Correction of sodium channel mutations in sensory neurons reverses aberrant properties.
Inherited erythromelalgia, small fibre neuropathy and paroxysmal extreme pain disorder are caused by gain-of-function mutations in the voltage-gated sodium channel Nav1.7. It remains unknown how different mutations in the same channel enhancing electrogenesis in sensory neurons results in such distinct disease presentations. Most of the work analysing the impact of these mutations on electrophysiological properties has used overexpression systems in cell lines and rodent sensory neurons, which might differ from the natural context. We have differentiated sensory neurons from induced pluripotent stem cells derived from patient samples that have the Nav1.7 A1632G mutation. This strategy reveals changes in electrophysiological properties, not previously observed in cell lines, that might be important for disease presentation. Furthermore, using CRISPR/Cas9, we corrected this mutation, which reduced the underlying hyperexcitability, providing a path for personalized medicine to treat these disorders, and we introduced the mutation into control induced pluripotent stem cells, which generated hyperexcitability, providing causality. Induced pluripotent stem cell sensory neurons are a robust, scalable and relevant model to study the effects of gain-of-function mutations in ion channels in pain-related disorders.