Your search keyword '"Shal Potassium Channels physiology"' showing total 22 results

1. Inhibition of A-type potassium current by the peptide toxin SNX-482.

Author

Kimm T and Bean BP

Subjects

Animals, Cells, Cultured, Dopaminergic Neurons physiology, Female, HEK293 Cells, Humans, Inhibitory Concentration 50, Ion Channel Gating physiology, Male, Membrane Potentials physiology, Mice, Patch-Clamp Techniques, Potassium metabolism, Shal Potassium Channels physiology, Dopaminergic Neurons drug effects, Ion Channel Gating drug effects, Membrane Potentials drug effects, Potassium Channel Blockers pharmacology, Shal Potassium Channels drug effects, Spider Venoms pharmacology

Abstract

SNX-482, a peptide toxin isolated from tarantula venom, has become widely used as an inhibitor of Cav2.3 voltage-gated calcium channels. Unexpectedly, we found that SNX-482 dramatically reduced the A-type potassium current in acutely dissociated dopamine neurons from mouse substantia nigra pars compacta. The inhibition persisted when calcium was replaced by cobalt, showing that it was not secondary to a reduction of calcium influx. Currents from cloned Kv4.3 channels expressed in HEK-293 cells were inhibited by SNX-482 with an IC50 of <3 nM, revealing substantially greater potency than for SNX-482 inhibition of Cav2.3 channels (IC50 20-60 nM). At sub-saturating concentrations, SNX-482 produced a depolarizing shift in the voltage dependence of activation of Kv4.3 channels and slowed activation kinetics. Similar effects were seen on gating of cloned Kv4.2 channels, but the inhibition was less pronounced and required higher toxin concentrations. These results reveal SNX-482 as the most potent inhibitor of Kv4.3 channels yet identified. Because of the effects on both Kv4.3 and Kv4.2 channels, caution is needed when interpreting the effects of SNX-482 on cells and circuits where these channels are present., (Copyright © 2014 the authors 0270-6474/14/349182-08$15.00/0.)

Published

2014

2. 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

3. Heteropoda toxin 2 interaction with Kv4.3 and Kv4.1 reveals differences in gating modification.

Author

DeSimone CV, Zarayskiy VV, Bondarenko VE, and Morales MJ

Subjects

Amino Acid Sequence, Animals, Female, Mice, Molecular Sequence Data, Protein Binding drug effects, Protein Binding physiology, Rats, Shal Potassium Channels physiology, Spider Venoms pharmacology, Xenopus laevis, Ion Channel Gating drug effects, Ion Channel Gating physiology, Shal Potassium Channels metabolism, Spider Venoms metabolism

Abstract

Kv4 (Shal) potassium channels are responsible for the transient outward K(+) currents in mammalian hearts and central nervous systems. Heteropoda toxin 2 (HpTx2) is an inhibitor cysteine knot peptide toxin specific for Kv4 channels that inhibits gating of Kv4.3 in the voltage-dependent manner typical for this type of toxin. HpTx2 interacts with four independent binding sites containing two conserved hydrophobic amino acids in the S3b transmembrane segments of Kv4.3 and the closely related Kv4.1. Despite these similarities, HpTx2 interaction with Kv4.1 is considerably less voltage-dependent, has smaller shifts in the voltage-dependences of conductance and steady-state inactivation, and a 3-fold higher K(d) value. Swapping four nonconserved amino acids in S3b between the two channels exchanges the phenotypic response to HpTx2. To understand these differences in gating modification, we constructed Markov models of Kv4.3 and Kv4.1 activation gating in the presence of HpTx2. Both models feature a series of voltage-dependent steps leading to a final voltage-independent transition to the open state and closely replicate the experimental data. Interaction with HpTx2 increases the energy barrier for channel opening by slowing activation and accelerating deactivation. The greater degree of voltage-dependence in Kv4.3 occurs because it is the voltage-dependent transitions that are most affected by HpTx2; in contrast, it is the voltage-independent step in Kv4.1 that is most affected by the presence of toxin. These data demonstrate the basis for subtype-specificity of HpTx2 and point the way to a general model of gating modifier toxin interaction with voltage-gated ion channels.

Published

2011

4. Up-regulation of dendritic Kv4.2 mRNA by activation of the NMDA receptor.

Author

Jo A and Kim HK

Subjects

Animals, Cells, Cultured, Rats, Rats, Sprague-Dawley, Up-Regulation physiology, Dendrites metabolism, Ion Channel Gating physiology, RNA, Messenger metabolism, Receptors, N-Methyl-D-Aspartate metabolism, Shal Potassium Channels physiology, Synaptic Transmission physiology

Abstract

The localization of Kv4.2 mRNAs in dendritic regions suggests that Kv4.2 channels, which originate from on-site protein synthesis in the dendrites, might play a role in synaptic function. In this study, we determined the molecular mechanisms of dendritic transport of Kv4.2 mRNA. Three hours of incubation following a brief depolarization resulted in significant increases in Kv4.2 mRNA levels in both cell bodies and dendrites. The increase in the mRNA in the dendrites was mediated by transcription- and translation-independent mechanisms. In order to further clarify the molecular mechanism of dendritic transport of Kv4.2 mRNA, we used the GFP-MS2 reporting system. Consistent with the in situ data, depolarization resulted in significant increases in dendritic levels of Kv4.2 mRNA at the maximal length at which Kv4.2 mRNA could be detected. These increases were mediated in a synaptic NMDA receptor- and Ca(2+)-dependent fashion. Collectively, these results indicate that Kv4.2 mRNA levels are regulated in response to synaptic activity, and this phenomenon may be the mechanism underlying the homeostasis of Kv4.2 protein on dendritic surfaces., (Copyright © 2011 Elsevier Ireland Ltd. All rights reserved.)

