Durga P. Mohapatra scite author profile

Voltage-dependent Kv2.1 K(+) channels, which mediate delayed rectifier Kv currents (I(K)), are expressed in large clusters on the somata and dendrites of principal pyramidal neurons, where they regulate neuronal excitability. Here we report activity-dependent changes in the localization and biophysical properties of Kv2.1. In the kainate model of continuous seizures in rat, we find a loss of Kv2.1 clustering in pyramidal neurons in vivo. Biochemical analysis of Kv2.1 in the brains of these rats shows a marked dephosphorylation of Kv2.1. In cultured rat hippocampal pyramidal neurons, glutamate stimulation rapidly causes dephosphorylation of Kv2.1, translocation of Kv2.1 from clusters to a more uniform localization, and a shift in the voltage-dependent activation of I(K). An influx of Ca(2+) leading to calcineurin activation is both necessary and sufficient for these effects. Our finding that neuronal activity modifies the phosphorylation state, localization and function of Kv2.1 suggests an important link between excitatory neurotransmission and the intrinsic excitability of pyramidal neurons.

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Localization and Targeting of Voltage-Dependent Ion Channels in Mammalian Central Neurons

Vacher

Mohapatra²,

Trimmer

2008

Physiological Reviews

444

469

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The intrinsic electrical properties and the synaptic input-output relationships of neurons are governed by the action of voltage-dependent ion channels. The localization of specific population of ion channels with distinct functional properties at discrete sites in neurons dramatically impacts excitability and synaptic transmission. Molecular cloning studies have revealed a large family of genes encoding voltage-dependent ion channel principal and auxiliary subunits, most of which are expressed in mammalian central neurons. Much recent effort has focused on determining which of these subunits co-assemble into native neuronal channel complexes, and the cellular and subcellular distributions of these complexes, as a crucial step in understanding the contribution of these channels to specific aspects of neuronal function. Here we review progress made on recent studies aimed at determining the cellular and subcellular distribution of specific ion channel subunits in mammalian brain neurons using in situ hybridization, and immunohistochemistry. We also discuss the repertoire of ion channel subunits in specific neuronal compartments and implications for neuronal physiology. Finally, we discuss the emerging mechanisms for determining the discrete subcellular distributions observed for many neuronal ion channels. I. OVERVIEW OF MAMMALIAN BRAIN VOLTAGE-DEPENDENT ION CHANNELS A. IntroductionMammalian central neurons express a large repertoire of voltage-dependent ion channels (VDICs) that form selective pores in the neuronal membrane and confer diverse properties of intrinsic neuronal excitability. This allows mammalian neurons to display a richness of firing behaviors over a wide range of stimuli and firing frequencies. The complex electrical behavior of mammalian neurons is due to a huge array of VDICs with distinct ion flux rates and selectivity, although the major VDICs underlying neuronal excitability and electrical signaling are those selective for Na + , K + and Ca 2+ ions. Neuronal VDICs also exhibit widely differing properties of how sensitive their gating, or the opening or closing of the channels pore, is to changes in membrane potential. Different VDICs also differ in the kinetics of these gating events. Importantly in the terms of mammalian brain, different VDICs differ widely in their cellular expression and subcellular localization, impacting their relative contribution to brain

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Graded Regulation of the Kv2.1 Potassium Channel by Variable Phosphorylation

Park

Mohapatra

Misonou

et al. 2006

Science

255

334

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Dynamic modulation of ion channels by phosphorylation underlies neuronal plasticity. The Kv2.1 potassium channel is highly phosphorylated in resting mammalian neurons. Activity-dependent Kv2.1 dephosphorylation by calcineurin induces graded hyperpolarizing shifts in voltage-dependent activation, causing suppression of neuronal excitability. Mass spectrometry-SILAC (stable isotope labeling with amino acids in cell culture) identified 16 Kv2.1 phosphorylation sites, of which 7 were dephosphorylated by calcineurin. Mutation of individual calcineurin-regulated sites to alanine produced incremental shifts mimicking dephosphorylation, whereas mutation to aspartate yielded equivalent resistance to calcineurin. Mutations at multiple sites were additive, showing that variable phosphorylation of Kv2.1 at a large number of sites allows graded activity-dependent regulation of channel gating and neuronal firing properties.

