Your search keyword '"Shaw Potassium Channels physiology"' showing total 50 results

1. A missense mutation in Kcnc3 causes hippocampal learning deficits in mice.

Author

Xu P, Shimomura K, Lee C, Gao X, Simpson EH, Huang G, Joseph CM, Kumar V, Ge WP, Pawlowski KS, Frye MD, Kourrich S, Kandel ER, and Takahashi JS

Subjects

Action Potentials physiology, Animals, Mice, Mice, Inbred C57BL, Hippocampus physiopathology, Learning Disabilities genetics, Memory, Mutation, Missense, Shaw Potassium Channels genetics, Shaw Potassium Channels physiology

Abstract

Although a wide variety of genetic tools has been developed to study learning and memory, the molecular basis of memory encoding remains incompletely understood. Here, we undertook an unbiased approach to identify novel genes critical for memory encoding. From a large-scale, in vivo mutagenesis screen using contextual fear conditioning, we isolated in mice a mutant, named Clueless , with spatial learning deficits. A causative missense mutation (G434V) was found in the voltage-gated potassium channel, subfamily C member 3 ( Kcnc3) gene in a region that encodes a transmembrane voltage sensor. Generation of a Kcnc3 G434V CRISPR mutant mouse confirmed this mutation as the cause of the learning defects. While G434V had no effect on transcription, translation, or trafficking of the channel, electrophysiological analysis of the G434V mutant channel revealed a complete loss of voltage-gated conductance, a broadening of the action potential, and decreased neuronal firing. Together, our findings have revealed a role for Kcnc3 in learning and memory.

Published

2022

2. Shaw and Shal voltage-gated potassium channels mediate circadian changes in Drosophila clock neuron excitability.

Author

Smith P, Buhl E, Tsaneva-Atanasova K, and Hodge JJL

Subjects

Animals, Circadian Rhythm, Drosophila, Female, Locomotion, Male, Models, Biological, Circadian Clocks physiology, Drosophila Proteins physiology, Neurons physiology, Shal Potassium Channels physiology, Shaw Potassium Channels physiology

Abstract

As in mammals, Drosophila circadian clock neurons display rhythms of activity with higher action potential firing rates and more positive resting membrane potentials during the day. This rhythmic excitability has been widely observed but, critically, its regulation remains unresolved. We have characterized and modelled the changes underlying these electrical activity rhythms in the lateral ventral clock neurons (LNvs). We show that currents mediated by the voltage-gated potassium channels Shaw (Kv3) and Shal (Kv4) oscillate in a circadian manner. Disruption of these channels, by expression of dominant negative (DN) subunits, leads to changes in circadian locomotor activity and shortens lifespan. LNv whole-cell recordings then show that changes in Shaw and Shal currents drive changes in action potential firing rate and that these rhythms are abolished when the circadian molecular clock is stopped. A whole-cell biophysical model using Hodgkin-Huxley equations can recapitulate these changes in electrical activity. Based on this model and by using dynamic clamp to manipulate clock neurons directly, we can rescue the pharmacological block of Shaw and Shal, restore the firing rhythm, and thus demonstrate the critical importance of Shaw and Shal. Together, these findings point to a key role for Shaw and Shal in controlling circadian firing of clock neurons and show that changes in clock neuron currents can account for this. Moreover, with dynamic clamp we can switch the LNvs between morning-like and evening-like states of electrical activity. We conclude that changes in Shaw and Shal underlie the daily oscillation in LNv firing rate., (© 2019 The Authors. The Journal of Physiology © 2019 The Physiological Society.)

Published

2019

3. KCNC1-related disorders: new de novo variants expand the phenotypic spectrum.

Author

Park J, Koko M, Hedrich UBS, Hermann A, Cremer K, Haberlandt E, Grimmel M, Alhaddad B, Beck-Woedl S, Harrer M, Karall D, Kingelhoefer L, Tzschach A, Matthies LC, Strom TM, Ringelstein EB, Sturm M, Engels H, Wolff M, Lerche H, and Haack TB

Subjects

Animals, Ataxia genetics, Child, Codon, Nonsense, Humans, Intellectual Disability genetics, Male, Myoclonic Epilepsies, Progressive, Seizures genetics, Shaw Potassium Channels physiology, Xenopus laevis, Genetic Association Studies, Mutation, Missense, Shaw Potassium Channels genetics

Abstract

A recurrent de novo missense variant in KCNC1, encoding a voltage-gated potassium channel expressed in inhibitory neurons, causes progressive myoclonus epilepsy and ataxia, and a nonsense variant is associated with intellectual disability. We identified three new de novo missense variants in KCNC1 in five unrelated individuals causing different phenotypes featuring either isolated nonprogressive myoclonus (p.Cys208Tyr), intellectual disability (p.Thr399Met), or epilepsy with myoclonic, absence and generalized tonic-clonic seizures, ataxia, and developmental delay (p.Ala421Val, three patients). Functional analyses demonstrated no measurable currents for all identified variants and dominant-negative effects for p.Thr399Met and p.Ala421Val predicting neuronal disinhibition as the underlying disease mechanism., (© 2019 The Authors. Annals of Clinical and Translational Neurology published by Wiley Periodicals, Inc on behalf of American Neurological Association.)

Published

2019

4. Complementary Tuning of Na + and K + Channel Gating Underlies Fast and Energy-Efficient Action Potentials in GABAergic Interneuron Axons.

Author

Hu H, Roth FC, Vandael D, and Jonas P

Subjects

Animals, Energy Metabolism physiology, Female, Hippocampus physiology, Ion Channel Gating physiology, Male, Organ Culture Techniques, Rats, Rats, Wistar, Action Potentials physiology, Axons physiology, GABAergic Neurons physiology, Interneurons physiology, Shaw Potassium Channels physiology, Sodium Channels physiology

Abstract

Fast-spiking, parvalbumin-expressing GABAergic interneurons (PV + -BCs) express a complex machinery of rapid signaling mechanisms, including specialized voltage-gated ion channels to generate brief action potentials (APs). However, short APs are associated with overlapping Na + and K + fluxes and are therefore energetically expensive. How the potentially vicious combination of high AP frequency and inefficient spike generation can be reconciled with limited energy supply is presently unclear. To address this question, we performed direct recordings from the PV + -BC axon, the subcellular structure where active conductances for AP initiation and propagation are located. Surprisingly, the energy required for the AP was, on average, only ∼1.6 times the theoretical minimum. High energy efficiency emerged from the combination of fast inactivation of Na + channels and delayed activation of Kv3-type K + channels, which minimized ion flux overlap during APs. Thus, the complementary tuning of axonal Na + and K + channel gating optimizes both fast signaling properties and metabolic efficiency., (Copyright © 2018 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2018

5. 4-Chloro-3-nitro-N-butylbenzenesulfonamide acts on K V 3.1 channels by an open-channel blocker mechanism.

Author

Bassetto Junior CAZ, Varanda WA, and González ERP

Subjects

Action Potentials physiology, Animals, Cell Line, Dose-Response Relationship, Drug, Fibroblasts, Mice, Patch-Clamp Techniques, Potassium Channel Blockers metabolism, Potassium Channel Blockers pharmacokinetics, Shaw Potassium Channels metabolism, Shaw Potassium Channels physiology, Sulfonamides metabolism, Sulfonamides pharmacokinetics, Potassium Channel Blockers pharmacology, Shaw Potassium Channels drug effects, Sulfonamides pharmacology

Abstract

The effects of 4-chloro-3-nitro-N-butylbenzenesulfonamide (SMD2) on K V 3.1 channels, heterologous expressed in L-929 cells, were studied with the whole cell patch-clamp technique. SMD2 blocks K V 3.1 in a reversible and use-dependent manner, with IC 50 around 10 µM, and a Hill coefficient around 2. Although the conductance vs. voltage relationship in control condition can be described by a single Boltzmann function, two terms are necessary to describe the data in the presence of SMD2. The activation and deactivation time constants are weakly voltage dependent both for control and in the presence of SMD2. SMD2 does not change the channel selectivity and tail currents show a typical crossover phenomenon. The time course of inactivation has a fast and a slow component, and SMD2 significantly decreased their values. Steady-state inactivation is best described by a Boltzmann equation with V 1/2 (the voltage where the probability to find the channels in the inactivated state is 50%) and K (slope factor) equals to -22.9 ± 1.5 mV and 5.3 ± 0.9 mV for control, and -30.3 ± 1.3 mV and 6 ± 0.8 mV for SMD2, respectively. The action of SMD2 is enhanced by high frequency stimulation, and by the time the channel stays open. Taken together, our results suggest that SMD2 blocks the open conformation of K V 3.1. From a pharmacological and therapeutic point of view, N-alkylsulfonamides may constitute a new class of pharmacological modulators of K V 3.1.

Published

2017

6. Action Potential Broadening in Capsaicin-Sensitive DRG Neurons from Frequency-Dependent Reduction of Kv3 Current.

Author

Liu PW, Blair NT, and Bean BP

Subjects

Action Potentials drug effects, Animals, Female, Ganglia, Spinal drug effects, Male, Neurons drug effects, Potassium Channel Blockers pharmacology, Rats, Rats, Long-Evans, Shaw Potassium Channels antagonists & inhibitors, Action Potentials physiology, Capsaicin pharmacology, Ganglia, Spinal physiology, Neurons physiology, Shaw Potassium Channels physiology

Abstract

Action potential (AP) shape is a key determinant of cellular electrophysiological behavior. We found that in small-diameter, capsaicin-sensitive dorsal root ganglia neurons corresponding to nociceptors (from rats of either sex), stimulation at frequencies as low as 1 Hz produced progressive broadening of the APs. Stimulation at 10 Hz for 3 s resulted in an increase in AP width by an average of 76 ± 7% at 22°C and by 38 ± 3% at 35°C. AP clamp experiments showed that spike broadening results from frequency-dependent reduction of potassium current during spike repolarization. The major current responsible for frequency-dependent reduction of overall spike-repolarizing potassium current was identified as Kv3 current by its sensitivity to low concentrations of 4-aminopyridine (IC 50 <100 μm) and block by the peptide inhibitor blood depressing substance I (BDS-I). There was a small component of Kv1-mediated current during AP repolarization, but this current did not show frequency-dependent reduction. In a small fraction of cells, there was a component of calcium-dependent potassium current that showed frequency-dependent reduction, but the contribution to overall potassium current reduction was almost always much smaller than that of Kv3-mediated current. These results show that Kv3 channels make a major contribution to spike repolarization in small-diameter DRG neurons and undergo frequency-dependent reduction, leading to spike broadening at moderate firing frequencies. Spike broadening from frequency-dependent reduction in Kv3 current could mitigate the frequency-dependent decreases in conduction velocity typical of C-fiber axons. SIGNIFICANCE STATEMENT Small-diameter dorsal root ganglia (DRG) neurons mediating nociception and other sensory modalities express many types of potassium channels, but how they combine to control firing patterns and conduction is not well understood. We found that action potentials of small-diameter rat DRG neurons showed spike broadening at frequencies as low as 1 Hz and that spike broadening resulted predominantly from frequency-dependent inactivation of Kv3 channels. Spike width helps to control transmitter release, conduction velocity, and firing patterns and understanding the role of particular potassium channels can help to guide new pharmacological strategies for targeting pain-sensing neurons selectively., (Copyright © 2017 the authors 0270-6474/17/379705-10$15.00/0.)

Published

2017

7. The expression and activity of K V 3.4 channel subunits are precociously upregulated in astrocytes exposed to Aβ oligomers and in astrocytes of Alzheimer's disease Tg2576 mice.