Published

2011

5. Mechanisms of closed-state inactivation in voltage-gated ion channels.

Author

Bähring R and Covarrubias M

Subjects

Animals, Humans, Shal Potassium Channels physiology, Ion Channel Gating physiology, Ion Channels physiology, Membrane Potentials physiology

Abstract

Inactivation of voltage-gated ion channels is an intrinsic auto-regulatory process necessary to govern the occurrence and shape of action potentials and establish firing patterns in excitable tissues. Inactivation may occur from the open state (open-state inactivation, OSI) at strongly depolarized membrane potentials, or from pre-open closed states (closed-state inactivation, CSI) at hyperpolarized and modestly depolarized membrane potentials. Voltage-gated Na(+), K(+), Ca(2+) and non-selective cationic channels utilize both OSI and CSI. Whereas there are detailed mechanistic descriptions of OSI, much less is known about the molecular basis of CSI. Here, we review evidence for CSI in voltage-gated cationic channels (VGCCs) and recent findings that shed light on the molecular mechanisms of CSI in voltage-gated K(+) (Kv) channels. Particularly, complementary observations suggest that the S4 voltage sensor, the S4S5 linker and the main S6 activation gate are instrumental in the installment of CSI in Kv4 channels. According to this hypothesis, the voltage sensor may adopt a distinct conformation to drive CSI and, depending on the stability of the interactions between the voltage sensor and the pore domain, a closed-inactivated state results from rearrangements in the selectivity filter or failure of the activation gate to open. Kv4 channel CSI may efficiently exploit the dynamics of the subthreshold membrane potential to regulate spiking properties in excitable tissues.

Published

2011

6. Circadian regulation of a-type potassium currents in the suprachiasmatic nucleus.

Author

Itri JN, Vosko AM, Schroeder A, Dragich JM, Michel S, and Colwell CS

Subjects

Animals, Feedback, Physiological physiology, Male, Mice, Mice, Inbred C57BL, Circadian Rhythm physiology, Ion Channel Gating physiology, Membrane Potentials physiology, Neurons physiology, Potassium metabolism, Shal Potassium Channels physiology, Suprachiasmatic Nucleus physiology

Abstract

In mammals, the precise circadian timing of many biological processes depends on the generation of oscillations in neural activity of pacemaker cells in the suprachiasmatic nucleus (SCN) of the hypothalamus. Understanding the ionic mechanisms underlying these rhythms is an important goal of research in chronobiology. Previous work has shown that SCN neurons express A-type potassium currents (IAs), but little is known about the properties of this current in the SCN. We sought to characterize some of these properties, including the identities of IA channel subunits found in the SCN and the circadian regulation of IA itself. In this study, we were able to detect significant hybridization for Shal-related family members 1 and 2 (Kv4.1 and 4.2) within the SCN. In addition, we used Western blot to show that the Kv4.1 and 4.2 proteins are expressed in SCN tissue. We further show that the magnitude of the IA current exhibits a diurnal rhythm that peaks during the day in the dorsal region of the mouse SCN. This rhythm seems to be driven by a subset of SCN neurons with a larger peak current and a longer decay constant. Importantly, this rhythm in neurons in the dorsal SCN continues in constant darkness, providing an important demonstration of the circadian regulation of an intrinsic voltage-gated current in mammalian cells. We conclude that the anatomical expression, biophysical properties, and pharmacological profiles measured are all consistent with the SCN IA current being generated by Kv4 channels. Additionally, these data suggest a role for IA in the regulation of spontaneous action potential firing during the transitions between day/night and in the integration of synaptic inputs to SCN neurons throughout the daily cycle.

Published

2010

7. Spike integration and cellular memory in a rhythmic network from Na+/K+ pump current dynamics.

Author

Pulver SR and Griffith LC

Subjects

Analysis of Variance, Animals, Animals, Genetically Modified, Biophysics, Calcium metabolism, Drosophila, Drosophila Proteins genetics, Electric Stimulation methods, Ganglia, Spinal cytology, Gene Expression Regulation genetics, Green Fluorescent Proteins genetics, Ion Channel Gating genetics, Ion Channels genetics, Larva, Locomotion genetics, Locomotion physiology, Models, Neurological, Nonlinear Dynamics, Patch-Clamp Techniques methods, Shal Potassium Channels genetics, Shal Potassium Channels physiology, Sodium-Potassium-Exchanging ATPase genetics, Synaptic Transmission genetics, Synaptic Transmission physiology, Ion Channel Gating physiology, Ion Channels physiology, Motor Neurons physiology, Nerve Net physiology, Periodicity, Sodium-Potassium-Exchanging ATPase physiology

Abstract

The output of a neural circuit results from an interaction between the intrinsic properties of neurons in the circuit and the features of the synaptic connections between them. The plasticity of intrinsic properties has been primarily attributed to modification of ion channel function and/or number. We have found a mechanism for intrinsic plasticity in rhythmically active Drosophila neurons that was not based on changes in ion conductance. Larval motor neurons had a long-lasting, sodium-dependent afterhyperpolarization (AHP) following bursts of action potentials that was mediated by the electrogenic activity of Na(+)/K(+) ATPase. This AHP persisted for multiple seconds following volleys of action potentials and was able to function as a pattern-insensitive integrator of spike number that was independent of external calcium. This current also interacted with endogenous Shal K(+) conductances to modulate spike timing for multiple seconds following rhythmic activity, providing a cellular memory of network activity on a behaviorally relevant timescale.

