Electrophysiological Remodeling Research Articles

Sex Differences in Electrophysiology and Calcium Handling in Atrial Health and Fibrillation.

The importance of biological sex on disease etiology and outcomes has long been underinvestigated. While recent focus on characterizing sex differences in cardiac pathophysiology has led to improved inclusion of both sexes in scientific studies and clinical trials, much is still unknown about underlying differences in normal cardiac physiology. This is particularly true for the atria, where the most common arrhythmia, atrial fibrillation (AF), occurs. AF is associated with adverse structural, electrophysiological, and calcium handling remodeling that leads to patient morbidity and mortality. Differences in the onset, prevalence, presentation, and prognosis of AF are known to differ between males and females, yet the sex-specific baseline phenotypes from which AF arises are not well characterized. This review examines what is currently known about sex differences in atrial physiology, the alterations that occur in AF, potential mechanisms underlying sex divergence, and the need for sex-targeted therapeutic strategies.

Neuro- and immuno-modulation mediated by the cardiac sympathetic nerve: a novel insight into the anti-ischemic efficacy of acupuncture.

Communication between sympathetic nerves and the immune system is a crucial and active process during myocardial ischemia (MI), as myocardial damage and inflammatory stimuli concurrently occur. Sympathetic nerves undergo structural and functional changes after MI, leading to adverse left ventricular (LV) remodeling and heart failure (HF). The complex inflammatory response to MI, including local myocardial anti-inflammatory repair and systemic immune reactions, plays a key role in adverse LV remodeling. Here, we review the progressive structural and electrophysiological remodeling of the LV and the involvement of sympathetic tone in complex and dynamic processes that are susceptible to MI pathological conditions. Acupuncture has been reported to effectively improve cardiac function, eliminate arrhythmia, and mitigate adverse LV remodeling via somatosensory regulation after MI. Moreover, acupuncture has an anti-inflammatory effect on the pathological process of myocardial ischemia. In this Review, we aim to summarize the involvement of sympathetic nerve activation in the neuro-immune modulation of structural and functional cardiac changes after MI. As a noninvasive method for sympathetic regulation, acupuncture is an ideal option because of its anti-ischemic efficacy. A better understanding of the neural circuitry that regulates cardiac function and immune responses following MI could reveal novel targets for acupuncture treatment.

Sympathetic structural and electrophysiological remodeling in a rabbit model of reperfused myocardial infarction.

Chondroitin sulfate proteoglycans (CSPGs) inhibit sympathetic reinnervation in rodent hearts post-myocardial infarction (MI), causing regional hypoinnervation that is associated with supersensitivity of β-adrenergic receptors and increased arrhythmia susceptibility. To investigate the role of CSPGs and hypoinnervation in the heart of larger mammals, we used a rabbit model of reperfused MI and tested electrophysiological responses to sympathetic nerve stimulation (SNS). Innervated hearts from MI and sham rabbits were optically mapped using voltage and Ca2+-sensitive dyes. SNS was performed with electrical stimulation of the spinal cord, and β-adrenergic responsiveness was tested using isoproterenol. Sympathetic nerve density and CSPG expression were evaluated using immunohistochemistry. CSPGs were robustly expressed in the infarct region of all MI hearts, and the presence of CSPGs was associated with reduced sympathetic nerve density in the infarct versus remote region. Action potential duration (APD) dispersion and tendency for induction of ventricular tachycardia/fibrillation (VT/VF) were increased with SNS in MI but not sham hearts. SNS decreased APD at 80% repolarization (APD80) in MI but not sham hearts, whereas isoproterenol decreased APD80 in both groups. Isoproterenol also shortened Ca2+ transient duration at 80% repolarization in both groups but to a greater extent in MI hearts. Our data suggest that sympathetic remodeling post-MI is similar between rodents and rabbits, with CSPGs associated with sympathetic hypoinnervation. Despite a reduction in sympathetic nerve density, the infarct region of MI hearts remained responsive to both physiological SNS and isoproterenol, potentially through preserved or elevated β-adrenergic responsiveness, which may underlie increased APD dispersion and tendency for VT/VF.NEW & NOTEWORTHY Here, we show that CSPGs are present in the infarcts of rabbit hearts with reperfused MI, where they are associated with reduced sympathetic nerve density. Despite hypoinnervation, sympathetic responsiveness is maintained or enhanced in MI rabbit hearts, which also demonstrate increased APD dispersion and tendency for arrhythmias following sympathetic modulation. Together, this study indicates that the mechanisms of sympathetic remodeling post-MI are similar between rodents and rabbits, with hypoinnervation likely associated with enhanced β-adrenergic sensitivity.

