The Kv4.2 mediates excitatory activity-dependent regulation of neuronal excitability in rat cortical neurons

Neuronal excitability can cooperate with synaptic transmission to control the information storage. This regulation of neuronal plasticity can be affected by alterations in neuronal inputs and accomplished by modulation of voltage-dependent ion channels. In this study, we report that enhanced excitatory input negatively regulated neuronal excitability. Enhanced excitatory input by glutamate, electric field stimulation or high K⁺ increased transient outward K⁺ current, whereas did not affect the delayed rectifier K⁺ current in rat cultured cortical neurons. Both the voltage-dependent K⁺ channel 4.2 and 4.3 subunits contributed to the increase. The increase in the K⁺ current density by Kv4.2 was ascribed to its cytoplasmic membrane translocation, which was mediated by NMDA type of glutamate receptor. Furthermore, enhanced excitatory input inhibited neuronal excitability. Taken together, our results suggest that excitatory neurotransmission affects neuronal excitability via the regulation of the K⁺ channel membrane translocation.     

Adult alveolar epithelial cells express multiple subtypes of voltage-gated K+ channels that are located in apical membrane

Whole cell perforated patch-clampexperiments were performed with adult rat alveolar epithelial cells.The holding potential was 60 mV, and depolarizing voltage stepsactivated voltage-gated K⁺ (Kv) channels. Thevoltage-activated currents exhibited a mean reversal potential of 32mV. Complete activation was achieved at 10 mV. The currents exhibitedslow inactivation, with significant variability in the time coursebetween cells. Tail current analysis revealed cell-to-cell variabilityin K⁺ selectivity, suggesting contributions of multiple Kv-subunits to the whole cell current. The Kv channels also displayedsteady-state inactivation when the membrane potential was held atdepolarized voltages with a window current between 30 and 5 mV.Analysis of RNA isolated from these cells by RT-PCR revealed thepresence of eight Kv -subunits (Kv1.1, Kv1.3, Kv1.4, Kv2.2, Kv4.1,Kv4.2, Kv4.3, and Kv9.3), three -subunits (Kv1.1, Kv2.1, andKv3.1), and two K⁺ channel interacting protein (KChIP)isoforms (KChIP2 and KChIP3). Western blot analysis with available Kv-subunit antibodies (Kv1.1, Kv1.3, Kv1.4, Kv4.2, and Kv4.3) showedlabeling of 50-kDa proteins from alveolar epithelial cells grown inmonolayer culture. Immunocytochemical analysis of cells from monolayersshowed that Kv1.1, Kv1.3, Kv1.4, Kv4.2, and Kv4.3 were localized to theapical membrane. We conclude that expression of multiple Kv -, -,and KChIP subunits explains the variability in inactivation gating andK⁺ selectivity observed between cells and that Kv channelsin the apical membrane may contribute to basal K⁺ secretionacross the alveolar epithelium.

     

Mossy fibre contact triggers the targeting of Kv4.2 potassium channels to dendrites and synapses in developing cerebellar granule neurons

Compartmentalization of neuronal function is achieved by highly localized clustering of ion channels in discrete subcellular membrane domains. Voltage-gated potassium (Kv) channels exhibit highly variable cellular and subcellular patterns of expression. Here, we describe novel activity-dependent synaptic targeting of Kv4.2, a dendritic Kv channel, in cerebellar granule cells (GCs). In vivo, Kv4.2 channels are highly expressed in cerebellar glomeruli, specializations of GC dendrites that form synapses with mossy fibres. In contrast, in cultured GCs, Kv4.2 was found localized, not to dendrites but to cell bodies. To investigate the role of synaptic contacts, we developed a co-culture system with cells from pontine grey nucleus, the origin of mossy fibres. In these co-cultures, synaptic structures formed, and Kv4.2 was now targeted to these synaptic sites in a manner dependent on synaptic activity. Activation of NMDA- and/or AMPA-type glutamate receptors was necessary for the targeting of Kv4.2 in co-cultures, and activation of these receptor systems in GC monocultures induced dendritic targeting of Kv4.2 in the absence of synapse formation. These results indicate that the proper targeting of Kv4.2 channels is dynamically regulated by synaptic activity. This activity-dependent regulation of Kv4.2 localization provides a crucial yet dynamic link between synaptic activity and dendritic excitability.     