Published

2010

8. Weighing the evidence for a ternary protein complex mediating A-type K+ currents in neurons.

Author

Maffie J and Rudy B

Subjects

Animals, Humans, Kv Channel-Interacting Proteins chemistry, Kv Channel-Interacting Proteins metabolism, Models, Molecular, Multiprotein Complexes chemistry, Multiprotein Complexes metabolism, Protein Binding, Protein Structure, Tertiary, Shal Potassium Channels chemistry, Shal Potassium Channels metabolism, Ion Channel Gating physiology, Multiprotein Complexes physiology, Neurons physiology, Shal Potassium Channels physiology

Abstract

The subthreshold-operating A-type K(+) current in neurons (I(SA)) has important roles in the regulation of neuronal excitability, the timing of action potential firing and synaptic integration and plasticity. The channels mediating this current (Kv4 channels) have been implicated in epilepsy, the control of dopamine release, and the regulation of pain plasticity. It has been proposed that Kv4 channels in neurons are ternary complexes of three types of protein: pore forming subunits of the Kv4 subfamily and two types of auxiliary subunits, the Ca(2+) binding proteins KChIPs and the dipeptidyl peptidase-like proteins (DPPLs) DPP6 (also known as DPPX) and DPP10 (4 molecules of each per channel for a total of 12 proteins in the complex). Here we consider the evidence supporting this hypothesis. Kv4 channels in many neurons are likely to be ternary complexes of these three types of protein. KChIPs and DPPLs are required to efficiently traffic Kv4 channels to the plasma membrane and regulate the functional properties of the channels. These proteins may also be important in determining the localization of the channels to specific neuronal compartments, their dynamics, and their response to neuromodulators. A surprisingly large number of additional proteins have been shown to modify Kv4 channels in heterologous expression systems, but their association with native Kv4 channels in neurons has not been properly validated. A critical consideration of the evidence suggests that it is unlikely that association of Kv4 channels with these additional proteins is widespread in the CNS. However, we cannot exclude that some of these proteins may associate with the channels transiently or in specific neurons or neuronal compartments, or that they may associate with the channels in other tissues.

Published

2008

9. Modulation of 'A'-type K+ current by rodent and human forms of amyloid beta protein.

Author

Kerrigan TL, Atkinson L, Peers C, and Pearson HA

Subjects

Amyloid beta-Peptides pharmacology, Animals, Cell Line, Cerebellum cytology, Humans, Kidney cytology, Neurons cytology, Neurons drug effects, Patch-Clamp Techniques, Peptide Fragments pharmacology, RNA, Messenger metabolism, Rats, Recombinant Proteins, Shal Potassium Channels genetics, Amyloid beta-Peptides physiology, Ion Channel Gating physiology, Neurons physiology, Peptide Fragments physiology, Potassium physiology, Shal Potassium Channels physiology

Abstract

The Alzheimer's disease related peptide amyloid beta (Abeta) might have a physiological role in upregulating K channel currents in neurones. Earlier studies used the human form of Abeta1-40 on rat neurones. We sought to confirm our hypothesis by use of rat Abeta, which has no Alzheimer's association. In rat cerebellar granule neurones and HEK293 cells expressing Kv4.2 subunits, whole-cell patch clamp of K currents revealed that preincubation of cells with recombinant human or rat Abeta1-40 (10 nM for 24 h) significantly increased K channel current density. This was accompanied by increased mRNA levels for Kv4.2. These data indicate that rodent and human Abeta are effective in modulating K currents. The effectiveness of nonaggregating rat Abeta also strongly supports a physiological role for the peptide.

Published

2008

10. Ternary Kv4.2 channels recapitulate voltage-dependent inactivation kinetics of A-type K+ channels in cerebellar granule neurons.

Author

Amarillo Y, De Santiago-Castillo JA, Dougherty K, Maffie J, Kwon E, Covarrubias M, and Rudy B

Subjects

Animals, Cell Line, Humans, Kinetics, Membrane Potentials physiology, Mice, Cerebellum metabolism, Ion Channel Gating physiology, Neurons metabolism, Shal Potassium Channels physiology

