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In vivo Dominant-Negative Effect of an SCN5A Brugada Syndrome Variant

Nicolas Doisne, Marta Grauso, Nathalie Mougenot, Michel Clergue, Charlotte Souil, Alain Coulombe, Pascale Guicheney, Nathalie Neyroud

2021Frontiers in Physiology19 citationsDOIOpen Access PDF

Abstract

Loss-of-function mutations in the cardiac Na + channel α-subunit Na v 1.5, encoded by SCN5A , cause Brugada syndrome (BrS), a hereditary disease characterized by sudden cardiac death due to ventricular fibrillation. We previously evidenced in vitro the dominant-negative effect of the BrS Na v 1.5-R104W variant, inducing retention of wild-type (WT) channels and leading to a drastic reduction of the resulting Na + current ( I Na ). To explore this dominant-negative effect in vivo , we created a murine model using adeno-associated viruses (AAVs). Methods Due to the large size of SCN5A , a dual AAV vector strategy was used combining viral DNA recombination and trans -splicing. Mice were injected with two AAV serotypes capsid 9: one packaging the cardiac specific troponin-T promoter, the 5′ half of hSCN5A cDNA, a splicing donor site and a recombinogenic sequence; and another packaging the complementary recombinogenic sequence, a splicing acceptor site, the 3′ half of hSCN5A cDNA fused to the gfp gene sequence, and the SV40 polyA signal. Eight weeks after AAV systemic injection in wild-type (WT) mice, echocardiography and ECG were recorded and mice were sacrificed. The full-length hSCN5A-gfp expression was assessed by western blot and immunohistochemistry in transduced heart tissues and the Na + current was recorded by the patch-clamp technique in isolated adult GFP-expressing heart cells. Results Almost 75% of the cardiomyocytes were transduced in hearts of mice injected with hNa v 1.5 and ∼30% in hNa v 1.5-R104W overexpressing tissues. In ventricular mice cardiomyocytes expressing R104W mutant channels, the endogenous I Na was significantly decreased. Moreover, overexpression of R104W channels in normal hearts led to a decrease of total Na v 1.5 expression. The R104W mutant also induced a slight dilatation of mice left ventricles and a prolongation of RR interval and P-wave duration in transduced mice. Altogether, our results demonstrated an in vivo dominant-negative effect of defective R104W channels on endogenous ones. Conclusion Using a trans -splicing and viral DNA recombination strategy to overexpress the Na + channel in mouse hearts allowed us to demonstrate in vivo the dominant-negative effect of a BrS variant identified in the N-terminus of Na v 1.5.

Topics & Concepts

Brugada syndromeIn vivoBiologyMedicineInternal medicineGeneticsCardiac electrophysiology and arrhythmiasIon channel regulation and functionNeuroscience and Neural Engineering
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