Modulation of potassium channel gating by coexpression of Kv2.1 with regulatory Kv5.1 or Kv6.1 alpha -subunits

We havedetermined the effects of coexpression of Kv2.1 with electricallysilent Kv5.1 or Kv6.1 -subunits inXenopus oocytes on channel gating.Kv2.1/5.1 selectively accelerated the rate of inactivation atintermediate potentials (30 to 0 mV), without affecting the rateat strong depolarization (0 to +40 mV), and markedly accelerated therate of cumulative inactivation evoked by high-frequency trains ofshort pulses. Kv5.1 coexpression also slowed deactivation of Kv2.1. Incontrast, Kv6.1 was much less effective in speeding inactivation atintermediate potentials, had a slowing effect on inactivation at strongdepolarizations, and had no effect on cumulative inactivation. Kv6.1,however, had profound effects on activation, including a negative shift of the steady-state activation curve and marked slowing of deactivation tail currents. Support for the notion that the Kv5.1's effects stemfrom coassembly of -subunits into heteromeric channels was obtainedfrom biochemical evidence of protein-protein interaction andsingle-channel measurements that showed heterogeneity in unitary conductance. Our results show that Kv5.1 and Kv6.1 function as regulatory -subunits that when coassembled with Kv2.1 can modulate gating in a physiologically relevant manner.

     

Augmentation of Kv4.2-encoded currents by accessory dipeptidyl peptidase 6 and 10 subunits reflects selective cell surface Kv4.2 protein stabilization

Rapidly activating and inactivating somatodendritic voltage-gated K(+) (Kv) currents, I(A), play critical roles in the regulation of neuronal excitability. Considerable evidence suggests that native neuronal I(A) channels function in macromolecular protein complexes comprising pore-forming (α) subunits of the Kv4 subfamily together with cytosolic, K(+) channel interacting proteins (KChIPs) and transmembrane, dipeptidyl peptidase 6 and 10 (DPP6/10) accessory subunits, as well as other accessory and regulatory proteins. Several recent studies have demonstrated a critical role for the KChIP subunits in the generation of native Kv4.2-encoded channels and that Kv4.2-KChIP complex formation results in mutual (Kv4.2-KChIP) protein stabilization. The results of the experiments here, however, demonstrate that expression of DPP6 in the mouse cortex is unaffected by the targeted deletion of Kv4.2 and/or Kv4.3. Further experiments revealed that heterologously expressed DPP6 and DPP10 localize to the cell surface in the absence of Kv4.2, and that co-expression with Kv4.2 does not affect total or cell surface DPP6 or DPP10 protein levels. In the presence of DPP6 or DPP10, however, cell surface Kv4.2 protein expression is selectively increased. Further addition of KChIP3 in the presence of DPP10 markedly increases total and cell surface Kv4.2 protein levels, compared with cells expressing only Kv4.2 and DPP10. Taken together, the results presented here demonstrate that the expression and localization of the DPP accessory subunits are independent of Kv4 α subunits and further that the DPP6/10 and KChIP accessory subunits independently stabilize the surface expression of Kv4.2.     

Modulation by Clamping: Kv4 and KChIP Interactions

The rapidly inactivating (A-type) potassium channels regulate membrane excitability that defines the fundamental mechanism of neuronal functions such as pain signaling. Cytosolic Kv channel-interacting proteins KChIPs that belong to neuronal calcium sensor (NCS) family of calcium binding EF-hand proteins co-assemble with Kv4 (Shal) α subunits to form a native complex that encodes major components of neuronal somatodendritic A-type K⁺ current, I_SA, in neurons and transient outward current, I_TO, in cardiac myocytes. The specific binding of auxiliary KChIPs to the Kv4 N-terminus results in modulation of gating properties, surface expression and subunit assembly of Kv4 channels. Here, I attempt to emphasize the interaction between KChIPs and Kv4 based on recent progress made in understanding the structure complex in which a single KChIP1 molecule laterally clamps two neighboring Kv4.3 N-termini in a 4:4 manner. Greater insights into molecular mechanism between KChIPs and Kv4 interaction may provide therapeutic potentials of designing compounds aimed at disrupting the protein–protein interaction for treatment of membrane excitability-related disorders. Special issue article in honor of Dr. Ji-Sheng Han.     

