Your search keyword '"Shab Potassium Channels physiology"' showing total 58 results

1. Synaptic mechanisms underlying modulation of locomotor-related motoneuron output by premotor cholinergic interneurons.

Author

Nascimento F, Broadhead MJ, Tetringa E, Tsape E, Zagoraiou L, and Miles GB

Subjects

Animals, Female, Homeodomain Proteins metabolism, Homeodomain Proteins physiology, Mice, Mice, Inbred C57BL, Shab Potassium Channels metabolism, Shab Potassium Channels physiology, Transcription Factors metabolism, Transcription Factors physiology, Homeobox Protein PITX2, Cholinergic Neurons physiology, Interneurons physiology, Locomotion physiology, Motor Neurons physiology, Synapses physiology

Abstract

Spinal motor networks are formed by diverse populations of interneurons that set the strength and rhythmicity of behaviors such as locomotion. A small cluster of cholinergic interneurons, expressing the transcription factor Pitx2, modulates the intensity of muscle activation via 'C-bouton' inputs to motoneurons. However, the synaptic mechanisms underlying this neuromodulation remain unclear. Here, we confirm in mice that Pitx2 + interneurons are active during fictive locomotion and that their chemogenetic inhibition reduces the amplitude of motor output. Furthermore, after genetic ablation of cholinergic Pitx2 + interneurons, M2 receptor-dependent regulation of the intensity of locomotor output is lost. Conversely, chemogenetic stimulation of Pitx2 + interneurons leads to activation of M2 receptors on motoneurons, regulation of Kv2.1 channels and greater motoneuron output due to an increase in the inter-spike afterhyperpolarization and a reduction in spike half-width. Our findings elucidate synaptic mechanisms by which cholinergic spinal interneurons modulate the final common pathway for motor output., Competing Interests: FN, MB, ET, ET, LZ, GM No competing interests declared, (© 2020, Nascimento et al.)

Published

2020

2. Microglia monitor and protect neuronal function through specialized somatic purinergic junctions.

Author

Cserép C, Pósfai B, Lénárt N, Fekete R, László ZI, Lele Z, Orsolits B, Molnár G, Heindl S, Schwarcz AD, Ujvári K, Környei Z, Tóth K, Szabadits E, Sperlágh B, Baranyi M, Csiba L, Hortobágyi T, Maglóczky Z, Martinecz B, Szabó G, Erdélyi F, Szipőcs R, Tamkun MM, Gesierich B, Duering M, Katona I, Liesz A, Tamás G, and Dénes Á

Subjects

Animals, Brain ultrastructure, Brain Injuries pathology, Calcium, Cell Communication immunology, HEK293 Cells, Humans, Mice, Mitochondria immunology, Shab Potassium Channels genetics, Shab Potassium Channels physiology, Signal Transduction, Brain immunology, Brain Injuries immunology, Intercellular Junctions immunology, Microglia immunology, Neurons immunology, Receptors, Purinergic P2Y12 physiology

Abstract

Microglia are the main immune cells in the brain and have roles in brain homeostasis and neurological diseases. Mechanisms underlying microglia-neuron communication remain elusive. Here, we identified an interaction site between neuronal cell bodies and microglial processes in mouse and human brain. Somatic microglia-neuron junctions have a specialized nanoarchitecture optimized for purinergic signaling. Activity of neuronal mitochondria was linked with microglial junction formation, which was induced rapidly in response to neuronal activation and blocked by inhibition of P2Y12 receptors. Brain injury-induced changes at somatic junctions triggered P2Y12 receptor-dependent microglial neuroprotection, regulating neuronal calcium load and functional connectivity. Thus, microglial processes at these junctions could potentially monitor and protect neuronal functions., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2020

3. Kv2.1 voltage-gated potassium channels in developmental perspective.

Author

Jędrychowska J and Korzh V

Subjects

Animals, Brain embryology, Brain growth & development, Humans, Neurodevelopmental Disorders genetics, Reproduction genetics, Growth and Development genetics, Shab Potassium Channels physiology

Abstract

Kv2.1 voltage-gated potassium channels consist of two types of α-subunits: (a) electrically-active Kcnb1 α-subunits and (b) silent or modulatory α-subunits plus β-subunits that, similar to silent α-subunits, also regulate electrically-active subunits. Voltage-gated potassium channels were traditionally viewed, mainly by electrophysiologists, as regulators of the electrical activity of the plasma membrane in excitable cells, a role that is performed by transmembrane protein domains of α-subunits that form the electric pore. Genetic studies revealed a role for this region of α-subunits of voltage-gated potassium channels in human neurodevelopmental disorders, such as epileptic encephalopathy. The N- and C-terminal domains of α-subunits interact to form the cytoplasmic subunit of heterotetrameric potassium channels that regulate electric pores. Subsequent animal studies revealed the developmental functions of Kcnb1-containing voltage-gated potassium channels and illustrated their role during brain development and reproduction. These functions of potassium channels are discussed in this review in the context of regulatory interactions between electrically-active and regulatory subunits., (© 2019 Wiley Periodicals, Inc.)

Published

2019

4. Identification of VAPA and VAPB as Kv2 Channel-Interacting Proteins Defining Endoplasmic Reticulum-Plasma Membrane Junctions in Mammalian Brain Neurons.

Author

Kirmiz M, Vierra NC, Palacio S, and Trimmer JS

Subjects

Amino Acid Sequence, Animals, Cells, Cultured, Cytoskeleton chemistry, Female, HEK293 Cells, Hippocampus cytology, Humans, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Neurons ultrastructure, Phosphorylation, Protein Processing, Post-Translational, Rats, Rats, Sprague-Dawley, Recombinant Proteins metabolism, Shab Potassium Channels deficiency, Shab Potassium Channels genetics, Vesicular Transport Proteins, Carrier Proteins physiology, Cell Membrane metabolism, Endoplasmic Reticulum metabolism, Membrane Proteins physiology, Neurons metabolism, Shab Potassium Channels physiology

Abstract

Membrane contacts between endoplasmic reticulum (ER) and plasma membrane (PM), or ER-PM junctions, are ubiquitous in eukaryotic cells and are platforms for lipid and calcium signaling and homeostasis. Recent studies have revealed proteins crucial to the formation and function of ER-PM junctions in non-neuronal cells, but little is known of the ER-PM junctions prominent in aspiny regions of mammalian brain neurons. The Kv2.1 voltage-gated potassium channel is abundantly clustered at ER-PM junctions in brain neurons and is the first PM protein that functions to organize ER-PM junctions. However, the molecular mechanism whereby Kv2.1 localizes to and remodels these junctions is unknown. We used affinity immunopurification and mass spectrometry-based proteomics on brain samples from male and female WT and Kv2.1 KO mice and identified the resident ER vesicle-associated membrane protein-associated proteins isoforms A and B (VAPA and VAPB) as prominent Kv2.1-associated proteins. Coexpression with Kv2.1 or its paralog Kv2.2 was sufficient to recruit VAPs to ER-PM junctions. Multiplex immunolabeling revealed colocalization of Kv2.1 and Kv2.2 with endogenous VAPs at ER-PM junctions in brain neurons from male and female mice in situ and in cultured rat hippocampal neurons, and KO of VAPA in mammalian cells reduces Kv2.1 clustering. The association of VAPA with Kv2.1 relies on a "two phenylalanines in an acidic tract" (FFAT) binding domain on VAPA and a noncanonical phosphorylation-dependent FFAT motif comprising the Kv2-specific clustering or PRC motif. These results suggest that Kv2.1 localizes to and organizes neuronal ER-PM junctions through an interaction with VAPs. SIGNIFICANCE STATEMENT Our study identified the endoplasmic reticulum (ER) proteins vesicle-associated membrane protein-associated proteins isoforms A and B (VAPA and VAPB) as proteins copurifying with the plasma membrane (PM) Kv2.1 ion channel. We found that expression of Kv2.1 recruits VAPs to ER-PM junctions, specialized membrane contact sites crucial to distinct aspects of cell function. We found endogenous VAPs at Kv2.1-mediated ER-PM junctions in brain neurons and other mammalian cells and that knocking out VAPA expression disrupts Kv2.1 clustering. We identified domains of VAPs and Kv2.1 necessary and sufficient for their association at ER-PM junctions. Our study suggests that Kv2.1 expression in the PM can affect ER-PM junctions via its phosphorylation-dependent association to ER-localized VAPA and VAPB., (Copyright © 2018 the authors 0270-6474/18/387562-23$15.00/0.)

Published

2018

5. Kv2 potassium channels form endoplasmic reticulum/plasma membrane junctions via interaction with VAPA and VAPB.

Author

Johnson B, Leek AN, Solé L, Maverick EE, Levine TP, and Tamkun MM

Subjects

Animals, Biotinylation, HEK293 Cells, Hippocampus metabolism, Humans, Protein Transport, Rats, Shab Potassium Channels physiology, Vesicular Transport Proteins metabolism, Cell Membrane chemistry, Endoplasmic Reticulum chemistry, Shab Potassium Channels chemistry, Vesicular Transport Proteins chemistry

Abstract

Kv2.1 exhibits two distinct forms of localization patterns on the neuronal plasma membrane: One population is freely diffusive and regulates electrical activity via voltage-dependent K + conductance while a second one localizes to micrometer-sized clusters that contain densely packed, but nonconducting, channels. We have previously established that these clusters represent endoplasmic reticulum/plasma membrane (ER/PM) junctions that function as membrane trafficking hubs and that Kv2.1 plays a structural role in forming these membrane contact sites in both primary neuronal cultures and transfected HEK cells. Clustering and the formation of ER/PM contacts are regulated by phosphorylation within the channel C terminus, offering cells fast, dynamic control over the physical relationship between the cortical ER and PM. The present study addresses the mechanisms by which Kv2.1 and the related Kv2.2 channel interact with the ER membrane. Using proximity-based biotinylation techniques in transfected HEK cells we identified ER VAMP-associated proteins (VAPs) as potential Kv2.1 interactors. Confirmation that Kv2.1 and -2.2 bind VAPA and VAPB employed colocalization/redistribution, siRNA knockdown, and Förster resonance energy transfer (FRET)-based assays. CD4 chimeras containing sequence from the Kv2.1 C terminus were used to identify a noncanonical VAP-binding motif. VAPs were first identified as proteins required for neurotransmitter release in Aplysia and are now known to be abundant scaffolding proteins involved in membrane contact site formation throughout the ER. The VAP interactome includes AKAPs, kinases, membrane trafficking machinery, and proteins regulating nonvesicular lipid transport from the ER to the PM. Therefore, the Kv2-induced VAP concentration at ER/PM contact sites is predicted to have wide-ranging effects on neuronal cell biology., Competing Interests: The authors declare no conflict of interest.

Published

2018

6. Cleavage of potassium channel Kv2.1 by BACE2 reduces neuronal apoptosis.

Author

Liu F, Zhang Y, Liang Z, Sun Q, Liu H, Zhao J, Xu J, Zheng J, Yun Y, Yu X, Song W, and Sun X

Subjects

Amino Acid Sequence, Animals, Apoptosis physiology, Cell Membrane metabolism, HEK293 Cells, Hippocampus metabolism, Humans, Neurons metabolism, Patch-Clamp Techniques, Potassium metabolism, Primary Cell Culture, Rats, Shab Potassium Channels metabolism, Substrate Specificity, Amyloid Precursor Protein Secretases metabolism, Amyloid Precursor Protein Secretases physiology, Aspartic Acid Endopeptidases metabolism, Aspartic Acid Endopeptidases physiology, Shab Potassium Channels physiology

Abstract

Potassium channel Kv2.1 regulates potassium current in cortical neurons and potassium efflux is necessary for cell apoptosis. As a major component of delayed rectifier current potassium channels, Kv2.1 forms clusters in the membrane of hippocampal neurons. BACE2 is an aspartyl protease to cleave APP to prevent the generation of Aβ, a central component of neuritic plaques in Alzheimer's brain. We now identified Kv2.1 as a novel substrate of BACE2. We found that BACE2 cleaved Kv2.1 at Thr376, Ala717, and Ser769 sites and disrupted Kv2.1 clustering on cell membrane, resulting in decreased I k of Kv2.1 and a hyperpolarizing shift in primary neurons. Furthermore, we discovered that the BACE2-cleaved Kv2.1 forms, Kv2.1-1-375, Kv2.1-1-716, and Kv2.1-1-768, depressed the delayed rectifier I k surge and reduced neuronal apoptosis. Our study suggests that BACE2 plays a neuroprotective role by cleavage of Kv2.1 to prevent the outward potassium currents, a potential new target for Alzheimer's treatment.

Published

2018

7. K v 2.1 clusters on β-cell plasma membrane act as reservoirs that replenish pools of newcomer insulin granule through their interaction with syntaxin-3.

