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Transmitter Modulation of Slow, Activity-dependent Alterations in Sodium Channel Availability Endows Neurons with a Novel Form of Cellular Plasticity

Overview
Journal Neuron
Publisher Cell Press
Specialty Neurology
Date 2003 Sep 2
PMID 12948446
Citations 85
Authors
David B Carr
Michelle Day
Angela R Cantrell
Joshua Held
Todd Scheuer
William A Catterall
D James Surmeier
Affiliations
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Abstract

Voltage-gated Na+ channels are major targets of G protein-coupled receptor (GPCR)-initiated signaling cascades. These cascades act principally through protein kinase-mediated phosphorylation of the channel alpha subunit. Phosphorylation reduces Na+ channel availability in most instances without producing major alterations of fast channel gating. The nature of this change in availability is poorly understood. The results described here show that both GPCR- and protein kinase-dependent reductions in Na+ channel availability are mediated by a slow, voltage-dependent process with striking similarity to slow inactivation, an intrinsic gating mechanism of Na+ channels. This process is strictly associated with neuronal activity and develops over seconds, endowing neurons with a novel form of cellular plasticity shaping synaptic integration, dendritic electrogenesis, and repetitive discharge.

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