Regulation of Kv4.2 channels by glutamate in cultured hippocampal neurons

Somatodendritic voltage-dependent K⁺ currents (Kv4.2) channels mediate transient A-type K⁺ currents and play critical roles in controlling neuronal excitability. Accumulating evidence has indicated that Kv4.2 channels are key regulatory components of the signaling pathways that lead to synaptic plasticity. In contrast to the extensive studies of glutamate-induced AMPA [(±) α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid hydrate] receptors redistribution, less is known about the regulation of Kv4.2 by glutamate. In this study, we report that brief treatment with glutamate rapidly reduced total Kv4.2 levels in cultured hippocampal neurons. The glutamate effect was mimicked by NMDA, but not by AMPA. The effect of glutamate on Kv4.2 was dramatically attenuated by pre-treatment of NMDA receptors antagonist MK-801 [(5 S ,10 R )-(+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine hydrogen maleate] or removal of extracellular Ca²⁺. Immunocytochemical analysis showed a loss of Kv4.2 clusters on the neuronal soma and dendrites following glutamate treatment, which was also dependent on the activation of NMDA receptors and the influx of Ca²⁺. Furthermore, whole-cell patch-clamp recordings revealed that glutamate caused a hyperpolarized shift in the inactivation curve of A-type K⁺ currents, while the activation curve remained unchanged. These results demonstrate a glutamate-induced alteration of Kv4.2 channels in cultured hippocampal neurons, which might be involved in activity-dependent changes of neuronal excitability and synaptic plasticity.     

Direct inhibition of the cloned Kv1.5 channel by AG-1478, a tyrosine kinase inhibitor

The action of tyrphostin AG-1478, a potentprotein tyrosine kinase (PTK) inhibitor, on rat brain Kv1.5 channels(Kv1.5) stably expressed in Chinese hamster ovary cells wasinvestigated using the whole cell patch-clamp technique. AG-1478rapidly and reversibly inhibited Kv1.5 currents at 50 mV in aconcentration-dependent manner with an IC₅₀ of 9.82 µM.AG-1478 accelerated the decay rate of inactivation of Kv1.5 currentswithout modifying the kinetics of current activation. Pretreatment withthe structurally dissimilar PTK inhibitors (genistein and lavendustinA) had no effect on the AG-1478-induced inhibition of Kv1.5 and did notmodify the AG-1478-induced current kinetics. The rate constants forbinding and unbinding of AG-1478 were 1.46 µM¹ · s¹ and 10.19 s¹, respectively. The AG-1478-induced inhibition of Kv1.5channels was voltage dependent, with a steep increase over the voltage range of channel opening. However, the inhibition exhibited voltage independence over the voltage range in which channels are fully activated. AG-1478 produced no significant effect on the steady-state activation or inactivation curves. AG-1478 slowed the deactivation timecourse, resulting in a tail crossover phenomenon. Inhibition of Kv1.5by AG-1478 was use dependent. The present results suggest that AG-1478acts directly on Kv1.5 currents as an open-channel blocker andindependently of the effects of AG-1478 on PTK activity.