Author

Greitzer-Antes D, Xie L, Qin T, Xie H, Zhu D, Dolai S, Liang T, Kang F, Hardy AB, He Y, Kang Y, and Gaisano HY

Subjects

Animals, Cell Membrane metabolism, Exocytosis physiology, Glucose pharmacology, Insulin-Secreting Cells drug effects, Male, Mice, Microscopy, Fluorescence, Protein Binding, Protein Domains, Qa-SNARE Proteins chemistry, Rats, Rats, Wistar, SNARE Proteins metabolism, Shab Potassium Channels physiology, Insulin metabolism, Insulin-Secreting Cells metabolism, Qa-SNARE Proteins metabolism, Secretory Vesicles metabolism, Shab Potassium Channels metabolism

Abstract

The voltage-dependent K + (K v ) channel K v 2.1 is a major delayed rectifier in many secretory cells, including pancreatic β cells. In addition, K v 2.1 has a direct role in exocytosis at an undefined step, involving SNARE proteins, that is independent of its ion-conducting pore function. Here, we elucidated the precise step in exocytosis. We previously reported that syntaxin-3 (Syn-3) is the key syntaxin that mediates exocytosis of newcomer secretory granules that spend minimal residence time on the plasma membrane before fusion. Using high-resolution total internal reflection fluorescence microscopy, we now show that K v 2.1 forms reservoir clusters on the β-cell plasma membrane and binds Syn-3 via its C-terminal C1b domain, which recruits newcomer insulin secretory granules into this large reservoir. Upon glucose stimulation, secretory granules were released from this reservoir to replenish the pool of newcomer secretory granules for subsequent fusion, occurring just adjacent to the plasma membrane K v 2.1 clusters. C1b deletion blocked the aforementioned K v 2.1-Syn-3-mediated events and reduced fusion of newcomer secretory granules. These insights have therapeutic implications, as K v 2.1 overexpression in type-2 diabetes rat islets restored biphasic insulin secretion., (© 2018 Greitzer-Antes et al.)

Published

2018

8. N'-mono- and N, N'-diacyl derivatives of benzyl and arylhydrazines as contact insecticides against adult Anopheles gambiae.

Author

Clements JS 2nd, Islam R, Sun B, Tong F, Gross AD, Bloomquist JR, and Carlier PR

Subjects

Animals, Cell Line, Tumor, HEK293 Cells, Humans, Mosquito Control methods, Shab Potassium Channels genetics, Shab Potassium Channels physiology, Anopheles drug effects, Hydrazines toxicity, Insecticides toxicity, Potassium Channel Blockers toxicity

Abstract

New public health insecticides are urgently required to prevent the spread of vector-borne disease. With the goal of identifying new K + -channel-directed mosquitocides, analogs of the RH-5849 family of diacyl t-butylhydrazines were synthesized and tested for topical toxicity against adult Anopheles gambiae, the African vector of malaria. In total, 80N'-monoacyl and N, N'-diacyl derivatives of benzyl- and arylhydrazines were prepared. Three compounds (2bo, 2kb, 3ab) were identified that were more toxic than RH-5849 and RH-1266. The potencies of these compounds to block K + currents in An. gambiae and human Kv2.1 channels were assessed to address their possible mechanism of mosquitocidal action. Selectivity for inhibition of An. gambiae Kv2.1 vs human Kv2.1 did not exceed 3-fold. Furthermore, no correlation was seen between the potency of insecticidal action and K + channel blocking potency. These observations, combined with the minimal knockdown seen with 2bo near its LD 50 value, suggests a mode of action outside of the nervous system., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

9. Reduced sensory synaptic excitation impairs motor neuron function via Kv2.1 in spinal muscular atrophy.

Author

Fletcher EV, Simon CM, Pagiazitis JG, Chalif JI, Vukojicic A, Drobac E, Wang X, and Mentis GZ

Subjects

Action Potentials physiology, Animals, Cell Survival physiology, Disease Models, Animal, Kainic Acid pharmacology, Metalloendopeptidases pharmacology, Mice, Mice, Transgenic, Motor Neurons drug effects, Motor Neurons metabolism, Neuromuscular Junction physiology, Reflex, Righting physiology, Shab Potassium Channels biosynthesis, Survival of Motor Neuron 1 Protein genetics, Survival of Motor Neuron 2 Protein genetics, Synapses drug effects, Tetanus Toxin pharmacology, Motor Neurons physiology, Muscular Atrophy, Spinal physiopathology, Proprioception physiology, Shab Potassium Channels physiology, Synapses physiology

Abstract

Behavioral deficits in neurodegenerative diseases are often attributed to the selective dysfunction of vulnerable neurons via cell-autonomous mechanisms. Although vulnerable neurons are embedded in neuronal circuits, the contributions of their synaptic partners to disease process are largely unknown. Here we show that, in a mouse model of spinal muscular atrophy (SMA), a reduction in proprioceptive synaptic drive leads to motor neuron dysfunction and motor behavior impairments. In SMA mice or after the blockade of proprioceptive synaptic transmission, we observed a decrease in the motor neuron firing that could be explained by the reduction in the expression of the potassium channel Kv2.1 at the surface of motor neurons. Chronically increasing neuronal activity pharmacologically in vivo led to a normalization of Kv2.1 expression and an improvement in motor function. Our results demonstrate a key role of excitatory synaptic drive in shaping the function of motor neurons during development and the contribution of its disruption to a neurodegenerative disease.

Published

2017

10. Angiotensin II reduces the surface abundance of K V 1.5 channels in arterial myocytes to stimulate vasoconstriction.

Author

Kidd MW, Bulley S, and Jaggar JH

Subjects

Animals, Male, Mesenteric Arteries cytology, Rats, Sprague-Dawley, Shab Potassium Channels physiology, Vasoconstriction, Angiotensin II physiology, Kv1.5 Potassium Channel physiology, Mesenteric Arteries physiology, Muscle Cells physiology

Abstract

Key Points: Several different voltage-dependent K + (K V ) channel isoforms are expressed in arterial smooth muscle cells (myocytes). Vasoconstrictors inhibit K V currents, but the isoform selectivity and mechanisms involved are unclear. We show that angiotensin II (Ang II), a vasoconstrictor, stimulates degradation of K V 1.5, but not K V 2.1, channels through a protein kinase C- and lysosome-dependent mechanism, reducing abundance at the surface of mesenteric artery myocytes. The Ang II-induced decrease in cell surface K V 1.5 channels reduces whole-cell K V 1.5 currents and attenuates K V 1.5 function in pressurized arteries. We describe a mechanism by which Ang II stimulates protein kinase C-dependent K V 1.5 channel degradation, reducing the abundance of functional channels at the myocyte surface., Abstract: Smooth muscle cells (myocytes) of resistance-size arteries express several different voltage-dependent K + (K V ) channels, including K V 1.5 and K V 2.1, which regulate contractility. Myocyte K V currents are inhibited by vasoconstrictors, including angiotensin II (Ang II), but the mechanisms involved are unclear. Here, we tested the hypothesis that Ang II inhibits K V currents by reducing the plasma membrane abundance of K V channels in myocytes. Angiotensin II (applied for 2 h) reduced surface and total K V 1.5 protein in rat mesenteric arteries. In contrast, Ang II did not alter total or surface K V 2.1, or K V 1.5 or K V 2.1 cellular distribution, measured as the percentage of total protein at the surface. Bisindolylmaleimide (BIM; a protein kinase C blocker), a protein kinase C inhibitory peptide or bafilomycin A (a lysosomal degradation inhibitor) each blocked the Ang II-induced decrease in total and surface K V 1.5. Immunofluorescence also suggested that Ang II reduced surface K V 1.5 protein in isolated myocytes; an effect inhibited by BIM. Arteries were exposed to Ang II or Ang II plus BIM (for 2 h), after which these agents were removed and contractility measurements performed or myocytes isolated for patch-clamp electrophysiology. Angiotensin II reduced both whole-cell K V currents and currents inhibited by Psora-4, a K V 1.5 channel blocker. Angiotensin II also reduced vasoconstriction stimulated by Psora-4 or 4-aminopyridine, another K V channel inhibitor. These data indicate that Ang II activates protein kinase C, which stimulates K V 1.5 channel degradation, leading to a decrease in surface K V 1.5, a reduction in whole-cell K V 1.5 currents and a loss of functional K V 1.5 channels in myocytes of pressurized arteries., (© 2016 The Authors. The Journal of Physiology © 2016 The Physiological Society.)

Published

2017

11. Physiological roles of Kv2 channels in entorhinal cortex layer II stellate cells revealed by Guangxitoxin-1E.

Author

Hönigsperger C, Nigro MJ, and Storm JF

Subjects

Animals, Entorhinal Cortex cytology, In Vitro Techniques, Male, Neurons physiology, Rats, Wistar, Arthropod Proteins pharmacology, Neurons drug effects, Shab Potassium Channels physiology, Spider Venoms pharmacology

Abstract

Key Points: Kv2 channels underlie delayed-rectifier potassium currents in various neurons, although their physiological roles often remain elusive. Almost nothing is known about Kv2 channel functions in medial entorhinal cortex (mEC) neurons, which are involved in representing space, memory formation, epilepsy and dementia. Stellate cells in layer II of the mEC project to the hippocampus and are considered to be space-representing grid cells. We used the new Kv2 blocker Guangxitoxin-1E (GTx) to study Kv2 functions in these neurons. Voltage clamp recordings from mEC stellate cells in rat brain slices showed that GTx inhibited delayed-rectifier K + current but not transient A-type current. In current clamp, GTx had multiple effects: (i) increasing excitability and bursting at moderate spike rates but reducing firing at high rates; (ii) enhancing after-depolarizations; (iii) reducing the fast and medium after-hyperpolarizations; (iv) broadening action potentials; and (v) reducing spike clustering. GTx is a useful tool for studying Kv2 channels and their functions in neurons., Abstract: The medial entorhinal cortex (mEC) is strongly involved in spatial navigation, memory, dementia and epilepsy. Although potassium channels shape neuronal activity, their roles in mEC are largely unknown. We used the new Kv2 blocker Guangxitoxin-1E (GTx; 10-100 nm) in rat brain slices to investigate Kv2 channel functions in mEC layer II stellate cells (SCs). These neurons project to the hippocampus and are considered to be grid cells representing space. Voltage clamp recordings from SCs nucleated patches showed that GTx inhibited a delayed rectifier K + current activating beyond -30 mV but not transient A-type current. In current clamp, GTx (i) had almost no effect on the first action potential but markedly slowed repolarization of late spikes during repetitive firing; (ii) enhanced the after-depolarization (ADP); (iii) reduced fast and medium after-hyperpolarizations (AHPs); (iv) strongly enhanced burst firing and increased excitability at moderate spike rates but reduced spiking at high rates; and (v) reduced spike clustering and rebound potentials. The changes in bursting and excitability were related to the altered ADPs and AHPs. Kv2 channels strongly shape the activity of mEC SCs by affecting spike repolarization, after-potentials, excitability and spike patterns. GTx is a useful tool and may serve to further clarify Kv2 channel functions in neurons. We conclude that Kv2 channels in mEC SCs are important determinants of intrinsic properties that allow these neurons to produce spatial representation. The results of the present study may also be important for the accurate modelling of grid cells., (© 2016 The Authors. The Journal of Physiology © 2016 The Physiological Society.)

Published

2017

12. Functional antagonism of voltage-gated K+ channel α-subunits in the developing brain ventricular system.

Author

Shen H, Bocksteins E, Kondrychyn I, Snyders D, and Korzh V

Subjects

Animals, Animals, Genetically Modified, Brain metabolism, Cell Proliferation genetics, Cerebral Ventricles metabolism, Embryo, Nonmammalian, Gene Expression Regulation, Developmental, Hydrocephalus embryology, Hydrocephalus genetics, Neuroepithelial Cells metabolism, Neuroepithelial Cells physiology, Potassium Channels, Voltage-Gated genetics, Protein Subunits antagonists & inhibitors, Protein Subunits physiology, Shab Potassium Channels antagonists & inhibitors, Shab Potassium Channels physiology, Zebrafish, Brain embryology, Cerebral Ventricles embryology, Organogenesis genetics, Potassium Channels, Voltage-Gated antagonists & inhibitors, Potassium Channels, Voltage-Gated physiology, Voltage-Dependent Anion Channels genetics, Zebrafish Proteins genetics

Abstract

The brain ventricular system is essential for neurogenesis and brain homeostasis. Its neuroepithelial lining effects these functions, but the underlying molecular pathways remain to be understood. We found that the potassium channels expressed in neuroepithelial cells determine the formation of the ventricular system. The phenotype of a novel zebrafish mutant characterized by denudation of neuroepithelial lining of the ventricular system and hydrocephalus is mechanistically linked to Kcng4b, a homologue of the 'silent' voltage-gated potassium channel α-subunit K v 6.4. We demonstrated that Kcng4b modulates proliferation of cells lining the ventricular system and maintains their integrity. The gain of Kcng4b function reduces the size of brain ventricles. Electrophysiological studies suggest that Kcng4b mediates its effects via an antagonistic interaction with Kcnb1, the homologue of the electrically active delayed rectifier potassium channel subunit K v 2.1. Mutation of kcnb1 reduces the size of the ventricular system and its gain of function causes hydrocephalus, which is opposite to the function of Kcng4b. This demonstrates the dynamic interplay between potassium channel subunits in the neuroepithelium as a novel and crucial regulator of ventricular development in the vertebrate brain., (© 2016. Published by The Company of Biologists Ltd.)