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Calcium- and Metabolic State-Dependent Modulation of the Voltage-Dependent Kv2.1 Channel Regulates Neuronal Excitability in Response to Ischemia

Misonou¹,

Mohapatra²,

Menegola³

et al. 2005

J. Neurosci.

174

275

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Ischemic stroke is often accompanied by neuronal hyperexcitability (i.e., seizures), which aggravates brain damage. Therefore, suppressing stroke-induced hyperexcitability and associated excitoxicity is a major focus of treatment for ischemic insults. Both ATP-dependent and Ca 2ϩ -activated K ϩ channels have been implicated in protective mechanisms to suppress ischemia-induced hyperexcitability. Here we provide evidence that the localization and function of Kv2.1, the major somatodendritic delayed rectifier voltage-dependent K ϩ channel in central neurons, is regulated by hypoxia/ischemia-induced changes in metabolic state and intracellular Ca 2ϩ levels. Hypoxia/ ischemia in rat brain induced a dramatic dephosphorylation of Kv2.1 and the translocation of surface Kv2.1 from clusters to a uniform localization. In cultured rat hippocampal neurons, chemical ischemia (CI) elicited a similar dephosphorylation and translocation of Kv2.1. These events were reversible and were mediated by Ca 2ϩ release from intracellular stores and calcineurin-mediated Kv2.1 dephosphorylation. CI also induced a hyperpolarizing shift in the voltage-dependent activation of neuronal delayed rectifier currents (I K ), leading to enhanced I K and suppressed neuronal excitability. The I K blocker tetraethylammonium reversed the ischemia-induced suppression of excitability and aggravated ischemic neuronal damage. Our results show that Kv2.1 can act as a novel Ca 2ϩ -and metabolic state-sensitive K ϩ channel and suggest that dynamic modulation of I K /Kv2.1 in response to hypoxia/ischemia suppresses neuronal excitability and could confer neuroprotection in response to brief ischemic insults.

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Regulation of Ca2+-dependent Desensitization in the Vanilloid Receptor TRPV1 by Calcineurin and cAMP-dependent Protein Kinase

Mohapatra¹,

Nau

2005

Journal of Biological Chemistry

272

225

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The vanilloid receptor TRPV1 is a polymodal nonselective cation channel of nociceptive sensory neurons involved in the perception of inflammatory pain. TRPV1 exhibits desensitization in a Ca 2؉ -dependent manner upon repeated activation by capsaicin or protons. The cAMP-dependent protein kinase (PKA) decreases desensitization of TRPV1 by directly phosphorylating the channel presumably at sites Ser 116 and Thr 370 . In the present study we investigated the influence of protein phosphatase 2B (calcineurin) on Ca 2؉ -dependent desensitization of capsaicin-and proton-activated currents. By using site-directed mutagenesis, we generated point mutations at PKA and protein kinase C consensus sites and studied wild type (WT) and mutant channels transiently expressed in HEK293t or HeLa cells under whole cell voltage clamp. We found that intracellular application of the cyclosporin A⅐cyclophilin A complex (CsA⅐CyP), a specific inhibitor of calcineurin, significantly decreased desensitization of capsaicin-or proton-activated TRPV1-WT currents. This effect was similar to that obtained by extracellular application of forskolin (FSK), an indirect activator of PKA. Simultaneous applications of CsA⅐CyP and FSK in varying concentrations suggested that these substances acted independently from each other. In mutation T370A, application of CsA⅐CyP did not reduce desensitization of capsaicin-activated currents as compared with WT and to mutant channels S116A and T144A. In a double mutation at candidate protein kinase C phosphorylation sites, application of CsA⅐CyP or FSK decreased desensitization of capsaicin-activated currents similar to WT channels. We conclude that Ca 2؉ -dependent desensitization of TRPV1 might be in part regulated through channel dephosphorylation by calcineurin and channel phosphorylation by PKA possibly involving Thr 370 as a key amino acid residue.

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