     

Differential regulation of voltage-gated K+ channels by oxidized and reduced pyridine nucleotide coenzymes

The activity of the voltage-sensitive K⁺ (Kv) channels varies as a function of the intracellular redox state and metabolism, and several Kv channels act as oxygen sensors. However, the mechanisms underlying the metabolic and redox regulation of these channels remain unclear. In this study we investigated the regulation of Kv channels by pyridine nucleotides. Heterologous expression of Kv1.5 in COS-7 cells led to the appearance of noninactivating currents. Inclusion of 0.1–1 mM NAD⁺ or 0.03–0.5 mM NADP⁺ in the internal solution of the patch pipette did not affect Kv currents. However, 0.5 and 1 mM NAD⁺ and 0.1 and 0.5 mM NADP⁺ prevented inactivation of Kv currents in cells transfected with Kv1.5 and Kv1.3 and shifted the voltage dependence of activation to depolarized potentials. The Kv-dependent inactivation of Kv currents was also decreased by internal pipette perfusion of the cell with 1 mM NAD⁺. The Kv1.5-Kv1.3 currents were unaffected by the internal application of 0.1 mM NADPH or 0.1 or 1 mM NADH. Excised inside-out patches from cells expressing Kv1.5-Kv1.3 showed transient single-channel activity. The mean open time and the open probability of these currents were increased by the inclusion of 1 mM NAD⁺ in the perfusate. These results suggest that NAD(P)⁺ prevents Kv-mediated inactivation of Kv currents and provide a novel mechanism by which pyridine nucleotides could regulate specific K⁺ currents as a function of the cellular redox state [NAD(P)H-to-NAD(P)⁺ ratio]. Shaker potassium ion channels; Kv subunits; patch clamp; aldo-keto reductase; COS-7 cells     

Functional stoichiometry underlying KChIP regulation of Kv4.2 functional expression

K channel‐interacting proteins (KChIPs) enhance functional expression of Kv4 channels by binding to an N‐terminal regulatory region located in the first 40 amino acids of Kv4.2 that we call the functional expression regulating N‐terminal (FERN) domain. Mutating two residues in the FERN domain to alanines, W8A and F11A, disrupts KChIP binding and regulation of Kv4.2 without eliminating the FERN domain's control of basal expression level or regulation by DPP6. When Kv4.2(W8A,F11A) is co‐expressed with wild type Kv4.2 and KChIP3 subunits, a dominant negative effect is seen where the current expression is reduced to levels normally seen without KChIP addition. The dominant negative effect correlates with heteromultimeric channels remaining on intracellular membranes despite KChIP binding to non‐mutant Kv4.2 subunits. In contrast, the deletion mutant Kv4.2(Δ1‐40), eliminating both KChIP binding and the FERN domain, has no dominant negative effect even though the maximal conductance level is 5x lower than seen with KChIP3. The 5x increased expression seen with KChIP integration into the channel is fully apparent even when a reduced number of KChIP subunits are incorporated as long as all FERN domains are bound. Our results support the hypothesis that KChIPs enhances Kv4.2 functional expression by a 1 : 1 suppression of the N‐terminal FERN domain and by producing additional positive regulatory effects on functional channel expression.     

Upregulation of Kv1.3 K(+) channels in microglia deactivated by TGF-beta

Microglial activation is accompanied by changes inK⁺ channel expression. Here we demonstrate that adeactivating cytokine changes the electrophysiological properties ofmicroglial cells. Upregulation of delayed rectifier (DR) K⁺channels was observed in microglia after exposure to transforming growth factor- (TGF-) for 24 h. In contrast, inwardrectifier K⁺ channel expression was unchanged by TGF-.DR current density was more than sixfold larger in TGF--treatedmicroglia than in untreated microglia. DR currents of TGF--treatedcells exhibited the following properties: activation at potentials morepositive than 40 mV, half-maximal activation at 27 mV, half-maximalinactivation at 38 mV, time dependent and strongly use-dependentinactivation, and a single channel conductance of 13 pS in Ringersolution. DR channels were highly sensitive to charybdotoxin (CTX) andkaliotoxin (KTX), whereas -dendrotoxin had little effect.With RT-PCR, mRNA for Kv1.3 and Kir2.1 was detected in microglia. Inaccordance with the observed changes in DR current density, the mRNAlevel for Kv1.3 (assessed by competitive RT-PCR) increased fivefold after treatment of microglia with TGF-.