Abstract

Kv4 channels mediate most of the somatodendritic subthreshold operating A-type current (I(SA)) in neurons. This current plays essential roles in the regulation of spike timing, repetitive firing, dendritic integration and plasticity. Neuronal Kv4 channels are thought to be ternary complexes of Kv4 pore-forming subunits and two types of accessory proteins, Kv channel interacting proteins (KChIPs) and the dipeptidyl-peptidase-like proteins (DPPLs) DPPX (DPP6) and DPP10. In heterologous cells, ternary Kv4 channels exhibit inactivation that slows down with increasing depolarization. Here, we compared the voltage dependence of the inactivation rate of channels expressed in heterologous mammalian cells by Kv4.2 proteins with that of channels containing Kv4.2 and KChIP1, Kv4.2 and DPPX-S, or Kv4.2, KChIP1 and DPPX-S, and found that the relation between inactivation rate and membrane potential is distinct for these four conditions. Moreover, recordings from native neurons showed that the inactivation kinetics of the I(SA) in cerebellar granule neurons has voltage dependence that is remarkably similar to that of ternary Kv4 channels containing KChIP1 and DPPX-S proteins in heterologous cells. The fact that this complex and unique behaviour (among A-type K(+) currents) is observed in both the native current and the current expressed in heterologous cells by the ternary complex containing Kv4, DPPX and KChIP proteins supports the hypothesis that somatically recorded native Kv4 channels in neurons include both types of accessory protein. Furthermore, quantitative global kinetic modelling showed that preferential closed-state inactivation and a weakly voltage-dependent opening step can explain the slowing of the inactivation rate with increasing depolarization. Therefore, it is likely that preferential closed-state inactivation is the physiological mechanism that regulates the activity of both ternary Kv4 channel complexes and native I(SA)-mediating channels.

Published

2008

11. Mechanism of the modulation of Kv4:KChIP-1 channels by external K+.

Author

Kaulin YA, De Santiago-Castillo JA, Rocha CA, and Covarrubias M

Subjects

Animals, Cells, Cultured, Computer Simulation, Dose-Response Relationship, Drug, Ion Channel Gating drug effects, Membrane Potentials drug effects, Membrane Potentials physiology, Oocytes drug effects, Shal Potassium Channels drug effects, Xenopus laevis, Ion Channel Gating physiology, Models, Biological, Models, Chemical, Oocytes physiology, Potassium administration & dosage, Shal Potassium Channels chemistry, Shal Potassium Channels physiology

Abstract

In response to a prolonged membrane depolarization, inactivation autoregulates the activity of voltage-gated ion channels. Slow inactivation involving a localized constriction of the selectivity filter (P/C-type mechanism) is prevalent in many voltage-gated K(+) channels of the Kv1 subfamily. However, the generalization of this mechanism to other Kv channel subfamilies has remained uncertain and controversial. In agreement with a "foot-in-the-door" mechanism and the presence of ion-ion interactions in the pore, elevated external K(+) slows the development of P/C-type inactivation and accelerates its recovery. In sharp contrast and resembling the regulation of the hippocampal A-type K(+) current, we found that Kv4.x channels associated with KChIP-1 (an auxiliary subunit) exhibit accelerated inactivation and unaffected recovery from inactivation when exposed to elevated external K(+). This regulation depends on the ability of a permeant ion to enter the selectivity filter (K(+) = Rb(+) = NH4(+) > Cs(+) > Na(+)); and the apparent equilibrium dissociation constant of a single regulatory site is 8 mM for K(+). By applying a robust quantitative global kinetic modeling approach to all macroscopic properties over a 210-mV range of membrane potentials, we determined that elevated external K(+) inhibits unstable closed states outside the main activation pathway and thereby promotes preferential closed-state inactivation. These results suggest the presence of a vestigial and unstable P/C-type mechanism of inactivation in Kv4 channels and strengthen the concept of novel mechanisms of closed-state inactivation. Regulation of Kv4 channel inactivation by hyperkalemia may help to explain the pathophysiology of electrolyte imbalances in excitable tissues.

Published

2008

12. Role of N-terminal domain and accessory subunits in controlling deactivation-inactivation coupling of Kv4.2 channels.

Author

Barghaan J, Tozakidou M, Ehmke H, and Bähring R

Subjects

Cell Line, Computer Simulation, Humans, Membrane Potentials physiology, Protein Conformation, Protein Subunits, Shal Potassium Channels ultrastructure, Structure-Activity Relationship, Ion Channel Gating physiology, Kidney physiology, Models, Biological, Models, Chemical, Shal Potassium Channels chemistry, Shal Potassium Channels physiology

Abstract

We examined the relationship between deactivation and inactivation in Kv4.2 channels. In particular, we were interested in the role of a Kv4.2 N-terminal domain and accessory subunits in controlling macroscopic gating kinetics and asked if the effects of N-terminal deletion and accessory subunit coexpression conform to a kinetic coupling of deactivation and inactivation. We expressed Kv4.2 wild-type channels and N-terminal deletion mutants in the absence and presence of Kv channel interacting proteins (KChIPs) and dipeptidyl aminopeptidase-like proteins (DPPs) in human embryonic kidney 293 cells. Kv4.2-mediated A-type currents at positive and deactivation tail currents at negative membrane potentials were recorded under whole-cell voltage-clamp and analyzed by multi-exponential fitting. The observed changes in Kv4.2 macroscopic inactivation kinetics caused by N-terminal deletion, accessory subunit coexpression, or a combination of the two maneuvers were compared with respective changes in deactivation kinetics. Extensive correlation analyses indicated that modulatory effects on deactivation closely parallel respective effects on inactivation, including both onset and recovery kinetics. Searching for the structural determinants, which control deactivation and inactivation, we found that in a Kv4.2 Delta 2-10 N-terminal deletion mutant both the initial rapid phase of macroscopic inactivation and tail current deactivation were slowed. On the other hand, the intermediate and slow phase of A-type current decay, recovery from inactivation, and tail current decay kinetics were accelerated in Kv4.2 Delta 2-10 by KChIP2 and DPPX. Thus, a Kv4.2 N-terminal domain, which may control both inactivation and deactivation, is not necessary for active modulation of current kinetics by accessory subunits. Our results further suggest distinct mechanisms for Kv4.2 gating modulation by KChIPs and DPPs.

