrical K⁺ conditions, the anandamide- and Zn²⁺-sensitive K⁺ currents were voltage independent. These data demonstrate the functional expression of TASK-1, and cellular expression of this channel was confirmed by RT-PCR and Western blotting. At concentrations that selectively inhibit TASK-1, anandamide and Zn²⁺ were without effect on the magnitude of the O₂-sensitive current or the hypoxic depolarization. Thus TASK-1 does not contribute to O₂ sensing in MAH cells, demonstrating the failure of a known O₂-sensitive K⁺ channel to respond to hypoxia in an O₂-sensing cell. These data demonstrate that, ultimately, the sensitivity of a particular K⁺ channel to hypoxia is determined by the cell, and we propose that this is achieved by coupling distinct hypoxia signaling systems to individual channels. Importantly, these data also reiterate the indirect O₂ sensitivity of TASK-1, which appears to require the presence of an intracellular mediator. hypoxia; background K⁺ channels; TASK-1; MAH cells     

Formation of functional heterodimers between the TASK-1 and TASK-3 two-pore domain potassium channel subunits.

The potassium channels in the two-pore domain family are widely expressed and regulate the excitability of neurons and other excitable cells. These channels have been shown to function as dimers, but heteromerization between the various channel subunits has not yet been reported. Here we demonstrate that two members of the TASK subfamily of potassium channels, TASK-1 and TASK-3, can form functional heterodimers when expressed in Xenopus laevis oocytes. To recognize the two TASK channel types, we took advantage of the higher sensitivity of TASK-1 over TASK-3 to physiological pH changes and the discriminating sensitivity of TASK-3 to the cationic dye ruthenium red. These features were clearly observed when the channels were expressed individually. However, when TASK-1 and TASK-3 were expressed together, the resulting current showed intermediate pH sensitivity and ruthenium red insensitivity (characteristic of TASK-1), indicating the formation of TASK-1/TASK-3 heterodimers. Expression of a tandem construct in which TASK-3 and TASK-1 were linked together yielded currents with features very similar to those observed when coexpressing the two channels. The tandem construct also responded to AT(1a) angiotensin II receptor stimulation with an inhibition that was weaker than the inhibition of homodimeric TASK-1 and greater than that shown by TASK-3. Expression of epitope-tagged channels in mammalian cells showed their primary presence in the plasma membrane consistent with their function in this location. Heteromerization of two-pore domain potassium channels may provide a greater functional diversity and additional means by which they can be regulated in their native tissues.     

Developmental expression of a functional TASK-1 2P domain K+ channel in embryonic chick heart

Background

Background K⁺ channels are the principal determinants of the resting membrane potential (RMP) in cardiac myocytes and thus, influence the magnitude and time course of the action potential (AP).

Methods

RT-PCR and in situ hybridization are used to study the distribution of TASK-1 and whole-cell patch clamp technique is employed to determine the functional expression of TASK-1 in embryonic chick heart.

Results

Chicken TASK-1 was expressed in the early tubular heart, then substantially decreased in the ventricles by embryonic day 5 (ED5), but remained relatively high in ED5 and ED11 atria. Unlike TASK-1, TASK-3 was uniformly expressed in heart at all developmental stages. In situ hybridization studies further revealed that TASK-1 was expressed throughout myocardium at Hamilton-Hamburger stages 11 and 18 (S11 &; S18) heart. In ED11 heart, TASK-1 expression was more restricted to atria. Consistent with TASK-1 expression data, patch clamp studies indicated that there was little TASK-1 current, as measured by the difference currents between pH 8.4 and pH 7.4, in ED5 and ED11 ventricular myocytes. However, TASK-1 current was present in the early embryonic heart and ED11 atrial myocytes. TASK-1 currents were also identified as 3 μM anandamide-sensitive currents. 3 μM anandamide reduced TASK-1 currents by about 58% in ED11 atrial myocytes. Zn²⁺ (100 μM) which selectively inhibits TASK-3 channel at this concentration had no effect on TASK currents. In ED11 ventricle where TASK-1 expression was down-regulated, I_K1 was about 5 times greater than in ED11 atrial myocytes.

Conclusion

Functional TASK-1 channels are differentially expressed in the developing chick heart and TASK-1 channels contribute to background K⁺ conductance in the early tubular embryonic heart and in atria. TASK-1 channels act as a contributor to background K⁺ current to modulate the cardiac excitability in the embryonic heart that expresses little I_K1.     