     

Distribution of Kv1-like potassium channels in the electromotor and electrosensory systems of the weakly electric fish Apteronotus leptorhynchus

The electromotor and electrosensory systems of the weakly electric fish Apteronotus leptorhynchus are model systems for studying mechanisms of high-frequency motor pattern generation and sensory processing. Voltage-dependent ionic currents, including low-threshold potassium currents, influence excitability of neurons in these circuits and thereby regulate motor output and sensory filtering. Although Kv1-like potassium channels are likely to carry low-threshold potassium currents in electromotor and electrosensory neurons, the distribution of Kv1 alpha subunits in A. leptorhynchus is unknown. In this study, we used immunohistochemistry with six different antibodies raised against specific mammalian Kv1 alpha subunits (Kv1.1-Kv1.6) to characterize the distribution of Kv1-like channels in electromotor and electrosensory structures. Each Kv1 antibody labeled a distinct subset of neurons, fibers, and/or dendrites in electromotor and electrosensory nuclei. Kv1-like immunoreactivity in the electrosensory lateral line lobe (ELL) and pacemaker nucleus are particularly relevant in light of previous studies suggesting that potassium currents carried by Kv1 channels regulate neuronal excitability in these regions. Immunoreactivity of pyramidal cells in the ELL with several Kv1 antibodies is consistent with Kv1 channels carrying low-threshold outward currents that regulate spike waveform in these cells (Fernandez et al., J Neurosci 2005;25:363-371). Similarly, Kv1-like immunoreactivity in the pacemaker nucleus is consistent with a role of Kv1 channels in spontaneous high-frequency firing in pacemaker neurons. Robust Kv1-like immunoreactivity in several other structures, including the dorsal torus semicircularis, tuberous electroreceptors, and the electric organ, indicates that Kv1 channels are broadly expressed and are likely to contribute significantly to generating the electric organ discharge and processing electrosensory inputs.     

The effects of nesfatin‐1 in the paraventricular nucleus on gastric motility and its potential regulation by the lateral hypothalamic area in rats

The current study investigated the effects of nesfatin‐1 in the hypothalamic paraventricular nucleus (PVN) on gastric motility and the regulation of the lateral hypothalamic area (LHA). Using single unit recordings in the PVN, we show that nesfatin‐1 inhibited the majority of the gastric distention (GD)‐excitatory neurons and excited more than half of the GD‐inhibitory (GD‐I) neurons in the PVN, which were weakened by oxytocin receptor antagonist H4928. Gastric motility experiments showed that administration of nesfatin‐1 in the PVN decreased gastric motility, which was also partly prevented by H4928. The nesfatin‐1 concentration producing a half‐maximal response (EC50) in the PVN was lower than the value in the dorsomedial hypothalamic nucleus, while nesfatin‐1 in the reuniens thalamic nucleus had no effect on gastric motility. Retrograde tracing and immunofluorescent staining showed that nucleobindin‐2/nesfatin‐1 and fluorogold double‐labeled neurons were observed in the LHA. Electrical LHA stimulation changed the firing rate of GD‐responsive neurons in the PVN. Pre‐administration of an anti‐ nucleobindin‐2/nesfatin‐1 antibody in the PVN strengthened gastric motility and decreased the discharging of the GD‐I neurons induced by electrical stimulation of the LHA. These results demonstrate that nesfatin‐1 in the PVN could serve as an inhibitory factor to inhibit gastric motility, which might be regulated by the LHA.