Published

2008

13. Non-native R1 substitution in the s4 domain uniquely alters Kv4.3 channel gating.

Author

Skerritt MR and Campbell DL

Subjects

Amino Acid Sequence, Animals, Biochemistry methods, Electrophysiology methods, Ferrets, Kinetics, Molecular Sequence Data, Mutagenesis, Mutation, Oocytes metabolism, Phenotype, Protein Structure, Tertiary, Shal Potassium Channels chemistry, Xenopus laevis, Ion Channel Gating, Shal Potassium Channels physiology

Abstract

The S4 transmembrane domain in Shaker (Kv1) voltage-sensitive potassium channels has four basic residues (R1-R4) that are responsible for carrying the majority of gating charge. In Kv4 channels, however, R1 is replaced by a neutral valine at position 287. Among other differences, Kv4 channels display prominent closed state inactivation, a mechanism which is minimal in Shaker. To determine if the absence of R1 is responsible for important variation in gating characteristics between the two channel types, we introduced the V287R mutant into Kv4.3 and analyzed its effects on several voltage sensitive gating transitions. We found that the mutant increased the voltage sensitivity of steady-state activation and altered the kinetics of activation and deactivation processes. Although the kinetics of macroscopic inactivation were minimally affected, the characteristics of closed-state inactivation and recovery from open and closed inactivated states were significantly altered. The absence of R1 can only partially account for differences in the effective voltage sensitivity of gating between Shaker and Kv4.3. These results suggest that the S4 domain serves an important functional role in Kv4 channel activation and deactivation processes, and also those of closed-state inactivation and recovery.

Published

2008

14. The aromatic cluster in KCHIP1b affects Kv4 inactivation gating.

Author

Van Hoorick D, Raes A, and Snyders DJ

Subjects

Alternative Splicing physiology, Amino Acid Substitution physiology, Amino Acids, Aromatic chemistry, Amino Acids, Aromatic genetics, Animals, Computer Simulation, Exons genetics, Kv Channel-Interacting Proteins chemistry, Membrane Potentials physiology, Mice, Models, Chemical, Phenotype, Transfection, Ion Channel Gating physiology, Kv Channel-Interacting Proteins genetics, Kv Channel-Interacting Proteins physiology, Shal Potassium Channels physiology

Abstract

The KChIP1b splice variant has been shown to induce slow recovery from inactivation for Kv4.2 whereas KChIP1a enhanced the recovery. Both splice variants differ only by the insertion of the exon1b, rich in aromatic residues (5/11). We analysed in detail the modifications of Kv4.2 gating induced by the KChIP1b splice variant and the role for the aromatic cluster in KChIP1b in inducing these changes. By substituting alanine for the aromatic residues individually or in combination, we could convert the KChIP1b recovery behaviour into that of KChIP1a. The replacement of one or two aromatic residues resulted in a partial restitution of the KChIP1a recovery behaviour. When three aromatic residues were replaced in the exon1b, the recovery from inactivation was fast with time constants that were similar to those obtained with KChIP1a. Moreover, similar findings were observed for closed state inactivation and for the voltage dependence of inactivation. Thus, reduction of the side chain bulkiness in exon1b resulted in the conversion of the KChIP1b phenotype into the KChIP1a phenotype. These results indicate that the aromatic cluster in exon1b modulates the transitions towards and from the closed inactivated states and the steady state distribution over the respective states.

Published

2007

15. Role of S4 positively charged residues in the regulation of Kv4.3 inactivation and recovery.

Author

Skerritt MR and Campbell DL

Subjects

Amino Acid Sequence, Animals, Ferrets, Molecular Sequence Data, Mutagenesis, Site-Directed, Oocytes physiology, Patch-Clamp Techniques, Protein Structure, Secondary, Protein Structure, Tertiary, Structure-Activity Relationship, Xenopus laevis, Ion Channel Gating physiology, Shal Potassium Channels chemistry, Shal Potassium Channels physiology

Abstract

The molecular and biophysical mechanisms by which voltage-sensitive K(+) (Kv)4 channels inactivate and recover from inactivation are presently unresolved. There is a general consensus, however, that Shaker-like N- and P/C-type mechanisms are likely not involved. Kv4 channels also display prominent inactivation from preactivated closed states [closed-state inactivation (CSI)], a process that appears to be absent in Shaker channels. As in Shaker channels, voltage sensitivity in Kv4 channels is thought to be conferred by positively charged residues localized to the fourth transmembrane segment (S4) of the voltage-sensing domain. To investigate the role of S4 positive charge in Kv4.3 gating transitions, we analyzed the effects of charge elimination at each positively charged arginine (R) residue by mutation to the uncharged residue alanine (A). We first demonstrated that R290A, R293A, R296A, and R302A mutants each alter basic activation characteristics consistent with positive charge removal. We then found strong evidence that recovery from inactivation is coupled to deactivation, showed that the precise location of the arginine residues within S4 plays an important role in the degree of development of CSI and recovery from CSI, and demonstrated that the development of CSI can be sequentially uncoupled from activation by R296A, specifically. Taken together, these results extend our current understanding of Kv4.3 gating transitions.