Author

Boscia F, Pannaccione A, Ciccone R, Casamassa A, Franco C, Piccialli I, de Rosa V, Vinciguerra A, Di Renzo G, and Annunziato L

Subjects

Amyloid beta-Peptides metabolism, Animals, Brain metabolism, Cells, Cultured, Disease Models, Animal, Glial Fibrillary Acidic Protein metabolism, Male, Mice, Mice, Inbred C57BL, Mice, Transgenic, Peptide Fragments adverse effects, Peptide Fragments metabolism, Rats, Wistar, Shaw Potassium Channels physiology, Alzheimer Disease genetics, Alzheimer Disease metabolism, Amyloid beta-Peptides adverse effects, Astrocytes drug effects, Astrocytes metabolism, Gene Expression, Shaw Potassium Channels genetics, Shaw Potassium Channels metabolism, Up-Regulation drug effects

Abstract

Astrocyte dysfunction emerges early in Alzheimer's disease (AD) and may contribute to its pathology and progression. Recently, the voltage gated potassium channel K V 3.4 subunit, which underlies the fast-inactivating K + currents, has been recognized to be relevant for AD pathogenesis and is emerging as a new target candidate for AD. In the present study, we investigated both in in vitro and in vivo models of AD the expression and functional activity of K V 3.4 potassium channel subunits in astrocytes. In primary astrocytes our biochemical, immunohistochemical, and electrophysiological studies demonstrated a time-dependent upregulation of K V 3.4 expression and functional activity after exposure to amyloid-β (Aβ) oligomers. Consistently, astrocytic K V 3.4 expression was upregulated in the cerebral cortex, hippocampus, and cerebellum of 6-month-old Tg2576 mice. Further, confocal triple labeling studies revealed that in 6-month-old Tg2576 mice, K V 3.4 was intensely coexpressed with Aβ in nonplaque associated astrocytes. Interestingly, in the cortical and hippocampal regions of 12-month-old Tg2576 mice, plaque-associated astrocytes much more intensely expressed K V 3.4 subunits, but not Aβ. More important, we evidenced that the selective knockdown of K V 3.4 expression significantly downregulated both glial fibrillary acidic protein levels and Aβ trimers in the brain of 6-month-old Tg2576 mice. Collectively, our results demonstrate that the expression and function of K V 3.4 channel subunits are precociously upregulated in cultured astrocytes exposed to Aβ oligomers and in reactive astrocytes of AD Tg2576 mice., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

8. Kv3.3 potassium channels and spinocerebellar ataxia.

Author

Zhang Y and Kaczmarek LK

Subjects

Animals, Humans, Shaw Potassium Channels genetics, Spinocerebellar Ataxias genetics, Spinocerebellar Ataxias physiopathology, Shaw Potassium Channels physiology, Spinocerebellar Ataxias congenital

Abstract

The voltage-dependent potassium channel subunit Kv3.3 is expressed at high levels in cerebellar Purkinje cells, in auditory brainstem nuclei and in many other neurons capable of firing at high rates. In the cerebellum, it helps to shape the very characteristic complex spike of Purkinje cells. Kv3.3 differs from other closely related channels in that human mutations in the gene encoding Kv3.3 (KCNC3) result in a unique neurodegenerative disease termed spinocerebellar ataxia type 13 (SCA13). This primarily affects the cerebellum, but also results in extracerebellar symptoms. Different mutations produce either early onset SCA13, associated with delayed motor and impaired cognitive skill acquisition, or late onset SCA13, which typically produces cerebellar degeneration in middle age. This review covers the localization and physiological function of Kv3.3 in the central nervous system and how the normal function of the channel is altered by the disease-causing mutations. It also describes experimental approaches that are being used to understand how Kv3.3 mutations are linked to neuronal survival, and to develop strategies for treatment., (© 2015 The Authors. The Journal of Physiology © 2015 The Physiological Society.)

Published

2016

9. KV1 and KV3 Potassium Channels Identified at Presynaptic Terminals of the Corticostriatal Synapses in Rat.

Author

Meneses D, Vega AV, Torres-Cruz FM, and Barral J

Subjects

Action Potentials drug effects, Action Potentials physiology, Animals, Cerebral Cortex drug effects, Corpus Striatum drug effects, Male, Potassium Channel Blockers pharmacology, Presynaptic Terminals drug effects, Protein Isoforms antagonists & inhibitors, Protein Isoforms physiology, Rats, Rats, Wistar, Shaker Superfamily of Potassium Channels antagonists & inhibitors, Shaw Potassium Channels antagonists & inhibitors, Synapses drug effects, Cerebral Cortex physiology, Corpus Striatum physiology, Presynaptic Terminals physiology, Shaker Superfamily of Potassium Channels physiology, Shaw Potassium Channels physiology, Synapses physiology

Abstract

In the last years it has been increasingly clear that KV-channel activity modulates neurotransmitter release. The subcellular localization and composition of potassium channels are crucial to understanding its influence on neurotransmitter release. To investigate the role of KV in corticostriatal synapses modulation, we combined extracellular recording of population-spike and pharmacological blockage with specific and nonspecific blockers to identify several families of KV channels. We induced paired-pulse facilitation (PPF) and studied the changes in paired-pulse ratio (PPR) before and after the addition of specific KV blockers to determine whether particular KV subtypes were located pre- or postsynaptically. Initially, the presence of KV channels was tested by exposing brain slices to tetraethylammonium or 4-aminopyridine; in both cases we observed a decrease in PPR that was dose dependent. Further experiments with tityustoxin, margatoxin, hongotoxin, agitoxin, dendrotoxin, and BDS-I toxins all rendered a reduction in PPR. In contrast heteropodatoxin and phrixotoxin had no effect. Our results reveal that corticostriatal presynaptic KV channels have a complex stoichiometry, including heterologous combinations KV1.1, KV1.2, KV1.3, and KV1.6 isoforms, as well as KV3.4, but not KV4 channels. The variety of KV channels offers a wide spectrum of possibilities to regulate neurotransmitter release, providing fine-tuning mechanisms to modulate synaptic strength.

Published

2016

10. Biophysical characterization of KV3.1 potassium channel activating compounds.

Author

Taskin B, von Schoubye NL, Sheykhzade M, Bastlund JF, Grunnet M, and Jespersen T

Subjects

Action Potentials drug effects, Action Potentials physiology, Dose-Response Relationship, Drug, HEK293 Cells, Humans, Hydantoins pharmacology, Kinetics, Pyridines pharmacology, Shaw Potassium Channels physiology, Shaw Potassium Channels agonists

Abstract

The effect of two positive modulators, RE1 and EX15, on the voltage-gated K(+) channel Kv3.1 was investigated using the whole-cell patch-clamp technique on HEK293 cells expressing Kv3.1a. RE1 and EX15 increased the Kv3.1 currents in a concentration-dependent manner with an EC50 value of 4.5 and 1.3µM, respectively. However, high compound concentrations caused an inhibition of the Kv3.1 current. The compound-induced activation of Kv3.1 channels showed a profound hyperpolarized shift in activation kinetics. 30µM RE1 shifted V1/2 from 5.63±0.31mV to -9.71±1.00mV and 10µM EX15 induced a shift from 10.77±0.32mV to -15.11±1.57mV. The activation time constant (Tauact) was reduced for both RE1 and EX15, with RE1 being the fastest activator. The deactivation time constant (Taudeact) was also markedly reduced for both RE1 and EX15, with EX15 inducing the most prominent effect. Furthermore, subjected to depolarizing pulses at 30Hz, both compounds were showing a use-dependent effect resulting in a reduction of the compound-mediated effect. However, during these conditions, RE1- and EX15-modified current amplitudes still exceeded the control condition amplitudes by up to 200%. In summary, the present study introduces the first detailed biophysical characterization of two new Kv3.1 channel modifying compounds with different modulating properties., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2015

11. A recurrent de novo mutation in KCNC1 causes progressive myoclonus epilepsy.

Author

Muona M, Berkovic SF, Dibbens LM, Oliver KL, Maljevic S, Bayly MA, Joensuu T, Canafoglia L, Franceschetti S, Michelucci R, Markkinen S, Heron SE, Hildebrand MS, Andermann E, Andermann F, Gambardella A, Tinuper P, Licchetta L, Scheffer IE, Criscuolo C, Filla A, Ferlazzo E, Ahmad J, Ahmad A, Baykan B, Said E, Topcu M, Riguzzi P, King MD, Ozkara C, Andrade DM, Engelsen BA, Crespel A, Lindenau M, Lohmann E, Saletti V, Massano J, Privitera M, Espay AJ, Kauffmann B, Duchowny M, Møller RS, Straussberg R, Afawi Z, Ben-Zeev B, Samocha KE, Daly MJ, Petrou S, Lerche H, Palotie A, and Lehesjoki AE

Subjects

Amino Acid Sequence, Amino Acid Substitution, Animals, Base Sequence, Carrier Proteins genetics, Conserved Sequence, Exome, Female, GTPase-Activating Proteins, Genes, Dominant, Heat-Shock Proteins genetics, Humans, Male, Membrane Proteins, Molecular Sequence Data, Nerve Tissue Proteins, Pedigree, Prion Proteins, Prions genetics, Protein Conformation, Sequence Alignment, Sequence Homology, Amino Acid, Shaw Potassium Channels physiology, Species Specificity, Mutation, Missense, Myoclonic Epilepsies, Progressive genetics, Point Mutation, Shaw Potassium Channels genetics

Abstract

Progressive myoclonus epilepsies (PMEs) are a group of rare, inherited disorders manifesting with action myoclonus, tonic-clonic seizures and ataxia. We sequenced the exomes of 84 unrelated individuals with PME of unknown cause and molecularly solved 26 cases (31%). Remarkably, a recurrent de novo mutation, c.959G>A (p.Arg320His), in KCNC1 was identified as a new major cause for PME. Eleven unrelated exome-sequenced (13%) and two affected individuals in a secondary cohort (7%) had this mutation. KCNC1 encodes KV3.1, a subunit of the KV3 voltage-gated potassium ion channels, which are major determinants of high-frequency neuronal firing. Functional analysis of the Arg320His mutant channel showed a dominant-negative loss-of-function effect. Ten cases had pathogenic mutations in known PME-associated genes (NEU1, NHLRC1, AFG3L2, EPM2A, CLN6 and SERPINI1). Identification of mutations in PRNP, SACS and TBC1D24 expand their phenotypic spectra to PME. These findings provide insights into the molecular genetic basis of PME and show the role of de novo mutations in this disease entity.

Published

2015

12. Kv3.4 channel function and dysfunction in nociceptors.

Author

Ritter DM, Zemel BM, Lepore AC, and Covarrubias M

Subjects

Action Potentials genetics, Action Potentials physiology, Animals, Cells, Cultured, Female, Ganglia, Spinal cytology, Ganglia, Spinal metabolism, Gene Expression, Male, Neurons metabolism, Nociceptors metabolism, Patch-Clamp Techniques, RNA Interference, Rats, Sprague-Dawley, Reverse Transcriptase Polymerase Chain Reaction, Shaw Potassium Channels genetics, Ganglia, Spinal physiology, Neurons physiology, Nociceptors physiology, Shaw Potassium Channels physiology

Abstract

Recently, we reported the isolation of the Kv3.4 current in dorsal root ganglion (DRG) neurons and described dysregulation of this current in a spinal cord injury (SCI) model of chronic pain. These studies strongly suggest that rat Kv3.4 channels are major regulators of excitability in DRG neurons from pups and adult females, where they help determine action potential (AP) repolarization and spiking properties. Here, we characterized the Kv3.4 current in rat DRG neurons from adult males and show that it transfers 40-70% of the total repolarizing charge during the AP across all ages and sexes. Following SCI, we also found remodeling of the repolarizing currents during the AP. In the light of these studies, homomeric Kv3.4 channels expressed in DRG nociceptors are emerging novel targets that may help develop new approaches to treat neuropathic pain.

Published

2015

13. Distinct Kv channel subtypes contribute to differences in spike signaling properties in the axon initial segment and presynaptic boutons of cerebellar interneurons.

