Loss-of-Function and Gain-of-Function Mutations in KCNQ5 Cause Intellectual Disability or Epileptic Encephalopathy
Lehman A., Thouta S., Mancini GMS., Naidu S., van Slegtenhorst M., McWalter K., Person R., Mwenifumbo J., Salvarinova R., Adam S., du Souich C., Elliott AM., Nelson TN., van Karnebeek C., Friedman JM., Boelman C., Bolbocean C., Buerki SE., Candido T., Eydoux P., Evans DM., Gibson W., Horvath G., Huh L., Sinclair G., Tarling T., Toyota EB., Townsend KN., Van Allen MI., Vercauteren S., Guella I., McKenzie MB., Datta A., Connolly MB., Kalkhoran SM., Poburko D., Farrer MJ., Demos M., Desai S., Claydon T.
KCNQ5 is a highly conserved gene encoding an important channel for neuronal function; it is widely expressed in the brain and generates M-type current. Exome sequencing identified de novo heterozygous missense mutations in four probands with intellectual disability, abnormal neurological findings, and treatment-resistant epilepsy (in two of four). Comprehensive analysis of this potassium channel for the four variants expressed in frog oocytes revealed shifts in the voltage dependence of activation, including altered activation and deactivation kinetics. Specifically, both loss-of-function and gain-of-function KCNQ5 mutations, associated with increased excitability and decreased repolarization reserve, lead to pathophysiology.