Niyathi H. Shah scite author profile

Voltage-gated potassium (Kv) channels are widely expressed in the central and peripheral nervous system, and are crucial mediators of neuronal excitability. Importantly, these channels also actively participate in cellular and molecular signaling pathways that regulate the life and death of neurons. Injury-mediated increased K+ efflux through Kv2.1 channels promotes neuronal apoptosis, contributing to widespread neuronal loss in neurodegenerative disorders such as Alzheimer’s disease and stroke. In contrast, some forms of neuronal activity can dramatically alter Kv2.1 channel phosphorylation levels and influence their localization. These changes are normally accompanied by modifications in channel voltage-dependence, which may be neuroprotective within the context of ischemic injury. Kv1 and Kv7 channel dysfunction leads to neuronal hyperexcitability that critically contributes to the pathophysiology of human clinical disorders such as episodic ataxia and epilepsy. This review summarizes the neurotoxic, neuroprotective, and neuroregulatory roles of Kv channels, and highlights the consequences of Kv channel dysfunction on neuronal physiology. The studies described in this review thus underscore the importance of normal Kv channel function in neurons, and emphasize the therapeutic potential of targeting Kv channels in the treatment of a wide range of neurological diseases.

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Disruption of K V 2.1 somato-dendritic clusters prevents the apoptogenic increase of potassium currents

Justice

Schulien

et al. 2017

Neuroscience

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As the predominant mediator of the delayed rectifier current, KV2.1 is an important regulator of neuronal excitability. KV2.1, however, also plays a well-established role in apoptotic cell death. Apoptogenic stimuli induce syntaxin-dependent trafficking of KV2.1, resulting in an augmented delayed rectifier current that acts as a conduit for K+ efflux required for pro-apoptotic protease/nuclease activation. Recent evidence suggests that KV2.1 somato-dendritic clusters regulate the formation of endoplasmic reticulum–plasma membrane junctions that function as scaffolding sites for plasma membrane trafficking of ion channels, including KV2.1. However, it is unknown whether KV2.1 somato-dendritic clusters are required for apoptogenic trafficking of KV2.1. By overexpression of a protein derived from the C-terminus of the cognate channel KV2.2 (KV2.2CT), we induced calcineurin-independent disruption of KV2.1 somato-dendritic clusters in rat cortical neurons, without altering the electrophysiological properties of the channel. We observed that KV2.2CT-expressing neurons are less susceptible to oxidative stress-induced cell death. Critically, expression of KV2.2CT effectively blocked the increased current density of the delayed rectifier current associated with oxidative injury, supporting a vital role of KV2.1-somato-dendritic clusters in apoptogenic increases in KV2.1-mediated currents.

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Cyclin E1 Regulates Kv2.1 Channel Phosphorylation and Localization in Neuronal Ischemia

et al. 2014

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Kv2.1 is a major delayed rectifying Kϩ channel normally localized to highly phosphorylated somatodendritic clusters in neurons. Excitatory stimuli induce calcineurin-dependent dephosphorylation and dispersal of Kv2.1 clusters, with a concomitant hyperpolarizing shift in the channel's activation kinetics. We showed previously that sublethal ischemia, which renders neurons transiently resistant to excitotoxic cell death, can also induce Zn 2ϩ -dependent changes in Kv2.1 localization and activation kinetics, suggesting that activitydependent modifications of Kv2.1 may contribute to cellular adaptive responses to injury. Recently, cyclin-dependent kinase 5 (Cdk5) was shown to phosphorylate Kv2.1, with pharmacological Cdk5 inhibition being sufficient to decluster channels. In another study, cyclin E1 was found to restrict neuronal Cdk5 kinase activity. We show here that cyclin E1 regulates Kv2.1 cellular localization via inhibition of Cdk5 activity. Expression of cyclin E1 in human embryonic kidney cells prevents Cdk5-mediated phosphorylation of Kv2.1, and cyclin E1 overexpression in rat cortical neurons triggers dispersal of Kv2.1 channel clusters. Sublethal ischemia in neurons induces calcineurindependent upregulation of cyclin E1 protein expression and cyclin E1-dependent Kv2.1 channel declustering. Importantly, overexpression of cyclin E1 in neurons is sufficient to reduce excitotoxic cell death. These results support a novel role for neuronal cyclin E1 in regulating the phosphorylation status and localization of Kv2.1 channels, a likely component of signaling cascades leading to ischemic preconditioning.

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Zn²⁺‐induced Ca²⁺ release via ryanodine receptors triggers calcineurin‐dependent redistribution of cortical neuronal Kv2.1 K⁺ channels

Schulien

Justice

Maio

et al. 2016

The Journal of Physiology

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Key pointsr Increases in intracellular Zn 2+ concentrations are an early, necessary signal for the modulation of Kv2.1 K + channel localization and physiological function. r We observe that a sublethal ischaemic preconditioning insult also leads to Kv2.1 redistribution in a ryanodine receptor-dependent fashion.r We suggest that Zn 2+ may be an early and ubiquitous signalling molecule mediating Ca 2+ release from the cortical endoplasmic reticulum via ryanodine receptor activation.Abstract Sublethal injurious stimuli in neurons induce transient increases in free intracellular Zn 2+ that are associated with regulating adaptive responses to subsequent lethal injury, including alterations in the function and localization of the delayed-rectifier potassium channel, Kv2.1. However, the link between intracellular Zn 2+ signalling and the observed changes in Kv2.1 remain undefined. In the present study, utilizing exogenous Zn 2+ treatment, along with a selective Zn 2+ ionophore, we show that transient elevations in intracellular Zn 2+ concentrations are sufficient to induce calcineurin-dependent Kv2.1 channel dispersal in rat cortical neurons in vitro, which is accompanied by a relatively small but significant hyperpolarizing shift in the voltage-gated activation kinetics of the channel. Critically, using a molecularly encoded calcium sensor, we found that the calcineurin-dependent changes in Kv2.1 probably occur as a result of Zn 2+ -induced cytosolic Ca 2+ release via activation of neuronal ryanodine receptors. Finally, we couple this mechanism with an established model for in vitro ischaemic preconditioning and show that Kv2.1 channel modulation in this process is also ryanodine receptor-sensitive. Our results strongly suggest that intracellular Zn 2+ -initiated signalling may represent an early and possibly widespread component of Ca 2+ -dependent processes in neurons.

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Niyathi H. Shah

Voltage-Gated Potassium Channels at the Crossroads of Neuronal Function, Ischemic Tolerance, and Neurodegeneration

Disruption of K V 2.1 somato-dendritic clusters prevents the apoptogenic increase of potassium currents

Cyclin E1 Regulates Kv2.1 Channel Phosphorylation and Localization in Neuronal Ischemia

Zn²⁺‐induced Ca²⁺ release via ryanodine receptors triggers calcineurin‐dependent redistribution of cortical neuronal Kv2.1 K⁺ channels

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Niyathi H. Shah

Voltage-Gated Potassium Channels at the Crossroads of Neuronal Function, Ischemic Tolerance, and Neurodegeneration

Disruption of K V 2.1 somato-dendritic clusters prevents the apoptogenic increase of potassium currents

Cyclin E1 Regulates Kv2.1 Channel Phosphorylation and Localization in Neuronal Ischemia

Zn2+‐induced Ca2+ release via ryanodine receptors triggers calcineurin‐dependent redistribution of cortical neuronal Kv2.1 K+ channels

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Zn²⁺‐induced Ca²⁺ release via ryanodine receptors triggers calcineurin‐dependent redistribution of cortical neuronal Kv2.1 K⁺ channels