Różne efekty blokerów kanałów sodowych na warianty SCN8A ze wzmocnioną funkcją związane z epilepsją wrażliwą lub oporną na leki

Gain-of-function variants (GOF) in SCN8A, which encodes the NaV1.6 sodium channel, lead to epilepsy syndromes ranging from drug-responsive self-limited (SeLIE) and intermediate epilepsy to drug-resistant developmental and epileptic encephalopathy (DEE). It is currently unclear why individuals with SCN8A GOF variants show variable responses to sodium channel blockers (SCBs). Here, we compared the clinical characteristics of 173 individuals with 25 different SCN8A GOF variants following the hypothesis that carriers of variants affecting activation gating respond less well to SCBs than those with variants affecting fast inactivation gating, given that use-dependent SCBs preferentially target inactivated channel states. We found that individuals with variants altering channel activation gating were more severely affected than those with variants altering inactivation properties: They had an earlier age at onset (3 vs. 5 months, P < 0.0001), higher prevalence of DEE (75% vs. 39%; P < 0.0001), and poorer response to SCBs (20% vs. 69% seizure free; P < 0.0001). We performed pharmacological studies on representative and recurrent variants from each group: two variants (F846S and M1760I) causing hyperpolarizing shifts of the voltage-dependent activation curves, and two variants (G1475R and N1877S) causing depolarizing shifts of the voltage-dependent fast inactivation curves. Phenytoin failed to suppress neuronal firing in neurons expressing activation-related variants, but showed good suppressing effects in neurons expressing inactivation-related variants. In contrast, PRAX-330, a new SCB, which showed much faster binding rates than phenytoin, was effective for both groups of variants by markedly reducing neuronal firing through rapidly and persistently stabilizing NaV1.6 in the inactivated state. Our findings provide new insights into the mechanism of drug-resistance in SCN8A-DEE and support PRAX-330 and compounds with similar pharmacological properties as a promising preclinical candidate for targeted therapies.