Author

Rowan MJ, Tranquil E, and Christie JM

Subjects

Animals, Cerebellum cytology, Electrophysiological Phenomena, Female, Fluorescent Dyes, Immunohistochemistry, Male, Mice, Mice, Inbred C57BL, Microscopy, Fluorescence, Patch-Clamp Techniques, Receptors, AMPA physiology, Receptors, GABA-A physiology, Receptors, N-Methyl-D-Aspartate physiology, Shaker Superfamily of Potassium Channels physiology, Shaw Potassium Channels physiology, Synaptic Transmission physiology, Axons physiology, Cerebellum physiology, Interneurons physiology, Potassium Channels physiology, Presynaptic Terminals physiology, Receptors, Presynaptic physiology

Abstract

The discrete arrangement of voltage-gated K(+) (Kv) channels in axons may impart functional advantages in action potential (AP) signaling yet, in compact cell types, the organization of Kv channels is poorly understood. We find that in cerebellar stellate cell interneurons of mice, the composition and influence of Kv channels populating the axon is diverse and depends on location allowing axonal compartments to differentially control APs in a local manner. Kv1 channels determine AP repolarization at the spike initiation site but not at more distal sites, limiting the expression of use-dependent spike broadening to the most proximal axon region, likely a key attribute informing spiking phenotype. Local control of AP repolarization at presynaptic boutons depends on Kv3 channels keeping APs brief, thus limiting Ca(2+) influx and synaptic strength. These observations suggest that AP repolarization is tuned by the local influence of distinct Kv channel types, and this organization enhances the functional segregation of axonal compartments.

Published

2014

14. Src regulates membrane trafficking of the Kv3.1b channel.

Author

Bae SH, Kim DH, Shin SK, Choi JS, and Park KS

Subjects

Animals, Blotting, Western, COS Cells, Cell Membrane physiology, Chlorocebus aethiops, HEK293 Cells, Humans, Membrane Potentials physiology, Mice, Mutagenesis, Site-Directed, Nerve Tissue Proteins genetics, Nerve Tissue Proteins physiology, Patch-Clamp Techniques, Protein Transport, Proto-Oncogene Proteins pp60(c-src) genetics, Rats, Shaw Potassium Channels genetics, Shaw Potassium Channels physiology, Cell Membrane metabolism, Endoplasmic Reticulum metabolism, Nerve Tissue Proteins metabolism, Proto-Oncogene Proteins pp60(c-src) metabolism, Shaw Potassium Channels metabolism

Abstract

The Kv3.1 channel plays a crucial role in regulating the high-frequency firing properties of neurons. Here, we determined whether Src regulates the subcellular distributions of the Kv3.1b channel. Co-expression of active Src induced a dramatic redistribution of Kv3.1b to the endoplasmic reticulum. Furthermore, co-expression of the Kv3.1b channel with active Src induced a remarkable decrease in the pool of Kv3.1b at the cell surface. Moreover, the co-expression of active Src results in a significant decrease in the peak current densities of the Kv3.1b channel, and a substantial alteration in the voltage dependence of its steady-state inactivation. Taken together, these results indicate that Src kinase may play an important role in regulating membrane trafficking of Kv3.1b channels., (Copyright © 2013 Federation of European Biochemical Societies. Published by Elsevier B.V. All rights reserved.)

Published

2014

15. Native gating behavior of ion channels in neurons with null-deviation modeling.

Author

Wang W, Luo J, Hou P, Yang Y, Xiao F, Yuchi M, Qu A, Wang L, and Ding J

Subjects

Action Potentials physiology, Algorithms, Animals, CHO Cells, Computer Simulation, Cricetinae, Cricetulus, HEK293 Cells, Humans, Ion Channels metabolism, Membrane Potentials physiology, Neurons metabolism, Patch-Clamp Techniques, Shaw Potassium Channels metabolism, Shaw Potassium Channels physiology, Ion Channel Gating physiology, Ion Channels physiology, Models, Neurological, Neurons physiology

Abstract

Computational modeling has emerged as an indispensable approach to resolve and predict the intricate interplay among the many ion channels underlying neuronal excitability. However, simulation results using the classic formula-based Hodgkin-Huxley (H-H) model or the superior Markov kinetic model of ion channels often deviate significantly from native cellular signals despite using carefully measured parameters. Here we found that the filters of patch-clamp amplifier not only delayed the signals, but also introduced ringing, and that the residual series resistance in experiments altered the command voltages, which had never been fully eliminated by improving the amplifier itself. To remove all the above errors, a virtual device with the parameters exactly same to that of amplifier was introduced into Markov kinetic modeling so as to establish a null-deviation model. We demonstrate that our novel null-deviation approach fully restores the native gating-kinetics of ion-channels with the data recorded at any condition, and predicts spike waveform and firing patterns clearly distinctive from those without correction.

Published

2013

16. Mutation in the kv3.3 voltage-gated potassium channel causing spinocerebellar ataxia 13 disrupts sound-localization mechanisms.

Author

Middlebrooks JC, Nick HS, Subramony SH, Advincula J, Rosales RL, Lee LV, Ashizawa T, and Waters MF

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Auditory Threshold, Child, Cues, Female, Genes, Dominant, Hearing genetics, Hearing physiology, Humans, Male, Middle Aged, Shaw Potassium Channels physiology, Signal Transduction physiology, Spinocerebellar Ataxias congenital, Spinocerebellar Degenerations physiopathology, Young Adult, Mutation, Shaw Potassium Channels genetics, Signal Transduction genetics, Sound Localization, Spinocerebellar Degenerations genetics

Abstract

Normal sound localization requires precise comparisons of sound timing and pressure levels between the two ears. The primary localization cues are interaural time differences, ITD, and interaural level differences, ILD. Voltage-gated potassium channels, including Kv3.3, are highly expressed in the auditory brainstem and are thought to underlie the exquisite temporal precision and rapid spike rates that characterize brainstem binaural pathways. An autosomal dominant mutation in the gene encoding Kv3.3 has been demonstrated in a large Filipino kindred manifesting as spinocerebellar ataxia type 13 (SCA13). This kindred provides a rare opportunity to test in vivo the importance of a specific channel subunit for human hearing. Here, we demonstrate psychophysically that individuals with the mutant allele exhibit profound deficits in both ITD and ILD sensitivity, despite showing no obvious impairment in pure-tone sensitivity with either ear. Surprisingly, several individuals exhibited the auditory deficits even though they were pre-symptomatic for SCA13. We would expect that impairments of binaural processing as great as those observed in this family would result in prominent deficits in localization of sound sources and in loss of the "spatial release from masking" that aids in understanding speech in the presence of competing sounds.

Published

2013

17. Vasoactive intestinal peptide produces long-lasting changes in neural activity in the suprachiasmatic nucleus.

Author

Kudo T, Tahara Y, Gamble KL, McMahon DG, Block GD, and Colwell CS

Subjects

Animals, Cyclic AMP-Dependent Protein Kinase Catalytic Subunits physiology, Guanine Nucleotide Exchange Factors physiology, In Vitro Techniques, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Neurons drug effects, Period Circadian Proteins metabolism, Shaw Potassium Channels genetics, Shaw Potassium Channels physiology, Signal Transduction, Suprachiasmatic Nucleus drug effects, Neurons physiology, Suprachiasmatic Nucleus physiology, Vasoactive Intestinal Peptide pharmacology

Abstract

The neuropeptide vasoactive intestinal peptide (VIP) is expressed at high levels in the neurons of the suprachiasmatic nucleus (SCN). While VIP is known to be important to the input and output pathways from the SCN, the physiological effects of VIP on electrical activity of SCN neurons are not well known. Here the impact of VIP on firing rate of SCN neurons was investigated in mouse slice cultures recorded during the night. The application of VIP produced an increase in electrical activity in SCN slices that lasted several hours after treatment. This is a novel mechanism by which this peptide can produce long-term changes in central nervous system physiology. The increase in action potential frequency was blocked by a VIP receptor antagonist and lost in a VIP receptor knockout mouse. In addition, inhibitors of both the Epac family of cAMP binding proteins and cAMP-dependent protein kinase (PKA) blocked the induction by VIP. The persistent increase in spike rate following VIP application was not seen in SCN neurons from mice deficient in Kv3 channel proteins and was dependent on the clock protein PER1. These findings suggest that VIP regulates the long-term firing rate of SCN neurons through a VIPR2-mediated increase in the cAMP pathway and implicate the fast delayed rectifier (FDR) potassium currents as one of the targets of this regulation.

Published

2013

18. Kv3 channel assembly, trafficking and activity are regulated by zinc through different binding sites.

Author

Gu Y, Barry J, and Gu C

Subjects

Animals, Binding Sites, Cells, Cultured, Cerebellum cytology, Cerebellum embryology, Embryo, Mammalian, HEK293 Cells, Hippocampus cytology, Hippocampus embryology, Humans, Protein Transport, Rats, Neurons physiology, Shaw Potassium Channels physiology, Zinc pharmacology

Abstract

Zinc, a divalent heavy metal ion and an essential mineral for life, regulates synaptic transmission and neuronal excitability via ion channels. However, its binding sites and regulatory mechanisms are poorly understood. Here, we report that Kv3 channel assembly, localization and activity are regulated by zinc through different binding sites. Local perfusion of zinc reversibly reduced spiking frequency of cultured neurons most likely by suppressing Kv3 channels. Indeed, zinc inhibited Kv3.1 channel activity and slowed activation kinetics, independent of its site in the N-terminal T1 domain. Biochemical assays surprisingly identified a novel zinc-binding site in the Kv3.1 C-terminus, critical for channel activity and axonal targeting, but not for the zinc inhibition. Finally, mutagenesis revealed an important role of the junction between the first transmembrane (TM) segment and the first extracellular loop in sensing zinc. Its mutant enabled fast spiking with relative resistance to the zinc inhibition. Therefore, our studies provide novel mechanistic insights into the multifaceted regulation of Kv3 channel activity and localization by divalent heavy metal ions.

Published

2013

19. Kv3.1 channels stimulate adult neural precursor cell proliferation and neuronal differentiation.

Author

Yasuda T, Cuny H, and Adams DJ

Subjects

Adult Stem Cells physiology, Animals, Apoptosis, Cell Differentiation, Cell Proliferation, Cells, Cultured, Gene Knockdown Techniques, Mice, Mice, Transgenic, Neural Stem Cells physiology, RNA, Messenger metabolism, RNA, Small Interfering genetics, Adult Stem Cells cytology, Neural Stem Cells cytology, Shaw Potassium Channels physiology

Abstract

Adult neural stem/precursor cells (NPCs) play a pivotal role in neuronal plasticity throughout life. Among ion channels identified in adult NPCs, voltage-gated delayed rectifier K(+) (KDR) channels are dominantly expressed. However, the KDR channel subtype and its physiological role are still undefined. We used real-time quantitative RT-PCR and gene knockdown techniques to identify a major functional KDR channel subtype in adult NPCs. Dominant mRNA expression of Kv3.1, a high voltage-gated KDR channel, was quantitatively confirmed. Kv3.1 gene knockdown with specific small interfering RNAs (siRNA) for Kv3.1 significantly inhibited Kv3.1 mRNA expression by 63.9% (P < 0.001) and KDR channel currents by 52.2% (P < 0.001). This indicates that Kv3.1 is the subtype responsible for producing KDR channel outward currents. Resting membrane properties, such as resting membrane potential, of NPCs were not affected by Kv3.1 expression. Kv3.1 knockdown with 300 nm siRNA inhibited NPC growth (increase in cell numbers) by 52.9% (P < 0.01). This inhibition was attributed to decreased cell proliferation, not increased cell apoptosis. We also established a convenient in vitro imaging assay system to evaluate NPC differentiation using NPCs from doublecortin-green fluorescent protein transgenic mice. Kv3.1 knockdown also significantly reduced neuronal differentiation by 31.4% (P < 0.01). We have demonstrated that Kv3.1 is a dominant functional KDR channel subtype expressed in adult NPCs and plays key roles in NPC proliferation and neuronal lineage commitment during differentiation.