Published

2007

16. W-7 modulates Kv4.3: pore block and Ca2+-calmodulin inhibition.

Author

Qu YJ, Bondarenko VE, Xie C, Wang S, Awayda MS, Strauss HC, and Morales MJ

Subjects

Animals, Cell Membrane Permeability drug effects, Cell Membrane Permeability physiology, Cells, Cultured, Ion Channel Gating drug effects, Oocytes drug effects, Porosity drug effects, Shal Potassium Channels drug effects, Xenopus laevis, Benzylamines administration & dosage, Calcium-Calmodulin-Dependent Protein Kinases antagonists & inhibitors, Ion Channel Gating physiology, Oocytes physiology, Potassium metabolism, Shal Potassium Channels physiology, Sulfonamides administration & dosage

Abstract

Ca(+)-calmodulin (Ca(2+)-CaM)-dependent protein kinase II (Ca(2+)/CaMKII) is an important regulator of cardiac ion channels, and its inhibition may be an approach for treatment of ventricular arrhythmias. Using the two-electrode voltage-clamp technique, we investigated the role of W-7, an inhibitor of Ca(2+)-occupied CaM, and KN-93, an inhibitor of Ca(2+)/CaMKII, on the K(v)4.3 channel in Xenopus laevis oocytes. W-7 caused a voltage- and concentration-dependent decrease in peak current, with IC(50) of 92.4 muM. The block was voltage dependent, with an effective electrical distance of 0.18 +/- 0.05, and use dependence was observed, suggesting that a component of W-7 inhibition of K(v)4.3 current was due to open-channel block. W-7 made recovery from open-state inactivation a biexponential process, also suggesting open-channel block. We compared the effects of W-7 with those of KN-93 after washout of 500 muM BAPTA-AM. KN-93 reduced peak current without evidence of voltage or use dependence. Both W-7 and KN-93 accelerated all components of inactivation. We used wild-type and mutated K(v)4.3 channels with mutant CaMKII consensus phosphorylation sites to examine the effects of W-7 and KN-93. In contrast to W-7, KN-93 at 35 muM selectively accelerated open-state inactivation in the wild-type vs. the mutant channel. W-7 had a significantly greater effect on recovery from inactivation in wild-type than in mutant channels. We conclude that, at certain concentrations, KN-93 selectively inhibits Ca(2+)/CaMKII activity in Xenopus oocytes and that the effects of W-7 are mediated by direct interaction with the channel pore and inhibition of Ca(2+)-CaM, as well as a change in activity of Ca(2+)-CaM-dependent enzymes, including Ca(2+)/CaMKII.

Published

2007

17. A dipeptidyl aminopeptidase-like protein remodels gating charge dynamics in Kv4.2 channels.

Author

Dougherty K and Covarrubias M

Subjects

Animals, Charybdotoxin pharmacology, Membrane Potentials drug effects, Oocytes, Xenopus, Dipeptidyl-Peptidases and Tripeptidyl-Peptidases physiology, Ion Channel Gating drug effects, Shal Potassium Channels physiology

Abstract

Dipeptidyl aminopeptidase-like proteins (DPLPs) interact with Kv4 channels and thereby induce a profound remodeling of activation and inactivation gating. DPLPs are constitutive components of the neuronal Kv4 channel complex, and recent observations have suggested the critical functional role of the single transmembrane segment of these proteins (Zagha, E., A. Ozaita, S.Y. Chang, M.S. Nadal, U. Lin, M.J. Saganich, T. McCormack, K.O. Akinsanya, S.Y. Qi, and B. Rudy. 2005. J. Biol. Chem. 280:18853-18861). However, the underlying mechanism of action is unknown. We hypothesized that a unique interaction between the Kv4.2 channel and a DPLP found in brain (DPPX-S) may remodel the channel's voltage-sensing domain. To test this hypothesis, we implemented a robust experimental system to measure Kv4.2 gating currents and study gating charge dynamics in the absence and presence of DPPX-S. The results demonstrated that coexpression of Kv4.2 and DPPX-S causes a -26 mV parallel shift in the gating charge-voltage (Q-V) relationship. This shift is associated with faster outward movements of the gating charge over a broad range of relevant membrane potentials and accelerated gating charge return upon repolarization. In sharp contrast, DPPX-S had no effect on gating charge movements of the Shaker B Kv channel. We propose that DPPX-S destabilizes resting and intermediate states in the voltage-dependent activation pathway, which promotes the outward gating charge movement. The remodeling of gating charge dynamics may involve specific protein-protein interactions of the DPPX-S's transmembrane segment with the voltage-sensing and pore domains of the Kv4.2 channel. This mechanism may determine the characteristic fast operation of neuronal Kv4 channels in the subthreshold range of membrane potentials.

