[HTML][HTML] Cold-aggravated pain in humans caused by a hyperactive NaV1.9 channel mutant

E Leipold, A Hanson-Kahn, M Frick, P Gong… - Nature …, 2015 - nature.com
E Leipold, A Hanson-Kahn, M Frick, P Gong, JA Bernstein, M Voigt, I Katona, R Oliver Goral
Nature communications, 2015nature.com
Gain-of-function mutations in the human SCN11A-encoded voltage-gated Na+ channel
NaV1. 9 cause severe pain disorders ranging from neuropathic pain to congenital pain
insensitivity. However, the entire spectrum of the NaV1. 9 diseases has yet to be defined.
Applying whole-exome sequencing we here identify a missense change (p. V1184A) in
NaV1. 9, which leads to cold-aggravated peripheral pain in humans. Electrophysiological
analysis reveals that p. V1184A shifts the voltage dependence of channel opening to …
Abstract
Gain-of-function mutations in the human SCN11A-encoded voltage-gated Na+ channel NaV1.9 cause severe pain disorders ranging from neuropathic pain to congenital pain insensitivity. However, the entire spectrum of the NaV1.9 diseases has yet to be defined. Applying whole-exome sequencing we here identify a missense change (p.V1184A) in NaV1.9, which leads to cold-aggravated peripheral pain in humans. Electrophysiological analysis reveals that p.V1184A shifts the voltage dependence of channel opening to hyperpolarized potentials thereby conferring gain-of-function characteristics to NaV1.9. Mutated channels diminish the resting membrane potential of mouse primary sensory neurons and cause cold-resistant hyperexcitability of nociceptors, suggesting a mechanistic basis for the temperature dependence of the pain phenotype. On the basis of direct comparison of the mutations linked to either cold-aggravated pain or pain insensitivity, we propose a model in which the physiological consequence of a mutation, that is, augmented versus absent pain, is critically dependent on the type of NaV1.9 hyperactivity.
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