Sodium channel biophysics, late sodium current and genetic arrhythmic syndromes

Chadda, Karan R.; Jeevaratnam, Kamalan; Lei, Ming; Huang, Christopher L.‐H.

doi:10.1007/s00424-017-1959-1

Cited by 55 publications

(58 citation statements)

References 86 publications

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“…Supporting a direct mechanism, SUMOylation of Na V 1.5 produces I LATE in the absence of hypoxia in membrane patches excised from cells, basal levels of Na V 1.5 SUMOylation are low under control conditions in iPS-CMs, and hypoxia leads to SUMOylation of the channels with the same time course as the increase in I LATE . Furthermore, SUMOylation produces changes in the gating of single Na V 1.5 ion channels, macroscopic I Na , and APDs like those described in human heart and in animal models with hypoxia (Chadda et al, 2017;Austen et al, 1963;Thung et al, 1962;Brown et al, 2014); and the effects are suppressed by the mutation of Na V 1.5 K442, the application of SENP1 deSUMOylase, or the application of ranolazine, an inhibitor of I LATE .…”

Section: Discussionmentioning

confidence: 94%

“…spatiotemporal changes in repolarization that promote reentrant arrhythmias, including ventricular TdP (Gaur et al, 2009;Shryock et al, 2013;Chadda et al, 2017). Medications like ranolazine that suppress I LATE minimize disruption of Ca 2+ homeostasis, reducing EADs and DADs (Maier and Sossalla, 2013).…”

Section: Discussionmentioning

confidence: 99%

“…In patients with an ischemic and failing heart, sudden infant death syndrome (SIDS), and mutations in SCN5A, the gene that encodes the Na V 1.5 channel, which produces long QT syndrome, the size of I LATE can increase to 4%-5% of peak I Na (Bennett et al, 1995;Plant et al, 2006;Belardinelli et al, 2015). Furthermore, acute hypoxia and ischemia have been recognized to increase I LATE in cardiac myocytes (Saint et al, 1992;Ju et al, 1996;Carmeliet, 1999;Belardinelli et al, 2006) prior to slower processes like remodeling (West, 2017), and excess I LATE has been shown to be pro-arrhythmic because it prolongs action potential duration (APD), reducing repolarization reserve, increasing suscepti-bility to after-depolarizations, and causing a predisposition to torsades de pointes (TdP), a ventricular dysrhythmia that is lethal when sustained (Gaur et al, 2009;Shryock et al, 2013;Chadda et al, 2017). Thus, increases in I LATE above baseline by just 0.3% to 1% predisposition to sudden cardiac death (Bennett et al, 1995;Belardinelli et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Hypoxia Produces Pro-arrhythmic Late Sodium Current in Cardiac Myocytes by SUMOylation of NaV1.5 Channels

et al. 2020

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Section: Discussionmentioning

confidence: 94%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Hypoxia Produces Pro-arrhythmic Late Sodium Current in Cardiac Myocytes by SUMOylation of NaV1.5 Channels

et al. 2020

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“…Mexiletine has a significant therapeutic effect on refractory TdP and that it can shorten the QT interval of the basic ECG. The enhanced late sodium channel currents (I Na-L ) can potentially cause pro-arrhythmic phenotypes [111]. Enhanced I Na-L can be observed in acquired conditions, such as hypertrophic cardiomyopathy, heart failure and drug-induced arrhythmias [112,113].…”

Section: Qt Prolongation With Tdpmentioning

confidence: 99%

Acquired long QT syndrome in chronic kidney disease patients

et al. 2019

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Cardiovascular disease (CVD) is the leading cause of morbidity and mortality in chronic kidney disease (CKD) patients. QT interval prolongation is a congenital or acquired condition that is associated with an increased risk of torsade de pointes (TdP), sudden cardiac death (SCD), and all-cause mortality in the general population. The prevalence of acquired long QT syndrome (aLQTS) is high, and various acquired conditions contribute to the prolonged QT interval in patients with CKD. More notably, the prolonged QT interval in CKD is an independent risk factor for SCD and all-cause mortality. In this review, we focus on the epidemiological characteristics, risk factors, underlying mechanisms and treatments of aLQTS in CKD, promoting the management of aLQTS in CKD patients.

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“…Initially I Na-late was believed to be a consequence of the overlapping steady-state activation and inactivation functions of the Na + current (window Na + current) [17], now it is better explained by the slow inactivation kinetics of a small fraction of cardiac Na + channels (mode-II gating, bursting and late openings) [4,6]. In spite of its relative importance, many aspects of I Na-late are still poorly understood.…”

Section: Introductionmentioning

confidence: 99%

Late sodium current in human, canine and guinea pig ventricular myocardium

Horváth

Hézsô

Szentandrássy

et al. 2020

Journal of Molecular and Cellular Cardiology

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Although late sodium current (I Na-late) has long been known to contribute to plateau formation of mammalian cardiac action potentials, lately it was considered as possible target for antiarrhythmic drugs. However, many aspects of this current are still poorly understood. The present work was designed to study the true profile of I Nalate in canine and guinea pig ventricular cells and compare them to I Na-late recorded in undiseased human hearts. I Na-late was defined as a tetrodotoxin-sensitive current, recorded under action potential voltage clamp conditions using either canonic-or self-action potentials as command signals. Under action potential voltage clamp conditions the amplitude of canine and human I Na-late monotonically decreased during the plateau (decrescendoprofile), in contrast to guinea pig, where its amplitude increased during the plateau (crescendo profile). The decrescendo-profile of canine I Na-late could not be converted to a crescendo-morphology by application of ramplike command voltages or command action potentials recorded from guinea pig cells. Conventional voltage clamp experiments revealed that the crescendo I Na-late profile in guinea pig was due to the slower decay of I Na-late in this species. When action potentials were recorded from multicellular ventricular preparations with sharp microelectrode, action potentials were shortened by tetrodotoxin, which effect was the largest in human, while smaller in canine, and the smallest in guinea pig preparations. It is concluded that important interspecies differences exist in the behavior of I Na-late. At present canine myocytes seem to represent the best model of human ventricular cells regarding the properties of I Na-late. These results should be taken into account when pharmacological studies with I Na-late are interpreted and extrapolated to human. Accordingly, canine ventricular tissues or myocytes are suggested for pharmacological studies with I Na-late inhibitors or modifiers. Incorporation of present data to human action potential models may yield a better understanding of the role of I Na-late in action potential morphology, arrhythmogenesis, and intracellular calcium dynamics. with physiological and pathological significance recognized long ago [1-3], its pathophysiological role in LQT3 [4] and heart failure [5-8] has been emphasized only in the last decades. I Na-late-as an inward current-contributes to plateau formation and is responsible for largely

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Sodium channel biophysics, late sodium current and genetic arrhythmic syndromes

Cited by 55 publications

References 86 publications

Hypoxia Produces Pro-arrhythmic Late Sodium Current in Cardiac Myocytes by SUMOylation of NaV1.5 Channels

Hypoxia Produces Pro-arrhythmic Late Sodium Current in Cardiac Myocytes by SUMOylation of NaV1.5 Channels

Acquired long QT syndrome in chronic kidney disease patients

Late sodium current in human, canine and guinea pig ventricular myocardium

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