NaV1.1 inhibition can reduce visceral hypersensitivity
Juan Salvatierra, Joel Castro, Andelain Erickson, Qian Li, Joao Braz, John Gilchrist, Luke Grundy, Grigori Y. Rychkov, Annemie Deiteren, Rana Rais, Glenn F. King, Barbara S. Slusher, Allan Basbaum, Pankaj J. Pasricha, Stuart M. Brierley, Frank Bosmans
Juan Salvatierra, Joel Castro, Andelain Erickson, Qian Li, Joao Braz, John Gilchrist, Luke Grundy, Grigori Y. Rychkov, Annemie Deiteren, Rana Rais, Glenn F. King, Barbara S. Slusher, Allan Basbaum, Pankaj J. Pasricha, Stuart M. Brierley, Frank Bosmans
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Research Article Gastroenterology Neuroscience

NaV1.1 inhibition can reduce visceral hypersensitivity

Abstract

Functional bowel disorder patients can suffer from chronic abdominal pain, likely due to visceral hypersensitivity to mechanical stimuli. As there is only a limited understanding of the basis of chronic visceral hypersensitivity (CVH), drug-based management strategies are ill defined, vary considerably, and include NSAIDs, opioids, and even anticonvulsants. We previously reported that the 1.1 subtype of the voltage-gated sodium (NaV; NaV1.1) channel family regulates the excitability of sensory nerve fibers that transmit a mechanical pain message to the spinal cord. Herein, we investigated whether this channel subtype also underlies the abdominal pain that occurs with CVH. We demonstrate that NaV1.1 is functionally upregulated under CVH conditions and that inhibiting channel function reduces mechanical pain in 3 mechanistically distinct mouse models of chronic pain. In particular, we use a small molecule to show that selective NaV1.1 inhibition (a) decreases sodium currents in colon-innervating dorsal root ganglion neurons, (b) reduces colonic nociceptor mechanical responses, and (c) normalizes the enhanced visceromotor response to distension observed in 2 mouse models of irritable bowel syndrome. These results provide support for a relationship between NaV1.1 and chronic abdominal pain associated with functional bowel disorders.

Authors

Juan Salvatierra, Joel Castro, Andelain Erickson, Qian Li, Joao Braz, John Gilchrist, Luke Grundy, Grigori Y. Rychkov, Annemie Deiteren, Rana Rais, Glenn F. King, Barbara S. Slusher, Allan Basbaum, Pankaj J. Pasricha, Stuart M. Brierley, Frank Bosmans

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Figure 2

Compound B reduces sodium currents in colon-innervating DRG neurons.

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Compound B reduces sodium currents in colon-innervating DRG neurons. (A)...
(A) Group data showing that sodium current density (pA/pF) in a population of colon-innervating DRG neurons was reduced when applying Compound B (100 μM). ****P < 0.0001, n = 14 neurons, paired t test. (B) Individual data from that the group data presented in A. ****P < 0.0001, n = 17 neurons, paired t test.(C) Compound B caused ~23% decrease in peak sodium currents in affected neurons (**P < 0.001, Mann Whitney U test). (D) Current-voltage (I-V) plots of sodium current density before (vehicle; black) and after (blue) Compound B application (100 μM) in inhibited colon-innervating DRG neurons. Data represent ± SEM.