Abstract Or105: Constitutive Deletion of the Obscurin Ig58/59 Domains Induces Structural and Electrophysiological Remodeling in Atria

Introduction: Obscurin is a giant cytoskeletal protein that supports muscle development, tethers intracellular compartments and regulates contraction. In the ObscnΔIg58/59 mouse model, expressing obscurin lacking Immunoglobulin (Ig) domains 58 and 59, aging males exhibit irregular heart rhythm with prominent atrial fibrillation, atrial enlargement, and progressive remodeling of the ventricles. A mechanistic basis for the emergence of arrhythmia early on could not be identified in ObscnΔIg58/59 ventricles, suggesting that the atria are preferentially impacted by deletion of the obscurin Ig58/59 module prior to the ventricles. Hypothesis: We hypothesize that Ig58/59 deletion elicits unique structural, electrical, and functional consequences in the atria preceding ventricular maladaptation. Aims: I. Examine the structural organization of ObscnΔIg58/59 atria II. Assess Ca 2+ handling in isolated atrial cardiomyocytes and determine molecular alterations. Methods: Electron microscopy and super resolution microscopy were utilized to visualize sarcomeric ultrastructure and the transverse-axial tubule (TAT) network, respectively. Ca 2+ handling activity and synchrony were also resolved, while Phos-Tag gels were used to quantify T-cap phospho-species. Results: ObscnΔIg58/59 atria exhibited misalignment of Z-disks. Spontaneous and stimulated Ca 2+ cycling behavior were [AB1] differentially disrupted in atrial cardiomyocytes in 6- and 12-month ObscnΔIg58/59 males. Relatedly, atrial cells showed an age-dependent deterioration in TAT architecture. Finally, as a function of aging, ObscnΔIg58/59 atria displayed alterations in the expression and phosphorylation of T-cap, a Z-disk protein implicated in the integration of t-tubules with the sarcomeric cytoskeleton. Conclusions: The structural and electrical alterations that arise in ObscnΔIg58/59 atria precede ventricular dysfunction and coincide with the emergence of atrial fibrillation. Collectively, our work indicates that the atria are principally affected by Ig58/59 elimination, instigating arrhythmias and morphological alterations with age. The ObscnΔIg58/59 mouse model has thus emerged as a proxy for atrial cardiomyopathy.

The Role of KACh Channels in Atrial Fibrillation.

This manuscript explores the intricate role of acetylcholine-activated inward rectifier potassium (KACh) channels in the pathogenesis of atrial fibrillation (AF), a common cardiac arrhythmia. It delves into the molecular and cellular mechanisms that underpin AF, emphasizing the vital function of KACh channels in modulating the atrial action potential and facilitating arrhythmogenic conditions. This study underscores the dual nature of KACh activation and its genetic regulation, revealing that specific variations in potassium channel genes, such as Kir3.4 and K2P3.1, significantly influence the electrophysiological remodeling associated with AF. Furthermore, this manuscript identifies the crucial role of the KACh-mediated current, IKACh, in sustaining arrhythmia through facilitating shorter re-entry circuits and stabilizing the re-entrant circuits, particularly in response to vagal nerve stimulation. Experimental findings from animal models, which could not induce AF in the absence of muscarinic activation, highlight the dependency of AF induction on KACh channel activity. This is complemented by discussions on therapeutic interventions, where KACh channel blockers have shown promise in AF management. Additionally, this study discusses the broader implications of KACh channel behavior, including its ubiquitous presence across different cardiac regions and species, contributing to a comprehensive understanding of AF dynamics. The implications of these findings are profound, suggesting that targeting KACh channels might offer new therapeutic avenues for AF treatment, particularly in cases resistant to conventional approaches. By integrating genetic, cellular, and pharmacological perspectives, this manuscript offers a holistic view of the potential mechanisms and therapeutic targets in AF, making a significant contribution to the field of cardiac arrhythmia research.