     

CCK-8S activates c-Fos in a dose-dependent manner in nesfatin-1 immunoreactive neurons in the paraventricular nucleus of the hypothalamus and in the nucleus of the solitary tract of the brainstem

Recently, a new neuropeptide, named nesfatin-1, was discovered. It has been reported that nesfatin-1 inhibits food intake after injection into the third ventricle as well as intraperitoneal (ip) injection. Cholecystokinin (CCK) is well established to play a role in the regulation of food intake. The aim of the study was to examine whether CCK-8S injected ip modulates neuronal activity in nesfatin-1 immunoreactive (ir) neurons localized in the PVN and in the nucleus of the solitary tract (NTS). Additionally, tyrosine hydroxylase-immunoreactivity (TH-ir) in the PVN was determined to assess the distribution of TH-ir fibers in relation to nesfatin-1-ir. Non-fasted male Sprague-Dawley rats received 6 or 10 µg CCK-8S/kg or vehicle solution (0.15 M NaCl; n = 4 all groups) ip. The number of c-Fos-ir neurons was determined in the PVN, arcuate nucleus (ARC), and NTS. Double staining procedure for nesfatin-1 and c-Fos revealed that CCK-8S increased significantly and in a dose-dependent manner the number of c-Fos positive nesfatin-1-ir neurons in the PVN ( 4-fold and 7-fold) and NTS ( 9-fold and 26-fold). Triple staining in the PVN showed a dose-dependent neuronal activation of nesfatin-1 neurons that were colocalized with CRF and oxytocin. Double labeling against nesfatin-1 and TH revealed that nefatin-1-ir neurons were encircled in a network of TH-ir fibers in the PVN. No effect on the number of c-Fos-ir neurons was observed in the ARC. These results suggest that the effects of CCK on the HPA axis and on food intake may, at least in part, be mediated by nesfatin-1-ir neurons in the PVN.     

Comparative genetic analysis of PP2A-Cdc55 regulators in budding yeast

Cdc55, a regulatory B subunit of the protein phosphatase 2A (PP2A) complex, plays various functions during mitosis. Sequestration of Cdc55 from the nucleus by Zds1 and Zds2 is important for robust activation of mitotic Cdk1 and mitotic progression in budding yeast. However, Zds1-family proteins are found only in fungi but not in higher eukaryotes. In animal cells, highly conserved ENSA/ARPP-19 family proteins bind and inhibit PP2A–B55 activity for mitotic entry.

In this study, we compared the relative contribution of Zds1/Zds2 and ENSA-family proteins Igo1/Igo2 on Cdc55 functions in budding yeast mitosis. We confirmed that Igo1/Igo2 can inhibit Cdc55 in early mitosis, but their contribution to Cdc55 regulation is relatively minor compared with the role of Zds1/Zds2. In contrast to Zds1, which primarily localized to the sites of cell polarity and in the cytoplasm, Igo1 is localized in the nucleus, suggesting that Igo1/Igo2 inhibit Cdc55 in a manner distinct from Zds1/Zds2.

Our analysis confirmed an evolutionarily conserved function of ENSA-family proteins in inhibiting PP2A-Cdc55, and we propose that Zds1-dependent sequestration of PP2A-Cdc55 from the nucleus is uniquely evolved to facilitate closed mitosis in fungal species.     

Kv3.4 channel function and dysfunction in nociceptors

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.     

Protein kinase CK2 contributes to diminished small conductance Ca2+‐activated K+ channel activity of hypothalamic pre‐sympathetic neurons in hypertension

Small conductance calcium‐activated K⁺ (SK) channels regulate neuronal excitability. However, little is known about changes in SK channel activity of pre‐sympathetic neurons in the hypothalamic paraventricular nucleus (PVN) in essential hypertension. SK channels, calmodulin, and casein kinase II (CK2) form a molecular complex. Because CK2 is up‐regulated in the PVN in spontaneously hypertensive rats (SHRs), we hypothesized that CK2 increases calmodulin phosphorylation and contributes to diminished SK channel activity in PVN pre‐sympathetic neurons in SHRs. Perforated whole‐cell recordings were performed on retrogradely labeled spinally projecting PVN neurons in Wistar‐Kyoto (WKY) rats and SHRs. Blocking SK channels with apamin significantly increased the firing rate of PVN neurons in WKY rats but not in SHRs. CK2 inhibition restored the stimulatory effect of apamin on the firing activity of PVN neurons in SHRs. Furthermore, apamin‐sensitive SK currents and depolarization‐induced medium after‐hyperpolarization potentials of PVN neurons were significantly larger in WKY rats than in SHRs. CK2 inhibition significantly increased the SK channel current and medium after‐depolarization potential of PVN neurons in SHRs. In addition, CK2‐mediated calmodulin phosphorylation level in the PVN was significantly higher in SHRs than in WKY rats. Although SK3 was detected in the PVN, its expression level did not differ significantly between SHRs and WKY rats. Our findings suggest that CK2‐mediated calmodulin phosphorylation is increased and contributes to diminished SK channel function of PVN pre‐sympathetic neurons in SHRs. This information advances our understanding of the mechanisms underlying hyperactivity of PVN pre‐sympathetic neurons and increased sympathetic vasomotor tone in hypertension.

