Terapia oparta na RNA dla kanału potasowego związanego z ciężką epilepsją dziecięcą i przedwczesną śmiercią

Dysfunction of the sodium-activated potassium channel K1.1 (encoded by KCNT1) is associated with a severe neurodevelopmental condition characterized by frequent seizures (up to hundreds per day), treatment resistance, and increased mortality during childhood. Yet, recent progress with an RNA therapy targeting KCNT1 offers clinical promise. We characterize the early developmental onset of K1.1 channels in prenatal and neonatal brain tissue, establishing a timeline for pathophysiology and a window for therapeutic intervention. Using patch-clamp electrophysiology, we observe functional prenatal K1.1 conductance that is developmentally regulated. In excitatory and inhibitory neurons derived from a child's induced pluripotent stem cells with a KCNT1 pathogenic variant (p.R474H), we detect gain-of-function K currents. We use an antisense oligonucleotide RNA therapy developed for two individuals with the p.R474H variant-which results in dramatic reductions in seizure occurrence and severity-to profile cellular neurophysiology in patient-derived excitatory and inhibitory neurons. We observe a knockdown of p.R474H gain-of-function K currents, resulting in a stimulation-dependent change in spiking output in patient-derived induced excitatory and inhibitory neurons. In mid-gestation primary human neurons, ASO knockdown suppresses current-evoked firing, suggesting a potential early therapeutic target before the onset of infantile encephalopathy.