Published

2016

13. Differential Regulation of Action Potential Shape and Burst-Frequency Firing by BK and Kv2 Channels in Substantia Nigra Dopaminergic Neurons.

Author

Kimm T, Khaliq ZM, and Bean BP

Subjects

Action Potentials drug effects, Animals, Dopaminergic Neurons drug effects, Electrophysiological Phenomena drug effects, Electrophysiological Phenomena physiology, Evoked Potentials drug effects, Female, Kinetics, Large-Conductance Calcium-Activated Potassium Channels drug effects, Male, Mice, Neurons drug effects, Patch-Clamp Techniques, Potassium Channel Blockers pharmacology, Recruitment, Neurophysiological, Shab Potassium Channels drug effects, Substantia Nigra cytology, Substantia Nigra drug effects, Action Potentials physiology, Large-Conductance Calcium-Activated Potassium Channels physiology, Neurons physiology, Shab Potassium Channels physiology, Substantia Nigra physiology

Abstract

Little is known about the voltage-dependent potassium currents underlying spike repolarization in midbrain dopaminergic neurons. Studying mouse substantia nigra pars compacta dopaminergic neurons both in brain slice and after acute dissociation, we found that BK calcium-activated potassium channels and Kv2 channels both make major contributions to the depolarization-activated potassium current. Inhibiting Kv2 or BK channels had very different effects on spike shape and evoked firing. Inhibiting Kv2 channels increased spike width and decreased the afterhyperpolarization, as expected for loss of an action potential-activated potassium conductance. BK inhibition also increased spike width but paradoxically increased the afterhyperpolarization. Kv2 channel inhibition steeply increased the slope of the frequency-current (f-I) relationship, whereas BK channel inhibition had little effect on the f-I slope or decreased it, sometimes resulting in slowed firing. Action potential clamp experiments showed that both BK and Kv2 current flow during spike repolarization but with very different kinetics, with Kv2 current activating later and deactivating more slowly. Further experiments revealed that inhibiting either BK or Kv2 alone leads to recruitment of additional current through the other channel type during the action potential as a consequence of changes in spike shape. Enhancement of slowly deactivating Kv2 current can account for the increased afterhyperpolarization produced by BK inhibition and likely underlies the very different effects on the f-I relationship. The cross-regulation of BK and Kv2 activation illustrates that the functional role of a channel cannot be defined in isolation but depends critically on the context of the other conductances in the cell., Significance Statement: This work shows that BK calcium-activated potassium channels and Kv2 voltage-activated potassium channels both regulate action potentials in dopamine neurons of the substantia nigra pars compacta. Although both channel types participate in action potential repolarization about equally, they have contrasting and partially opposite effects in regulating neuronal firing at frequencies typical of bursting. Our analysis shows that this results from their different kinetic properties, with fast-activating BK channels serving to short-circuit activation of Kv2 channels, which tend to slow firing by producing a deep afterhyperpolarization. The cross-regulation of BK and Kv2 activation illustrates that the functional role of a channel cannot be defined in isolation but depends critically on the context of the other conductances in the cell., (Copyright © 2015 the authors 0270-6474/15/3516404-14$15.00/0.)

Published

2015

14. Selective down-regulation of KV2.1 function contributes to enhanced arterial tone during diabetes.

Author

Nieves-Cintrón M, Nystoriak MA, Prada MP, Johnson K, Fayer W, Dell'Acqua ML, Scott JD, and Navedo MF

Subjects

Animals, Diabetes Mellitus, Experimental physiopathology, Mice, Mice, Inbred C57BL, Arteries physiology, Diabetes Mellitus, Experimental metabolism, Down-Regulation, Muscle Tonus physiology, Shab Potassium Channels physiology

Abstract

Enhanced arterial tone is a leading cause of vascular complications during diabetes. Voltage-gated K(+) (KV) channels are key regulators of vascular smooth muscle cells (VSMCs) contractility and arterial tone. Whether impaired KV channel function contributes to enhance arterial tone during diabetes is unclear. Here, we demonstrate a reduction in KV-mediated currents (IKv) in VSMCs from a high fat diet (HFD) mouse model of type 2 diabetes. In particular, IKv sensitive to stromatoxin (ScTx), a potent KV2 blocker, were selectively reduced in diabetic VSMCs. This was associated with decreased KV2-mediated regulation of arterial tone and suppression of the KV2.1 subunit mRNA and protein in VSMCs/arteries isolated from HFD mice. We identified protein kinase A anchoring protein 150 (AKAP150), via targeting of the phosphatase calcineurin (CaN), and the transcription factor nuclear factor of activated T-cells c3 (NFATc3) as required determinants of KV2.1 suppression during diabetes. Interestingly, substantial reduction in transcript levels for KV2.1 preceded down-regulation of large conductance Ca(2+)-activated K(+) (BKCa) channel β1 subunits, which are ultimately suppressed in chronic hyperglycemia to a similar extent. Together, our study supports the concept that transcriptional suppression of KV2.1 by activation of the AKAP150-CaN/NFATc3 signaling axis contributes to enhanced arterial tone during diabetes., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

15. Heme Oxygenase-1 Influences Apoptosis via CO-mediated Inhibition of K+ Channels.

Author

Al-Owais MM, Dallas ML, Boyle JP, Scragg JL, and Peers C

Subjects

Animals, Cytoprotection, HEK293 Cells, Humans, Medulloblastoma pathology, Rats, Rats, Wistar, Shab Potassium Channels antagonists & inhibitors, Apoptosis, Carbon Monoxide physiology, Heme Oxygenase-1 physiology, Shab Potassium Channels physiology

Abstract

Hypoxic/ischemic episodes can trigger oxidative stress-mediated loss of central neurons via apoptosis, and low pO2 is also a feature of the tumor microenvironment, where cancer cells are particularly resistant to apoptosis. In the CNS, ischemic insult increases expression of the CO-generating enzyme heme oxygenase-1 (HO-1), which is commonly constitutively active in cancer cells. It has been proposed that apoptosis can be regulated by the trafficking and activity of K(+) channels, particularly Kv2.1. We have explored the idea that HO-1 may influence apoptosis via regulation of Kv2.1. Overexpression of Kv2.1 in HEK293 cells increased their vulnerability to oxidant-induced apoptosis. CO (applied as the donor CORM-2) protected cells against apoptosis and inhibited Kv2.1 channels. Similarly in hippocampal neurones, CO selectively inhibited Kv2.1 and protected neurones against oxidant-induced apoptosis. In medulloblastoma sections we identified constitutive expression of HO-1 and Kv2.1, and in the medulloblastoma-derived cell line DAOY, hypoxic HO-1 induction or exposure to CO protected cells against apoptosis, and also selectively inhibited Kv2.1 channels expressed in these cells. These studies are consistent with a central role for Kv2.1 in apoptosis in both central neurones and cancer cells. They also suggest that HO-1 expression can strongly influence apoptosis via CO-mediated regulation of Kv2.1 activity.

Published

2015

16. Kv2.2: a novel molecular target to study the role of basal forebrain GABAergic neurons in the sleep-wake cycle.

Author

Hermanstyne TO, Subedi K, Le WW, Hoffman GE, Meredith AL, Mong JA, and Misonou H

Subjects

Animals, Electroencephalography, Electromyography, Genotype, Male, Mice, Mice, Inbred C57BL, Mice, Knockout genetics, Parvalbumins physiology, Prosencephalon cytology, Proto-Oncogene Proteins c-fos physiology, Shab Potassium Channels genetics, Sleep genetics, Sleep Deprivation physiopathology, Wakefulness genetics, GABAergic Neurons physiology, Prosencephalon physiology, Shab Potassium Channels physiology, Sleep physiology, Wakefulness physiology

Abstract

Study Objectives: The basal forebrain (BF) has been implicated as an important brain region that regulates the sleep-wake cycle of animals. Gamma-aminobutyric acidergic (GABAergic) neurons are the most predominant neuronal population within this region. However, due to the lack of specific molecular tools, the roles of the BF GABAergic neurons have not been fully elucidated. Previously, we have found high expression levels of the Kv2.2 voltage-gated potassium channel on approximately 60% of GABAergic neurons in the magnocellular preoptic area and horizontal limb of the diagonal band of Broca of the BF and therefore proposed it as a potential molecular target to study this neuronal population. In this study, we sought to determine the functional roles of the Kv2.2-expressing neurons in the regulation of the sleep-wake cycle., Design: Sleep analysis between two genotypes and within each genotype before and after sleep deprivation., Setting: Animal sleep research laboratory., Participants: Adult mice. Wild-type and Kv2.2 knockout mice with C57/BL6 background., Interventions: EEG/EMG recordings from the basal state and after sleep-deprivation which was induced by mild agitation for 6 h., Results: Immunostaining of a marker of neuronal activity indicates that these Kv2.2-expressing neurons appear to be preferentially active during the wake state. Therefore, we tested whether Kv2.2-expressing neurons in the BF are involved in arousal using Kv2.2-deficient mice. BF GABAergic neurons exhibited augmented expression of c-Fos. These knockout mice exhibited longer consolidated wake bouts than wild-type littermates, and that phenotype was further exacerbated by sleep deprivation. Moreover, in-depth analyses of their cortical electroencephalogram revealed a significant decrease in the delta-frequency activity during the nonrapid eye movement sleep state., Conclusions: These results revealed the significance of Kv2.2-expressing neurons in the regulation of the sleep-wake cycle.

Published

2013

17. Protection from noise-induced hearing loss by Kv2.2 potassium currents in the central medial olivocochlear system.

Author

Tong H, Kopp-Scheinpflug C, Pilati N, Robinson SW, Sinclair JL, Steinert JR, Barnes-Davies M, Allfree R, Grubb BD, Young SM Jr, and Forsythe ID

Subjects

Action Potentials drug effects, Action Potentials genetics, Animals, Animals, Newborn, Cell Line, Tumor, Disease Models, Animal, Evoked Potentials, Auditory, Brain Stem physiology, Female, Gene Expression Regulation drug effects, Gene Expression Regulation genetics, Hearing Loss etiology, In Vitro Techniques, Male, Mice, Mice, Inbred CBA, Mice, Transgenic, Mutation genetics, Neuroblastoma pathology, Patch-Clamp Techniques, Shab Potassium Channels deficiency, Shaw Potassium Channels metabolism, Transfection, Auditory Pathways physiology, Cochlea physiology, Hearing Loss prevention & control, Noise adverse effects, Olivary Nucleus physiology, Shab Potassium Channels physiology

Abstract

The central auditory brainstem provides an efferent projection known as the medial olivocochlear (MOC) system, which regulates the cochlear amplifier and mediates protection on exposure to loud sound. It arises from neurons of the ventral nucleus of the trapezoid body (VNTB), so control of neuronal excitability in this pathway has profound effects on hearing. The VNTB and the medial nucleus of the trapezoid body are the only sites of expression for the Kv2.2 voltage-gated potassium channel in the auditory brainstem, consistent with a specialized function of these channels. In the absence of unambiguous antagonists, we used recombinant and transgenic methods to examine how Kv2.2 contributes to MOC efferent function. Viral gene transfer of dominant-negative Kv2.2 in wild-type mice suppressed outward K(+) currents, increasing action potential (AP) half-width and reducing repetitive firing. Similarly, VNTB neurons from Kv2.2 knock-out mice (Kv2.2KO) also showed increased AP duration. Control experiments established that Kv2.2 was not expressed in the cochlea, so any changes in auditory function in the Kv2.2KO mouse must be of central origin. Further, in vivo recordings of auditory brainstem responses revealed that these Kv2.2KO mice were more susceptible to noise-induced hearing loss. We conclude that Kv2.2 regulates neuronal excitability in these brainstem nuclei by maintaining short APs and enhancing high-frequency firing. This safeguards efferent MOC firing during high-intensity sounds and is crucial in the mediation of protection after auditory overexposure.

Published

2013

18. Shab K (+) channel slow inactivation: a test for U-type inactivation and a hypothesis regarding K (+) -facilitated inactivation mechanisms.

Author

Carrillo E, Arias-Olguín II, Islas LD, and Gómez-Lagunas F

Subjects

Animals, Drosophila Proteins antagonists & inhibitors, Drosophila Proteins chemistry, Drosophila melanogaster chemistry, Drosophila melanogaster physiology, Potassium metabolism, Potassium Channel Blockers pharmacology, Protein Structure, Tertiary, Quinidine pharmacology, Sf9 Cells, Shab Potassium Channels antagonists & inhibitors, Shab Potassium Channels chemistry, Spodoptera, Tetraethylammonium pharmacology, Drosophila Proteins physiology, Ion Channel Gating, Potassium pharmacology, Shab Potassium Channels physiology

Abstract

Herein, we report the first characterization of Shab slow inactivation. Open Shab channels inactivate within seconds, with two voltage-independent time constants. Additionally, Shab presents significant closed-state inactivation. We found that with short depolarizing pulses, shorter than the slowest inactivation time constant, the resulting inactivation curve has a marked U-shape, but as pulse duration increases, approaching steady-state conditions, the U-shape vanishes, and the resulting inactivation curves converge to the classical Boltzmann h∞ curve. Regarding the mechanism of inactivation, we found that external K (+) and TEA facilitate both open- and closed-state inactivation, while the cavity blocker quinidine hinders inactivation. These results together with our previous observations regarding the K (+) -dependent stability of the K (+) conductance, suggest the novel hypothesis that inactivation of Shab channels, and possibly that of other Kv channels whose inactivation is facilitated by K (+) , does not involve a significant narrowing of the extracellular entry of the pore. Instead, we hypothesize that there is only a rearrangement of a more internal segment of the pore that affects the central cavity and halts K (+) conduction.