Desmosomal proteins in cultured and intact human periodontal ligament fibroblasts

This study examined the kinds of desmosomal proteins in the human periodontal ligament fibroblasts (PDLFs). The PDLFs obtained from young and older patients were cultured and the amounts of desmosomal proteins were measured by ELISA with antibodies to desmoplakins, desmogleins, and desmocollins. Cultured cells and tissue sections of the human periodontal ligament were immunostained with the same antibodies. Expression of desmosomal proteins in the PDLFs was clearly demonstrated both by ELISA and the immunohistochemical studies, suggesting the existence of desmosome-like junctions in the PDLFs. The junctions are considered to protect gap junctions in the PDLFs against cell transformation caused by cell contraction, which may relate to tooth eruption and repair of periodontal tissue, and/or strong occlusal forces. Statistically significant differences (P < 0.0001) in the expression of desmoplakins and desmogleins between younger and older patients were observed in this study.     

A specific two-pore domain potassium channel blocker defines the structure of the TASK-1 open pore

Two-pore domain potassium (K(2P)) channels play a key role in setting the membrane potential of excitable cells. Despite their role as putative targets for drugs and general anesthetics, little is known about the structure and the drug binding site of K(2P) channels. We describe A1899 as a potent and highly selective blocker of the K(2P) channel TASK-1. As A1899 acts as an open-channel blocker and binds to residues forming the wall of the central cavity, the drug was used to further our understanding of the channel pore. Using alanine mutagenesis screens, we have identified residues in both pore loops, the M2 and M4 segments, and the halothane response element to form the drug binding site of TASK-1. Our experimental data were used to validate a K(2P) open-pore homology model of TASK-1, providing structural insights for future rational design of drugs targeting K(2P) channels.     

TWIK-1, a ubiquitous human weakly inward rectifying K+ channel with a novel structure.

A new human weakly inward rectifying K+ channel, TWIK-1, has been isolated. This channel is 336 amino acids long and has four transmembrane domains. Unlike other mammalian K+ channels, it contains two pore-forming regions called P domains. Genes encoding structural homologues are present in the genome of Caenorhabditis elegans. TWIK-1 currents expressed in Xenopus oocytes are time-independent and present a nearly linear I-V relationship that saturated for depolarizations positive to O mV in the presence of internal Mg2+. This inward rectification is abolished in the absence of internal Mg2+. TWIK-1 has a unitary conductance of 34 pS and a kinetic behaviour that is dependent on the membrane potential. In the presence of internal Mg2+, the mean open times are 0.3 and 1.9 ms at -80 and +80 mV, respectively. The channel activity is up-regulated by activation of protein kinase C and down-regulated by internal acidification. Both types of regulation are indirect. TWIK-1 channel activity is blocked by Ba2+(IC50=100 microM), quinine (IC50=50 microM) and quinidine (IC50=95 microM). This channel is of particular interest because its mRNA is widely distributed in human tissues, and is particularly abundant in brain and heart. TWIK-1 channels are probably involved in the control of background K+ membrane conductances.     

A novel two-pore domain K+ channel,TRESK, is localized in the spinal cord

To find a novel human ion channel gene we have executed an extensive search by using a human genome draft sequencing data base. Here we report a novel two-pore domain K+ channel, TRESK (TWIK-related spinal cord K+ channel). TRESK is coded by 385 amino acids and shows low homology (19%) with previously characterized two-pore domain K+ channels. However, the most similar channel is TREK-2 (two-pore domain K+ channel), and TRESK also has two pore-forming domains and four transmembrane domains that are evolutionarily conserved in the two-pore domain K+ channel family. Moreover, we confirmed that TRESK is expressed in the spinal cord. Electrophysiological analysis demonstrated that TRESK induced outward rectification and functioned as a background K+ channel. Pharmacological analysis showed TRESK to be inhibited by previously reported K+ channel inhibitors Ba2+, propafenone, glyburide, lidocaine, quinine, quinidine, and triethanolamine. Functional analysis demonstrated TRESK to be inhibited by unsaturated free fatty acids such as arachidonic acid and docosahexaenoic acid. TRESK is also sensitive to extreme changes in extracellular and intracellular pH. These results indicate that TRESK is a novel two-pore domain K+ channel that may set the resting membrane potential of cells in the spinal cord.     

双孔钾通道TASK-1 的研究进展

双孔钾离子通道是一种背景钾离子通道,广泛分布于各种兴奋和非兴奋细胞中,并具有许多重要的生理功能。TASK-1是双孔钾离子通道家族的重要一员,它对缺氧和细胞外酸化敏感,参与形成心肌动作电位平台期,调节呼吸、肺动脉平滑肌收缩和醛固酮的分泌,并且是麻醉剂的作用靶点,人们不断对其进行研究并取得了很多重要结果,本文将概述双孔钾通道TASK-1的研究进展。     

Expression of TASK-1, a pH-sensitive twin-pore domain K(+) channel,in rat myocytes

