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Depolarizing Na<sub>V</sub> and Hyperpolarizing K<sub>V</sub> Channels Are Co-Trafficked in Sensory Neurons

Grant P. Higerd‐Rusli, Matthew Alsaloum, Sidharth Tyagi, Nivedita Sarveswaran, Mark Estación, Elizabeth J. Akin, Fadia B. Dib-Hajj, Shujun Liu, Daniel Sosniak, Peng Zhao, Sulayman D. Dib‐Hajj, Stephen G. Waxman

2022Journal of Neuroscience23 citationsDOIOpen Access PDF

Abstract

Neuronal excitability relies on coordinated action of functionally distinction channels. Voltage-gated sodium (Na V ) and potassium (K V ) channels have distinct but complementary roles in firing action potentials: Na V channels provide depolarizing current while K V channels provide hyperpolarizing current. Mutations and dysfunction of multiple Na V and K V channels underlie disorders of excitability, including pain and epilepsy. Modulating ion channel trafficking may offer a potential therapeutic strategy for these diseases. A fundamental question, however, is whether these channels with distinct functional roles are transported independently or packaged together in the same vesicles in sensory axons. We have used Optical Pulse-Chase Axonal Long-distance imaging to investigate trafficking of Na V and K V channels and other axonal proteins from distinct functional classes in live rodent sensory neurons (from male and female rats). We show that, similar to Na V 1.7 channels, Na V 1.8 and K V 7.2 channels are transported in Rab6a-positive vesicles, and that each of the Na V channel isoforms expressed in healthy, mature sensory neurons (Na V 1.6, Na V 1.7, Na V 1.8, and Na V 1.9) is cotransported in the same vesicles. Further, we show that multiple axonal membrane proteins with different physiological functions (Na V 1.7, K V 7.2, and TNFR1) are cotransported in the same vesicles. However, vesicular packaging of axonal membrane proteins is not indiscriminate, since another axonal membrane protein (NCX2) is transported in separate vesicles. These results shed new light on the development and organization of sensory neuron membranes, revealing complex sorting of axonal proteins with diverse physiological functions into specific transport vesicles.

Topics & Concepts

DepolarizationSodium channelIon channelNeuroscienceVesicleMembrane potentialSensory systemChemistryNeuronBiologyBiophysicsCell biologyBiochemistrySodiumMembraneReceptorOrganic chemistryNeuroscience and Neuropharmacology ResearchIon channel regulation and functionLipid Membrane Structure and Behavior
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