Hypernatremia and Intercalated Disc Edema Synergistically Exacerbate Long QT Syndrome Type 3 Phenotype

Background: Cardiac voltage-gated sodium channel gain-of-function prolongs repolarization in the Long-QT Syndrome Type 3 (LQT3). Previous studies suggest that narrowing the perinexus within the intercalated disc, leading to rapid sodium depletion, attenuates LQT3-associated action potential duration (APD) prolongation. However, it remains unknown whether extracellular sodium concentration modulates APD prolongation during sodium channel gain-of-function. We hypothesized that elevated extracellular sodium concentration and widened perinexus synergistically prolong APD in LQT3. Methods and Results: LQT3 was induced with anemone toxin type II (ATXII) in Langendorff-perfused guinea pig hearts (n=20). Sodium concentration was increased from 145 to 160 mM. Perinexal expansion was induced with mannitol or the sodium channel β1-subunit adhesion domain antagonist (βadp1). Epicardial ventricular action potentials were optically mapped. Individual and combined effects of varying clefts and sodium concentrations were simulated in a computational model. With ATXII, both mannitol and βadp1 significantly widened the perinexus and prolonged APD, respectively. The elevated sodium concentration alone significantly prolonged APD as well. Importantly, the combination of elevated sodium concentration and perinexal widening synergistically prolonged APD. Computational modeling results were consistent with animal experiments. Conclusions: Concurrently elevating extracellular sodium and increasing intercalated disc edema prolongs repolarization more than the individual interventions alone in the LQT3. This synergistic effect suggests an important clinical implication that hypernatremia in the presence of cardiac edema can markedly increase LQT3-associated APD prolongation. Therefore, this is the first study to provide evidence of a tractable and effective strategy to mitigate LQT3 phenotype by managing patient sodium levels and preventing cardiac edema.

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Abstract 13191: Increased Extracellular Sodium and Intercellular Cleft Separation Synergistically Prolong Repolarization in the Long-qt Syndrome Type 3

Circulation ◽

10.1161/circ.142.suppl_3.13191 ◽

2020 ◽

Vol 142 (Suppl_3) ◽

Author(s):

Xiaobo Wu ◽

Gregory HOEKER ◽

David Ryan King ◽

Robert G Gourdie ◽

Seth Weinberg ◽

...

Keyword(s):

Long Qt Syndrome ◽

Sodium Current ◽

Syndrome Type ◽

Long Qt ◽

Late Sodium Current ◽

Individual Effects ◽

Qt Syndrome ◽

The Individual ◽

Extracellular Sodium ◽

Type 3

Introduction: Long-QT syndrome type 3 (LQT3) is caused by a gain-of-function mutation in the cardiac sodium channel that increases the late sodium current and prolongs repolarization. We previously suggested that narrowing the perinexus which is adjacent gap junction conceals the LQT3 phenotype by depleting extracellular sodium ([Na]) within this nanodomain and curtails the late current and repolarization. However, it is unknown if elevating bulk [Na] alone modulates action potential duration (APD) in widened perinexi to unmask LQT3. Hypothesis: Elevated [Na] and widened perinexi synergistically prolong APD in LQT3. Methods: The dependence of APD on [Na] and perinexal width was explored with a computational model and in Langendorff-perfused guinea pig hearts. The late sodium current was induced with ATXII (7nM). Perfusate [Na] changed from 145 (145Na) to 160 mM (160Na). Perinexal expansion was induced with βadp1 (1uM). APD was quantified from whole-heart optical maps. Perinexal width was quantified by transmission electron microscopy. Results: A computational model, including preferential sodium channel location at the intercalated disk, predicts that combination of elevated [Na] and widened perinexus prolongs APD greater than summing the effect of the individual interventions alone. Therefore, the combination is synergistic and not additive. Isolated heart experiments are consistent with the model. Specifically, ATXII+βadp1 significantly widens perinexal width from 27.8±4.1 to 49.7±9.3 nm and prolongs APD by 18.1±5.1ms with 600ms pacing relative to ATXII alone. In the presence of ATXII, 160Na significantly prolongs APD by 12.0±5.8ms relative to 145Na. Furthermore, the combination of both interventions is synergistic. Specifically, in the presence of ATXII, 160Na+βadp1 significantly prolongs APD more than the sum of the individual effects (49.9±7.5ms vs. 30.2±5.4ms). Conclusions: The data demonstrate that in LQT3, enhancing sodium and perinexal width concurrently prolong APD more than the individual effects alone. This synergistic effect suggests that maintaining reduced plasma sodium level can be a simple and effective method to conceal LQT3, even in the presence of perinexal expansion associated with osmotically induced stress.

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