Sympathetic structural and electrophysiological remodeling in a rabbit model of reperfused myocardial infarction.

Here we show that CSPGs are present in the infarcts of rabbit hearts with reperfused MI, where they are associated with reduced sympathetic nerve density. Despite hypo-innervation, sympathetic responsiveness is maintained or enhanced in MI rabbit hearts, which also demonstrate increased APD dispersion and tendency for arrhythmias following sympathetic modulation. Together, this study indicates that the mechanisms of sympathetic remodeling post-MI are similar between species, with hypo-innervation likely associated with enhanced β-adrenergic sensitivity.

Activation of Exchange Proteins directly Activated by cAMP (EPAC) promotes electrophysiological remodeling and arrhythmogenic activity in human atrial cardiomyocytes

Activation of Exchange Proteins directly Activated by cAMP (EPAC) promotes electrophysiological remodeling and arrhythmogenic activity in human atrial cardiomyocytes

Metabolic remodelling in atrial fibrillation: manifestations, mechanisms and clinical implications.

Atrial fibrillation (AF) is a continually growing health-care burden that often presents together with metabolic disorders, including diabetes mellitus and obesity. Current treatments often fall short of preventing AF and its adverse outcomes. Accumulating evidence suggests that metabolic disturbances can promote the development of AF through structural and electrophysiological remodelling, but the underlying mechanisms that predispose an individual to AF are aetiology-dependent, thus emphasizing the need for tailored therapeutic strategies to treat AF that target an individual's metabolic profile. AF itself can induce changes in glucose, lipid and ketone metabolism, mitochondrial function and myofibrillar energetics (as part of a process referred to as 'metabolic remodelling'), which can all contribute to atrial dysfunction. In this Review, we discuss our current understanding of AF in the setting of metabolic disorders, as well as changes in atrial metabolism that are relevant to the development of AF. We also describe the potential of available and emerging treatment strategies to target metabolic remodelling in the setting of AF and highlight key questions and challenges that need to be addressed to improve outcomes in these patients.

Bioenergetics and mitochondrial deregulation underlie self-sustained persistency of atrial fibrillation in an ovine model