Published

2013

19. Regulation of Kv2.1 K(+) conductance by cell surface channel density.

Author

Fox PD, Loftus RJ, and Tamkun MM

Subjects

Animals, Cells, Cultured, HEK293 Cells, Hippocampus cytology, Humans, Membrane Potentials genetics, Neurons cytology, Rats, Cell Membrane physiology, Hippocampus physiology, Neurons physiology, Shab Potassium Channels physiology

Abstract

The Kv2.1 voltage-gated K(+) channel is found both freely diffusing over the plasma membrane and concentrated in micron-sized clusters localized to the soma, proximal dendrites, and axon initial segment of hippocampal neurons. In transfected HEK cells, Kv2.1 channels within cluster microdomains are nonconducting. Using total internal reflection fluorescence microscopy, the number of GFP-tagged Kv2.1 channels on the HEK cell surface was compared with K(+) channel conductance measured by whole-cell voltage clamp of the same cell. This approach indicated that, as channel density increases, nonclustered channels cease conducting. At the highest density observed, only 4% of all channels were conducting. Mutant Kv2.1 channels that fail to cluster also possessed the nonconducting state with 17% conducting K(+) at higher surface densities. The nonconducting state was specific to Kv2.1 as Kv1.4 was always conducting regardless of the cell-surface expression level. Anti-Kv2.1 immunofluorescence intensity, standardized to Kv2.1 surface density in transfected HEK cells, was used to determine the expression levels of endogenous Kv2.1 in cultured rat hippocampal neurons. Endogenous Kv2.1 levels were compared with the number of conducting channels determined by whole-cell voltage clamp. Only 13 and 27% of the endogenous Kv2.1 was conducting in neurons cultured for 14 and 20 d, respectively. Together, these data indicate that the nonconducting state depends primarily on surface density as opposed to cluster location and that this nonconducting state also exists for native Kv2.1 found in cultured hippocampal neurons. This excess of Kv2.1 protein relative to K(+) conductance further supports a nonconducting role for Kv2.1 in excitable tissues.

Published

2013

20. Toxic role of K+ channel oxidation in mammalian brain.

Author

Cotella D, Hernandez-Enriquez B, Wu X, Li R, Pan Z, Leveille J, Link CD, Oddo S, and Sesti F

Subjects

2,2'-Dipyridyl analogs & derivatives, 2,2'-Dipyridyl toxicity, Age Factors, Alanine genetics, Alzheimer Disease genetics, Alzheimer Disease pathology, Alzheimer Disease physiopathology, Amyloid beta-Peptides toxicity, Amyloid beta-Protein Precursor genetics, Analysis of Variance, Animals, Animals, Genetically Modified, Apoptosis drug effects, Apoptosis genetics, Apoptosis physiology, Caenorhabditis elegans, Cells, Cultured, Cricetinae, Cricetulus, Cysteine genetics, Disease Models, Animal, Disulfides toxicity, Electric Stimulation, Embryo, Mammalian, Female, Fluoresceins pharmacology, Humans, Hydrogen Peroxide pharmacology, Male, Mass Spectrometry methods, Membrane Potentials genetics, Membrane Potentials physiology, Mice, Neurons drug effects, Oxidants toxicity, Oxidation-Reduction drug effects, Oxidative Stress drug effects, Oxidative Stress genetics, Patch-Clamp Techniques, Peptide Fragments toxicity, Presenilin-1 genetics, Propanols pharmacology, Shab Potassium Channels genetics, Transfection, Brain cytology, Neurons physiology, Oxidative Stress physiology, Shab Potassium Channels physiology

Abstract

Potassium (K(+)) channels are essential to neuronal signaling and survival. Here we show that these proteins are targets of reactive oxygen species in mammalian brain and that their oxidation contributes to neuropathy. Thus, the KCNB1 (Kv2.1) channel, which is abundantly expressed in cortex and hippocampus, formed oligomers upon exposure to oxidizing agents. These oligomers were ∼10-fold more abundant in the brain of old than young mice. Oxidant-induced oligomerization of wild-type KCNB1 enhanced apoptosis in neuronal cells subject to oxidative insults. Consequently, a KCNB1 variant resistant to oxidation, obtained by mutating a conserved cysteine to alanine, (C73A), was neuroprotective. The fact that oxidation of KCNB1 is toxic, argues that this mechanism may contribute to neuropathy in conditions characterized by high levels of oxidative stress, such as Alzheimer's disease (AD). Accordingly, oxidation of KCNB1 channels was exacerbated in the brain of a triple transgenic mouse model of AD (3xTg-AD). The C73A variant protected neuronal cells from apoptosis induced by incubation with β-amyloid peptide (Aβ(1-42)). In an invertebrate model (Caenorhabditis elegans) that mimics aspects of AD, a C73A-KCNB1 homolog (C113S-KVS-1) protected specific neurons from apoptotic death induced by ectopic expression of human Aβ(1-42). Together, these data underscore a novel mechanism of toxicity in neurodegenerative disease.

Published

2012

21. BKCa and KV channels limit conducted vasomotor responses in rat mesenteric terminal arterioles.

Author

Hald BO, Jacobsen JC, Braunstein TH, Inoue R, Ito Y, Sørensen PG, Holstein-Rathlou NH, and Jensen LJ

Subjects

Animals, Calcium metabolism, Computer Simulation, Large-Conductance Calcium-Activated Potassium Channel alpha Subunits, Male, Membrane Potentials physiology, Models, Animal, Models, Theoretical, Muscle, Smooth, Vascular physiology, Rats, Rats, Sprague-Dawley, Arterioles physiology, Kv1.5 Potassium Channel physiology, Mesenteric Arteries physiology, Potassium Channels physiology, Shab Potassium Channels physiology, Vasomotor System physiology

Abstract

Intracellular Ca(2+) signals underlying conducted vasoconstriction to local application of a brief depolarizing KCl stimulus was investigated in rat mesenteric terminal arterioles (<40 μm). Using a computer model of an arteriole segment comprised of coupled endothelial cells (EC) and vascular smooth muscle cells (VSMC) simulations of both membrane potential and intracellular [Ca(2+)] were performed. The "characteristic" length constant, λ, was approximated using a modified cable equation in both experiments and simulations. We hypothesized that K(+) conductance in the arteriolar wall limit the electrotonic spread of a local depolarization along arterioles by current dissipation across the VSMC plasma membrane. Thus, we anticipated an increased λ by inhibition of voltage-activated K(+) channels. Application of the BK(Ca) channel blocker iberiotoxin (100 nM) onto mesenteric arterioles in vitro and inhibition of BK(Ca) channel current in silico increased λ by 34% and 32%, respectively. Similarly, inhibition of K(V) channels in vitro (4-aminopyridine, 1 mM) or in silico increased λ by 41% and 21%, respectively. Immunofluorescence microscopy demonstrated expression of BK(Ca), Kv1.5, Kv2.1, but not Kv1.2, in VSMCs of rat mesenteric terminal arterioles. Our results demonstrate that inhibition of voltage-activated K(+) channels enhance vascular-conducted responses to local depolarization in terminal arterioles by increasing the membrane resistance of VSMCs. These data contribute to our understanding of how differential expression patterns of voltage-activated K(+) channels may influence conducted vasoconstriction in small arteriolar networks. This finding is potentially relevant to understanding the compromised microcirculatory blood flow in systemic vascular diseases such as diabetes mellitus and hypertension.

Published

2012

22. Extracellular chloride regulation of Kv2.1, contributor to the major outward Kv current in mammalian outer hair cells.

Author

Li X, Surguchev A, Bian S, Navaratnam D, and Santos-Sacchi J

Subjects

Animals, CHO Cells, Cricetinae, Cricetulus, Guinea Pigs, Chlorides physiology, Extracellular Fluid physiology, Hair Cells, Auditory, Outer physiology, Shab Potassium Channels physiology

Abstract

Outer hair cells (OHC) function as both receptors and effectors in providing a boost to auditory reception. Amplification is driven by the motor protein prestin, which is under anionic control. Interestingly, we now find that the major, 4-AP-sensitive, outward K(+) current of the OHC (I(K)) is also sensitive to Cl(-), although, in contrast to prestin, extracellularly. I(K) is inhibited by reducing extracellular Cl(-) levels, with a linear dependence of 0.4%/mM. Other voltage-dependent K(+) (Kv) channel conductances in supporting cells, such as Hensen and Deiters' cells, are not affected by reduced extracellular Cl(-). To elucidate the molecular basis of this Cl(-)-sensitive I(K), we looked at potential molecular candidates based on Cl(-) sensitivity and/or similarities in kinetics. For I(K), we identified three different Ca(2+)-independent components of I(K) based on the time constant of inactivation: a fast, transient outward current, a rapidly activating, slowly inactivating current (Ik(1)), and a slowly inactivating current (Ik(2)). Extracellular Cl(-) differentially affects these components. Because the inactivation time constants of Ik(1) and Ik(2) are similar to those of Kv1.5 and Kv2.1, we transiently transfected these constructs into CHO cells and found that low extracellular Cl(-) inhibited both channels with linear current reductions of 0.38%/mM and 0.49%/mM, respectively. We also tested heterologously expressed Slick and Slack conductances, two intracellularly Cl(-)-sensitive K(+) channels, but found no extracellular Cl(-) sensitivity. The Cl(-) sensitivity of Kv2.1 and its robust expression within OHCs verified by single-cell RT-PCR indicate that these channels underlie the OHC's extracellular Cl(-) sensitivity.

Published

2012

23. The voltage-gated channel accessory protein KCNE2: multiple ion channel partners, multiple ways to long QT syndrome.

Author

Eldstrom J and Fedida D

Subjects

Action Potentials, Amino Acid Sequence, ERG1 Potassium Channel, Ether-A-Go-Go Potassium Channels metabolism, Ether-A-Go-Go Potassium Channels physiology, Humans, Molecular Sequence Data, Mutation, Potassium Channels, Voltage-Gated chemistry, Potassium Channels, Voltage-Gated physiology, Shab Potassium Channels metabolism, Shab Potassium Channels physiology, Long QT Syndrome genetics, Potassium Channels, Voltage-Gated genetics

Abstract

The single-pass transmembrane protein KCNE2 or MIRP1 was once thought to be the missing accessory protein that combined with hERG to fully recapitulate the cardiac repolarising current IKr. As a result of this role, it was an easy next step to associate mutations in KCNE2 to long QT syndrome, in which there is delayed repolarisation of the heart. Since that time however, KCNE2 has been shown to modify the behaviour of several other channels and currents, and its role in the heart and in the aetiology of long QT syndrome has become less clear. In this article, we review the known interactions of the KCNE2 protein and the resulting functional effects, and the effects of mutations in KCNE2 and their clinical role.

Published

2011

24. Identification of novel and selective Kv2 channel inhibitors.

Author

Herrington J, Solly K, Ratliff KS, Li N, Zhou YP, Howard A, Kiss L, Garcia ML, McManus OB, Deng Q, Desai R, Xiong Y, and Kaczorowski GJ

Subjects

Animals, CHO Cells, Cricetinae, Cricetulus, Humans, Rats, Shab Potassium Channels physiology, Structure-Activity Relationship, Drug Discovery methods, Potassium Channel Blockers chemistry, Potassium Channel Blockers pharmacology, Shab Potassium Channels antagonists & inhibitors

Abstract

Identification of selective ion channel inhibitors represents a critical step for understanding the physiological role that these proteins play in native systems. In particular, voltage-gated potassium (K(V)2) channels are widely expressed in tissues such as central nervous system, pancreas, and smooth muscle, but their particular contributions to cell function are not well understood. Although potent and selective peptide inhibitors of K(V)2 channels have been characterized, selective small molecule K(V)2 inhibitors have not been reported. For this purpose, high-throughput automated electrophysiology (IonWorks Quattro; Molecular Devices, Sunnyvale, CA) was used to screen a 200,000-compound mixture (10 compounds per sample) library for inhibitors of K(V)2.1 channels. After deconvolution of 190 active samples, two compounds (A1 and B1) were identified that potently inhibit K(V)2.1 and the other member of the K(V)2 family, K(V)2.2 (IC(50), 0.1-0.2 μM), and that possess good selectivity over K(V)1.2 (IC(50) >10 μM). Modeling studies suggest that these compounds possess a similar three-dimensional conformation. Compounds A1 and B1 are >10-fold selective over Na(V) channels and other K(V) channels and display weak activity (5-9 μM) on Ca(V) channels. The biological activity of compound A1 on native K(V)2 channels was confirmed in electrophysiological recordings of rat insulinoma cells, which are known to express K(V)2 channels. Medicinal chemistry efforts revealed a defined structure-activity relationship and led to the identification of two compounds (RY785 and RY796) without significant Ca(V) channel activity. Taken together, these newly identified channel inhibitors represent important tools for the study of K(V)2 channels in biological systems.

