Specific Modulation of Na<sup>+</sup>Channels in Hippocampal Neurons by Protein Kinase Cϵ

Chen, Yuan; Cantrell, Angela R.; Messing, Robert O.; Scheuer, Todd; Catterall, William A.

doi:10.1523/jneurosci.4089-04.2005

Cited by 64 publications

(46 citation statements)

References 66 publications

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“…Setting our search parameters at the highest level of stringency produced the list of 12 kinases shown in Table 1. Of this list, three kinases had previously described actions on voltage-gated ion channels: protein kinase C (PKC), calcium/calmodulin-dependent protein kinase II (CAMKII), and p38 MAPK (Varga et al, 2004;Chen et al, 2005;Wittmack et al, 2005). Of the entire list, p38 MAPK had the highest score for likely HCN interactions, and was predicted to phosphorylate both HCN1 and HCN2.…”

Section: Resultsmentioning

confidence: 99%

Modulation of h-Channels in Hippocampal Pyramidal Neurons by p38 Mitogen-Activated Protein Kinase

2006

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Hyperpolarization-activated cyclic nucleotide-gated ion channels (h-channels; I h ; HCN) modulate intrinsic excitability in hippocampal and neocortical pyramidal neurons, among others. Whereas I h mediated by the HCN2 isoform is regulated by cAMP, there is little known about kinase modulation of I h , especially for the HCN1 isoform predominant in pyramidal neurons. We used a computational method to identify a novel kinase modulator of h-channels, p38 mitogen-activated protein kinase (p38 MAPK). Inhibition of p38 MAPK in hippocampal pyramidal neurons caused a ϳ25 mV hyperpolarization of I h voltage-dependent activation. This downregulation of I h produced hyperpolarization of resting potential, along with increased input resistance and temporal summation of excitatory inputs. Activation of p38 MAPK caused a ϳ11 mV depolarizing shift in I h activation, along with depolarized resting potential, and decreased input resistance and temporal summation. Inhibition of related MAPKs, ERK1/2 (extracellular signal-related kinase 1/2) and JNK (c-Jun N-terminal kinase), produced no effect on I h . These results show that p38 MAPK is a strong modulator of h-channel biophysical properties and may deserve additional exploration as a link between altered I h and pathological conditions such as epilepsy.

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Section: Resultsmentioning

confidence: 99%

Modulation of h-Channels in Hippocampal Pyramidal Neurons by p38 Mitogen-Activated Protein Kinase

2006

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“…The selective peptide inhibitor of εPKC (eV1-2) shortened the time to ID in brain slices from AGSs but not in rats even though εV1-2 decreased activation of εPKC in brain slices from both species. Activation of εPKC inhibits Na + /K + ATPase and voltage-gated sodium channels (Chen et al, 2005;Nowak et al, 2004), both of which contribute to the collapse of ion homeostasis during ischemia and may be targets of εPKC during cerebral ischemia in AGSs (Dave et al, 2009). Blocking or delaying the ID can significantly improve recovery (Anderson et al, 2005;Takeda et al, 2003).…”