Abstract Background Atrial fibrillation (AF) often transitions from paroxysmal to more sustained forms in a 4-15/100 person-year range(1). It is well-recognized from both clinical and animal studies that some individuals undergo this transition much more readily than others, but the underlying mechanisms remain unclear. Purpose To identify potential differences in atrial bioenergetics between animals developing stable AF (AF-S) versus those resistant to this transition (AF-R) in a sheep AF-model. Methods AF was induced through repeated bursts of atrial tachystimulation (2). Stability of AF was monitored with telemetry. In-vivo electrophysiological remodeling was assessed via contact mapping. Metabolic and bioenergetic remodeling were evaluated using frozen left atrial appendage (LAA) tissues and isolated LAA mitochondria. Results AF-S sheep developed stable (>24-hour self-sustained) AF after 13 (range 5-22) days on average, whereas AF-R sheep failed to develop stable AF despite 120-day tachystimulation. Contact mapping and histological analysis revealed similar electro-anatomical remodeling in AF-S and AF-R groups, with the only significant difference observed in the decrease of activation time and conduction velocity in the AF-S atria. Both AF-S and AF-R animals displayed a notable increase in mitochondrial mass. Proteomic analysis showed significant differences in metabolism-related proteins and pathways between AF-S and AF-R, in particular concerning the anaplerotic supplementation of the tricarboxylic acid cycle at the level of α-ketoglutarate. Furthermore, compared to AF-R, AF-S LAA exhibited a 45% increase in succinate content, and a 23% decrease in ATP and Creatine Phosphate (PCr) content, suggesting a pathological metabolic alteration linked to a bioenergetic default. AF-S mitochondria presented abnormal succinate-oxidation, associated with a significant 20% decrease in ATP-synthesis rate, 22% increase in ROS-production, mitochondrial-membrane hyperpolarization, and decreased Complex I/II specific activity ratio. AF-S mitochondria alterations were prevented by complex I inhibitor S1QEL1.1, hinting to a participation of mitochondrial ROS into the mechanism of AF stabilization. In vivo acute intravenous perfusion of succinate in rats made them more susceptible to more frequent (OR 35 CI=[1.63-449.80]) and longer AF episodes upon treansesophageal stimulation; this vulnerability to AF was prevented by intraperitoneal pretreatment with SQEL1.1. Conclusions Resistance to AF-stabilization is associated with specific bioenergetic remodeling. These findings provide new mechanistic insights into AF-resistance and might open avenues for novel therapeutic strategies for AF-management.

Bariatric surgery partially reverses subclinical proarrhythmic structural, electrophysiological, and autonomic changes in obesity

BackgroundObesity confers higher risks of cardiac arrhythmias. The extent to which weight loss reverses subclinical proarrhythmic adaptations in arrhythmia-free obese individuals is unknown. ObjectiveThe purpose of this study was to study structural, electrophysiological, and autonomic remodeling in arrhythmia-free obese patients and their reversibility with bariatric surgery using electrocardiographic imaging (ECGi). MethodsSixteen arrhythmia-free obese patients (mean age 43 ± 12 years; 13 (81%) female participants; BMI 46.7 ± 5.5 kg/m2) had ECGi pre–bariatric surgery, of whom 12 (75%) had ECGi postsurgery (BMI 36.8 ± 6.5 kg/m2). Sixteen age- and sex-matched lean healthy individuals (mean age 42 ± 11 years; BMI 22.8 ± 2.6 kg/m2) acted as controls and had ECGi only once. ResultsObesity was associated with structural (increased epicardial fat volumes and left ventricular mass), autonomic (blunted heart rate variability), and electrophysiological (slower atrial conduction and steeper ventricular repolarization time gradients) remodeling. After bariatric surgery, there was partial structural reverse remodeling, with a reduction in epicardial fat volumes (68.7 cm3 vs 64.5 cm3; P = .0010) and left ventricular mass (33 g/m2.7 vs 25 g/m2.7; P < .0005). There was also partial electrophysiological reverse remodeling with a reduction in mean spatial ventricular repolarization gradients (26 mm/ms vs 19 mm/ms; P = .0009), although atrial activation remained prolonged. Heart rate variability, quantified by standard deviation of successive differences in R-R intervals, was also partially improved after bariatric surgery (18.7 ms vs 25.9 ms; P = .017). Computational modeling showed that presurgical obese hearts had a larger window of vulnerability to unidirectional block and had an earlier spiral-wave breakup with more complex reentry patterns than did postsurgery counterparts. ConclusionObesity is associated with adverse electrophysiological, structural, and autonomic remodeling that is partially reversed after bariatric surgery. These data have important implications for bariatric surgery weight thresholds and weight loss strategies.

Proteomics couples electrical remodelling to inflammation in a murine model of heart failure with sinus node dysfunction.