Published

2011

25. Stromatoxin-sensitive, heteromultimeric Kv2.1/Kv9.3 channels contribute to myogenic control of cerebral arterial diameter.

Author

Zhong XZ, Abd-Elrahman KS, Liao CH, El-Yazbi AF, Walsh EJ, Walsh MP, and Cole WC

Subjects

Animals, HEK293 Cells, Humans, KCNQ3 Potassium Channel chemistry, Male, Protein Subunits chemistry, Rats, Rats, Sprague-Dawley, Shab Potassium Channels antagonists & inhibitors, Shab Potassium Channels chemistry, Spider Venoms, Cerebral Arteries physiology, KCNQ3 Potassium Channel physiology, Peptides physiology, Protein Multimerization physiology, Protein Subunits physiology, Shab Potassium Channels physiology, Vasoconstriction physiology

Abstract

Cerebral vascular smooth muscle contractility plays a crucial role in controlling arterial diameter and, thereby, blood flow regulation in the brain. A number of K(+) channels have been suggested to contribute to the regulation of diameter by controlling smooth muscle membrane potential (E(m)) and Ca(2+) influx. Previous studies indicate that stromatoxin (ScTx1)-sensitive, Kv2-containing channels contribute to the control of cerebral arterial diameter at 80 mmHg, but their precise role and molecular composition were not determined. Here, we tested if Kv2 subunits associate with 'silent' subunits from the Kv5, Kv6, Kv8 or Kv9 subfamilies to form heterotetrameric channels that contribute to control of diameter of rat middle cerebral arteries (RMCAs) over a range of intraluminal pressure from 10 to 100 mmHg. The predominant mRNAs expressed by RMCAs encode Kv2.1 and Kv9.3 subunits. Co-localization of Kv2.1 and Kv9.3 proteins at the plasma membrane of dissociated single RMCA myocytes was detected by proximity ligation assay. ScTx1-sensitive native current of RMCA myocytes and Kv2.1/Kv9.3 currents exhibited functional identity based on the similarity of their deactivation kinetics and voltage dependence of activation that were distinct from those of homomultimeric Kv2.1 channels. ScTx1 treatment enhanced the myogenic response of pressurized RMCAs between 40 and 100 mmHg, but this toxin also caused constriction between 10 and 40 mmHg that was not previously observed following inhibition of large conductance Ca(2+)-activated K(+) (BK(Ca)) and Kv1 channels. Taken together, this study defines the molecular basis of Kv2-containing channels and contributes to our understanding of the functional significance of their expression in cerebral vasculature. Specifically, our findings provide the first evidence of heteromultimeric Kv2.1/Kv9.3 channel expression in RMCA myocytes and their distinct contribution to control of cerebral arterial diameter over a wider range of E(m) and transmural pressure than Kv1 or BK(Ca) channels owing to their negative range of voltage-dependent activation.

Published

2010

26. Quinidine interaction with Shab K+ channels: pore block and irreversible collapse of the K+ conductance.

Author

Gomez-Lagunas F

Subjects

Animals, Cell Line, Cell Membrane Permeability drug effects, Electric Conductivity, Membrane Potentials drug effects, Shab Potassium Channels drug effects, Spodoptera, Cell Membrane Permeability physiology, Ion Channel Gating physiology, Membrane Potentials physiology, Potassium metabolism, Quinidine administration & dosage, Quinidine pharmacokinetics, Shab Potassium Channels physiology

Abstract

Quinidine is a commonly used antiarrhythmic agent and a tool to study ion channels. Here it is reported that quinidine equilibrates within seconds across the Sf9 plasma membrane, blocking the open pore of Shab channels from the intracellular side of the membrane in a voltage-dependent manner with 1:1 stoichiometry. On binding to the channels, quinidine interacts with pore K(+) ions in a mutually destabilizing manner. As a result, when the channels are blocked by quinidine with the cell bathed in an external medium lacking K(+), the Shab conductance G(K) collapses irreversibly, despite the presence of a physiological [K(+)] in the intracellular solution. The quinidine-promoted collapse of Shab G(K) resembles the collapse of Shaker G(K) observed with 0 K(+) solutions on both sides of the membrane: thus the extent of G(K) drop depends on the number of activating pulses applied in the presence of quinidine, but is independent of the pulse duration. Taken together the observations indicate that, as in Shaker, the quinidine-promoted collapse of Shab G(K) occurs during deactivation of the channels, at the end of each activating pulse, with a probability of 0.1 per pulse at 80 mV. It appears that when Shab channels are open, the pore conformation able to conduct is stable in the absence of K(+), but on deactivation this conformation collapses irreversibly.

Published

2010

27. Localization-dependent activity of the Kv2.1 delayed-rectifier K+ channel.

Author

O'Connell KM, Loftus R, and Tamkun MM

Subjects

Algorithms, Cell Line, Cell Membrane metabolism, Cell Membrane physiology, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Humans, Membrane Potentials, Patch-Clamp Techniques, Quantum Dots, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Shab Potassium Channels genetics, Shab Potassium Channels metabolism, Transfection, Ion Channel Gating physiology, Potassium metabolism, Shab Potassium Channels physiology

Abstract

The Kv2.1 K(+) channel is highly expressed throughout the brain, where it regulates excitability during periods of high-frequency stimulation. Kv2.1 is unique among Kv channels in that it targets to large surface clusters on the neuronal soma and proximal dendrites. These clusters also form in transfected HEK cells. Following excessive excitatory stimulation, Kv2.1 declusters with an accompanying 20- to 30-mV hyperpolarizing shift in the activation threshold. Although most Kv2.1 channels are clustered, there is a pool of Kv2.1 resident outside of these domains. Using the cell-attached patch clamp technique, we investigated the hypothesis that Kv2.1 activity varies as a function of cell surface location. We found that clustered Kv2.1 channels do not efficiently conduct K(+), whereas the nonclustered channels are responsible for the high threshold delayed rectifier K(+) current typical of Kv2.1. Comparison of gating and ionic currents indicates only 2% of the surface channels conduct, suggesting that the clustered channels still respond to membrane potential changes. Declustering induced via either actin depolymerization or alkaline phosphatase treatment did not increase whole-cell currents. Dephosphorylation resulted in a 25-mV hyperpolarizing shift, whereas actin depolymerization did not alter the activation midpoint. Taken together, these data demonstrate that clusters do not contain high threshold Kv2.1 channels whose voltage sensitivity shifts upon declustering; nor are they a reservoir of nonconducting channels that are activated upon release. On the basis of these findings, we propose unique roles for the clustered Kv2.1 that are independent of K(+) conductance.

Published

2010

28. Solution structure of GxTX-1E, a high-affinity tarantula toxin interacting with voltage sensors in Kv2.1 potassium channels .

Author

Lee S, Milescu M, Jung HH, Lee JY, Bae CH, Lee CW, Kim HH, Swartz KJ, and Kim JI

Subjects

Amino Acid Sequence, Animals, Arthropod Proteins, Hydrogen Bonding, Molecular Sequence Data, Nuclear Magnetic Resonance, Biomolecular, Peptides metabolism, Protein Conformation, Sequence Homology, Amino Acid, Shab Potassium Channels physiology, Spider Venoms metabolism, Xenopus laevis, Peptides chemistry, Shab Potassium Channels metabolism, Spider Venoms chemistry

Abstract

GxTX-1E is a neurotoxin recently isolated from Plesiophrictus guangxiensis venom that inhibits the Kv2.1 channel in pancreatic beta-cells. The sequence of the toxin is related to those of previously studied tarantula toxins that interact with the voltage sensors in Kv channels, and GxTX-1E interacts with the Kv2.1 channel with unusually high affinity, making it particularly useful for structural and mechanistic studies. Here we determined the three-dimensional solution structure of GxTX-1E using NMR spectroscopy and compared it to that of several related tarantula toxins. The molecular structure of GxTX-1E is similar to those of tarantula toxins that target voltage sensors in Kv channels in that it contains an ICK motif, composed of beta-strands, and contains a prominent cluster of solvent-exposed hydrophobic residues surrounded by polar residues. When compared with the structure of SGTx1, a toxin for which mutagenesis data are available, the residue compositions of the two toxins are distinct in regions that are critical for activity, suggesting that their modes of binding to voltage sensors may be different. Interestingly, the structural architecture of GxTX-1E is also similar to that of JZTX-III, a tarantula toxin that interacts with Kv2.1 with low affinity. The most striking structural differences between GxTX-1E and JZTX-III are found in the orientation between the first and second cysteine loops and the C-terminal region of the toxins, suggesting that these regions of GxTX-1E are responsible for its high affinity.

Published

2010

29. Voltage-gated K+ channel modulators as neuroprotective agents.

Author

Leung YM

Subjects

Action Potentials drug effects, Action Potentials physiology, Animals, Apoptosis drug effects, Apoptosis physiology, Humans, Neurons drug effects, Neurons physiology, Neuroprotective Agents therapeutic use, Potassium Channel Blockers therapeutic use, Potassium Channels physiology, Shab Potassium Channels drug effects, Shab Potassium Channels physiology, Neuroprotective Agents pharmacology, Potassium Channel Blockers pharmacology, Potassium Channels drug effects

Abstract

A manifestation in neurodegeneration is apoptosis of neurons. Neurons undergoing apoptosis may lose a substantial amount of cytosolic K+ through a number of pathways including K+ efflux via voltage-gated K+ (Kv) channels. The consequent drop in cytosolic [K+] relieves inhibition of an array of pro-apoptotic enzymes such as caspases and nucleases. Blocking Kv channels has been known to prevent neuronal apoptosis by preventing K+ efflux. Some neural diseases such as epilepsy are caused by neuronal hyperexcitability, which eventually may lead to neuronal apoptosis. Reduction in activities of A-type Kv channels and Kv7 subfamily members is amongst the etiological causes of neuronal hyperexcitation; enhancing the opening of these channels may offer opportunities of remedy. This review discusses the potential uses of Kv channel modulators as neuroprotective drugs.

Published

2010

30. Mechanisms of Kv2.1 channel inhibition by celecoxib--modification of gating and channel block.

Author

Frolov RV, Bondarenko VE, and Singh S

Subjects

Animals, Celecoxib, Cell Line, Dose-Response Relationship, Drug, Humans, Ion Channel Gating drug effects, Patch-Clamp Techniques, Rats, Cyclooxygenase 2 Inhibitors pharmacology, Pyrazoles pharmacology, Shab Potassium Channels antagonists & inhibitors, Shab Potassium Channels physiology, Sulfonamides pharmacology

Abstract

Background and Purpose: Selective cyclooxygenase-2 (COX-2) inhibitors such as rofecoxib (Vioxx) and celecoxib (Celebrex) were developed as NSAIDs with reduced gastric side effects. Celecoxib has now been shown to affect cellular physiology via an unexpected, COX-independent, pathway - by inhibiting K(v)2.1 and other ion channels. In this study, we investigated the mechanism of the action of celecoxib on K(v)2.1 channels., Experimental Approach: The mode of action of celecoxib on rat K(v)2.1 channels was studied by whole-cell patch-clamping to record currents from channels expressed in HEK-293 cells., Key Results: Celecoxib reduced current through K(v)2.1 channels when applied from the extracellular side. At low concentrations (3 microM, celecoxib led to closed-channel block with relative slowing of activation. At 30 microM, it additionally induced open-channel block that manifested in use-dependent inhibition and slower recovery from inactivation., Conclusions and Implications: Celecoxib reduced current through K(v)2.1 channels by modifying gating and inducing closed- and open-channel block, with the three effects manifesting at different concentrations. These data will help to elucidate the mechanisms of action of this widely prescribed drug on ion channels and those underlying its neurological, cardiovascular and other effects.

Published

2010

31. Regulation of apoptotic potassium currents by coordinated zinc-dependent signalling.

Author

Redman PT, Hartnett KA, Aras MA, Levitan ES, and Aizenman E

Subjects

Animals, CHO Cells, Cricetinae, Cricetulus, Feedback, Physiological physiology, Apoptosis physiology, Ion Channel Gating physiology, Membrane Potentials physiology, Potassium metabolism, Shab Potassium Channels physiology, Signal Transduction physiology, Zinc metabolism

Abstract

Oxidant-liberated intracellular Zn(2+) regulates neuronal apoptosis via an exocytotic membrane insertion of Kv2.1-encoded ion channels, resulting in an enhancement of voltage-gated K(+) currents and a loss of intracellular K(+) that is necessary for caspase-mediated proteolysis. In the present study we show that an N-terminal tyrosine of Kv2.1 (Y124), which is a known target of Src kinase, is critical for the apoptotic current surge. Moreover, we demonstrate that Y124 works in concert with a C-terminal serine (S800) target of p38 mitogen-activated protein kinase (MAPK) to regulate Kv2.1-mediated current enhancement. While Zn(2+) was previously shown to activate p38, we show here that this metal inhibits cytoplasmic protein tyrosine phosphatase (Cyt-PTPepsilon), which specifically targets Y124. Importantly, a point mutation of Y124 to a non-phosphorylatable residue or over-expression of Cyt-PTPepsilon protects cells from injury. Kv2.1-encoded channels thus regulate neuronal survival by providing a converging input for two Zn(2+)-dependent signal transduction cascades.

