Abstract
Mutations in the genes encoding for voltage-gated sodium channels cause profound sensory disturbances and other symptoms dependent on the distribution of a particular channel subtype in different organs. Humans with the gain-of-function mutation p.Leu811Pro in SCN11A (encoding for the voltage-gated Nav1.9 channel) exhibit congenital insensitivity to pain, pruritus, self-inflicted injuries, slow healing wounds, muscle weakness, Charcot-like arthropathies, and intestinal dysmotility. As already shown, knock-in mice (Scn11a+/L799P) carrying the orthologous mutation p.Leu799Pro replicate reduced pain sensitivity and show frequent tissue lesions. In the present study we explored whether Scn11a+/L799P mice develop also pruritus, muscle weakness, and changes in gastrointestinal transit time. Furthermore, we analyzed morphological and functional differences in nerves, skeletal muscle, joints and small intestine from Scn11a+/L799P and Scn11a+/+ wild type mice. Compared to Scn11a+/+ mice, Scn11a+/L799P mice showed enhanced scratching bouts before skin lesions developed, indicating pruritus. Scn11a+/L799P mice exhibited reduced grip strength, but no disturbances in motor coordination. Skeletal muscle fiber types and joint architecture were unaltered in Scn11a+/L799P mice. Their gastrointestinal transit time was unaltered. The small intestine from Scn11a+/L799P showed a small shift towards less frequent peristaltic movements. Similar proportions of lumbar dorsal root ganglion neurons from Scn11a+/L799P and Scn11a+/+ mice were calcitonin gene-related peptide (CGRP-) positive, but isolated sciatic nerves from Scn11a+/L799P mice exhibited a significant reduction of the capsaicin-evoked release of CGRP indicating reduced neurogenic inflammation. These data indicate important Nav1.9 channel functions in several organs in both humans and mice. They support the pathophysiological relevance of increased basal activity of Nav1.9 channels for sensory abnormalities (pain and itch) and suggest resulting malfunctions of the motor system and of the gastrointestinal tract. Scn11a+/L799P mice are suitable to investigate the role of Nav1.9, and to explore the pathophysiological changes and mechanisms which develop as a consequence of Nav1.9 hyperactivity.
Highlights
Essential body functions depend on ion channels such as voltage-gated sodium channels (VGSC)
We quantified the count of scratching bouts in a total time span of 60 min by video analysis and found in the total group of mice a significantly increased number of bouts in older, middle aged (9–12 months [25]) Scn11a+/L799P mice compared to their wild-type (Scn11a+/+) littermates
Similar as humans with the rare gain-of-function mutation p.Leu811Pro in SCN11A, Scn11a+/L799P mice show significant changes in several organs with similar manifestations. These findings indicate important Nav1.9 channel functions in several organs across different species
Summary
Essential body functions depend on ion channels such as voltage-gated sodium channels (VGSC). VGSC produce action potentials in neurons, and regulate neuronal excitability. Since there are several VGSC isoforms (NaV1.1-NaV1.9) the functional significance of each isoform needs to be established. Leipold et al and Woods et al identified in three young individuals a gain-of-function mutation (p.Leu811Pro) in SCN11A, the gene that encodes for NaV1.9 [3, 4]. NaV1.9 is preferentially expressed in dorsal root ganglion (DRG) neurons (including functionally identified nociceptors), trigeminal neurons and intrinsic myenteric neurons [6]. NaV1.9 acts as a threshold channel by contributing a sodium conductance that regulates resting potentials and prolongs the depolarizing response to subthreshold stimuli [6]
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