GTP up‐regulated persistent Na+ current and enhanced nociceptor excitability require NaV1.9

JAR Östman, MA Nassar, JN Wood… - The Journal of …, 2008 - Wiley Online Library
JAR Östman, MA Nassar, JN Wood, MD Baker
The Journal of physiology, 2008Wiley Online Library
Persistent tetrodotoxin‐resistant (TTX‐r) sodium currents up‐regulated by intracellular GTP
have been invoked as the site of action of peripheral inflammatory mediators that lower pain
thresholds, and ascribed to the NaV1. 9 sodium channel. Here we describe the properties of
a global knock‐out of NaV1. 9 produced by replacing exons 4 and 5 in SCN11A with a
neomycin resistance cassette, deleting the domain 1 voltage sensor and introducing a
frameshift mutation. Recordings from small (< 25 μm apparent diameter) sensory neurones …
Persistent tetrodotoxin‐resistant (TTX‐r) sodium currents up‐regulated by intracellular GTP have been invoked as the site of action of peripheral inflammatory mediators that lower pain thresholds, and ascribed to the NaV1.9 sodium channel. Here we describe the properties of a global knock‐out of NaV1.9 produced by replacing exons 4 and 5 in SCN11A with a neomycin resistance cassette, deleting the domain 1 voltage sensor and introducing a frameshift mutation. Recordings from small (< 25 μm apparent diameter) sensory neurones indicated that channel loss eliminates a TTX‐r persistent current. Intracellular dialysis of GTP‐γ‐S did not cause an up‐regulation of persistent Na+ current in NaV1.9‐null neurones and the concomitant negative shift in voltage‐threshold seen in wild‐type and heterozygous neurones. Heterologous hNaV1.9 expression in NaV1.9 knock‐out sensory neurones confirms that the human clone can restore the persistent Na+ current. Taken together, these findings demonstrate that NaV1.9 underlies the G‐protein pathway‐regulated TTX‐r persistent Na+ current in small diameter sensory neurones that may drive spontaneous discharge in nociceptive nerve fibres during inflammation.
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