Published

2009

32. Intracellular regions of potassium channels: Kv2.1 and heag.

Author

Wray D

Subjects

Amino Acid Sequence, Animals, Ether-A-Go-Go Potassium Channels chemistry, Ether-A-Go-Go Potassium Channels genetics, Humans, Intracellular Space metabolism, Ion Channel Gating physiology, Models, Molecular, Molecular Sequence Data, Protein Structure, Tertiary, Shab Potassium Channels chemistry, Ether-A-Go-Go Potassium Channels physiology, Shab Potassium Channels physiology

Abstract

Intracellular regions of voltage-gated potassium channels often comprise the largest part of the channel protein, and yet the functional role of these regions is not fully understood. For the Kv2.1 channel, although there are differences in activation kinetics between rat and human channels, there are, for instance, no differences in movement of the S4 region between the two channels, and indeed our mutagenesis studies have identified interacting residues in both the N- and C -terminal intracellular regions that are responsible for these functional effects. Furthermore, using FRET with fluorescent-tagged Kv2.1 channels, we have shown movement of the C-termini relative to the N-termini during activation. Such interactions and movements of the intracellular regions of the channel appear to form part of the channel gating machinery. Heag1 and heag2 channels also display differing activation properties, despite their considerable homology. By a chimeric approach, we have shown that these differences in activation kinetics are determined by multiple interacting regions in the N-terminus and membrane-spanning regions. Furthermore, alanine mutations of many residues in the C-terminal cyclic nucleotide binding domain affect activation kinetics. The data again suggest interacting regions between N- and C- termini that participate in the conformational changes during channel activation. Using a mass-spectrometry approach, we have identified alpha-tubulin and a heat shock protein as binding to the C-terminus of the heag2 channel, and alpha-tubulin itself has functional effects on channel activation kinetics. Clearly, the intracellular regions of these ion channels (and most likely many other ion channels too) are important regions in determining channel function.

Published

2009

33. VAMP2 interacts directly with the N terminus of Kv2.1 to enhance channel inactivation.

Author

Lvov A, Chikvashvili D, Michaelevski I, and Lotan I

Subjects

Animals, Blotting, Western, Brain Chemistry, Cell Membrane metabolism, Electrophysiology, Glutathione Transferase metabolism, Immunoprecipitation, Kinetics, Models, Molecular, Oocytes, Patch-Clamp Techniques, Rats, Xenopus laevis, Shab Potassium Channels physiology, Vesicle-Associated Membrane Protein 2 physiology

Abstract

Recently, we demonstrated that the Kv2.1 channel plays a role in regulated exocytosis of dense-core vesicles (DCVs) through direct interaction of its C terminus with syntaxin 1A, a plasma membrane soluble NSF attachment receptor (SNARE) component. We report here that Kv2.1 interacts with VAMP2, the vesicular SNARE partner that is also present at high concentration in neuronal plasma membrane. This is the first report of VAMP2 interaction with an ion channel. The interaction was demonstrated in brain membranes and characterized using electrophysiological and biochemical analyses in Xenopus oocytes combined with an in vitro binding analysis and protein modeling. Comparative study performed with wild-type and mutant Kv2.1, wild-type Kv1.5, and chimeric Kv1.5N/Kv2.1 channels revealed that VAMP2 enhanced the inactivation of Kv2.1, but not of Kv1.5, via direct interaction with the T1 domain of the N terminus of Kv2.1. Given the proposed role for surface VAMP2 in the regulation of the vesicle cycle and the important role for the sustained Kv2.1 current in the regulation of dendritic calcium entry during high-frequency stimulation, the interaction of VAMP2 with Kv2.1 N terminus may contribute, alongside with the interaction of syntaxin with Kv2.1 C terminus, to the activity dependence of DCV release.

Published

2008

34. Glutamate transporters regulate extrasynaptic NMDA receptor modulation of Kv2.1 potassium channels.

Author

Mulholland PJ, Carpenter-Hyland EP, Hearing MC, Becker HC, Woodward JJ, and Chandler LJ

Subjects

Analysis of Variance, Animals, Animals, Newborn, Cells, Cultured, Cerebral Cortex cytology, Disks Large Homolog 4 Protein, Dizocilpine Maleate pharmacology, Excitatory Amino Acid Agonists pharmacology, Excitatory Amino Acid Antagonists pharmacology, Hippocampus cytology, Intracellular Signaling Peptides and Proteins metabolism, Male, Membrane Potentials drug effects, Membrane Potentials physiology, Membrane Potentials radiation effects, Membrane Proteins metabolism, N-Methylaspartate pharmacology, Neurons drug effects, Neurons physiology, Neurons radiation effects, Organ Culture Techniques, Patch-Clamp Techniques methods, Pentylenetetrazole, Rats, Rats, Sprague-Dawley, Seizures chemically induced, Amino Acid Transport System X-AG physiology, Receptors, N-Methyl-D-Aspartate metabolism, Shab Potassium Channels physiology, Synapses metabolism

Abstract

Delayed-rectifier Kv2.1 potassium channels regulate somatodendritic excitability during periods of repetitive, high-frequency activity. Recent evidence suggests that Kv2.1 channel modulation is linked to glutamatergic neurotransmission. Because NMDA-type glutamate receptors are critical regulators of synaptic plasticity, we investigated NMDA receptor modulation of Kv2.1 channels in rodent hippocampus and cortex. Bath application of NMDA potently unclustered and dephosphorylated Kv2.1 and produced a hyperpolarizing shift in voltage-dependent activation of voltage-sensitive potassium currents (I(K)). In contrast, driving synaptic activity in Mg2+-free media to hyperactivate synaptic NMDA receptors had no effect on Kv2.1 channels, and moderate pentylenetetrazole-induced seizure activity in adult mice did not dephosphorylate hippocampal Kv2.1 channels. Selective activation of extrasynaptic NMDA receptors unclustered and dephosphorylated Kv2.1 channels and produced a hyperpolarizing shift in neuronal I(K). In addition, inhibition of glutamate uptake rapidly activated NMDA receptors and dephosphorylated Kv2.1 channels. These observations demonstrate that regulation of intrinsic neuronal activity by Kv2.1 is coupled to extrasynaptic but not synaptic NMDA receptors. These data support a novel mechanism for glutamate transporters in regulation of neuronal excitability and plasticity through extrasynaptic NMDA receptor modulation of Kv2.1 channels.

Published

2008

35. Expressions of voltage-gated K+ channel 2.1 and 2.2 in rat bladder with detrusor hyperreflexia.

Author

Gan XG, An RH, Bai YF, and Zong DB

Subjects

Animals, Female, In Vitro Techniques, Muscle Contraction, Rats, Rats, Sprague-Dawley, Reverse Transcriptase Polymerase Chain Reaction, Shab Potassium Channels physiology, Urinary Bladder, Overactive etiology, RNA, Messenger analysis, Shab Potassium Channels genetics, Urinary Bladder metabolism, Urinary Bladder, Overactive metabolism

Abstract

Background: Voltage-gated K+ channel (Kv) plays a critical role in the modulation of detrusor contraction. This study was conducted to investigate the expressions of Kv2.1 and Kv2.2 in rat bladder with detrusor hyperreflexia (DH)., Methods: Thirty adult female Sprague-Dawley rats (200-220 g) were randomly divided into the control group and the experimental group. The experimental group was subjected to spinal cord injury (SCI). In the controls, the surgical procedure was identical with the exception that dura and spinal cord were transected. Four weeks after SCI, in vivo cystometry and mechanical pulling tests of isolated detrusor strips were performed. mRNA was extracted from the detrusors of normal and DH rats for the detection of expression of Kv2.1 and Kv2.2 by RT-PCR. Differences in expression between normal and overactive detrusors were identified by gel imaging., Results: Fourteen rats in the experimental group exhibited uninhibited bladder contraction (>8 cmH2O) before voiding after SCI. One rat died from infection. The frequency of DH in the experimental group was significantly different from that in the control group with or without treatment with 4-aminopyridine (4-AP) (P < 0.05), while the amplitude of DH did not change markedly. The rates of variation of the automatic contractile frequency and amplitude were (66.8 +/- 12.4)% and (42.6 +/- 12.6)% respectively in the control group, and (38.4 +/- 9.8)% and (28.0 +/- 4.6)% respectively in the DH group. 4-AP increased the automatic contractile frequency apart from the automatic contractile amplitude in both the control and DH groups (P < 0.05). 4-AP increased the rate of variation of the automatic contractile frequency more markedly in the control group than in the DH group (P < 0.05). Significant expression of Kv2.2 was not detected in bladders in the control group. Compared to the mRNA levels of beta-actin, the mRNA level of Kv2.1 was 1.26 +/- 0.12 in the control group and 0.66 +/- 0.08 in the DH group. SCI significantly reduced the mRNA level of Kv2.1 in rat bladders with DH (P < 0.05)., Conclusions: Our study showed that the mRNA level of Kv2.1 decreased significantly in rat bladder with DH, which was one of the important pathogenetic mechanisms for DH, and suggested that Kv2.1 might be one of the therapeutic targets for bladder overactivity.

Published

2008

36. Functional and pharmacological characterization of a Shal-related K+ channel subunit in Zebrafish.

Author

Nakamura TY and Coetzee WA

Subjects

Amino Acid Sequence, Animals, Cells, Cultured, Ion Channel Gating drug effects, Molecular Sequence Data, Protein Subunits, Shab Potassium Channels drug effects, Structure-Activity Relationship, Ion Channel Gating physiology, Membrane Potentials physiology, Shab Potassium Channels chemistry, Shab Potassium Channels physiology, Zebrafish physiology

Abstract

Background: K+ channels are diverse; both in terms of their function and their molecular composition. Shal subunits were first described in Drosophila. There are three mammalian orthologs, which are members of the Kv4 subfamily. They are involved in neuronal firing patterns as well as control of the cardiac action potential duration., Results: Here, we report the biophysical and pharmacological characterization of zShal3, which is the ortholog of the mammalian Kv4.3 subunit, which in mammals is involved in action potential repolarization and gives rise to neuronal A-type K+ currents involved in somatodendretic signal integration., Conclusion: We demonstrate that zShal has similar functional and pharmacological characteristics compared to Kv4.3 and it is similarly regulated by pharmacological agents and by the Kv4 accessory subunit, NCS-1.

Published

2008

37. Voltage gated K+ channel expression in arteries of Wistar-Kyoto and spontaneously hypertensive rats.

Author

Cox RH, Fromme SJ, Folander KL, and Swanson RJ

Subjects

Animals, Antibody Specificity, CHO Cells, Cricetinae, Cricetulus, Gene Expression physiology, Humans, Kidney cytology, Kv1.2 Potassium Channel genetics, Kv1.2 Potassium Channel immunology, Kv1.2 Potassium Channel physiology, Kv1.5 Potassium Channel genetics, Kv1.5 Potassium Channel immunology, Kv1.5 Potassium Channel physiology, Male, Mesenteric Arteries physiology, Monocytes physiology, Patch-Clamp Techniques, Potassium Channels, Voltage-Gated immunology, Rats, Rats, Inbred SHR, Rats, Inbred WKY, Shab Potassium Channels genetics, Shab Potassium Channels immunology, Shab Potassium Channels physiology, Tail blood supply, Thoracic Arteries physiology, Hypertension genetics, Hypertension physiopathology, Potassium Channels, Voltage-Gated genetics, Potassium Channels, Voltage-Gated physiology

Abstract

Background: We have previously demonstrated differences in the gene expression of voltage-gated K v1.X channel alpha-subunits in arteries from Wistar-Kyoto rats (WKYs) and spontaneously hypertensive rats (SHRs). The purpose of this study was to test the hypothesis that these differences are also present at the protein level., Methods: Proteins were isolated from the aorta, mesenteric (MAs) and tail arteries (TAs) of 12- to 15-week-old male WKY and SHR, and analyzed by immunoblotting. K(v) currents were recorded from MA myocytes by patch clamp methods., Results: Expression of Kv1.2, Kv1.5, and Kv2.1 was higher in MAs but was not different in aortas of SHRs as compared to WKYs. In the TA, expression of Kv1.2 and Kv1.5 was higher while that of Kv2.1 was lower in SHR compared to WKY. In the MA, the larger expression of an 80 kDa species of Kv1.2 in SHRs was associated with a lower expression of a 60 kDa species. Kv2.1 gene expression was larger in MAs from SHRs but not different in TAs. K(v) currents associated with Kv1.X and Kv2.1 channels were both larger in MA myocytes from SHRs but less than expected based upon differences in K(v) alpha-subunit protein expression., Conclusions: For the MA, K(v) protein expression and current components between WKYs and SHRs were qualitatively consistent, but differences in gene and protein expression were not closely correlated. The higher expression of K(v) subunits in small mesenteric arteries (SMAs) of SHR would tend to maintain normal myogenic activity and vasoconstrictor reserve, and could be viewed as a form of homeostatic remodeling.