Published

2013

20. Modeling-independent elucidation of inactivation pathways in recombinant and native A-type Kv channels.

Author

Fineberg JD, Ritter DM, and Covarrubias M

Subjects

Animals, Kinetics, Male, Membrane Potentials, Neurons physiology, Protein Subunits genetics, Rats, Rats, Sprague-Dawley, Recombinant Proteins genetics, Recombinant Proteins metabolism, Shal Potassium Channels genetics, Shaw Potassium Channels genetics, Xenopus, Ion Channel Gating, Protein Subunits physiology, Shal Potassium Channels physiology, Shaw Potassium Channels physiology

Abstract

A-type voltage-gated K(+) (Kv) channels self-regulate their activity by inactivating directly from the open state (open-state inactivation [OSI]) or by inactivating before they open (closed-state inactivation [CSI]). To determine the inactivation pathways, it is often necessary to apply several pulse protocols, pore blockers, single-channel recording, and kinetic modeling. However, intrinsic hurdles may preclude the standardized application of these methods. Here, we implemented a simple method inspired by earlier studies of Na(+) channels to analyze macroscopic inactivation and conclusively deduce the pathways of inactivation of recombinant and native A-type Kv channels. We investigated two distinct A-type Kv channels expressed heterologously (Kv3.4 and Kv4.2 with accessory subunits) and their native counterparts in dorsal root ganglion and cerebellar granule neurons. This approach applies two conventional pulse protocols to examine inactivation induced by (a) a simple step (single-pulse inactivation) and (b) a conditioning step (double-pulse inactivation). Consistent with OSI, the rate of Kv3.4 inactivation (i.e., the negative first derivative of double-pulse inactivation) precisely superimposes on the profile of the Kv3.4 current evoked by a single pulse because the channels must open to inactivate. In contrast, the rate of Kv4.2 inactivation is asynchronous, already changing at earlier times relative to the profile of the Kv4.2 current evoked by a single pulse. Thus, Kv4.2 inactivation occurs uncoupled from channel opening, indicating CSI. Furthermore, the inactivation time constant versus voltage relation of Kv3.4 decreases monotonically with depolarization and levels off, whereas that of Kv4.2 exhibits a J-shape profile. We also manipulated the inactivation phenotype by changing the subunit composition and show how CSI and CSI combined with OSI might affect spiking properties in a full computational model of the hippocampal CA1 neuron. This work unambiguously elucidates contrasting inactivation pathways in neuronal A-type Kv channels and demonstrates how distinct pathways might impact neurophysiological activity.

Published

2012

21. NOX2 (gp91phox) is a predominant O2 sensor in a human airway chemoreceptor cell line: biochemical, molecular, and electrophysiological evidence.

Author

Buttigieg J, Pan J, Yeger H, and Cutz E

Subjects

Cell Line, Tumor, Down-Regulation, Humans, Membrane Glycoproteins chemistry, NADPH Oxidase 2, NADPH Oxidase 4, NADPH Oxidases chemistry, Nerve Tissue Proteins chemistry, Nerve Tissue Proteins physiology, Potassium Channels, Tandem Pore Domain chemistry, Potassium Channels, Tandem Pore Domain physiology, Serotonin metabolism, Shal Potassium Channels chemistry, Shal Potassium Channels physiology, Shaw Potassium Channels chemistry, Shaw Potassium Channels physiology, Chemoreceptor Cells physiology, Membrane Glycoproteins physiology, NADPH Oxidases physiology, Neuroepithelial Bodies physiology, Oxygen physiology

Abstract

Pulmonary neuroepithelial bodies (NEBs), composed of clusters of amine [serotonin (5-HT)] and peptide-producing cells, are widely distributed within the airway mucosa of human and animal lungs. NEBs are thought to function as airway O(2)-sensors, since they are extensively innervated and release 5-HT upon hypoxia exposure. The small cell lung carcinoma cell line (H146) provides a useful model for native NEBs, since they contain (and secrete) 5-HT and share the expression of a membrane-delimited O(2) sensor [classical NADPH oxidase (NOX2) coupled to an O(2)-sensitive K(+) channel]. In addition, both native NEBs and H146 cells express different NADPH oxidase homologs (NOX1, NOX4) and its subunits together with a variety of O(2)-sensitive voltage-dependent K(+) channel proteins (K(v)) and tandem pore acid-sensing K(+) channels (TASK). Here we used H146 cells to investigate the role and interactions of various NADPH oxidase components in O(2)-sensing using a combination of coimmunoprecipitation, Western blot analysis (quantum dot labeling), and electrophysiology (patchclamp, amperometry) methods. Coimmunoprecipitation studies demonstrated formation of molecular complexes between NOX2 and K(v)3.3 and K(v)4.3 ion channels but not with TASK1 ion channels, while NOX4 associated with TASK1 but not with K(v) channel proteins. Downregulation of mRNA for NOX2, but not for NOX4, suppressed hypoxia-sensitive outward current and significantly reduced hypoxia -induced 5-HT release. Collectively, our studies suggest that NOX2/K(v) complexes are the predominant O(2) sensor in H146 cells and, by inference, in native NEBs. Present findings favor a NEB cell-specific plasma membrane model of O(2)-sensing and suggest that unique NOX/K(+) channel combinations may serve diverse physiological functions.

Published

2012

22. Kv3 channels contribute to the delayed rectifier current in small cultured mouse dorsal root ganglion neurons.

Author

Bocksteins E, Van de Vijver G, Van Bogaert PP, and Snyders DJ

Subjects

Animals, Cells, Cultured, Gene Expression Regulation drug effects, Gene Expression Regulation physiology, Ion Channel Gating drug effects, Ion Channel Gating physiology, Membrane Potentials, Mice, Neurons drug effects, Potassium Channel Blockers pharmacology, Protein Subunits, RNA, Messenger genetics, RNA, Messenger metabolism, Tetraethylammonium, Ganglia, Spinal cytology, Neurons physiology, Shaw Potassium Channels physiology

Abstract

Delayed rectifier voltage-gated K(+) (K(V)) channels are important determinants of neuronal excitability. However, the large number of K(V) subunits poses a major challenge to establish the molecular composition of the native neuronal K(+) currents. A large part (∼60%) of the delayed rectifier current (I(K)) in small mouse dorsal root ganglion (DRG) neurons has been shown to be carried by both homotetrameric K(V)2.1 and heterotetrameric channels of K(V)2 subunits with silent K(V) subunits (K(V)S), while a contribution of K(V)1 channels has also been demonstrated. Because K(V)3 subunits also generate delayed rectifier currents, we investigated the contribution of K(V)3 subunits to I(K) in small mouse DRG neurons. After stromatoxin (ScTx) pretreatment to block the K(V)2-containing component, application of 1 mM TEA caused significant additional block, indicating that the ScTx-insensitive part of I(K) could include K(V)1, K(V)3, and/or M-current channels (KCNQ2/3). Combining ScTx and dendrotoxin confirmed a relevant contribution of K(V)2 and K(V)2/K(V)S, and K(V)1 subunits to I(K) in small mouse DRG neurons. After application of these toxins, a significant TEA-sensitive current (∼19% of total I(K)) remained with biophysical properties that corresponded to those of K(V)3 currents obtained in expression systems. Using RT-PCR, we detected K(V)3.1-3 mRNA in DRG neurons. Furthermore, Western blot and immunocytochemistry using K(V)3.1-specific antibodies confirmed the presence of K(V)3.1 in cultured DRG neurons. These biophysical, pharmacological, and molecular results demonstrate a relevant contribution (∼19%) of K(V)3-containing channels to I(K) in small mouse DRG neurons, supporting a substantial role for K(V)3 subunits in these neurons.

Published

2012

23. Altered Kv3.3 channel gating in early-onset spinocerebellar ataxia type 13.

Author

Minassian NA, Lin MC, and Papazian DM

Subjects

Animals, Humans, In Vitro Techniques, Mutation, Oocytes physiology, Protein Subunits physiology, Spinocerebellar Ataxias congenital, Xenopus laevis, Ion Channel Gating physiology, Shaw Potassium Channels physiology, Spinocerebellar Degenerations physiopathology

Abstract

Mutations in Kv3.3 cause spinocerebellar ataxia type 13 (SCA13). Depending on the causative mutation, SCA13 is either a neurodevelopmental disorder that is evident in infancy or a progressive neurodegenerative disease that emerges during adulthood. Previous studies did not clarify the relationship between these distinct clinical phenotypes and the effects of SCA13 mutations on Kv3.3 function. The F448L mutation alters channel gating and causes early-onset SCA13. R420H and R423H suppress Kv3 current amplitude by a dominant negative mechanism. However, R420H results in the adult form of the disease whereas R423H produces the early-onset, neurodevelopmental form with significant clinical overlap with F448L. Since individuals with SCA13 have one wild type and one mutant allele of the Kv3.3 gene, we analysed the properties of tetrameric channels formed by mixtures of wild type and mutant subunits. We report that one R420H subunit and at least one R423H subunit can co-assemble with the wild type protein to form active channels. The functional properties of channels containing R420H and wild type subunits strongly resemble those of wild type alone. In contrast, channels containing R423H and wild type subunits show significantly altered gating, including a hyperpolarized shift in the voltage dependence of activation, slower activation, and modestly slower deactivation. Notably, these effects resemble the modified gating seen in channels containing a mixture of F448L and wild type subunits, although the F448L subunit slows deactivation more dramatically than the R423H subunit. Our results suggest that the clinical severity of R423H reflects its dual dominant negative and dominant gain of function effects. However, as shown by R420H, reducing current amplitude without altering gating does not result in infant onset disease. Therefore, our data strongly suggest that changes in Kv3.3 gating contribute significantly to an early age of onset in SCA13.

Published

2012

24. BK and Kv3.1 potassium channels control different aspects of deep cerebellar nuclear neurons action potentials and spiking activity.

Author

Pedroarena CM

Subjects

Animals, Animals, Newborn, Cerebellar Nuclei cytology, Mice, Mice, Inbred C57BL, Neural Inhibition physiology, Neurons cytology, Organ Culture Techniques, Action Potentials physiology, Cerebellar Nuclei physiology, Large-Conductance Calcium-Activated Potassium Channels physiology, Neurons physiology, Shaw Potassium Channels physiology

Abstract

Deep cerebellar nuclear neurons (DCNs) display characteristic electrical properties, including spontaneous spiking and the ability to discharge narrow spikes at high frequency. These properties are thought to be relevant to processing inhibitory Purkinje cell input and transferring well-timed signals to cerebellar targets. Yet, the underlying ionic mechanisms are not completely understood. BK and Kv3.1 potassium channels subserve similar functions in spike repolarization and fast firing in many neurons and are both highly expressed in DCNs. Here, their role in the abovementioned spiking characteristics was addressed using whole-cell recordings of large and small putative-glutamatergic DCNs. Selective BK channel block depolarized DCNs of both groups and increased spontaneous firing rate but scarcely affected evoked activity. After adjusting the membrane potential to control levels, the spike waveforms under BK channel block were indistinguishable from control ones, indicating no significant BK channel involvement in spike repolarization. The increased firing rate suggests that lack of DCN-BK channels may have contributed to the ataxic phenotype previously found in BK channel-deficient mice. On the other hand, block of Kv3.1 channels with low doses of 4-aminopyridine (20 μM) hindered spike repolarization and severely depressed evoked fast firing. Therefore, I propose that despite similar characteristics of BK and Kv3.1 channels, they play different roles in DCNs: BK channels control almost exclusively spontaneous firing rate, whereas DCN-Kv3.1 channels dominate the spike repolarization and enable fast firing. Interestingly, after Kv3.1 channel block, BK channels gained a role in spike repolarization, demonstrating how the different function of each of the two channels is determined in part by their co-expression and interplay.

Published

2011

25. Sparse but highly efficient Kv3 outpace BKCa channels in action potential repolarization at hippocampal mossy fiber boutons.

