Abstract

The inhibition of voltage-gated sodium (NaV) channels in somatosensory neurons presents a promising novel modality for the treatment of pain. However, the precise contribution of these channels to neuronal excitability, the cellular correlate of pain, is unknown; previous studies using genetic knockout models or pharmacologic block of NaV channels have identified general roles for distinct sodium channel isoforms, but have never quantified their exact contributions to these processes. To address this deficit, we have utilized dynamic clamp electrophysiology to precisely tune in varying levels of NaV1.8 and NaV1.9 currents into induced pluripotent stem cell-derived sensory neurons (iPSC-SNs), allowing us to quantify how graded changes in these currents affect different parameters of neuronal excitability and electrogenesis. We quantify and report direct relationships between NaV1.8 current density and action potential half-width, overshoot, and repetitive firing. We additionally quantify the effect varying NaV1.9 current densities have on neuronal membrane potential and rheobase. Furthermore, we examined the simultaneous interplay between NaV1.8 and NaV1.9 on neuronal excitability. Finally, we show that minor biophysical changes in the gating of NaV1.8 can render human iPSC-SNs hyperexcitable, in a first-of-its-kind investigation of a gain-of-function NaV1.8 mutation in a human neuronal background.

Highlights

  • The inhibition of voltage-gated sodium ­(NaV) channels in somatosensory neurons presents a promising novel modality for the treatment of pain

  • Unpublished work from our lab and others in this field has questioned whether current induced pluripotent stem cell (iPSC)-SN differentiation protocols are able to express the TTX-R ­NaV channels, N­ aV1.8 and ­NaV1.9, seen in human dorsal root ganglion (DRG) neurons

  • The studies performed here display the utility of dynamic clamp in iPSC-SNs to probe somatosensory neuronal physiology and investigate the pathophysiology of human disease

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Summary

Introduction

The inhibition of voltage-gated sodium ­(NaV) channels in somatosensory neurons presents a promising novel modality for the treatment of pain. The precise contribution of these channels to neuronal excitability, the cellular correlate of pain, is unknown; previous studies using genetic knockout models or pharmacologic block of ­NaV channels have identified general roles for distinct sodium channel isoforms, but have never quantified their exact contributions to these processes. To address this deficit, we have utilized dynamic clamp electrophysiology to precisely tune in varying levels of ­NaV1.8 and ­NaV1.9 currents into induced pluripotent stem cell-derived sensory neurons (iPSCSNs), allowing us to quantify how graded changes in these currents affect different parameters of neuronal excitability and electrogenesis. There is a pressing need for these studies to be carried out in human DRG neurons

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