Georges Romey

Inhalational anesthetics activate two-pore-domain background K + channels

Volatile anesthetics produce safe, reversible unconsciousness, amnesia and analgesia via hyperpolarization of mammalian neurons. In molluscan pacemaker neurons, they activate an inhibitory synaptic K+ current (IKAn), proposed to be important in general anesthesia. Here we show that TASK and TREK-1, two recently cloned mammalian two-P-domain K+ channels similar to IKAn in biophysical properties, are activated by volatile general anesthetics. Chloroform, diethyl ether, halothane and isoflurane activated TREK-1, whereas only halothane and isoflurane activated TASK. Carboxy (C)-terminal regions were critical for anesthetic activation in both channels. Thus both TREK-1 and TASK are possibly important target sites for these agents.

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.

Polyunsaturated fatty acids are potent neuroprotectors

Results reported in this work suggest a potential therapeutic value of polyunsaturated fatty acids for cerebral pathologies as previously proposed by others for cardiac diseases. We show that the polyunsaturated fatty acid linolenic acid prevents neuronal death in an animal model of transient global ischemia even when administered after the insult. Linolenic acid also protects animals treated with kainate against seizures and hippocampal lesions. The same effects have been observed in an in vitro model of seizure‐like activity using glutamatergic neurons and they have been shown to be associated with blockade of glutamatergic transmission by low concentrations of distinct polyunsaturated fatty acids. Our data suggest that the opening of background K+ channels, like TREK‐1 and TRAAK, which are activated by arachidonic acid and other polyunsaturated fatty acids such as docosahexaenoic acid and linolenic acid, is a significant factor in this neuroprotective effect. These channels are abundant in the brain where they are located both pre‐ and post‐synaptically, and are insensitive to saturated fatty acids, which offer no neuroprotection.

Cloning, functional expression and brain localization of a novel unconventional outward rectifier K+ channel.

Human TWIK‐1, which has been cloned recently, is a new structural type of weak inward rectifier K+ channel. Here we report the structural and functional properties of TREK‐1, a mammalian TWIK‐1‐related K+ channel. Despite a low amino acid identity between TWIK‐1 and TREK‐1 (approximately 28%), both channel proteins share the same overall structural arrangement consisting of two pore‐forming domains and four transmembrane segments (TMS). This structural similarity does not give rise to a functional analogy. K+ currents generated by TWIK‐1 are inwardly rectifying while K+ currents generated by TREK‐1 are outwardly rectifying. These channels have a conductance of 14 pS. TREK‐1 currents are insensitive to pharmacological agents that block TWIK‐1 activity such as quinine and quinidine. Extensive inhibitions of TREK‐1 activity are observed after activation of protein kinases A and C. TREK‐1 currents are sensitive to extracellular K+ and Na+. TREK‐1 mRNA is expressed in most tissues and is particularly abundant in the lung and in the brain. Its localization in this latter tissue has been studied by in situ hybridization. TREK‐1 expression is high in the olfactory bulb, hippocampus and cerebellum. These results provide the first evidence for the existence of a K+ channel family with four TMS and two pore domains in the nervous system of mammals. They also show that different members in this structural family can have totally different functional properties.

TREK-1, a K+ channel involved in neuroprotection and general anesthesia

TREK‐1 is a two‐pore‐domain background potassium channel expressed throughout the central nervous system. It is opened by polyunsaturated fatty acids and lysophospholipids. It is inhibited by neurotransmitters that produce an increase in intracellular cAMP and by those that activate the Gq protein pathway. TREK‐1 is also activated by volatile anesthetics and has been suggested to be an important target in the action of these drugs. Using mice with a disrupted TREK‐1 gene, we now show that TREK‐1 has an important role in neuroprotection against epilepsy and brain and spinal chord ischemia. Trek1−/− mice display an increased sensitivity to ischemia and epilepsy. Neuroprotection by polyunsaturated fatty acids, which is impressive in Trek1+/+ mice, disappears in Trek1−/− mice indicating a central role of TREK‐1 in this process. Trek1−/− mice are also resistant to anesthesia by volatile anesthetics. TREK‐1 emerges as a potential innovative target for developing new therapeutic agents for neurology and anesthesiology.

Properties of KvLQT1 K+ channel mutations in Romano–Ward and Jervell and Lange-Nielsen inherited cardiac arrhythmias

Mutations in the delayed rectifier K+ channel subunit KvLQT1 have been identified as responsible for both Romano–Ward (RW) and Jervell and Lange‐Nielsen (JLN) inherited long QT syndromes. We report the molecular cloning of a human KvLQT1 isoform that is expressed in several human tissues including heart. Expression studies revealed that the association of KvLQT1 with another subunit, IsK, reconstitutes a channel responsible for the IKs current involved in ventricular myocyte repolarization. Six RW and two JLN mutated KvLQT1 subunits were produced and co‐expressed with IsK in COS cells. All the mutants, except R555C, fail to produce functional homomeric channels and reduce the K+ current when co‐expressed with the wild‐type subunit. Thus, in both syndromes, the main effect of the mutations is a dominant‐negative suppression of KvLQT1 function. The JLN mutations have a smaller dominant‐negative effect, in agreement with the fact that the disease is recessive. The R555C subunit forms a functional channel when expressed with IsK, but with altered gating properties. The voltage dependence of the activation is strongly shifted to more positive values, and deactivation kinetics are accelerated. This finding indicates the functional importance of a small positively charged cytoplasmic region of the KvLQT structure where two RW and one JLN mutations have been found to take place.