Author

Alle H, Kubota H, and Geiger JR

Subjects

Action Potentials drug effects, Animals, CA3 Region, Hippocampal drug effects, CA3 Region, Hippocampal physiology, Calcium metabolism, Chelating Agents pharmacology, Egtazic Acid analogs & derivatives, Egtazic Acid pharmacology, Female, In Vitro Techniques, Large-Conductance Calcium-Activated Potassium Channel alpha Subunits, Male, Mossy Fibers, Hippocampal drug effects, Patch-Clamp Techniques methods, Pyramidal Cells physiology, Rats, Rats, Wistar, Shaker Superfamily of Potassium Channels physiology, Synaptic Transmission drug effects, Synaptic Transmission physiology, Action Potentials physiology, Mossy Fibers, Hippocampal physiology, Potassium Channels physiology, Presynaptic Terminals physiology, Shaw Potassium Channels physiology

Abstract

Presynaptic elements of axons, in which action potentials (APs) cause release of neurotransmitter, are sites of high densities and complex interactions of proteins. We report that the presence of K(v)3 channels in addition to K(v)1 at glutamatergic mossy fiber boutons (MFBs) in rat hippocampal slices considerably limits the number of fast, voltage-activated potassium channels necessary to achieve basal presynaptic AP repolarization. The ∼ 10-fold higher repolarization efficacy per K(v)3 channel compared with presynaptic K(v)1 results from a higher steady-state availability at rest, a better recruitment by the presynaptic AP as a result of faster activation kinetics, and a larger single-channel conductance. Large-conductance calcium- and voltage-activated potassium channels (BK(Ca)) at MFBs give rise to a fast activating/fast inactivating and a slowly activating/sustained K(+) current component during long depolarizations. However, BK(Ca) contribute to MFB-AP repolarization only after presynaptic K(v)3 have been disabled. The calcium chelators EGTA and BAPTA are equally effective in preventing BK(Ca) activation, suggesting that BK(Ca) are not organized in nanodomain complexes with presynaptic voltage-gated calcium channels. Thus, the functional properties of K(v)3 channels at MFBs are tuned to both promote brevity of presynaptic APs limiting glutamate release and at the same time keep surface protein density of potassium channels low. Presynaptic BK(Ca) channels are restricted to limit additional increases of the AP half-duration in case of K(v)3 hypofunction, because rapid membrane repolarization by K(v)3 combined with distant calcium sources prevent BK(Ca) activation during basal APs.

Published

2011

26. Gastrin-releasing peptide modulates fast delayed rectifier potassium current in Per1-expressing SCN neurons.

Author

Gamble KL, Kudo T, Colwell CS, and McMahon DG

Subjects

Action Potentials drug effects, Action Potentials physiology, Animals, Circadian Clocks physiology, Circadian Rhythm drug effects, Circadian Rhythm physiology, Gastrin-Releasing Peptide pharmacology, Mice, Mice, Inbred C3H, Mice, Inbred C57BL, Mice, Inbred ICR, Mice, Knockout, Neurons metabolism, Photic Stimulation methods, Photoperiod, Potassium metabolism, Shaw Potassium Channels metabolism, Suprachiasmatic Nucleus metabolism, Gastrin-Releasing Peptide physiology, Neurons physiology, Period Circadian Proteins biosynthesis, Shaw Potassium Channels physiology, Suprachiasmatic Nucleus physiology

Abstract

The mammalian circadian clock in the suprachiasmatic nucleus (SCN) drives and maintains 24-h physiological rhythms, the phases of which are set by the local environmental light-dark cycle. Gastrin-releasing peptide (GRP) communicates photic phase setting signals in the SCN by increasing neurophysiological activity of SCN neurons. Here, the ionic basis for persistent GRP-induced changes in neuronal activity was investigated in SCN slice cultures from Per1::GFP reporter mice during the early night. Recordings from Per1 -fluorescent neurons in SCN slices several hours after GRP treatment revealed a significantly greater action potential frequency, a significant increase in voltage-activated outward current at depolarized potentials, and a significant increase in 4-aminopyridine-sensitive fast delayed rectifier (fDR) potassium currents when compared to vehicle-treated slices. In addition, the persistent increase in spike rate following early-night GRP application was blocked in SCN neurons from mice deficient in Kv3 channel proteins. Because fDR currents are regulated by the clock and are elevated in amplitude during the day, the present results support the model that GRP delays the phase of the clock during the early night by prolonging day-like membrane properties of SCN cells. Furthermore, these findings implicate fDR currents in the ionic basis for GRP-mediated entrainment of the primary mammalian circadian pacemaker., (© 2011 Sage Publications)

Published

2011

27. Fast delayed rectifier potassium current: critical for input and output of the circadian system.

Author

Kudo T, Loh DH, Kuljis D, Constance C, and Colwell CS

Subjects

Animals, Circadian Rhythm radiation effects, Light, Male, Membrane Potentials genetics, Membrane Potentials radiation effects, Mice, Mice, Inbred ICR, Mice, Knockout, Neurons cytology, Neurons radiation effects, Potassium Channels deficiency, Potassium Channels genetics, Shaw Potassium Channels deficiency, Shaw Potassium Channels genetics, Suprachiasmatic Nucleus cytology, Suprachiasmatic Nucleus radiation effects, Circadian Rhythm genetics, Neurons physiology, Potassium Channels physiology, Shaw Potassium Channels physiology, Suprachiasmatic Nucleus physiology

Abstract

The ability to generate intrinsic circadian rhythms in electrical activity appears to be a key property of central pacemaker neurons and one essential to the function of the circadian timing system. Previous work has demonstrated that suprachiasmatic nucleus (SCN) neurons express the fast delayed rectifier (FDR) potassium current and raise questions about the function of this current. Here, we report that mice lacking both Kcnc1 and Kcnc2 genes [double knock-out (dKO)] fail to express the Kv3.1 and 3.2 channels in the SCN as well as exhibit a greatly reduced FDR current. SCN neurons from these dKO mice exhibit reduced spontaneous activity during the day as well as reduced NMDA-evoked excitatory responses during the night. Interestingly, the daily rhythm in PER2 expression in the SCN was not altered in the dKO mice, although the photic induction of c-Fos was attenuated. Behaviorally, the dKO mice exhibited extremely disrupted daily rhythms in wheel-running behavior. In a light/dark cycle, some of the dKO mice were arrhythmic, whereas others expressed a diurnal rhythm with low amplitude and significant activity during the day. When placed in constant darkness, the dKO mice exhibited low-amplitude, fragmented rhythms and attenuated light responses. Together, these data are consistent with the hypothesis that the FDR current is critical for the generation of robust circadian rhythms in behavior as well as the synchronization of the circadian system to the photic environment.

Published

2011

28. Kv3-like potassium channels are required for sustained high-frequency firing in basal ganglia output neurons.

Author

Ding S, Matta SG, and Zhou FM

Subjects

Animals, Female, Ion Channel Gating physiology, Male, Rats, Rats, Sprague-Dawley, Action Potentials physiology, Basal Ganglia physiology, Biological Clocks physiology, Motor Neurons physiology, Movement physiology, Shaw Potassium Channels physiology

Abstract

The GABA projection neurons in the substantial nigra pars reticulata (SNr) are key output neurons of the basal ganglia motor control circuit. These neurons fire sustained high-frequency, short-duration spikes that provide a tonic inhibition to their targets and are critical to movement control. We hypothesized that a robust voltage-activated K(+) conductance that activates quickly and resists inactivation is essential to the remarkable fast-spiking capability in these neurons. Semi-quantitative RT-PCR (qRT-PCR) analysis on laser capture-microdissected nigral neurons indicated that mRNAs for Kv3.1 and Kv3.4, two key subunits for forming high activation threshold, fast-activating, slow-inactivating, 1 mM tetraethylammonium (TEA)-sensitive, fast delayed rectifier (I(DR-fast)) type Kv channels, are more abundant in fast-spiking SNr GABA neurons than in slow-spiking nigral dopamine neurons. Nucleated patch clamp recordings showed that SNr GABA neurons have a strong Kv3-like I(DR-fast) current sensitive to 1 mM TEA that activates quickly at depolarized membrane potentials and is resistant to inactivation. I(DR-fast) is smaller in nigral dopamine neurons. Pharmacological blockade of I(DR-fast) by 1 mM TEA impaired the high-frequency firing capability in SNr GABA neurons. Taken together, these results indicate that Kv3-like channels mediating fast-activating, inactivation-resistant I(DR-fast) current are critical to the sustained high-frequency firing in SNr GABA projection neurons and hence movement control.

Published

2011

29. Mechanisms of sustained high firing rates in two classes of vestibular nucleus neurons: differential contributions of resurgent Na, Kv3, and BK currents.

Author

Gittis AH, Moghadam SH, and du Lac S

Subjects

Animals, Mice, Mice, Inbred C57BL, Time Factors, Action Potentials physiology, Large-Conductance Calcium-Activated Potassium Channels physiology, Neurons physiology, Shaw Potassium Channels physiology, Sodium Channels physiology, Vestibular Nuclei physiology

Abstract

To fire at high rates, neurons express ionic currents that work together to minimize refractory periods by ensuring that sodium channels are available for activation shortly after each action potential. Vestibular nucleus neurons operate around high baseline firing rates and encode information with bidirectional modulation of firing rates up to several hundred Hz. To determine the mechanisms that enable these neurons to sustain firing at high rates, ionic currents were measured during firing by using the action potential clamp technique in vestibular nucleus neurons acutely dissociated from transgenic mice. Although neurons from the YFP-16 line fire at rates higher than those from the GIN line, both classes of neurons express Kv3 and BK currents as well as both transient and resurgent Na currents. In the fastest firing neurons, Kv3 currents dominated repolarization at all firing rates and minimized Na channel inactivation by rapidly transitioning Na channels from the open to the closed state. In slower firing neurons, BK currents dominated repolarization at the highest firing rates and sodium channel availability was protected by a resurgent blocking mechanism. Quantitative differences in Kv3 current density across neurons and qualitative differences in immunohistochemically detected expression of Kv3 subunits could account for the difference in firing range within and across cell classes. These results demonstrate how divergent firing properties of two neuronal populations arise through the interplay of at least three ionic currents.

Published

2010

30. Functional effects of spinocerebellar ataxia type 13 mutations are conserved in zebrafish Kv3.3 channels.

Author

Mock AF, Richardson JL, Hsieh JY, Rinetti G, and Papazian DM

Subjects

Amino Acid Sequence, Animals, Chromosomes genetics, Cloning, Molecular, Conserved Sequence, Disease Models, Animal, Electrophysiology, Humans, Informatics, Molecular Sequence Data, Mutagenesis, Phylogeny, Shaw Potassium Channels physiology, Zebrafish Proteins physiology, Mutation physiology, Shaw Potassium Channels genetics, Spinocerebellar Ataxias genetics, Zebrafish physiology, Zebrafish Proteins genetics

Abstract

Background: The zebrafish has been suggested as a model system for studying human diseases that affect nervous system function and motor output. However, few of the ion channels that control neuronal activity in zebrafish have been characterized. Here, we have identified zebrafish orthologs of voltage-dependent Kv3 (KCNC) K+ channels. Kv3 channels have specialized gating properties that facilitate high-frequency, repetitive firing in fast-spiking neurons. Mutations in human Kv3.3 cause spinocerebellar ataxia type 13 (SCA13), an autosomal dominant genetic disease that exists in distinct neurodevelopmental and neurodegenerative forms. To assess the potential usefulness of the zebrafish as a model system for SCA13, we have characterized the functional properties of zebrafish Kv3.3 channels with and without mutations analogous to those that cause SCA13., Results: The zebrafish genome (release Zv8) contains six Kv3 family members including two Kv3.1 genes (kcnc1a and kcnc1b), one Kv3.2 gene (kcnc2), two Kv3.3 genes (kcnc3a and kcnc3b), and one Kv3.4 gene (kcnc4). Both Kv3.3 genes are expressed during early development. Zebrafish Kv3.3 channels exhibit strong functional and structural homology with mammalian Kv3.3 channels. Zebrafish Kv3.3 activates over a depolarized voltage range and deactivates rapidly. An amino-terminal extension mediates fast, N-type inactivation. The kcnc3a gene is alternatively spliced, generating variant carboxyl-terminal sequences. The R335H mutation in the S4 transmembrane segment, analogous to the SCA13 mutation R420H, eliminates functional expression. When co-expressed with wild type, R335H subunits suppress Kv3.3 activity by a dominant negative mechanism. The F363L mutation in the S5 transmembrane segment, analogous to the SCA13 mutation F448L, alters channel gating. F363L shifts the voltage range for activation in the hyperpolarized direction and dramatically slows deactivation., Conclusions: The functional properties of zebrafish Kv3.3 channels are consistent with a role in facilitating fast, repetitive firing of action potentials in neurons. The functional effects of SCA13 mutations are well conserved between human and zebrafish Kv3.3 channels. The high degree of homology between human and zebrafish Kv3.3 channels suggests that the zebrafish will be a useful model system for studying pathogenic mechanisms in SCA13.

Published

2010

31. Rescue of motor coordination by Purkinje cell-targeted restoration of Kv3.3 channels in Kcnc3-null mice requires Kcnc1.

