Rationale: Loss-of-function of the cardiac sodium channel Na V 1.5 causes conduction slowing and arrhythmias. Na V 1.5 is differentially distributed within subcellular domains of cardiomyocytes, with sodium current (I Na ) being enriched at the intercalated discs (ID). Various pathophysiological conditions associated with lethal arrhythmias display ID-specific I Na reduction, but the mechanisms underlying microdomain-specific targeting of Na V 1.5 remain largely unknown. Objective: To investigate the role of the microtubule (MT) plus-end tracking proteins end binding protein 1 (EB1) and CLIP-associated protein 2 (CLASP2) in mediating Na V 1.5 trafficking and subcellular distribution in cardiomyocytes. Methods and Results: EB1 overexpression in human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) resulted in enhanced whole-cell I Na , increased action potential (AP) upstroke velocity (V max ), and enhanced Na V 1.5 localization at the plasma membrane as detected by multi-color stochastic optical reconstruction microscopy (STORM). Fluorescence recovery after photobleaching (FRAP) experiments in HEK293A cells demonstrated that EB1 overexpression promoted Na V 1.5 forward trafficking. Knockout of MAPRE1 in hiPSC-CMs led to reduced whole-cell I Na , decreased V max and AP duration (APD) prolongation. Similarly, acute knockout of the MAPRE1 homolog in zebrafish (mapre1b) resulted in decreased ventricular conduction velocity and V max as well as increased APD. STORM imaging and macropatch I Na measurements showed that subacute treatment (2-3 hours) with SB216763 (SB2), a GSK3β inhibitor known to modulate CLASP2-EB1 interaction, reduced GSK3β localization and increased Na V 1.5 and I Na preferentially at the ID region of wild type murine ventricular cardiomyocytes. By contrast, SB2 did not affect whole cell I Na or Na V 1.5 localization in cardiomyocytes from Clasp2-deficient mice, uncovering the crucial role of CLASP2 in SB2-mediated modulation of NaV1.5 at the ID. Conclusions: Our findings demonstrate the modulatory effect of the MT plus-end tracking protein EB1 on Na V 1.5 trafficking and function, and identify the EB1-CLASP2 complex as a target for preferential modulation of I Na within the ID region of cardiomyocytes.
Rationale: Genome-wide association studies previously identified an association of rs9388451 at chromosome 6q22.3 (near HEY2 ) with Brugada syndrome. The causal gene and underlying mechanism remain unresolved. Objective: We used an integrative approach entailing transcriptomic studies in human hearts and electrophysiological studies in Hey2 +/− ( Hey2 heterozygous knockout) mice to dissect the underpinnings of the 6q22.31 association with Brugada syndrome. Methods and Results: We queried expression quantitative trait locus data acquired in 190 human left ventricular samples from the genotype-tissue expression consortium for cis -expression quantitative trait locus effects of rs9388451, which revealed an association between Brugada syndrome risk allele dosage and HEY2 expression (β=+0.159; P =0.0036). In the same transcriptomic data, we conducted genome-wide coexpression analysis for HEY2 , which uncovered KCNIP2 , encoding the β-subunit of the channel underlying the transient outward current ( I to ), as the transcript most robustly correlating with HEY2 expression (β=+1.47; P =2×10 −34 ). Transcript abundance of Hey2 and the I to subunits Kcnip2 and Kcnd2 , assessed by quantitative reverse transcription–polymerase chain reaction, was higher in subepicardium versus subendocardium in both left and right ventricles, with lower levels in Hey2 +/− mice compared with wild type. Surface ECG measurements showed less prominent J waves in Hey2 +/− mice compared with wild-type. In wild-type mice, patch-clamp electrophysiological studies on cardiomyocytes from right ventricle demonstrated a shorter action potential duration and a lower V max in subepicardium compared with subendocardium cardiomyocytes, which was paralleled by a higher I to and a lower sodium current ( I Na ) density in subepicardium versus subendocardium. These transmural differences were diminished in Hey2 +/− mice because of changes in subepicardial cardiomyocytes. Conclusions: This study uncovers a role of HEY2 in the normal transmural electrophysiological gradient in the ventricle and provides compelling evidence that genetic variation at 6q22.31 (rs9388451) is associated with Brugada syndrome through a HEY2 -dependent alteration of ion channel expression across the cardiac ventricular wall.
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