Published

2008

38. mGlu4 potentiation of K(2P)2.1 is dependant on C-terminal dephosphorylation.

Author

Cain SM, Meadows HJ, Dunlop J, and Bushell TJ

Subjects

8-Bromo Cyclic Adenosine Monophosphate pharmacology, Animals, CHO Cells drug effects, CHO Cells physiology, CHO Cells radiation effects, Cricetinae, Cricetulus, Cyclic AMP pharmacology, Electric Stimulation methods, Enzyme Inhibitors pharmacology, Excitatory Amino Acid Agents pharmacology, Green Fluorescent Proteins metabolism, Membrane Potentials drug effects, Membrane Potentials physiology, Membrane Potentials radiation effects, Mutation physiology, Patch-Clamp Techniques methods, Pertussis Toxin pharmacology, Phosphorylation, Propionates pharmacology, Shab Potassium Channels genetics, Transfection, Peptide Fragments metabolism, Receptors, Metabotropic Glutamate physiology, Shab Potassium Channels physiology

Abstract

Two-pore domain potassium (K(2P)) channels are proposed to underlie the background or leak current found in many excitable cells. Extensive studies have been performed investigating the inhibition of K(2P)2.1 by Galpha(q)- and Galpha(s)-coupled G-protein-coupled receptors (GPCRs), whereas in the present study we investigate the mechanisms underlying Galpha(i)/Galpha(o)-coupled GPCR increases in K(2P)2.1 activity. Activation of mGlu4 increases K(2P)2.1 activity, with pharmacological inhibition of protein kinases and phosphatases revealing the involvement of PKA whereas PKC, PKG or protein phosphatases play no role. Mutational analysis of potential C-terminal phosphorylation sites indicates S333 to control approximately 70%, with S300 controlling approximately 30% of the increase in K(2P)2.1 activity following mGlu4 activation. These data reveal that activation of mGlu4 leads to an increase in K(2P)2.1 activity through a reduction in C-terminal phosphorylation, which represents a novel mechanism by which group III mGlu receptors may regulate cell excitability and synaptic activity.

Published

2008

39. Botulinum neurotoxin A and neurotoxin E cleavage products of synaptosome-associated protein of 25 kd exhibit distinct actions on pancreatic islet beta-cell Kv2.1 channel gating.

Author

He Y, Elias CL, Huang YC, Gao X, Leung YM, Kang Y, Xie H, Chaddock JA, Tsushima RG, and Gaisano HY

Subjects

Animals, Blotting, Western, Cell Line, Glutathione Transferase genetics, Insulin metabolism, Insulin Secretion, Insulin-Secreting Cells physiology, Ion Channel Gating drug effects, Microscopy, Confocal, Patch-Clamp Techniques, Peptide Fragments genetics, Rats, Recombinant Fusion Proteins genetics, Shab Potassium Channels physiology, Synaptosomal-Associated Protein 25 genetics, Synaptosomal-Associated Protein 25 pharmacology, Transfection, Botulinum Toxins metabolism, Botulinum Toxins, Type A metabolism, Insulin-Secreting Cells chemistry, Peptide Fragments pharmacology, Shab Potassium Channels drug effects, Synaptosomal-Associated Protein 25 metabolism

Abstract

Objectives: Synaptosome-associated protein of 25 kd (SNAP-25) regulates pancreatic islet beta-cell-delayed rectifier K channels (Kv2.1) in addition to insulin exocytosis. Botulinum neurotoxin A (BoNT/A) and E (BoNT/E) cleavage and presumed deletion of SNAP-25 have been used to examine SNAP-25 function. We hypothesized that proteolytic products of SNAP-25 (206 amino acids) resulting from BoNT/A and BoNT/E cleavage, SNAP-25(1-197) and SNAP-25(1-180), have independent actions on beta-cell Kv gating., Methods: We examined by confocal microscopy and immunoblotting BoNT/A and BoNT/E cleavage of SNAP-25 to these N-terminal fragments, and the consequent effects of these BoNTs and SNAP-25 fragments on Kv currents in rat beta cells and MIN6 cells by patch clamp electrophysiology., Results: Confocal microscopy and immunoblotting showed that MIN6 cells transfected with BoNT/A or BoNT/E generated SNAP-25(1-197) and SNAP-25(1-180) fragments that were retained in the cytosol. Both BoNTs caused increased rate of channel activation and slowed channel inactivation, mimicked by these SNAP-25 fragments, but not full-length SNAP-25. These SNAP-25 fragments potentiated tetraethylammonium block of beta-cell Kv currents., Conclusions: BoNT/A or BoNT/E treatment of beta cells generates N-terminal SNAP-25 fragments that are retained in beta cells to directly influence Kv channel gating in a manner distinct from full-length SNAP-25, contributing to overall actions of these BoNTs on insulin secretion.

Published

2008

40. Microglia induce neurotoxicity via intraneuronal Zn(2+) release and a K(+) current surge.

Author

Knoch ME, Hartnett KA, Hara H, Kandler K, and Aizenman E

Subjects

Animals, Cell Death physiology, Cerebral Cortex cytology, Cerebral Cortex physiology, Coculture Techniques, Electrophysiology, Female, Immunohistochemistry, Ion Channel Gating physiology, Ion Channels drug effects, Ion Channels physiology, Luciferases genetics, MAP Kinase Kinase Kinase 5 genetics, MAP Kinase Kinase Kinase 5 physiology, Microglia pathology, Potassium Channels drug effects, Pregnancy, Rats, Rats, Sprague-Dawley, Shab Potassium Channels genetics, Shab Potassium Channels physiology, Signal Transduction physiology, Transfection, Microglia physiology, Neurodegenerative Diseases pathology, Neurons pathology, Potassium Channels physiology, Zinc metabolism

Abstract

Microglial cells are critical components of the injurious cascade in a large number of neurodegenerative diseases. However, the precise molecular mechanisms by which microglia mediate neuronal cell death have not been fully delineated. We report here that reactive species released from activated microglia induce the liberation of Zn(2+) from intracellular stores in cultured cortical neurons, with a subsequent enhancement in neuronal voltage-gated K(+) currents, two events that have been intimately linked to apoptosis. Both the intraneuronal Zn(2+) release and the K(+) current surge could be prevented by the NADPH oxidase inhibitor apocynin, the free radical scavenging mixture of superoxide dismutase and catalase, as well as by 5,10,15,20-tetrakis(4-sulfonatophenyl)porphyrinato iron(III) chloride. The enhancement of K(+) currents was prevented by neuronal overexpression of metallothionein III or by expression of a dominant negative (DN) vector for the upstream mitogen-activated protein kinase apoptosis signal regulating kinase-1 (ASK-1). Importantly, neurons overexpressing metallothionein-III or transfected with DN vectors for ASK-1 or Kv2.1-encoded K(+) channels were resistant to microglial-induced toxicity. These results establish a direct link between microglial-generated oxygen and nitrogen reactive products and neuronal cell death mediated by intracellular Zn(2+) release and a surge in K(+) currents., ((c) 2007 Wiley-Liss, Inc.)

Published

2008

41. Stability of the Shab K+ channel conductance in 0 K+ solutions: the role of the membrane potential.

Author

Gómez-Lagunas F

Subjects

Animals, Cell Line, Electric Conductivity, Hydrogen-Ion Concentration, Ion Channel Gating physiology, Membrane Potentials physiology, Potassium metabolism, Shab Potassium Channels physiology, Spodoptera metabolism

Abstract

Shab channels are fairly stable with K(+) present on only one side of the membrane. However, on exposure to 0 K(+) solutions on both sides of the membrane, the Shab K(+) conductance (G(K)) irreversibly drops while the channels are maintained undisturbed at the holding potential. Herein it is reported that the drop of G(K) follows first-order kinetics, with a voltage-dependent decay rate r. Hyperpolarized potentials drastically inhibit the drop of G(K). The G(K) drop at negative potentials cannot be explained by a shift in the voltage dependence of activation. At depolarized potentials, where the channels undergo a slow inactivation process, G(K) drops in 0 K(+) with rates slower than those predicted based on the behavior of r at negative potentials, endowing the r-V(m) relationship with a maximum. Regardless of voltage, r is very small compared with the rate of ion permeation. Observations support the hypothesized presence of a stabilizing K(+) site (or sites) located either within the pore itself or in its external vestibule, at an inactivation-sensitive location. It is argued that part of the G(K) stabilization achieved at hyperpolarized potentials could be the result of a conformational change in the pore itself.

Published

2007

42. Dynamic regulation of the voltage-gated Kv2.1 potassium channel by multisite phosphorylation.

Author

Mohapatra DP, Park KS, and Trimmer JS

Subjects

Cell Line, Humans, Neurons physiology, Phosphorylation, Shab Potassium Channels chemistry, Shab Potassium Channels metabolism, Tandem Mass Spectrometry, Ion Channel Gating, Shab Potassium Channels physiology

Abstract

Voltage-gated K(+) channels are key regulators of neuronal excitability. The Kv2.1 voltage-gated K(+) channel is the major delayed rectifier K(+) channel expressed in most central neurons, where it exists as a highly phosphorylated protein. Kv2.1 plays a critical role in homoeostatic regulation of intrinsic neuronal excitability through its activity- and calcineurin-dependent dephosphorylation. Here, we review studies leading to the identification and functional characterization of in vivo Kv2.1 phosphorylation sites, a subset of which contribute to graded modulation of voltage-dependent gating. These findings show that distinct developmental-, cell- and state-specific regulation of phosphorylation at specific sites confers a diversity of functions on Kv2.1 that is critical to its role as a regulator of intrinsic neuronal excitability.

Published

2007

43. Characterization of the heteromeric potassium channel formed by kv2.1 and the retinal subunit kv8.2 in Xenopus oocytes.

Author

Czirják G, Tóth ZE, and Enyedi P

Subjects

Animals, Cloning, Molecular, Female, In Situ Hybridization, Male, Mice, Mice, Inbred Strains, Mutagenesis, Site-Directed, Potassium Channels, Voltage-Gated genetics, Protein Subunits, RNA genetics, RNA, Messenger genetics, Rats, Reverse Transcriptase Polymerase Chain Reaction, Shab Potassium Channels genetics, Xenopus, Oocytes physiology, Potassium Channels, Voltage-Gated physiology, Retina physiology, Shab Potassium Channels physiology

Abstract

Kv8.2 (KCNV2) subunits do not form homotetrameric potassium channels, although they coassemble with Kv2.1 to constitute functional heteromers. High expression of Kv8.2 was reported in the human retina and its mutations were linked to the visual disorder "cone dystrophy with supernormal rod electroretinogram." We detected abundant Kv8.2 expression in the photoreceptor layer of mouse retina, where Kv2.1 is also known to be present. When the two subunits were coexpressed in Xenopus oocytes in equal amounts, Kv8.2 abolished the current of Kv2.1. If the proportion of Kv8.2 was reduced then the current of heteromeric channels emerged. Kv8.2 shifted the steady-state activation of Kv2.1 to more negative potentials, without affecting the voltage dependence of inactivation. This gave rise to a window current within the -40 to -10 mV membrane potential range. Ba2+ inhibited the heteromeric channel and shifted its activation to more positive potentials. These electrophysiological and pharmacological properties resemble those of the voltage-gated K+ current (named I Kx) described in amphibian retinal rods. Furthermore, oocytes expressing Kv2.1/Kv8.2 developed transient hyperpolarizing overshoots in current-clamp experiments, whereas those expressing only Kv2.1 failed to do so. Similar overshoots are characteristic responses of photoreceptors to light flashes. We demonstrated that Kv8.2 G476D, analogous to a disease-causing human mutation, eliminated Kv2.1 current, if the subunits were coexpressed equally. However, Kv8.2 G476D did not form functional heteromers under any conditions. Therefore we suggest that the custom-tailored current of Kv2.1/Kv8.2 functionally contributes to photoreception, and this is the reason that mutations of Kv8.2 lead to a genetic visual disorder.

Published

2007

44. Modulation of the pancreatic islet beta-cell-delayed rectifier potassium channel Kv2.1 by the polyunsaturated fatty acid arachidonate.