Author

Hurlock EC, Bose M, Pierce G, and Joho RH

Subjects

Action Potentials genetics, Alleles, Animals, Cerebellar Nuclei metabolism, Cerebellar Nuclei pathology, Female, Gait Ataxia genetics, Gait Ataxia pathology, Male, Mice, Mice, Knockout, Purkinje Cells cytology, Purkinje Cells pathology, Shaw Potassium Channels biosynthesis, Gene Targeting, Psychomotor Performance physiology, Purkinje Cells physiology, Shaw Potassium Channels deficiency, Shaw Potassium Channels genetics, Shaw Potassium Channels physiology

Abstract

The role of cerebellar Kv3.1 and Kv3.3 channels in motor coordination was examined with an emphasis on the deep cerebellar nuclei (DCN). Kv3 channel subunits encoded by Kcnc genes are distinguished by rapid activation and deactivation kinetics that support high-frequency, narrow action potential firing. Previously we reported that increased lateral deviation while ambulating and slips while traversing a narrow beam of ataxic Kcnc3-null mice were corrected by restoration of Kv3.3 channels specifically to Purkinje cells, whereas Kcnc3-mutant mice additionally lacking one Kcnc1 allele were partially rescued. Here, we report mice lacking all Kcnc1 and Kcnc3 alleles exhibit no such rescue. For Purkinje cell output to reach the rest of the brain it must be conveyed by neurons of the DCN or vestibular nuclei. As Kcnc1, but not Kcnc3, alleles are lost, mutant mice exhibit increasing gait ataxia accompanied by spike broadening and deceleration in DCN neurons, suggesting the facet of coordination rescued by Purkinje-cell-restricted Kv3.3 restoration in mice lacking just Kcnc3 is hypermetria, while gait ataxia emerges when additionally Kcnc1 alleles are lost. Thus, fast repolarization in Purkinje cells appears important for normal movement velocity, whereas DCN neurons are a prime candidate locus where fast repolarization is necessary for normal gait patterning.

Published

2009

32. Function of the Shaw potassium channel within the Drosophila circadian clock.

Author

Hodge JJ and Stanewsky R

Subjects

Animals, Animals, Genetically Modified, Brain metabolism, Immunohistochemistry, Locomotion physiology, Luminescence, Male, Neurons metabolism, Shaw Potassium Channels metabolism, Biological Clocks, Circadian Rhythm, Shaw Potassium Channels physiology

Abstract

Background: In addition to the molecular feedback loops, electrical activity has been shown to be important for the function of networks of clock neurons in generating rhythmic behavior. Most studies have used over-expression of foreign channels or pharmacological manipulations that alter membrane excitability. In order to determine the cellular mechanisms that regulate resting membrane potential (RMP) in the native clock of Drosophila we modulated the function of Shaw, a widely expressed neuronal potassium (K(+)) channel known to regulate RMP in Drosophila central neurons., Methodology/principal Findings: We show that Shaw is endogenously expressed in clock neurons. Differential use of clock gene promoters was employed to express a range of transgenes that either increase or decrease Shaw function in different clusters of clock neurons. Under LD conditions, increasing Shaw levels in all clock neurons (LNv, LNd, DN(1), DN(2) and DN(3)), or in subsets of clock neurons (LNd and DNs or DNs alone) increases locomotor activity at night. In free-running conditions these manipulations result in arrhythmic locomotor activity without disruption of the molecular clock. Reducing Shaw in the DN alone caused a dramatic lengthening of the behavioral period. Changing Shaw levels in all clock neurons also disrupts the rhythmic accumulation and levels of Pigment Dispersing Factor (PDF) in the dorsal projections of LNv neurons. However, changing Shaw levels solely in LNv neurons had little effect on locomotor activity or rhythmic accumulation of PDF., Conclusions/significance: Based on our results it is likely that Shaw modulates pacemaker and output neuronal electrical activity that controls circadian locomotor behavior by affecting rhythmic release of PDF. The results support an important role of the DN clock neurons in Shaw-mediated control of circadian behavior. In conclusion, we have demonstrated a central role of Shaw for coordinated and rhythmic output from clock neurons.

Published

2008

33. Purkinje-cell-restricted restoration of Kv3.3 function restores complex spikes and rescues motor coordination in Kcnc3 mutants.

Author

Hurlock EC, McMahon A, and Joho RH

Subjects

Action Potentials genetics, Action Potentials radiation effects, Analysis of Variance, Animals, Behavior, Animal, Cerebellum cytology, Dose-Response Relationship, Radiation, Electric Stimulation methods, Female, Gene Expression physiology, Green Fluorescent Proteins metabolism, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Patch-Clamp Techniques, Shaw Potassium Channels deficiency, Action Potentials physiology, Motor Skills physiology, Mutation physiology, Postural Balance physiology, Purkinje Cells physiology, Shaw Potassium Channels physiology

Abstract

The fast-activating/deactivating voltage-gated potassium channel Kv3.3 (Kcnc3) is expressed in various neuronal cell types involved in motor function, including cerebellar Purkinje cells. Spinocerebellar ataxia type 13 (SCA13) patients carrying dominant-negative mutations in Kcnc3 and Kcnc3-null mutant mice both display motor incoordination, suggested in mice by increased lateral deviation while ambulating and slips on a narrow beam. Motor skill learning, however, is spared. Mice lacking Kcnc3 also exhibit muscle twitches. In addition to broadened spikes, recordings of Kcnc3-null Purkinje cells revealed fewer spikelets in complex spikes and a lower intraburst frequency. Targeted reexpression of Kv3.3 channels exclusively in Purkinje cells in Kcnc3-null mice as well as in mice also heterozygous for Kv3.1 sufficed to restore simple spike brevity along with normal complex spikes and to rescue specifically coordination. Therefore, spike parameters requiring Kv3.3 function in Purkinje cells are involved in the ataxic null phenotype and motor coordination, but not motor learning.

Published

2008

34. Kv3.3 channels at the Purkinje cell soma are necessary for generation of the classical complex spike waveform.

Author

Zagha E, Lang EJ, and Rudy B

Subjects

Action Potentials drug effects, Animals, Animals, Newborn, Cell Membrane drug effects, Cerebellum cytology, Cerebellum drug effects, In Vitro Techniques, Mice, Mice, Knockout, Phenotype, Potassium Channel Blockers pharmacology, Purkinje Cells drug effects, Shaw Potassium Channels antagonists & inhibitors, Action Potentials physiology, Cell Membrane physiology, Cerebellum physiology, Purkinje Cells physiology, Shaw Potassium Channels physiology

Abstract

Voltage-gated potassium channel subunit Kv3.3 is prominently expressed in cerebellar Purkinje cells and is known to be important for cerebellar function, as human and mouse movement disorders result from mutations in Kv3.3. To understand these behavioral deficits, it is necessary to know the role of Kv3.3 channels on the physiological responses of Purkinje cells. We studied the function of Kv3.3 channels in regulating the synaptically evoked Purkinje cell complex spike, the massive postsynaptic response to the activation of climbing fiber afferents, believed to be fundamental to cerebellar physiology. Acute slice recordings revealed that Kv3.3 channels are required for generation of the repetitive spikelets of the complex spike. We found that spikelet expression is regulated by somatic, and not by dendritic, Kv3 activity, which is consistent with dual somatic-dendritic recordings that demonstrate spikelet generation at axosomatic membranes. Simulations of Purkinje cell Na+ currents show that the unique electrical properties of Kv3 and resurgent Na+ channels are coordinated to limit accumulation of Na+ channel inactivation and enable rapid, repetitive firing. We additionally show that Kv3.3 knock-out mice produce altered complex spikes in vitro and in vivo, which is likely a cellular substrate of the cerebellar phenotypes observed in these mice. This characterization presents new tools to study complex spike function, cerebellar signaling, and Kv3.3-dependent human and mouse phenotypes.

Published

2008

35. Modulation of potassium ion channel proteins utilising antibodies.

Author

Dallas ML, Deuchars SA, and Deuchars J

Subjects

Animals, Antibody Specificity, Immunohistochemistry, Patch-Clamp Techniques, Protein Subunits immunology, Rats, Action Potentials physiology, Antibodies, Brain Stem physiology, Nerve Tissue Proteins immunology, Nerve Tissue Proteins physiology, Neurons physiology, Shaw Potassium Channels immunology, Shaw Potassium Channels physiology

Abstract

The application of antibodies to living cells has the potential to modulate the function of specific proteins by virtue of their high specificity. This specificity has proven effective in determining the involvement of many proteins in neuronal function where specific agonists and antagonists do not exist, e.g. ion channel subunits. We discuss a way to utilise subunit specific antibodies to target individual channel subunits in electrophysiological experiments to determine functional roles within native neurones. Utilising this approach, we have investigated the role of the voltage-gated potassium channel Kv3.1b subunit within a region of the brainstem important in the regulation of autonomic function. We provide some useful control experiments in order to help validate this method. We conclude that antibodies can be extremely valuable in determining the functions of specific proteins in living neurones in neuroscience research.

Published

2008

36. The MiRP2-Kv3.4 potassium channel: muscling in on Alzheimer's disease.

Author

Choi E and Abbott GW

Subjects

Alzheimer Disease etiology, Alzheimer Disease pathology, Amyloid beta-Peptides chemistry, Amyloid beta-Peptides toxicity, Animals, Apoptosis drug effects, Cell Death drug effects, Cnidarian Venoms pharmacology, Humans, Models, Biological, Muscle, Skeletal chemistry, Muscle, Skeletal cytology, NF-kappa B antagonists & inhibitors, Peptide Fragments chemistry, Peptide Fragments toxicity, Potassium Channel Blockers pharmacology, Potassium Channels, Voltage-Gated antagonists & inhibitors, Sea Anemones chemistry, Shaw Potassium Channels antagonists & inhibitors, Alzheimer Disease genetics, Alzheimer Disease metabolism, Muscle, Skeletal metabolism, Potassium Channels, Voltage-Gated physiology, Shaw Potassium Channels physiology

Abstract

In this issue of Molecular Pharmacology (p. 665), Pannacione et al. provide evidence of a role for the voltage-gated potassium channel alpha subunit Kv3.4 and its ancillary subunit MiRP2 in beta-amyloid (Abeta) peptide-mediated neuronal death. The MiRP2-Kv3.4 channel complex-previously found to be important in skeletal myocyte physiology-is now argued to be a molecular correlate of the transient outward potassium current up-regulated by Abeta peptide, considered a significant step in the etiology of Alzheimer's disease. The authors conclude that MiRP2 and Kv3.4 are up-regulated by Abeta peptide in a nuclear factor kappaB-dependent fashion at the transcriptional level, and the sea anemone toxin BDS-I is shown to protect against Abeta peptide-mediated cell death by specific blockade of Kv3.4-generated current. The findings lend weight to the premise that specific channels, such as MiRP2-Kv3.4, could hold promise as future therapeutic targets in Alzheimer's disease and potentially other neurodegenerative disorders.

Published

2007

37. Age-related decline in Kv3.1b expression in the mouse auditory brainstem correlates with functional deficits in the medial olivocochlear efferent system.

Author

Zettel ML, Zhu X, O'Neill WE, and Frisina RD

Subjects

Animals, Female, Male, Mice, Mice, Inbred C57BL, Mice, Inbred CBA, Mice, Inbred ICR, Shaw Potassium Channels physiology, Aging physiology, Cochlear Nucleus physiology, Evoked Potentials, Auditory, Brain Stem, Olivary Nucleus physiology, Shaw Potassium Channels analysis

Abstract

Kv3.1b channel protein is widely distributed in the mammalian auditory brainstem, but studies have focused mainly on regions critical for temporal processing, including the medial nucleus of the trapezoid body (MNTB) and anteroventral cochlear nucleus (AVCN). Because temporal processing declines with age, this study was undertaken to determine if the expression of Kv3.1b likewise declines, and if changes are specific to these nuclei. Immunocytochemistry using an anti-Kv3.1b antibody was performed, and the relative optical density of cells and neuropil was determined from CBA/CaJ mice of four age groups. Declines in expression in AVCN, MNTB, and lateral superior olive (35, 26, and 23%) were found, but changes were limited to neuropil. Interestingly, cellular optical density declines were found in superior paraolivary nucleus, ventral nucleus of the trapezoid body, and lateral nucleus of the trapezoid body (24, 29, and 26%), which comprise the medial olivocochlear (MOC) feedback system. All declines occurred by middle age (15 months old). No age-related changes were found in the remaining regions of cochlear nucleus or in the inferior colliculus. Contralateral suppression of distortion-product otoacoustic emission amplitudes of age-matched littermates also declined by middle age, suggesting a correlation between Kv3.1 expression and MOC function. In search of more direct evidence for such a correlation, Kv3.1b knockout mice were examined. Knockouts show poor MOC function as compared to +/+ and +/- genotypes. Thus, Kv3.1b expression declines in MOC neurons by middle age, and these changes appear to correlate with functional declines in efferent activity in both middle-aged CBA mice and Kv3.1b knockout mice.

