Cheng Chang Lien scite author profile

Voltage-gated potassium (Kv) channels control action potential repolarization, interspike membrane potential, and action potential frequency in excitable cells. It is thought that the combinatorial association between distinct alpha and beta subunits determines whether Kv channels function as non-inactivating delayed rectifiers or as rapidly inactivating A-type channels. We show that membrane lipids can convert A-type channels into delayed rectifiers and vice versa. Phosphoinositides remove N-type inactivation from A-type channels by immobilizing the inactivation domains. Conversely, arachidonic acid and its amide anandamide endow delayed rectifiers with rapid voltage-dependent inactivation. The bidirectional control of Kv channel gating by lipids may provide a mechanism for the dynamic regulation of electrical signaling in the nervous system.

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Hyperpolarization‐activated cation channels in fast‐spiking interneurons of rat hippocampus

Aponte

Lien

Reisinger

et al. 2006

The Journal of Physiology

196

200

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Hyperpolarization-activated channels (I h or HCN channels) are widely expressed in principal neurons in the central nervous system. However, I h in inhibitory GABAergic interneurons is less well characterized. We examined the functional properties of I h in fast-spiking basket cells (BCs) of the dentate gyrus, using hippocampal slices from 17-to 21-day-old rats. Bath application of the I h channel blocker ZD 7288 at a concentration of 30 μM induced a hyperpolarization of 5.7 ± 1.5 mV, an increase in input resistance and a correlated increase in apparent membrane time constant. ZD 7288 blocked a hyperpolarization-activated current in a concentration-dependent manner (IC 50 , 1.4 μM). The effects of ZD 7288 were mimicked by external Cs + . The reversal potential of I h was −27.4 mV, corresponding to a Na + to K + permeability ratio (P Na /P K ) of 0.36. The midpoint potential of the activation curve of I h was −83.9 mV, and the activation time constant at −120 mV was 190 ms. Single-cell expression analysis using reverse transcription followed by quantitative polymerase chain reaction revealed that BCs coexpress HCN1 and HCN2 subunit mRNA, suggesting the formation of heteromeric HCN1/2 channels. ZD 7288 increased the current threshold for evoking antidromic action potentials by extracellular stimulation, consistent with the expression of I h in BC axons. Finally, ZD 7288 decreased the frequency of miniature inhibitory postsynaptic currents (mIPSCs) in hippocampal granule cells, the main target cells of BCs, to 70 ± 4% of the control value. In contrast, the amplitude of mIPSCs was unchanged, consistent with the presence of I h in inhibitory terminals. In conclusion, our results suggest that I h channels are expressed in the somatodendritic region, axon and presynaptic elements of fast-spiking BCs in the hippocampus.

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Kv3 Potassium Conductance is Necessary and Kinetically Optimized for High-Frequency Action Potential Generation in Hippocampal Interneurons

2003

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Kv3 channels are thought to be essential for the fast-spiking (FS) phenotype in GABAergic interneurons, but how these channels confer the ability to generate action potentials (APs) at high frequency is unknown. To address this question, we developed a fast dynamic-clamp system (approximately 50 kHz) that allowed us to add a Kv3 model conductance to CA1 oriens alveus (OA) interneurons in hippocampal slices. Selective pharmacological block of Kv3 channels by 0.3 mm 4-aminopyridine or 1 mm tetraethylammonium ions led to a marked broadening of APs during trains of short stimuli and a reduction in AP frequency during 1 sec stimuli. The addition of artificial Kv3 conductance restored the original AP pattern. Subtraction of Kv3 conductance by dynamic clamp mimicked the effects of the blockers. Application of artificial Kv3 conductance also led to FS in OA interneurons after complete K+ channel block and even induced FS in hippocampal pyramidal neurons in the absence of blockers. Adding artificial Kv3 conductance with altered deactivation kinetics revealed a nonmonotonic relationship between mean AP frequency and deactivation rate, with a maximum slightly above the original value. Insertion of artificial Kv3 conductance with either lowered activation threshold or inactivation also led to a reduction in the mean AP frequency. However, the mechanisms were distinct. Shifting the activation threshold induced adaptation, whereas adding inactivation caused frequency-dependent AP broadening. In conclusion, Kv3 channels are necessary for the FS phenotype of OA interneurons, and several of their gating properties appear to be optimized for high-frequency repetitive activity.

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Mutations in KCND3 cause spinocerebellar ataxia type 22

Lee

Dürr

Majczenko

et al. 2012

Annals of Neurology

138

145

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Objective To identify the causative gene in SCA22, an autosomal dominant cerebellar ataxia mapped to chromosome 1p21-q23. Subjects and Methods We previously characterized a large Chinese family with progressive ataxia designated SCA22, which overlaps with the locus of SCA19. The disease locus in a French family and an Ashkenazi Jewish American family was also mapped to this region. Members from all three families were enrolled. Whole exome sequencing was performed to identify candidate mutations, which were narrowed by linkage analysis and confirmed by Sanger sequencing and co-segregation analyses. Mutational analyses were also performed in 105 Chinese and 55 Japanese families with cerebellar ataxia. Mutant gene products were examined in a heterologous expression system to address the changes in protein localization and electrophysiological functions. Results We identified heterozygous mutations in the voltage-gated potassium channel Kv4.3-encoding gene KCND3: an in-frame three-nucleotide deletion c.679_681delTTC p.F227del in both the Chinese and French pedigrees, and a missense mutation c.1034G>T p.G345V in the Ashkenazi Jewish family. Direct sequencing of KCND3 further identified three mutations, c.1034G>T p.G345V, c.1013T>C p.V338E and c.1130C>T p.T377M, in three Japanese kindreds. Immunofluorescence analyses revealed that the mutant p.F227del Kv4.3 subunits were retained in the cytoplasm, consistent with the lack of A-type K+ channel conductance in whole-cell patch-clamp recordings. Interpretation Our data identify the cause of SCA19/22 in patients of diverse ethnic origins as mutations in KCND3. These findings further emphasize the important role of ion channels as key regulators of neuronal excitability in the pathogenesis of cerebellar degeneration.

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Cheng Chang Lien

Functional Conversion Between A-Type and Delayed Rectifier K ⁺ Channels by Membrane Lipids

Hyperpolarization‐activated cation channels in fast‐spiking interneurons of rat hippocampus

Kv3 Potassium Conductance is Necessary and Kinetically Optimized for High-Frequency Action Potential Generation in Hippocampal Interneurons

Mutations in KCND3 cause spinocerebellar ataxia type 22

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Cheng Chang Lien

Functional Conversion Between A-Type and Delayed Rectifier K + Channels by Membrane Lipids

Hyperpolarization‐activated cation channels in fast‐spiking interneurons of rat hippocampus

Kv3 Potassium Conductance is Necessary and Kinetically Optimized for High-Frequency Action Potential Generation in Hippocampal Interneurons

Mutations in KCND3 cause spinocerebellar ataxia type 22

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Product

Resources

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Functional Conversion Between A-Type and Delayed Rectifier K ⁺ Channels by Membrane Lipids