Published

2006

18. KChIP2b modulates the affinity and use-dependent block of Kv4.3 by nifedipine.

Author

Bett GC, Morales MJ, Strauss HC, and Rasmusson RL

Subjects

Animals, Binding Sites, Calcium Channel Blockers pharmacology, Cells, Cultured, Kv Channel-Interacting Proteins drug effects, Membrane Potentials drug effects, Membrane Potentials physiology, Oocytes drug effects, Protein Binding, Shal Potassium Channels drug effects, Xenopus laevis, Ion Channel Gating physiology, Kv Channel-Interacting Proteins physiology, Nifedipine pharmacology, Oocytes physiology, Shal Potassium Channels antagonists & inhibitors, Shal Potassium Channels physiology

Abstract

Rapidly activating Kv4 voltage-gated ion channels are found in heart, brain, and diverse other tissues including colon and uterus. Kv4.3 can co-assemble with KChIP ancillary subunits, which modify kinetic behavior. We examined the affinity and use dependence of nifedipine block on Kv4.3 and its modulation by KChIP2b. Nifedipine (150 microM) reduced peak Kv4.3 current approximately 50%, but Kv4.3/KChIP2b current only approximately 27%. Nifedipine produced a very rapid component of open channel block in both Kv4.3 and Kv4.3/KChIP2b. However, recovery from the blocked/inactivated state was strongly sensitive to KChIP2b. Kv4.3 Thalf,recovery was slowed significantly by nifedipine (120.0+/-12.4 ms vs. 213.1+/-18.2 ms), whereas KChIP2b eliminated nifedipine's effect on recovery: Kv4.3/KChIP2b Thalf,recovery was 45.3+/-7.2 ms (control) and 47.8+/-8.2 ms (nifedipine). Consequently, Kv4.3 exhibited use-dependent nifedipine block in response to a series of depolarizing pulses which was abolished by KChIP2b. KChIPs alter drug affinity and use dependence of Kv4.3.

Published

2006

19. Kv4 potassium channel subunits control action potential repolarization and frequency-dependent broadening in rat hippocampal CA1 pyramidal neurones.

Author

Kim J, Wei DS, and Hoffman DA

Subjects

Animals, Cells, Cultured, Neuronal Plasticity physiology, Protein Subunits, Rats, Rats, Sprague-Dawley, Action Potentials physiology, Calcium Signaling physiology, Dendrites physiology, Hippocampus physiology, Ion Channel Gating physiology, Pyramidal Cells physiology, Shal Potassium Channels physiology

Abstract

A-type potassium channels regulate neuronal firing frequency and the back-propagation of action potentials (APs) into dendrites of hippocampal CA1 pyramidal neurones. Recent molecular cloning studies have found several families of voltage-gated K(+) channel genes expressed in the mammalian brain. At present, information regarding the relationship between the protein products of these genes and the various neuronal functions performed by voltage-gated K(+) channels is lacking. Here we used a combination of molecular, electrophysiological and imaging techniques to show that one such gene, Kv4.2, controls AP half-width, frequency-dependent AP broadening and dendritic action potential propagation. Using a modified Sindbis virus, we expressed either the enhanced green fluorescence protein (EGFP)-tagged Kv4.2 or an EGFP-tagged dominant negative mutant of Kv4.2 (Kv4.2g(W362F)) in CA1 pyramidal neurones of organotypic slice cultures. Neurones expressing Kv4.2g(W362F) displayed broader action potentials with an increase in frequency-dependent AP broadening during a train compared with control neurones. In addition, Ca(2)(+) imaging of Kv4.2g(W362F) expressing dendrites revealed enhanced AP back-propagation compared to control neurones. Conversely, neurones expressing an increased A-type current through overexpression of Kv4.2 displayed narrower APs with less frequency dependent broadening and decreased dendritic propagation. These results point to Kv4.2 as the major contributor to the A-current in hippocampal CA1 neurones and suggest a prominent role for Kv4.2 in regulating AP shape and dendritic signalling. As Ca(2)(+) influx occurs primarily during AP repolarization, Kv4.2 activity can regulate cellular processes involving Ca(2)(+)-dependent second messenger cascades such as gene expression and synaptic plasticity.

Published

2005

20. Transient outward potassium current, 'Ito', phenotypes in the mammalian left ventricle: underlying molecular, cellular and biophysical mechanisms.

Author

Patel SP and Campbell DL

Subjects

Animals, Biophysics methods, Cell Membrane chemistry, Cell Membrane physiology, Humans, Mammals, Models, Biological, Molecular Biology methods, Phenotype, Shal Potassium Channels classification, Heart Ventricles chemistry, Ion Channel Gating physiology, Potassium chemistry, Potassium metabolism, Shal Potassium Channels chemistry, Shal Potassium Channels physiology, Ventricular Function

Abstract

At least two functionally distinct transient outward K(+) current (I(to)) phenotypes can exist across the free wall of the left ventricle (LV). Based upon their voltage-dependent kinetics of recovery from inactivation, these two phenotypes are designated 'I(to,fast)' (recovery time constants on the order of tens of milliseconds) and 'I(to,slow)' (recovery time constants on the order of thousands of milliseconds). Depending upon species, either I(to,fast), I(to,slow) or both current phenotypes may be expressed in the LV free wall. The expression gradients of these two I(to) phenotypes across the LV free wall are typically heterogeneous and, depending upon species, may consist of functional phenotypic gradients of both I(to,fast) and I(to,slow) and/or density gradients of either phenotype. We review the present evidence (molecular, biophysical, electrophysiological and pharmacological) for Kv4.2/4.3 alpha subunits underlying LV I(to,fast) and Kv1.4 alpha subunits underlying LV I(to,slow) and speculate upon the potential roles of each of these currents in determining frequency-dependent action potential characteristics of LV subepicardial versus subendocardial myocytes in different species. We also review the possible functional implications of (i) ancillary subunits that regulate Kv1.4 and Kv4.2/4.3 (Kvbeta subunits, DPPs), (ii) KChIP2 isoforms, (iii) spider toxin-mediated block of Kv4.2/4.3 (Heteropoda toxins, phrixotoxins), and (iv) potential mechanisms of modulation of I(to,fast) and I(to,slow) by cellular redox state, [Ca(2)(+)](i) and kinase-mediated phosphorylation. I(to) phenotypic activation and state-dependent gating models and molecular structure-function relationships are also discussed.

