Abstract
Mutations in SCN1A, encoding the voltage-gated sodium channel Na(V)1.1, are the most common cause of severe myoclonic epilepsy of infancy (SMEI) or Dravet syndrome. SMEI is most often associated with premature truncations of Na(V)1.1 that cause loss of function, but nontruncating mutations also occur. We hypothesized that some nontruncating mutations might impair trafficking of Na(V)1.1 to the plasma membrane. Here we demonstrated that seven nontruncating missense or in-frame deletion mutations (L986F, delF1289, R1648C, F1661S, G1674R, and G1979E) exhibited reduced cell surface expression relative to wild type (WT) Na(V)1.1 consistent with impaired trafficking. We tested whether two commonly prescribed antiepileptic drugs (phenytoin, lamotrigine), as well as the cystic fibrosis transmembrane conductance regulator (CFTR) trafficking corrector VRT-325, could rescue cell surface and functional expression of two representative Na(V)1.1 mutants (R1648C, G1674R). Treatment of cells with phenytoin increased cell surface expression of WT-Na(V)1.1 and both mutant channels, whereas lamotrigine only increased surface expression of R1648C. VRT-325 did not alter surface expression of WT-Na(V)1.1 or mutant channels. Although phenytoin increased surface expression of G1674R, channel function was not restored, suggesting that this mutation also causes an intrinsic loss of function. Both phenytoin and lamotrigine increased functional expression of R1648C, but lamotrigine also increased persistent sodium current evoked by this mutation. Our findings indicate that certain nontruncating SCN1A mutations associated with SMEI have impaired cell surface expression and that some alleles may be amenable to pharmacological rescue of this defect. However, rescue of dysfunctional Na(V)1.1 channels to the plasma membrane could contribute to exacerbating rather than ameliorating the disease.
Highlights
Nontruncating SCN1A mutations can cause severe myoclonic epilepsy of infancy (SMEI)
SMEI-associated Mutations R1648C and G1674R Impair NaV1.1 Trafficking— most SCN1A mutations associated with SMEI are predicted to cause truncation of the coding region leading to loss of function, many missense alleles have
We have previously determined that the SMEI-associated missense mutations illustrated in Fig. 1A exhibited a range of functional properties in vitro (10 –12, 22), but none of these alleles has been studied for cell surface expression
Summary
Results: Some SMEI-associated mutations exhibit reduced cell surface expression, which is reversible for certain alleles by pharmacological treatment. Conclusion: Nontruncating SCN1A mutations with reduced cell surface expression may be amenable to pharmacological rescue. Significance: rescue of trafficking-impaired SCN1A alleles may be beneficial, increased surface expression of dysfunctional channels could exacerbate SMEI. We demonstrated that seven nontruncating missense or in-frame deletion mutations (L986F, delF1289, R1648C, F1661S, G1674R, and G1979E) exhibited reduced cell surface expression relative to wild type (WT) NaV1.1 consistent with impaired trafficking. Phenytoin increased surface expression of G1674R, channel function was not restored, suggesting that this mutation causes an intrinsic loss of function. Our findings indicate that certain nontruncating SCN1A mutations associated with SMEI have impaired cell surface expression and that some alleles may be amenable to pharmacological rescue of this defect. Rescue of dysfunctional NaV1.1 channels to the plasma membrane could contribute to exacerbating rather than ameliorating the disease
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