Section: Resistance To Ischemia/reperfusion In the Euthermic State Inmentioning

confidence: 99%

No oxygen? No problem! Intrinsic brain tolerance to hypoxia in vertebrates

Larson

Drew

Folkow

et al. 2014

Journal of Experimental Biology

134

102

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Many vertebrates are challenged by either chronic or acute episodes of low oxygen availability in their natural environments. Brain function is especially vulnerable to the effects of hypoxia and can be irreversibly impaired by even brief periods of low oxygen supply. This review describes recent research on physiological mechanisms that have evolved in certain vertebrate species to cope with brain hypoxia. Four model systems are considered: freshwater turtles that can survive for months trapped in frozen-over lakes, arctic ground squirrels that respire at extremely low rates during winter hibernation, seals and whales that undertake breath-hold dives lasting minutes to hours, and naked mole-rats that live in crowded burrows completely underground for their entire lives. These species exhibit remarkable specializations of brain physiology that adapt them for acute or chronic episodes of hypoxia. These specializations may be reactive in nature, involving modifications to the catastrophic sequelae of oxygen deprivation that occur in non-tolerant species, or preparatory in nature, preventing the activation of those sequelae altogether. Better understanding of the mechanisms used by these hypoxiatolerant vertebrates will increase appreciation of how nervous systems are adapted for life in specific ecological niches as well as inform advances in therapy for neurological conditions such as stroke and epilepsy.KEY WORDS: Arctic ground squirrel, Cetacean, Hypoxia, Naked mole-rat, Seal, Turtle IntroductionEnvironmental conditions vary enormously for vertebrates, both with respect to the extreme conditions tolerated by a given species at different times and with respect to average living conditions tolerated by different species. Temperature is perhaps the most obvious example: from the poles to the equator, average ambient temperatures vary widely and have been accompanied by physiological adaptations appropriate to resident species; seasonal variations in temperature and resource variability can induce dramatic changes in physiological and/or behavioral patterns including migration and hibernation. Oxygen levels also vary widely, with animals adapted to sea level, high-altitude, underground and aquatic habitats. Oxygen levels can also change dramatically on a shorter-term basis, as can occur in tidal pools or in breath-hold divers. Approximately 20% of the oxygen consumed by the human body is used by the brain. The greater part of this oxygen is used to produce the ATP required to maintain the membrane potentials necessary for electrical signaling with synaptic and action potentials (Harris et al., 2012). In many vertebrates, including adult humans, interruption of the oxygen supply to the brain for more than a few minutes leads to irreversible neurological damage, including neuronal death. Without oxidative phosphorylation, ATP-dependent neuronal processes including ion transport and neurotransmitter reuptake decline sharply. Without pumping, ion gradients fail and neurons depolarize, releasing excessive levels...

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“…Between stages 44 -46 and stage 49, the observed decrease in peak Na ϩ current amplitude could be attributable to a change in the density of voltage-gated Na ϩ channels or to a change in their modulation (Huguenard et al, 1988;Bevan and Storey, 2002;Chen et al, 2005). The fact that the decrease in the peak Na ϩ current is accompanied by an increase in the spike rise time and rate of rise ( Table 1), suggests that a change in the number of functional channels is the likely mechanism underlying a decrease in spike rate.…”

Section: Developmental Regulation Of Intrinsic Excitabilitymentioning

confidence: 99%

Homeostatic Regulation of Intrinsic Excitability and Synaptic Transmission in a Developing Visual Circuit

Pratt¹,

Aizenman²

2007

J. Neurosci.

142

163

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One of the major challenges faced by the developing visual system is how to stably process visual information, yet at the same time remain flexible enough to accommodate growth and plasticity induced by visual experience. We find that in the Xenopus retinotectal circuit, during a period in development when the retinotectal map undergoes activity-dependent refinement and visual inputs strengthen, tectal neurons adapt their intrinsic excitability such that a stable relationship between the total level of synaptic input and tectal neuron spike output is conserved. This homeostatic balance between synaptic and intrinsic properties is maintained, in part, via regulation of voltagegated Na ϩ currents, resulting in a stable neuronal input-output function. We experimentally manipulated intrinsic excitability or synapse strengthening in developing tectal neurons in vivo by electroporation of a leak K ϩ channel gene or a peptide that interferes with normal AMPA receptor trafficking. Both manipulations resulted in a compensatory increase in voltage-gated Na ϩ currents. This suggests that intrinsic neuronal properties are actively regulated as a function of the total level of neuronal activity experienced during development. We conclude that the coordinated changes between synaptic and intrinsic properties allow developing optic tectal neurons to remain within a stable dynamic range, even as the pattern and strength of visual inputs changes over development, suggesting that homeostatic regulation of intrinsic properties plays a central role in the functional development of neural circuits.

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Specific Modulation of Na⁺Channels in Hippocampal Neurons by Protein Kinase Cϵ

Cited by 64 publications

References 66 publications

Modulation of h-Channels in Hippocampal Pyramidal Neurons by p38 Mitogen-Activated Protein Kinase

Modulation of h-Channels in Hippocampal Pyramidal Neurons by p38 Mitogen-Activated Protein Kinase

No oxygen? No problem! Intrinsic brain tolerance to hypoxia in vertebrates

Homeostatic Regulation of Intrinsic Excitability and Synaptic Transmission in a Developing Visual Circuit

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Specific Modulation of Na+Channels in Hippocampal Neurons by Protein Kinase Cϵ

Cited by 64 publications

References 66 publications

Modulation of h-Channels in Hippocampal Pyramidal Neurons by p38 Mitogen-Activated Protein Kinase

Modulation of h-Channels in Hippocampal Pyramidal Neurons by p38 Mitogen-Activated Protein Kinase

No oxygen? No problem! Intrinsic brain tolerance to hypoxia in vertebrates

Homeostatic Regulation of Intrinsic Excitability and Synaptic Transmission in a Developing Visual Circuit

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Specific Modulation of Na⁺Channels in Hippocampal Neurons by Protein Kinase Cϵ