Published

2007

38. Quantifying noise-induced stability of a cortical fast-spiking cell model with Kv3-channel-like current.

Author

Tateno T and Robinson HP

Subjects

Interneurons physiology, Somatosensory Cortex cytology, Action Potentials, Models, Neurological, Shaw Potassium Channels physiology, Somatosensory Cortex physiology

Abstract

Population oscillations in neural activity in the gamma (>30 Hz) and higher frequency ranges are found over wide areas of the mammalian cortex. Recently, in the somatosensory cortex, the details of neural connections formed by several types of GABAergic interneurons have become apparent, and they are believed to play a significant role in generating these oscillations through synaptic and gap-junctional interactions. However, little is known about the mechanism of how such oscillations are maintained stably by particular interneurons and by their local networks, in a noisy environment with abundant synaptic inputs. To obtain more insight into this, we studied a fast-spiking (FS)-cell model including Kv3-channel-like current, which is a distinctive feature of these cells, from the viewpoint of nonlinear dynamical systems. To examine the specific role of the Kv3-channel in determining oscillation properties, we analyzed basic properties of the FS-cell model, such as the bifurcation structure and phase resetting curves (PRCs). Furthermore, to quantitatively characterize the oscillation stability under noisy fluctuations mimicking small fast synaptic inputs, we applied a recently developed method from random dynamical system theory to estimate Lyapunov exponents, both for the original four-dimensional dynamics and for a reduced one-dimensional phase-equation on the circle. The results indicated that the presence of the Kv3-channel-like current helps to regulate the stability of noisy neural oscillations and a transient-period length to stochastic attractors.

Published

2007

39. In vivo calcium imaging from genetically specified target cells in mouse cerebellum.

Author

Díez-García J, Akemann W, and Knöpfel T

Subjects

Animals, Cerebellum cytology, Mice, Mice, Transgenic, Neurons cytology, Calcium metabolism, Calcium Signaling physiology, Cerebellum metabolism, Gene Targeting methods, Microscopy, Fluorescence, Multiphoton methods, Neurons metabolism, Shaw Potassium Channels physiology

Abstract

Genetically encoded fluorescent calcium indicator proteins provide the potential to monitor activity from genetically specified target cells without a need for single cell resolution. Here we report the use of transgenic mice expressing the fluorescent calcium indicator protein GCaMP2 in cerebellar granule cells to image parallel fiber activity transcranially in vivo. We demonstrated reliable measurements of calcium transients from beams of parallel fibers in response to electrical stimulation in the molecular layer through the intact skull. These parallel fiber calcium transients differed from intrinsic postsynaptic autofluorescence signals in their faster kinetics and resistance to blockers of synaptic transmission. Finally, we used 2P laser-scanning microscopy to demonstrate reliable measurements of calcium transients from beams of parallel fibers at high spatial resolution in living mice. We expect that genetically targeted fluorescent calcium indicator proteins along with optical imaging techniques will be instrumental for the construction of macroscopic and microscopic maps of the function of specific brain circuits.

Published

2007

40. Properties and expression of Kv3 channels in cerebellar Purkinje cells.

Author

Sacco T, De Luca A, and Tempia F

Subjects

Animals, Cerebellum cytology, Cerebellum growth & development, Cerebellum physiology, Cnidarian Venoms pharmacology, Female, Gene Expression, In Vitro Techniques, Male, Membrane Potentials drug effects, Membrane Potentials physiology, Mice, Mice, Inbred Strains, Patch-Clamp Techniques, RNA, Messenger, Purkinje Cells physiology, Shaw Potassium Channels genetics, Shaw Potassium Channels physiology

Abstract

In cerebellar Purkinje cells, Kv3 potassium channels are indispensable for firing at high frequencies. In Purkinje cells from young mice (P4-P7), Kv3 currents, recorded in whole-cell in slices, activated at -30 mV, with rapid activation and deactivation kinetics, and they were partially blocked by blood depressing substance-I (BDS-I, 1 microM). At positive potentials, Kv3 currents were slowly but completely inactivating, while the recovery from inactivation was about eightfold slower, suggesting that a previous firing activity or a small change of the resting potential could in principle accumulate inactivated Kv3 channels, thereby finely tuning Kv3 current availability for subsequent action potentials. Single-cell RT-PCR analysis showed the expression by all Purkinje cells (n=10 for each subunit) of Kv3.1, Kv3.3 and Kv3.4 mRNA, while Kv3.2 was not expressed. These results add to the framework for interpreting the physiological function and the molecular determinants of Kv3 currents in cerebellar Purkinje cells.

Published

2006

41. K+ channel KV3.1 associates with OSP/claudin-11 and regulates oligodendrocyte development.

Author

Tiwari-Woodruff S, Beltran-Parrazal L, Charles A, Keck T, Vu T, and Bronstein J

Subjects

Animals, Axons physiology, Axons ultrastructure, Cell Division physiology, Cell Lineage, Cell Movement physiology, Claudins, Electric Conductivity, Electrophysiology, Immunohistochemistry, Mice, Mice, Knockout, Myelin Sheath physiology, Myelin Sheath ultrastructure, Oligodendroglia cytology, Optic Nerve ultrastructure, RNA, Messenger metabolism, Shaw Potassium Channels deficiency, Shaw Potassium Channels genetics, Shaw Potassium Channels metabolism, Stem Cells metabolism, Nerve Tissue Proteins physiology, Oligodendroglia physiology, Shaw Potassium Channels physiology

Abstract

K(+) channels are differentially expressed throughout oligodendrocyte (Olg) development. K(V)1 family voltage-sensitive K(+) channels have been implicated in proliferation and migration of Olg progenitor cell (OPC) stage, and inward rectifier K+ channels (K(IR))4.1 are required for OPC differentiation to myelin-forming Olg. In this report we have identified a Shaw family K(+) channel, K(V)3.1, that is involved in proliferation and migration of OPC and axon myelination. Application of anti-K(V)3.1 antibody or knockout of Kv3.1 gene decreased the sustained K(+) current component of OPC by 50% and 75%, respectively. In functional assays block of K(V)3.1-specific currents or knockout of Kv3.1 gene inhibited proliferation and migration of OPC. Adult Kv3.1 gene-knockout mice had decreased diameter of axons and decreased thickness of myelin in optic nerves compared with age-matched wild-type littermates. Additionally, K(V)3.1 was identified as an associated protein of Olg-specific protein (OSP)/claudin-11 via yeast two-hybrid analysis, which was confirmed by coimmunoprecipitation and coimmunohistochemistry. In summary, the K(V)3.1 K(+) current accounts for a significant component of the total K(+) current in cells of the Olg lineage and, in association with OSP/claudin-11, plays a significant role in OPC proliferation and migration and myelination of axons.

Published

2006

42. Development of synapses and expression of a voltage-gated potassium channel in chick embryonic auditory nuclei.

Author

Feng JJ and Morest DK

Subjects

Animals, Astrocytes metabolism, Astrocytes physiology, Chick Embryo, Cochlear Nerve embryology, Cochlear Nerve metabolism, Cochlear Nucleus embryology, Gene Expression Regulation, Developmental, Immunohistochemistry, Neurons metabolism, Olivary Nucleus embryology, Shaw Potassium Channels metabolism, Cochlear Nucleus metabolism, Olivary Nucleus physiology, Shaw Potassium Channels physiology, Synapses physiology

Abstract

The potassium channel protein, Kv3.1, is abundantly expressed in the chick auditory pathway. Its b-isoform is found in nucleus magnocellularis, which receives the cochlear input, both before and after the establishment of synaptic connections. It is also present in cell cultures in the absence of any peripheral input. However, the expression of this isoform in the embryo has been shown to increase with development. Here, we address the question of the correlation between maturation of synapses in the auditory pathway and the pattern of expression of the b-isoform in a series of embryos prepared for immunohistochemistry at Hamburger-Hamilton stages equivalent to E10, E12, E14, and E17. We show here that this subunit translocates from the perinuclear cytoplasm to the cell membrane domain in nucleus magnocellularis at the time that cochlear nerve endings emerge as endbulbs of Held (E17). In nucleus laminaris, by this time, while abundant Kv3.1b occurs in the perinuclear cytoplasm, a translocation to the cell membrane domain has not yet occurred, and the mature peri-synaptic localization is delayed to a later stage. This difference suggests a hierarchy in the developmental expression of Kv3.1. An unexpected finding is the expression of the a-isoform of Kv3.1 in astrocytes, especially those which surround the developing nuclei and their connecting fibers. We also report here for the first time the presence of Kv3.1b in the initial segments of axons at the times when they begin to form. Our observations suggest that the Kv3.1 channel protein is regulated through mechanisms linked to the development of synaptic activity.

Published

2006

43. Atypical phenotypes from flatworm Kv3 channels.

Author

Klassen TL, Buckingham SD, Atherton DM, Dacks JB, Gallin WJ, and Spencer AN

Subjects

Animals, Cloning, Molecular methods, Dose-Response Relationship, Radiation, Electric Conductivity, Electric Stimulation methods, Ion Channel Gating drug effects, Ion Channel Gating physiology, Ion Channel Gating radiation effects, Membrane Potentials drug effects, Membrane Potentials physiology, Membrane Potentials radiation effects, Microinjections methods, Oocytes physiology, Patch-Clamp Techniques methods, Phylogeny, Potassium pharmacology, RNA, Messenger biosynthesis, Reverse Transcriptase Polymerase Chain Reaction methods, Sequence Analysis, DNA methods, Sequence Analysis, Protein methods, Shaw Potassium Channels physiology, Phenotype, Platyhelminths genetics, Shaw Potassium Channels genetics

Abstract

Divergence of the Shaker superfamily of voltage-gated (Kv) ion channels early in metazoan evolution created numerous electrical phenotypes that were presumably selected to produce a wide range of excitability characteristics in neurons, myocytes, and other cells. A comparative approach that emphasizes this early radiation provides a comprehensive sampling of sequence space that is necessary to develop generally applicable models of the structure-function relationship in the Kv potassium channel family. We have cloned and characterized two Shaw-type potassium channels from a flatworm (Notoplana atomata) that is arguably a representative of early diverging bilaterians. When expressed in Xenopus oocytes, one of these cloned channels, N.at-Kv3.1, exhibits a noninactivating, outward current with slow opening kinetics that are dependent on both the holding potential and the activating potential. A second Shaw-type channel, N.at-Kv3.2, has very different properties, showing weak inward rectification. These results demonstrate that broad phylogenetic sampling of proteins of a single family will reveal unexpected properties that lead to new interpretations of structure-function relationships.

Published

2006

44. Kv3 potassium channels control the duration of different arousal states by distinct stochastic and clock-like mechanisms.