In patients with heart failure (HF), concomitant sinus node dysfunction (SND) is an important predictor of mortality, yet its molecular underpinnings are poorly understood. Using proteomics, this study aimed to dissect the protein and phosphorylation remodelling within the sinus node in an animal model of HF with concurrent SND. We acquired deep sinus node proteomes and phosphoproteomes in mice with heart failure and SND and report extensive remodelling. Intersecting the measured (phospho)proteome changes with human genomics pharmacovigilance data, highlighted downregulated proteins involved in electrical activity such as the pacemaker ion channel, Hcn4. We confirmed the importance of ion channel downregulation for sinus node physiology using computer modelling. Guided by the proteomics data, we hypothesized that an inflammatory response may drive the electrophysiological remodeling underlying SND in heart failure. In support of this, experimentally induced inflammation downregulated Hcn4 and slowed pacemaking in the isolated sinus node. From the proteomics data we identified proinflammatory cytokine-like protein galectin-3 as a potential target to mitigate the effect. Indeed, in vivo suppression of galectin-3 in the animal model of heart failure prevented SND. Collectively, we outline the protein and phosphorylation remodeling of SND in heart failure, we highlight a role for inflammation in electrophysiological remodelling of the sinus node, and we present galectin-3 signalling as a target to ameliorate SND in heart failure.

Semaglutide attenuates pathological electrophysiological remodeling in diabetic cardiomyopathy via restoring Cx43 expression.

Semaglutide is a relatively new anti-hyperglycemic agent that was shown to carry cardioprotective potentials. However, the exact effects of semaglutide on diabetic cardiomyopathy (DCM) and their underlining mechanism remain unclear. This study aimed to evaluate the effects of semaglutide on myocardium injury and cardiac function in DCM mice and its potential mechanisms, with emphasis on its effects on Cx43 and electrophysiological remodeling. C57BL/6 mice were randomly divided into four groups: control group, semaglutide group, diabetes group, and diabetes + semaglutide treatment group. Type 1 diabetes were induced by intraperitoneal injection of streptozotocin. Mice in the semaglutide intervention group were injected subcutaneously with semaglutide (0.15 mg/kg) every week for 8 weeks. The blood glucose, cardiac function, oxidative stress markers, apoptosis, expression of Sirt1, AMPK, Cx43, and electrocardiogram of mice in each group were evaluated. Treatment with semaglutide alleviated glucose metabolism disorders and improved cardiac dysfunction in diabetic mice. In addition, semaglutide ameliorated the increase in oxidative stress and apoptosis in diabetic heart. Sirt1/AMPK pathway was activated after semaglutide treatment. Furthermore, diabetic mice showed reduced expression of Cx43 in the myocardium, accompanied by changes in electrocardiogram, including significantly prolonged RR, QRS, QT and QTc interval. Semaglutide treatment restored Cx43 expression and reversed the above-mentioned ECG abnormalities. Our research results showed that semaglutide protected against oxidative stress and apoptosis in diabetic heart, thereby improving cardiac function and electrophysiological remodelling in DCM mice, which may attribute to activation of Sirt1/AMPK pathway and restore of Cx43 expression.

Late Presentation of Pulmonary Hypertension Crisis Concurrent with Atrial Arrhythmia after Atrial Septal Defect Device Closure

