Modulation of the effects of class Ib antiarrhythmics on cardiac NaV1.5-encoded channels by accessory NaVβ subunits
Wandi Zhu, Wei Wang, Paweorn Angsutararux, Rebecca L. Mellor, Lori L. Isom, Jeanne M. Nerbonne, Jonathan R. Silva
Wandi Zhu, Wei Wang, Paweorn Angsutararux, Rebecca L. Mellor, Lori L. Isom, Jeanne M. Nerbonne, Jonathan R. Silva
View: Text | PDF
Research Article Cardiology Therapeutics

Modulation of the effects of class Ib antiarrhythmics on cardiac NaV1.5-encoded channels by accessory NaVβ subunits

Abstract

Native myocardial voltage-gated sodium (NaV) channels function in macromolecular complexes comprising a pore-forming (α) subunit and multiple accessory proteins. Here, we investigated the impact of accessory NaVβ1 and NaVβ3 subunits on the functional effects of 2 well-known class Ib antiarrhythmics, lidocaine and ranolazine, on the predominant NaV channel α subunit, NaV1.5, expressed in the mammalian heart. We showed that both drugs stabilized the activated conformation of the voltage sensor of domain-III (DIII-VSD) in NaV1.5. In the presence of NaVβ1, the effect of lidocaine on the DIII-VSD was enhanced, whereas the effect of ranolazine was abolished. Mutating the main class Ib drug-binding site, F1760, affected but did not abolish the modulation of drug block by NaVβ1/β3. Recordings from adult mouse ventricular myocytes demonstrated that loss of Scn1b (NaVβ1) differentially affected the potencies of lidocaine and ranolazine. In vivo experiments revealed distinct ECG responses to i.p. injection of ranolazine or lidocaine in WT and Scn1b-null animals, suggesting that NaVβ1 modulated drug responses at the whole-heart level. In the human heart, we found that SCN1B transcript expression was 3 times higher in the atria than ventricles, differences that could, in combination with inherited or acquired cardiovascular disease, dramatically affect patient response to class Ib antiarrhythmic therapies.

Authors

Wandi Zhu, Wei Wang, Paweorn Angsutararux, Rebecca L. Mellor, Lori L. Isom, Jeanne M. Nerbonne, Jonathan R. Silva

×

Figure 2

Coexpression with NaVβ1 or NaVβ3 differentially modulates the effect of lidocaine and ranolazine on the DIII-VSD.

Options: View larger image (or click on image) Download as PowerPoint
Coexpression with NaVβ1 or NaVβ3 differentially modulates the effect of ...
(A) In the presence of NaVβ1, the hyperpolarizing shift in the DIII F-V curve produced by lidocaine was enhanced compared with the Nav1.5 α subunit expressed alone. In marked contrast, the DIV F-V curve was not affected by lidocaine with NaVβ1 present. (B) In contrast with NaVβ1 (A), the hyperpolarized shift in the DIII F-V curve induced by lidocaine was eliminated when NaVβ3 was coexpressed. Similar to NaVβ1, however, the DIV F-V curve was minimally affected by lidocaine. (C) In the presence of NaVβ1, the effect of ranolazine on the DIII F-V curve was eliminated, whereas the DIV F-V was slightly hyperpolarized. (D) In contrast with NaVβ1 (C), the hyperpolarized shift in the DIII F-V curve caused by ranolazine was enhanced when NaVβ3 was coexpressed. In the presence of NaVβ3, ranolazine also caused a small hyperpolarizing shift in the DIV F-V curve. Each data set represents mean ± SEM values from 4–6 cells.