Author

Joho RH, Marks GA, and Espinosa F

Subjects

Animals, Kinetics, Light, Mice, Mice, Knockout, Polysomnography, Shaw Potassium Channels genetics, Sleep physiology, Sleep, REM physiology, Stochastic Processes, Wakefulness physiology, Arousal physiology, Periodicity, Shaw Potassium Channels physiology

Abstract

Sleep-wake behavior is tightly controlled in many animal species, suggesting genetically encoded, homeostatic control mechanisms that determine arousal-state dynamics. We reported that two voltage-gated potassium channels, Kv3.1 and Kv3.3, control sleep in wild-type and Kv3-mutant mice. Compared with wild-type (WT), homozygous double mutants (DKO) that lack these channels sleep 40% less in the light and 22% less in the dark. To understand how the lack of these channels affects sleep, we analysed arousal-state changes during the light period where the differences are greatest between WT and DKO. We determined the kinetic complexity of each arousal state from the episode durations of wakefulness, slow-wave sleep and rapid eye movement sleep (REMS). Based on the number of exponential components in episode-duration histograms, WT and DKO mice have several kinetically distinct states of wakefulness, and these states are longer in duration in DKO. For slow-wave sleep, WT mice have a single slow-wave sleep (SWS) state in contrast to DKO mice, which show two distinct SWS states, one that is 60% shorter than that in WT and a second that is similar in duration. Both WT and DKO mice have two kinetically distinct REMS states. DKO mice show an 84% reduction in the frequency of short REMS episodes (<45 s) without any change in the occurrence of long REMS episodes (>60 s). In contrast to the stochastic control of episode durations of wakefulness and SWS, the durations of both REMS states are normally distributed, indicating that the underlying control processes are fundamentally different.

Published

2006

45. Pharmacology and surface electrostatics of the K channel outer pore vestibule.

Author

Quinn CC and Begenisich T

Subjects

Action Potentials drug effects, Amino Acid Sequence, Amino Acids, Animals, Gallamine Triethiodide pharmacology, Humans, Molecular Sequence Data, Oocytes chemistry, Oocytes metabolism, Osmolar Concentration, Potassium Channels genetics, Potassium Channels metabolism, Shab Potassium Channels antagonists & inhibitors, Shab Potassium Channels physiology, Shaw Potassium Channels antagonists & inhibitors, Shaw Potassium Channels chemistry, Shaw Potassium Channels genetics, Shaw Potassium Channels physiology, Static Electricity, Tetraethylammonium pharmacology, Xenopus laevis, Potassium Channels chemistry, Potassium Channels physiology

Abstract

In spite of a generally well-conserved outer vestibule and pore structure, there is considerable diversity in the pharmacology of K channels. We have investigated the role of specific outer vestibule charged residues in the pharmacology of K channels using tetraethylammonium (TEA) and a trivalent TEA analog, gallamine. Similar to Shaker K channels, gallamine block of Kv3.1 channels was more sensitive to solution ionic strength than was TEA block, a result consistent with a contribution from an electrostatic potential near the blocking site. In contrast, TEA block of another type of K channel (Kv2.1) was insensitive to solution ionic strength and these channels were resistant to block by gallamine. Neutralizing either of two lysine residues in the outer vestibule of these Kv2.1 channels conferred ionic strength sensitivity to TEA block. Kv2.1 channels with both lysines neutralized were sensitive to block by gallamine, and the ionic strength dependence of this block was greater than that for TEA. These results demonstrate that Kv3.1 (like Shaker) channels contain negatively charged residues in the outer vestibule of the pore that influence quaternary ammonium pharmacology. The presence of specific lysine residues in wild-type Kv2.1 channels produces an outer vestibule with little or no net charge, with important consequences for quaternary ammonium block. Neutralizing these key lysines results in a negatively charged vestibule with pharmacological properties approaching those of other types of K channels.

Published

2006

46. A C-terminal domain directs Kv3.3 channels to dendrites.

Author

Deng Q, Rashid AJ, Fernandez FR, Turner RW, Maler L, and Dunn RJ

Subjects

Amino Acid Sequence, Animals, Cell Line, Cricetinae, Dendrites genetics, Drosophila, Fish Proteins biosynthesis, Fish Proteins genetics, Gymnotiformes, Mice, Molecular Sequence Data, Neurons, Afferent metabolism, Peptide Fragments biosynthesis, Peptide Fragments genetics, Protein Structure, Tertiary genetics, Rats, Shaw Potassium Channels biosynthesis, Shaw Potassium Channels genetics, Dendrites physiology, Fish Proteins physiology, Neurons, Afferent physiology, Peptide Fragments physiology, Shaw Potassium Channels physiology

Abstract

Pyramidal neurons of the electrosensory lateral line lobe (ELL) of Apteronotus leptorhynchus express Kv3-type voltage-gated potassium channels that give rise to high-threshold currents at the somatic and dendritic levels. Two members of the Kv3 channel family, AptKv3.1 and AptKv3.3, are coexpressed in these neurons. AptKv3.3 channels are expressed at uniformly high levels in each of four ELL segments, whereas AptKv3.1 channels appear to be expressed in a graded manner with higher levels of expression in segments that process high-frequency electrosensory signals. Immunohistochemical and recombinant channel expression studies show a differential distribution of these two channels in the dendrites of ELL pyramidal neurons. AptKv3.1 is concentrated in somas and proximal dendrites, whereas AptKv3.3 is distributed throughout the full extent of the large dendritic tree. Recombinant channel expression of AptKv3 channels through in vivo viral injections allowed directed retargeting of AptKv3 subtypes over the somadendritic axis, revealing that the sequence responsible for targeting channels to distal dendrites lies within the C-terminal domain of the AptKv3.3 protein. The targeting domain includes a consensus sequence predicted to bind to a PDZ (postsynaptic density-95/Discs large/zona occludens-1)-type protein-protein interaction motif. These findings reveal that different functional roles for Kv3 potassium channels at the somatic and dendritic level of a sensory neuron are attained through specific targeting that selectively distributes Kv3.3 channels to the dendritic compartment.

Published

2005

47. Contribution of Kv channels to phenotypic remodeling of human uterine artery smooth muscle cells.

Author

Miguel-Velado E, Moreno-Domínguez A, Colinas O, Cidad P, Heras M, Pérez-García MT, and López-López JR

Subjects

Cells, Cultured, Female, Humans, Large-Conductance Calcium-Activated Potassium Channels physiology, Phenotype, Potassium Channels, Voltage-Gated analysis, Potassium Channels, Voltage-Gated genetics, Protein Subunits, RNA, Messenger analysis, Shaker Superfamily of Potassium Channels drug effects, Shaker Superfamily of Potassium Channels physiology, Shal Potassium Channels analysis, Shal Potassium Channels genetics, Shaw Potassium Channels drug effects, Shaw Potassium Channels genetics, Shaw Potassium Channels physiology, Tetraethylammonium Compounds pharmacology, Triterpenes pharmacology, Cell Proliferation, Muscle, Smooth, Vascular cytology, Myocytes, Smooth Muscle cytology, Potassium Channels, Voltage-Gated physiology, Uterus blood supply

Abstract

Vascular smooth muscle cells (VSMCs) perform diverse functions that can be classified into contractile and synthetic (or proliferating). All of these functions can be fulfilled by the same cell because of its capacity of phenotypic modulation in response to environmental changes. The resting membrane potential is a key determinant for both contractile and proliferating functions. Here, we have explored the expression of voltage-dependent K+ (Kv) channels in contractile (freshly dissociated) and proliferating (cultured) VSMCs obtained from human uterine arteries to establish their contribution to the functional properties of the cells and their possible participation in the phenotypic switch. We have studied the expression pattern (both at the mRNA and at the protein level) of Kvalpha subunits in both preparations as well as their functional contribution to the K+ currents of VSMCs. Our results indicate that phenotypic remodeling associates with a change in the expression and distribution of Kv channels. Whereas Kv currents in contractile VSMCs are mainly performed by Kv1 channels, Kv3.4 is the principal contributor to K+ currents in cultured VSMCs. Furthermore, selective blockade of Kv3.4 channels resulted in a reduced proliferation rate, suggesting a link between Kv channels expression and phenotypic remodeling.

Published

2005

48. Potassium channels and proliferation of vascular smooth muscle cells.

Author

Jackson WF

Subjects

Calcium metabolism, Female, Humans, Shaw Potassium Channels physiology, Uterus blood supply, Cell Proliferation, Muscle, Smooth, Vascular cytology, Myocytes, Smooth Muscle cytology, Potassium Channels, Voltage-Gated physiology

Published

2005

49. The T1 domain of Kv1.3 mediates intracellular targeting to axons.

Author

Rivera JF, Chu PJ, and Arnold DB

Subjects

Animals, Animals, Newborn, Axons drug effects, Cells, Cultured, Cerebral Cortex cytology, Diagnostic Imaging methods, Embryo, Mammalian, Gene Expression Regulation genetics, Green Fluorescent Proteins metabolism, Immunohistochemistry methods, In Vitro Techniques, Models, Molecular, Mutagenesis physiology, Neurons physiology, Protein Structure, Tertiary physiology, Rats, Rats, Sprague-Dawley, Shaw Potassium Channels chemistry, Transfection methods, Axons physiology, Extracellular Space physiology, Neurons cytology, Shaw Potassium Channels physiology

Abstract

Shaker K+ channels play an important role in modulating electrical excitability of axons. Recent work has demonstrated that the T1 tetramerization domain of Kv1.2 is both necessary and sufficient for targeting of the channel to the axonal surface [Gu, C., Jan, Y.N. & Jan, L.Y. (2003) Science,301, 646-649]. Here we use a related channel, Kv1.3, as a model to investigate cellular mechanisms that mediate axonal targeting. We show that the T1 domain of Kv1.3 is necessary and sufficient to mediate targeting of the channel to the axonal surface in pyramidal neurons in slices of cortex from neonatal rat. The T1 domain is also sufficient to cause preferential axonal localization of intracellular protein, which indicates that the domain probably does not work through compartment-specific endocytosis or compartment-specific vesicle docking. To determine whether the T1 domain mediates axonal trafficking of transport vesicles, we compared the trafficking of vesicles containing green fluorescent protein-labelled transferrin receptor with those containing the same protein fused with the T1 domain in living cortical neurons. Vesicles containing the wild-type transferrin receptor did not traffic to the axon, in accord with previously published results; however, those containing the transferrin receptor fused to T1 did traffic to the axon. These results are consistent with the T1 domain of Kv1.3 mediating axonal targeting by causing transport vesicles to traffic to axons and they represent the first evidence that such a mechanism might underlie axonal targeting.

Published

2005

50. Modulation of Kv3 subfamily potassium currents by the sea anemone toxin BDS: significance for CNS and biophysical studies.

Author

Yeung SY, Thompson D, Wang Z, Fedida D, and Robertson B

Subjects

Animals, Cell Line, Central Nervous System drug effects, Central Nervous System physiology, Electrophysiology, Humans, Potassium Channel Blockers pharmacology, Rats, Shaw Potassium Channels genetics, Cnidarian Venoms pharmacology, Neurotoxins pharmacology, Sea Anemones, Shaw Potassium Channels antagonists & inhibitors, Shaw Potassium Channels physiology

Abstract

Kv3 potassium channels, with their ultra-rapid gating and high activation threshold, are essential for high-frequency firing in many CNS neurons. Significantly, the Kv3.4 subunit has been implicated in the major CNS disorders Parkinson's and Alzheimer's diseases, and it is claimed that selectively targeting this subunit will have therapeutic utility. Previous work suggested that BDS toxins ("blood depressing substance," from the sea anemone Anemonia sulcata) were specific blockers for rapidly inactivating Kv3.4 channels, and consequently these toxins are increasingly used as diagnostic agents for Kv3.4 subunits in central neurons. However, precisely how selective are these toxins for this important CNS protein? We show that BDS is not selective for Kv3.4 but markedly inhibits current through Kv3.1 and Kv3.2 channels. Inhibition comes about not by "pore block" but by striking modification of Kv3 gating kinetics and voltage dependence. Activation and inactivation kinetics are slowed by BDS-I and BDS-II, and V(1/2) for activation is shifted to more positive voltages. Alanine substitution mutagenesis around the S3b and S4 segments of Kv3.2 reveals that BDS acts via voltage-sensing domains, and, consistent with this, ON gating currents from nonconducting Kv3.2 are markedly inhibited. The altered kinetics and gating properties, combined with lack of subunit selectivity with Kv3 subunits, seriously affects the usefulness of BDS toxins in CNS studies. Furthermore, our results do not easily fit with the voltage sensor "paddle" structure proposed recently for Kv channels. Our data will be informative for experiments designed to dissect out the roles of Kv3 subunits in CNS function and dysfunction.

Published

2005