Nils Bögeholz scite author profile

The cardiac Na+/Ca2+ exchanger (NCX) generates an inward electrical current during SR-Ca2+ release, thus possibly promoting afterdepolarizations of the action potential (AP). We used transgenic mice 12.5 weeks or younger with cardiomyocyte-directed overexpression of NCX (NCX-Tg) to study the proarrhythmic potential and mechanisms of enhanced NCX activity. NCX-Tg exhibited normal echocardiographic left ventricular function and heart/body weight ratio, while the QT interval was prolonged in surface ECG recordings. Langendorff-perfused NCX-Tg, but not wild-type (WT) hearts, developed ventricular tachycardia. APs and ionic currents were measured in isolated cardiomyocytes. Cell capacitance was unaltered between groups. APs were prolonged in NCX-Tg versus WT myocytes along with voltage-activated K+ currents (Kv) not being reduced but even increased in amplitude. During abrupt changes in pacing cycle length, early afterdepolarizations (EADs) were frequently recorded in NCX-Tg but not in WT myocytes. Next to EADs, delayed afterdepolarizations (DAD) triggering spontaneous APs (sAPs) occurred in NCX-Tg but not in WT myocytes. To test whether sAPs were associated with spontaneous Ca2+ release (sCR), Ca2+ transients were recorded. Despite the absence of sAPs in WT, sCR was observed in myocytes of both genotypes suggesting a facilitated translation of sCR into DADs in NCX-Tg. Moreover, sCR was more frequent in NCX-Tg as compared to WT. Myocardial protein levels of Ca2+-handling proteins were not different between groups except the ryanodine receptor (RyR), which was increased in NCX-Tg versus WT. We conclude that NCX overexpression is proarrhythmic in a non-failing environment even in the absence of reduced KV. The underlying mechanisms are: (1) occurrence of EADs due to delayed repolarization; (2) facilitated translation from sCR into DADs; (3) proneness to sCR possibly caused by altered Ca2+ handling and/or increased RyR expression.

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Suppression of Early and Late Afterdepolarizations by Heterozygous Knockout of the Na ⁺ /Ca ²⁺ Exchanger in a Murine Model

Bögeholz

Pauls

Bauer

et al. 2015

Circ: Arrhythmia and Electrophysiology

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Background-The Na + /Ca 2+ exchanger (NCX) has been implied to cause arrhythmias. To date, information on the role of NCX in arrhythmogenesis derived from models with increased NCX expression, hypertrophy, and heart failure. Furthermore, the exact mechanism by which NCX exerts its potentially proarrhythmic effect, ie, by promoting early afterdepolarization (EAD) or delayed afterdepolarization (DAD) or both, is unknown. Methods and Results-We investigated isolated cardiomyocytes from a murine model with heterozygous knockout of NCX (hetKO) using the patch clamp and Ca 2+ imaging techniques. Action potential duration was shorter in hetKO with I Ktot not being increased. The rate of spontaneous Ca 2+ release events and the rate of DADs were unaltered; however, DADs had lower amplitude in hetKO. A DAD triggered a spontaneous action potential significantly less often in hetKO when compared with wild-type. The occurrence of EADs was also drastically reduced in hetKO. I Ca activity was reduced in hetKO, an effect that was abolished in the presence of the Ca 2+ buffer BAPTA. Conclusions-Genetic suppression of NCX reduces both EADs and DADs. The following molecular mechanisms apply: (1) Although the absolute number of DADs is unaffected, an impaired translation of DADs into spontaneous action potentials results from a reduced DAD amplitude. (2) EADs are reduced in absolute number of occurrence, which is presumably a consequence of shortened action potential duration because of reduced NCX activity but also reduced I Ca the latter possibly being caused by a direct modulation of Ca 2+ -dependent I Ca inhibition by reduced NCX activity. This is the first study to demonstrate that genetic inhibition of NCX protects against afterdepolarizations and to investigate the underlying mechanisms. (Circ Arrhythm Electrophysiol.

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Ranolazine and Vernakalant Prevent Ventricular Arrhythmias in an Experimental Whole‐Heart Model of Short QT Syndrome

Frommeyer

Ellermann

Dechering

et al. 2016

Cardiovasc electrophysiol

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Effective suppression of atrial fibrillation by the antihistaminic agent antazoline: First experimental insights into a novel antiarrhythmic agent

Frommeyer

Sterneberg

Dechering

et al. 2017

Cardiovascular Therapeutics

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Nils Bögeholz

Proarrhythmia in a non-failing murine model of cardiac-specific Na+/Ca2+ exchanger overexpression: whole heart and cellular mechanisms

Suppression of Early and Late Afterdepolarizations by Heterozygous Knockout of the Na ⁺ /Ca ²⁺ Exchanger in a Murine Model

Ranolazine and Vernakalant Prevent Ventricular Arrhythmias in an Experimental Whole‐Heart Model of Short QT Syndrome

Effective suppression of atrial fibrillation by the antihistaminic agent antazoline: First experimental insights into a novel antiarrhythmic agent

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Nils Bögeholz

Proarrhythmia in a non-failing murine model of cardiac-specific Na+/Ca2+ exchanger overexpression: whole heart and cellular mechanisms

Suppression of Early and Late Afterdepolarizations by Heterozygous Knockout of the Na + /Ca 2+ Exchanger in a Murine Model

Ranolazine and Vernakalant Prevent Ventricular Arrhythmias in an Experimental Whole‐Heart Model of Short QT Syndrome

Effective suppression of atrial fibrillation by the antihistaminic agent antazoline: First experimental insights into a novel antiarrhythmic agent

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Product

Resources

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Suppression of Early and Late Afterdepolarizations by Heterozygous Knockout of the Na ⁺ /Ca ²⁺ Exchanger in a Murine Model