Author

Jacobson DA, Weber CR, Bao S, Turk J, and Philipson LH

Subjects

Animals, Calcium metabolism, Carbachol pharmacology, Cell Line, Humans, Islets of Langerhans metabolism, Mice, Mice, Inbred C57BL, Phospholipases A physiology, Rats, Shab Potassium Channels physiology, Arachidonic Acid pharmacology, Islets of Langerhans drug effects, Shab Potassium Channels drug effects

Abstract

Glucose stimulates both insulin secretion and hydrolysis of arachidonic acid (AA) esterified in membrane phospholipids of pancreatic islet beta-cells, and these processes are amplified by muscarinic agonists. Here we demonstrate that nonesterified AA regulates the biophysical activity of the pancreatic islet beta-cell-delayed rectifier channel, Kv2.1. Recordings of Kv2.1 currents from INS-1 insulinoma cells incubated with AA (5 mum) and subjected to graded degrees of depolarization exhibit a significantly shorter time-to-peak current interval than do control cells. AA causes a rapid decay and reduced peak conductance of delayed rectifier currents from INS-1 cells and from primary beta-cells isolated from mouse, rat, and human pancreatic islets. Stimulating mouse islets with AA results in a significant increase in the frequency of glucose-induced [Ca(2+)] oscillations, which is an expected effect of Kv2.1 channel blockade. Stimulation with concentrations of glucose and carbachol that accelerate hydrolysis of endogenous AA from islet phosphoplipids also results in accelerated Kv2.1 inactivation and a shorter time-to-peak current interval. Group VIA phospholipase A(2) (iPLA(2)beta) hydrolyzes beta-cell membrane phospholipids to release nonesterified fatty acids, including AA, and inhibiting iPLA(2)beta prevents the muscarinic agonist-induced accelerated Kv2.1 inactivation. Furthermore, glucose and carbachol do not significantly affect Kv2.1 inactivation in beta-cells from iPLA(2)beta(-/-) mice. Stably transfected INS-1 cells that overexpress iPLA(2)beta hydrolyze phospholipids more rapidly than control INS-1 cells and also exhibit an increase in the inactivation rate of the delayed rectifier currents. These results suggest that Kv2.1 currents could be dynamically modulated in the pancreatic islet beta-cell by phospholipase-catalyzed hydrolysis of membrane phospholipids to yield non-esterified fatty acids, such as AA, that facilitate Ca(2+) entry and insulin secretion.

Published

2007

45. Proteomic analyses of K(v)2.1 channel phosphorylation sites determining cell background specific differences in function.

Author

Park KS, Mohapatra DP, and Trimmer JS

Subjects

Animals, COS Cells, Calcineurin metabolism, Cell Line, Chlorocebus aethiops, Humans, Isotope Labeling, Kidney cytology, Mass Spectrometry, Patch-Clamp Techniques, Phosphorylation, Potassium metabolism, Rats, Recombinant Proteins metabolism, Shab Potassium Channels genetics, Shab Potassium Channels isolation & purification, Shab Potassium Channels physiology, Proteomics, Shab Potassium Channels analysis, Shab Potassium Channels metabolism

Abstract

The K(v)2.1 potassium channel plays an important role in regulating membrane excitability and is highly phosphorylated in mammalian neurons. Our previous results showed that variable phosphorylation of K(v)2.1 at multiple sites allows graded activity-dependent regulation of channel gating. Our previous studies also found functional differences between recombinant K(v)2.1 channels expressed in HEK293 cells and COS-1 cells that were eliminated upon complete dephosphorylation of K(v)2.1. To better understand how phosphorylation affects K(v)2.1 gating in HEK293 and COS-1 cells we used stable isotope labeling by amino acids in cell culture (SILAC) and mass spectrometry to determine the level of phosphorylation at one newly and thirteen previously identified sites on K(v)2.1 purified from HEK293 and COS-1 cells. We identified seven phosphorylation sites on the K(v)2.1 C-terminus that exhibit different levels of phosphorylation in HEK293 and COS-1 cells. Six sites have enhanced phosphorylation in HEK293 compared to COS-1, while one site exhibits enhanced phosphorylation in COS-1 cells. No sites were found phosphorylated in one cell type and not the other. Interestingly, the sites exhibiting differential phosphorylation in HEK293 and COS-1 cells under basal conditions are similar to the subset targeted by calcineurin-mediated signaling pathways. The data presented here suggests that differential phosphorylation at a specific subset of sites, as opposed to utilization of novel cell-specific phosphorylation sites, can explain differences in the gating properties of K(v)2.1 in different cell types under basal conditions, and in the same cell type under basal versus stimulated conditions.

Published

2007

46. K+ channel facilitation of exocytosis by dynamic interaction with syntaxin.

Author

Singer-Lahat D, Sheinin A, Chikvashvili D, Tsuk S, Greitzer D, Friedrich R, Feinshreiber L, Ashery U, Benveniste M, Levitan ES, and Lotan I

Subjects

Animals, Calcium metabolism, Dose-Response Relationship, Radiation, Electric Stimulation methods, Exocytosis drug effects, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Immunoprecipitation methods, Membrane Potentials genetics, Membrane Potentials radiation effects, Mutagenesis physiology, Neuropeptides metabolism, Oocytes, PC12 Cells, Patch-Clamp Techniques, Potassium Chloride pharmacology, Rats, Secretory Vesicles drug effects, Transfection methods, Xenopus, Exocytosis physiology, Qa-SNARE Proteins metabolism, Secretory Vesicles physiology, Shab Potassium Channels physiology

Abstract

Kv channels inhibit release indirectly by hyperpolarizing membrane potential, but the significance of Kv channel interaction with the secretory apparatus is not known. The Kv2.1 channel is commonly expressed in the soma and dendrites of neurons, where it could influence the release of neuropeptides and neurotrophins, and in neuroendocrine cells, where it could influence hormone release. Here we show that Kv2.1 channels increase dense-core vesicle (DCV)-mediated release after elevation of cytoplasmic Ca2+. This facilitation occurs even after disruption of pore function and cannot be explained by changes in membrane potential and cytoplasmic Ca2+. However, triggering release increases channel binding to syntaxin, a secretory apparatus protein. Disrupting this interaction with competing peptides or by deleting the syntaxin association domain of the channel at the C terminus blocks facilitation of release. Thus, direct association of Kv2.1 with syntaxin promotes exocytosis. The dual functioning of the Kv channel to influence release, through its pore to hyperpolarize the membrane potential and through its C-terminal association with syntaxin to directly facilitate release, reinforces the requirements for repetitive firing for exocytosis of DCVs in neuroendocrine cells and in dendrites.

Published

2007

47. cAMP/protein kinase A signalling pathway protects against neuronal apoptosis and is associated with modulation of Kv2.1 in cerebellar granule cells.

Author

Jiao S, Liu Z, Ren WH, Ding Y, Zhang YQ, Zhang ZH, and Mei YA

Subjects

Animals, Animals, Newborn, Apoptosis drug effects, Cells, Cultured, Colforsin pharmacology, Dose-Response Relationship, Drug, Dose-Response Relationship, Radiation, Drug Interactions, Electric Stimulation, Enzyme Inhibitors pharmacology, Membrane Potentials drug effects, Membrane Potentials physiology, Neurons drug effects, Patch-Clamp Techniques methods, Potassium Chloride pharmacology, RNA, Small Interfering pharmacology, Rats, Reverse Transcriptase Polymerase Chain Reaction methods, Shab Potassium Channels genetics, Transfection methods, Apoptosis physiology, Cerebellum cytology, Cyclic AMP physiology, Cyclic AMP-Dependent Protein Kinases physiology, Neurons physiology, Shab Potassium Channels physiology

Abstract

Previously, we have reported that apoptosis of cerebellar granular neurons induced by incubation in 5 mm K(+) and serum-free medium (LK-S) was associated with an increase in the delayed rectifier K(+) current (I(K)). Here, we show that I(K) associated with apoptotic neurons is mainly encoded by a Kv2.1 subunit. Silencing Kv2.1 expression by small interfering RNA reduces I(K) and increases neuron viability. Forskolin is able to decrease the I(K) amplitude recording from neurons of both the LK-S and control group, and prevents apoptosis of granule cells that are induced by LK-S. Dibutyryl cAMP mimicks the effect of forskolin on the modulation of I(K) and, accordingly, the inhibitor of protein kinase A, H-89, aborts the neuron-protective effect induced by forskolin. Whereas the expression of Kv2.1 was silenced by Kv2.1 small interfering RNA, the inhibition of forskolin on the current amplitude was significantly reduced. Quantitative RT-PCR and whole-cell recording revealed that the expression of Kv2.1 was elevated in the apoptotic neurons, and forskolin significantly depressed the expression of Kv2.1. We conclude that the protection against apoptosis via the protein kinase A pathway is associated with a double modulation on I(K) channel properties and its expression of alpha-subunit that is mainly encoded by the Kv2.1 gene.

Published

2007

48. Effects and mechanism of Chinese tarantula toxins on the Kv2.1 potassium channels.

Author

Yuan C, Yang S, Liao Z, and Liang S

Subjects

Animals, Cells, Cultured, Dose-Response Relationship, Drug, Ion Channel Gating drug effects, Membrane Potentials drug effects, Oocytes drug effects, Xenopus laevis, Ion Channel Gating physiology, Membrane Potentials physiology, Oocytes physiology, Shab Potassium Channels drug effects, Shab Potassium Channels physiology, Spider Venoms administration & dosage

Abstract

Three neurotoxins, Jingzhaotoxin-I, -III, and -V (JZTX-I, -III, and -V), isolated from the venom of the Chinese tarantula Chilobrachys Jingzhao, are 29-36-amino acid peptides. Electrophysiological recordings carried out in Xenopus laevis oocytes show that these toxins acted as gating modifier of voltage-dependent K+ channels. They slow the rate of Kv2.1 channel activation and increase the tail current deactivation, suggesting that toxin-bound channels can still open but are modified. JZTX-III selectively inhibits Kv2.1 channels, and JZTX-V exhibits a higher affinity to Kv4.2 channels than to Kv2.1 channels, whereas JZTX-I inhibits Kv2.1 and Kv4.1 channels with low affinity. Structure-function analysis indicates that electrostatic interactions can benefit for toxin affinity and the feature of electrostatic anisotropy may be correlated with the different affinity of the toxins for the Kv2.1 and Kv4.1 channels. Furthermore, phylogenetic analysis of these and other gating modifiers provides clues for the exploration of toxin-channel interaction.

Published

2007

49. Bidirectional activity-dependent regulation of neuronal ion channel phosphorylation.

Author

Misonou H, Menegola M, Mohapatra DP, Guy LK, Park KS, and Trimmer JS

Subjects

Animals, Cells, Cultured, Ion Channel Gating drug effects, Ion Channels agonists, Kainic Acid pharmacology, Membrane Potentials drug effects, Membrane Potentials physiology, Mice, Mice, Knockout, Neurons drug effects, Neurons physiology, Pentobarbital pharmacology, Phosphorylation drug effects, Rabbits, Rats, Shab Potassium Channels agonists, Shab Potassium Channels physiology, Ion Channel Gating physiology, Ion Channels metabolism, Neurons metabolism

Abstract

Activity-dependent dephosphorylation of neuronal Kv2.1 channels yields hyperpolarizing shifts in their voltage-dependent activation and homoeostatic suppression of neuronal excitability. We recently identified 16 phosphorylation sites that modulate Kv2.1 function. Here, we show that in mammalian neurons, compared with other regulated sites, such as serine (S)563, phosphorylation at S603 is supersensitive to calcineurin-mediated dephosphorylation in response to kainate-induced seizures in vivo, and brief glutamate stimulation of cultured hippocampal neurons. In vitro calcineurin digestion shows that supersensitivity of S603 dephosphorylation is an inherent property of Kv2.1. Conversely, suppression of neuronal activity by anesthetic in vivo causes hyperphosphorylation at S603 but not S563. Distinct regulation of individual phosphorylation sites allows for graded and bidirectional homeostatic regulation of Kv2.1 function. S603 phosphorylation represents a sensitive bidirectional biosensor of neuronal activity.

Published

2006

50. Kv2 channels oppose myogenic constriction of rat cerebral arteries.

Author

Amberg GC and Santana LF

Subjects

Animals, Cells, Cultured, In Vitro Techniques, Male, Rats, Rats, Sprague-Dawley, Cerebral Arteries physiology, Ion Channel Gating physiology, Muscle Contraction physiology, Myocytes, Smooth Muscle physiology, Shab Potassium Channels physiology, Vasoconstriction physiology

Abstract

By hyperpolarizing arterial smooth muscle, voltage-gated, Ca2+-independent K+ (Kv) channels decrease calcium influx and thus oppose constriction. However, the molecular nature of the Kv channels function in arterial smooth muscle remains controversial. Recent investigations have emphasized a predominant role of Kv1 channels in regulating arterial tone. In this study, we tested the hypothesis Kv2 channels may also significantly regulate tone of rat cerebral arteries. We found that Kv2.1 transcript and protein are present in cerebral arterial smooth muscle. In addition, our analysis indicates that a substantial component (approximately 50%) of the voltage dependencies and kinetics of Kv currents in voltage-clamped cerebral arterial myocytes is consistent with Kv2 channels. Accordingly, we found that stromatoxin, a specific inhibitor of Kv2 channels, significantly decreased Kv currents in these cells. Furthermore, stromatoxin enhanced myogenic constriction of pressurized arterial segments. We also found that during angiotensin II-induced hypertension, Kv2 channel function was reduced in isolated myocytes and in intact arteries. This suggests that impaired Kv2 channel activity may contribute to arterial dysfunction during hypertension. On the basis of these novel observations, we propose a new model of Kv channel function in arterial smooth muscle in which Kv2 channels (in combination with Kv1 channels) contribute to membrane hyperpolarization and thus oppose constriction.

Published

2006