Published

2005

21. Multiprotein assembly of Kv4.2, KChIP3 and DPP10 produces ternary channel complexes with ISA-like properties.

Author

Jerng HH, Kunjilwar K, and Pfaffinger PJ

Subjects

Animals, CHO Cells, Cells, Cultured, Cricetinae, Cricetulus, Dipeptidyl-Peptidases and Tripeptidyl-Peptidases chemistry, Kv Channel-Interacting Proteins chemistry, Membrane Potentials physiology, Multiprotein Complexes chemistry, Multiprotein Complexes metabolism, Rats, Shal Potassium Channels chemistry, Xenopus laevis, Dipeptidyl-Peptidases and Tripeptidyl-Peptidases physiology, Ion Channel Gating physiology, Kv Channel-Interacting Proteins physiology, Oocytes physiology, Potassium metabolism, Shal Potassium Channels physiology

Abstract

Kv4 pore-forming subunits are the principal constituents of the voltage-gated K+ channel underlying somatodendritic subthreshold A-type currents (I(SA)) in neurones. Two structurally distinct types of Kv4 channel modulators, Kv channel-interacting proteins (KChIPs) and dipeptidyl-peptidase-like proteins (DPLs: DPP6 or DPPX, DPP10 or DPPY), enhance surface expression and modify functional properties. Since KChIP and DPL distributions overlap in the brain, we investigated the potential coassembly of Kv4.2, KChIP3 and DPL proteins, and the contribution of DPLs to ternary complex properties. Immunoprecipitation results show that KChIP3 and DPP10 associate simultaneously with Kv4.2 proteins in rat brain as well as heterologously expressing Xenopus oocytes, indicating Kv4.2 + KChIP3 + DPP10 multiprotein complexes. Consistent with ternary complex formation, coexpression of Kv4.2, KChIP3 and DPP10 in oocytes and CHO cells results in current waveforms distinct from the arithmetic sum of Kv4.2 + KChIP3 and Kv4.2 + DPP10 currents. Furthermore, the Kv4.2 + KChIP3 + DPP10 channels recover from inactivation very rapidly (tau(rec) approximately 18-26 ms), closely matching that of native I(SA) and significantly faster than the recovery of Kv4.2 + KChIP3 or Kv4.2 + DPP10 channels. For comparison, identical triple coexpression experiments were performed using DPP6 variants. While most results are similar, the Kv4.2 + KChIP3 + DPP6 channels exhibit inactivation that slows with increasing membrane potential, resulting in inactivation slower than that of Kv4.2 + KChIP3 + DPP10 channels at positive voltages. In conclusion, the native neuronal subthreshold A-type channel is probably a macromolecular complex formed from Kv4 and a combination of both KChIP and DPL proteins, with the precise composition of channel alpha and auxiliary subunits underlying tissue and regional variability in I(SA) properties.

Published

2005

22. Transient outward K+ currents in rat dissociated subfornical organ neurones and angiotensin II effects.

Author

Ono K, Toyono T, Honda E, and Inenaga K

Subjects

Animals, Cells, Cultured, Dose-Response Relationship, Drug, Ion Channel Gating drug effects, Male, Neurons drug effects, Rats, Rats, Wistar, Shal Potassium Channels drug effects, Subfornical Organ drug effects, Angiotensin II pharmacology, Ion Channel Gating physiology, Neurons physiology, Potassium metabolism, Shal Potassium Channels physiology, Subfornical Organ physiology

Abstract

Although angiotensin II inhibits transient outward K+ currents (I(A)s) in subfornical organ neurones, there is no evidence concerning which Kv channels are involved. We investigated I(A)-generating Kv channels in dissociated rat subfornical organ neurones, using molecular, electrophysiological and pharmacological techniques, and studied the effects of angiotensin II. Conventional RT-PCR showed the presence of mRNAs for channels of the Kv3.4, Kv1.4 and Kv4 families, which are capable of generating I(A)s. Tetraethylammonium at 1 mm, which blocks Kv3 channel-derived currents, and blood-depressing substance-I, a Kv3.4-specific blocker, at 2 microm suppressed the I(A)-like component of whole-cell outward currents in some neurones. 4-Aminopyridine at 5 mm inhibited I(A)s in the presence of tetraethylammonium at 1 mm. Cd2+ at 300 microm shifted the activation and inactivation curves of the 4-aminopyridine-sensitive and tetraethylammonium-resistant I(A)s positively. The tetraethylammonium-resistant I(A)s showed fast and slow components during the process of recovery from inactivation, but the slow component was not seen in all neurones. The time constant of the fast recovery component was less than 200 ms, while that of the slow recovery component was around 1 s. Using single-cell RT-PCR, mRNAs for Kv4.2 and Kv4.3L were detected frequently, but those for Kv1.4 and Kv3.4 were seen only rarely. Angiotensin II at 30 nm inhibited the fast recovery component of tetraethylammonium-resistant I(A)s in many neurones. These results suggest that the fast recovery component of the tetraethylammonium-resistant I(A) in subfornical organ neurones depends upon Kv4, and that it can be modulated by angiotensin II.

Published

2005