We have investigated the expression of TASK-1, a pH-sensitive, twin-pore domain K(+) channel in the rat heart. A mammalian cell line of Chinese hamster ovary cells (CHO), transfected with a plasmid containing mouse TASK-1, demonstrated the specificity of the anti-TASK-1 antibody. TASK-1 expression in cardiac tissue was initially demonstrated by Western blot and then localized by immunofluorescence. In single rat ventricular myocytes, strong staining of the TASK-1 protein was located at the intercalated disks and across the cell in a striated pattern, corresponding to the transverse axial tubular network (T tubules). In contrast, single rat atrial myocytes were stained at the intercalated disks with a weak punctate, striated pattern corresponding to underdeveloped T tubules. Also, formamide was used to induce the detubulation of ventricular myocytes, which enabled confirmation that TASK-1 protein expression occurs in T tubules. Consistent with this, RT-PCR revealed the expression of TASK-1 mRNA in total RNA from both the ventricles and atria. In this study, we conclusively demonstrated that TASK-1 protein and mRNA were expressed in rat atrial and ventricular tissue. The extensive distribution of TASK-1 shown to exist within myocyte membranes may provide a potential future target for antiarrhythmic drugs.     

双孔钾通道TASK-1的研究进展

双孔钾离子通道是一种背景钾离子通道,广泛分布于各种兴奋和非兴奋细胞中,并具有许多重要的生理功能。TASK-1是双孔钾离子通道家族的重要一员,它对缺氧和细胞外酸化敏感,参与形成心肌动作电住平台期,调节呼吸、肺动脉平滑肌收缩和醛固酮的分泌,并且是麻醉剂的作用靶点,人们不断对其进行研究并取得了很多重要结果,本文将概述双孔钾通道TASK-1的研究进展。     

Lipids and two-pore domain K+ channels in excitable cells

Two-pore domain potassium channels (2PK) make up the newest branch of the potassium channel super-family. The channels are time- and voltage-independent and carry leak or "background" currents that are regulated by many different signaling molecules. These currents play an important role in setting the resting membrane potential and excitability of excitable cells, and, as a consequence, modulation of 2PK channel activity is thought to underlie the function of physiological processes as diverse as the sedation of anesthesia, regulation of normal cardiac rhythm and synaptic plasticity associated with simple forms of learning. Lipids, including arachidonate and its lipoxygenase metabolites, platelet-activating factor and anandamide have been identified as important mediators of some 2PK channels. Regulation can be effected by several different mechanisms. Some channels are regulated by G-protein-coupled receptors using well described signaling pathways that terminate in the activation of protein kinase C, whereas others are modulated by the direct interaction of the lipid with the channel.     

Dimerization of TWIK-1 K+ channel subunits via a disulfide bridge.

TWIK-1 is a new type of K+ channel with two P domains and is abundantly expressed in human heart and brain. Here we show that TWIK-1 subunits can self-associate to give dimers containing an interchain disulfide bridge. This assembly involves a 34 amino acid domain that is localized to the extracellular M1P1 linker loop. Cysteine 69 which is part of this interacting domain is implicated in the formation of the disulfide bond. Replacing this cysteine with a serine residue results in the loss of functional K+ channel expression. This is the first example of a covalent association of functional subunits in voltage-sensitive channels via a disulfide bridge.     

The two-pore domain K+ channel, TRESK, is activated by the cytoplasmic calcium signal through calcineurin

Agonist-induced cytoplasmic calcium signals often have profound effects on the membrane potential during cellular activation. In the present study, we report that cytoplasmic calcium elevation can regulate the membrane potential by a novel mechanism. TRESK, a recently described member of the two-pore domain potassium (2PK(+)) channel family, was activated 5-15-fold after stimulation of various Ca(2+)-mobilizing receptors in Xenopus oocytes. Extracellular application of ionomycin, as well as the microinjection of inositol 1,4,5-trisphosphate or calcium, also evoked TRESK activation, whereas microinjection of EGTA or pretreatment of the oocytes with thapsigargin prevented the receptor-mediated effect. These data indicate that TRESK is activated by increased cytoplasmic calcium concentration. However, application of Ca(2+) to inside-out membrane patches failed to influence TRESK single channel activity, suggesting that cytoplasmic factors are also required for the regulation. Cyclosporin A and FK506, specific inhibitors of the calcium/calmodulin-dependent protein phosphatase (calcineurin), completely eliminated TRESK activation. Coexpression of a constitutively active form of calcineurin with TRESK increased the basal background K(+) current and attenuated the response of the channel to the calcium signal, indicating that TRESK was activated by the permanent calcineurin activity. Serine 276 was identified as the major functional target of calcineurin in TRESK by alanine-scanning mutagenesis. This is the first example of calcineurin being involved in the regulation of a two-pore domain K(+) channel, and thus, TRESK channels may regulate the excitability of neurons and other cell types in response to Ca(2+)-mobilizing hormones and neurotransmitters in a manner that is sensitive to immunosuppressive drugs.