TREK‐1, a K+ channel involved in polymodal pain perception

The TREK‐1 channel is a temperature‐sensitive, osmosensitive and mechano‐gated K+ channel with a regulation by Gs and Gq coupled receptors. This paper demonstrates that TREK‐1 qualifies as one of the molecular sensors involved in pain perception. TREK‐1 is highly expressed in small sensory neurons, is present in both peptidergic and nonpeptidergic neurons and is extensively colocalized with TRPV1, the capsaicin‐activated nonselective ion channel. Mice with a disrupted TREK‐1 gene are more sensitive to painful heat sensations near the threshold between anoxious warmth and painful heat. This phenotype is associated with the primary sensory neuron, as polymodal C‐fibers were found to be more sensitive to heat in single fiber experiments. Knockout animals are more sensitive to low threshold mechanical stimuli and display an increased thermal and mechanical hyperalgesia in conditions of inflammation. They display a largely decreased pain response induced by osmotic changes particularly in prostaglandin E2‐sensitized animals. TREK‐1 appears as an important ion channel for polymodal pain perception and as an attractive target for the development of new analgesics.

Molecular Properties of Neuronal G-protein-activated Inwardly Rectifying K+ Channels

Four cDNA-encoding G-activated inwardly rectifying K+ channels have been cloned recently (Kubo, Y., Reuveny, E., Slesinger, P. A., Jan, Y. N., and Jan, L. Y.(1993) Nature 364, 802-806; Lesage, F., Duprat, F., Fink, M., Guillemare, E., Coppola, T., Lazdunski, M., and Hugnot, J. P. (1994) FEBS Lett. 353, 37-42; Krapivinsky, G., Gordon, E. A., Wickman, K., Velimirovic, B., Krapivinsky, L., and Clapham, D. E. (1995) Nature 374, 135-141). We report the cloning of a mouse GIRK2 splice variant, noted mGIRK2A. Both channel proteins are functionally expressed in Xenopus oocytes upon injection of their cRNA, alone or in combination with the GIRK1 cRNA. Three GIRK channels, mGIRK1-3, are shown to be present in the brain. Colocalization in the same neurons of mGIRK1 and mGIRK2 supports the hypothesis that native channels are made by an heteromeric subunit assembly. GIRK3 channels have not been expressed successfully, even in the presence of the other types of subunits. However, GIRK3 chimeras with the amino- and carboxyl-terminal of GIRK2 are functionally expressed in the presence of GIRK1. The expressed mGIRK2 and mGIRK1, −2 currents are blocked by Ba2+ and Cs+ ions. They are not regulated by protein kinase A and protein kinase C. Channel activity runs down in inside-out excised patches, and ATP is required to prevent this rundown. Since the nonhydrolyzable ATP analog AMP-PCP is also active and since addition of kinases A and C as well as alkaline phosphatase does not modify the ATP effect, it is concluded that ATP hydrolysis is not required. An ATP binding process appears to be essential for maintaining a functional state of the neuronal inward rectifier K+ channel. A Na+ binding site on the cytoplasmic face of the membrane acts in synergy with the ATP binding site to stabilize channel activity.

Mechanisms underlying excitatory effects of group I metabotropic glutamate receptors via inhibition of 2P domain K+ channels

Group I metabotropic glutamate receptors (mGluRs) are implicated in diverse processes such as learning, memory, epilepsy, pain and neuronal death. By inhibiting background K+ channels, group I mGluRs mediate slow and long‐lasting excitation. The main neuronal representatives of this K+ channel family (K2P or KCNK) are TASK and TREK. Here, we show that in cerebellar granule cells and in heterologous expression systems, activation of group I mGluRs inhibits TASK and TREK channels. D‐myo‐inositol‐1,4,5‐triphosphate and phosphatidyl‐4,5‐inositol‐biphosphate depletion are involved in TASK channel inhibition, whereas diacylglycerols and phosphatidic acids directly inhibit TREK channels. Mechanisms described here with group I mGluRs will also probably stand for many other receptors of hormones and neurotransmitters.

The coexistence in rat muscle cells of two distinct classes of Ca2+-dependent K+ channels with different pharmacological properties and different physiological functions

Ca2+-dependent K+ channels responsible for the long-lasting after-hyperpolarization in rat muscle cells in culture are not those extensively studied by the patch-clamp technique. The first ones are blocked by apamin, a bee venom polypeptide, and they are unaffected by tetraethylammonium (TEA) whereas the second ones are blocked by TEA and unaffected by apamin. These two Ca2+-dependent K+ channels coexist in rat muscle cells in culture but also probably in many other cellular types.