     

Kv 1.1 is associated with neuronal apoptosis and modulated by protein kinase C in the rat cerebellar granule cell

Previously, we reported that apoptosis of cerebellar granular neurons induced by low‐K⁺ and serum‐free (LK‐S) was associated with an increase in the A‐type K⁺ channel current (I_A), and an elevated expression of main α‐subunit of the I_A channel, which is known as Kv4.2 and Kv4.3. Here, we show, as assessed by quantitative RT‐PCR and whole‐cell recording, that besides Kv4.2 and Kv4.3, Kv1.1 is very important for I_A channel. The expression of Kv1.1 was elevated in the apoptotic neurons, while silencing Kv1.1 expression by siRNA reduced the I_A amplitude of the apoptotic neuron, and increased neuron viability. Inhibiting Kv1.1 current by dendrotoxin‐K evoked a similar effect of reduction of I_A amplitude and protection of neurons. Applying a protein kinase C (PKC) activator, phorbol ester acetate A (PMA) mimicked the LK‐S‐induced neuronal apoptotic effect, enhanced the I_A amplitude and reduced the granule cell viability. The PKC inhibitor, bisindolylmaleimide I and Gö6976 protected the cell against apoptosis induced by LK‐S. After silencing the Kv1.1 gene, the effect of PMA on the residual K⁺ current was reduced significantly. Quantitative RT‐PCR and Western immunoblot techniques revealed that LK‐S treatment and PMA increased the level of the expression of Kv1.1, in contrast, bisindolylmaleimide I inhibited Kv1.1 expression. In addition, the activation of the PKC isoform was identified in apoptotic neurons. We thus conclude that in the rat cerebellar granule cell, the I_A channel associated with apoptotic neurons is encoded mainly by the Kv1.1 gene, and that the PKC pathway promotes neuronal apoptosis by a brief modulation of the I_A amplitude and a permanent increase in the levels of expression of the Kv1.1 α‐subunit.     

KCNE4 is an inhibitory subunit to Kv1.1 and Kv1.3 potassium channels

Kv1 potassium channels are widely distributed in mammalian tissues and are involved in a variety of functions from controlling the firing rate of neurons to maturation of T-lymphocytes. Here we show that the newly described KCNE4 beta-subunit has a drastic inhibitory effect on currents generated by Kv1.1 and Kv1.3 potassium channels. The inhibition is found on channels expressed heterologously in both Xenopus oocytes and mammalian HEK293 cells. mKCNE4 does not inhibit Kv1.2, Kv1.4, Kv1.5, or Kv4.3 homomeric complexes, but it does significantly reduce current through Kv1.1/Kv1.2 and Kv1.2/Kv1.3 heteromeric complexes. Confocal microscopy and Western blotting reveal that Kv1.1 is present at the cell surface together with KCNE4. Real-time RT-PCR shows a relatively high presence of mKCNE4 mRNA in several organs, including uterus, kidney, lung, intestine, and in embryo, whereas a much lower mRNA level is detected in the heart and in five different parts of the brain. Having the broad distribution of Kv1 channels in mind, the demonstrated inhibitory property of KCNE4-subunits could locally and/or transiently have a dramatic influence on cellular excitability and on setting resting membrane potentials.