Flecainide, a class IC antiarrhythmic, was shown to improvemyotonia caused by sodium channel mutations in situations where the class IB antiarrhythmic drug mexiletine was less efficient. Yet little is known about molecular interactions between flecainide and human skeletal muscle sodium (hNav1.4) channels. Whole-cell sodium currents (INa) were recorded in tsA201 cells expressing wild-type (WT) and mutant hNav1.4 channels (R1448C, paramyotonia congenita; G1306E, potassium-aggravated myotonia). At a holding potential (HP) of –120 mV, flecainide use-dependently blockedWTand G1306E INa equally but was more potent on R1448C channels. For WT, the extent of block depended on a holding voltage more negative than the activation threshold, being greater at –90 mV as compared to –120 and –180 mV. This behaviour was exacerbated by the R1448C mutation since block at –120 mV was greater than that at –180 mV. Thus flecainide can bind to inactivated sodium channels in the absence of channel opening. Nevertheless, all the channels showed the same closed-state affinity constant (KR ∼480 µM) and the same inactivated-state affinity constant (KI ∼18 µM). Simulations according to the modulated receptor hypothesis mimic the voltage-dependent block ofWTandmutant channels by flecainide and mexiletine. All the results suggest similar blocking mechanisms for the two drugs. Yet, since flecainide exerts use-dependent block at lower frequency than mexiletine, it may exhibit greater benefit in all myotonic syndromes. Moreover, flecainide blocks hNav1.4 channelmutants with a rightward shift of availability voltage dependence more specifically than mexiletine, owing to a lower KR/KI ratio. This study offers a pharmacogenetic strategy to better address treatment in individual myotonic patients.

Different flecainide sensititivity of hNav1.4 channels and myotonic mutants explained by state-dependent block

DESAPHY, Jean Francois;DE LUCA, Annamaria;CONTE, Diana
2004-01-01

Abstract

Flecainide, a class IC antiarrhythmic, was shown to improvemyotonia caused by sodium channel mutations in situations where the class IB antiarrhythmic drug mexiletine was less efficient. Yet little is known about molecular interactions between flecainide and human skeletal muscle sodium (hNav1.4) channels. Whole-cell sodium currents (INa) were recorded in tsA201 cells expressing wild-type (WT) and mutant hNav1.4 channels (R1448C, paramyotonia congenita; G1306E, potassium-aggravated myotonia). At a holding potential (HP) of –120 mV, flecainide use-dependently blockedWTand G1306E INa equally but was more potent on R1448C channels. For WT, the extent of block depended on a holding voltage more negative than the activation threshold, being greater at –90 mV as compared to –120 and –180 mV. This behaviour was exacerbated by the R1448C mutation since block at –120 mV was greater than that at –180 mV. Thus flecainide can bind to inactivated sodium channels in the absence of channel opening. Nevertheless, all the channels showed the same closed-state affinity constant (KR ∼480 µM) and the same inactivated-state affinity constant (KI ∼18 µM). Simulations according to the modulated receptor hypothesis mimic the voltage-dependent block ofWTandmutant channels by flecainide and mexiletine. All the results suggest similar blocking mechanisms for the two drugs. Yet, since flecainide exerts use-dependent block at lower frequency than mexiletine, it may exhibit greater benefit in all myotonic syndromes. Moreover, flecainide blocks hNav1.4 channelmutants with a rightward shift of availability voltage dependence more specifically than mexiletine, owing to a lower KR/KI ratio. This study offers a pharmacogenetic strategy to better address treatment in individual myotonic patients.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11586/135232
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