Background: ASD occurs when there is a septal defect between the right and left atria, resulting in a left-to-right shunt that increases the volume of the right heart and pulmonary circulation. Increased pulmonary resistance can lead to pulmonary hypertension (PH), resulting in progressive deterioration of right ventricular function, leading to right heart failure and death. Prolonged elevation of atrial pressure induces progressive atrial dilatation and electrophysiological remodelling. Together with autonomic modulation, this leads to atrial arrhythmias (AAs). Patients with significant shunts leading to ventricular volume overload are considered for ASD closure. However, in some cases, PH occurs after ASD closure.  Case Presentation: We report a 21 yo man diagnosed with ASD Secundum Post Closure with Device (September 1th, 2023) and Pulmonary Hypertension Crisis. The left atria (LA), right atria (RA) and right ventricle (RV) were dilated. We also found moderate mitral regurgitation, severe tricuspid regurgitation, and mild to moderate pulmonary regurgitation. There was a decline in systolic function in the right ventricle, and grade III diastolic dysfunction in left ventricle. There was a well-seated device with no residual shunt on interatrial septal. The pulmonary arteries were confluence and dilated. From ECG we found atrial flutter with variable conduction. This patient was transferred to HCU. This patient treated with digoxin, furosemide, milrinon, ceftriaxone, miniaspi, sildenafil, electrophysiology, and 3D ablation.  Conclusion: Pulmonary hypertension can occur in cases of congenital heart defects, such as ASD. The operative management of ASD is closure of the ASD, but in some unique groups, this can lead to pulmonary hypertensive crisis after its closure.

Atrial cardiomyocytes contribute to the inflammatory status associated with atrial fibrillation in right heart disease.

Right heart disease (RHD), characterized by right ventricular (RV) and atrial (RA) hypertrophy, and cardiomyocytes' (CM) dysfunctions have been described to be associated with the incidence of atrial fibrillation (AF). Right heart disease and AF have in common, an inflammatory status, but the mechanisms relating RHD, inflammation, and AF remain unclear. We hypothesized that right heart disease generates electrophysiological and morphological remodelling affecting the CM, leading to atrial inflammation and increased AF susceptibility. Pulmonary artery banding (PAB) was surgically performed (except for sham) on male Wistar rats (225-275 g) to provoke an RHD. Twenty-one days (D21) post-surgery, all rats underwent echocardiography and electrophysiological studies (EPS). Optical mapping was performed in situ, on Langendorff-perfused hearts. The contractility of freshly isolated CM was evaluated and recorded during 1 Hz pacing in vitro. Histological analyses were performed on formalin-fixed RA to assess myocardial fibrosis, connexin-43 levels, and CM morphology. Right atrial levels of selected genes and proteins were obtained by qPCR and Western blot, respectively. Pulmonary artery banding induced severe RHD identified by RV and RA hypertrophy. Pulmonary artery banding rats were significantly more susceptible to AF than sham. Compared to sham RA CM from PAB rats were significantly elongated and hypercontractile. Right atrial CM from PAB animals showed significant augmentation of mRNA and protein levels of pro-inflammatory interleukin (IL)-6 and IL1β. Sarcoplasmic-endoplasmic reticulum Ca2+-ATPase-2a (SERCA2a) and junctophilin-2 were decreased in RA CM from PAB compared to sham rats. Right heart disease-induced arrhythmogenicity may occur due to dysfunctional SERCA2a and inflammatory signalling generated from injured RA CM, which leads to an increased risk of AF.

Loss of Cardiac PFKFB2 Drives Metabolic, Functional, and Electrophysiological Remodeling in the Heart.

Phosphofructo-2-kinase/fructose-2,6-bisphosphatase (PFK-2) is a critical glycolytic regulator responsible for upregulation of glycolysis in response to insulin and adrenergic signaling. PFKFB2, the cardiac isoform of PFK-2, is degraded in the heart in the absence of insulin signaling, contributing to diabetes-induced cardiac metabolic inflexibility. However, previous studies have not examined how the loss of PFKFB2 affects global cardiac metabolism and function. To address this, we have generated a mouse model with a cardiomyocyte-specific knockout of PFKFB2 (cKO). Using 9-month-old cKO and control mice, we characterized the impacts of PFKFB2 on cardiac metabolism, function, and electrophysiology. cKO mice have a shortened life span of 9 months. Metabolically, cKO mice are characterized by increased glycolytic enzyme abundance and pyruvate dehydrogenase activity, as well as decreased mitochondrial abundance and beta oxidation, suggesting a shift toward glucose metabolism. This was supported by a decrease in the ratio of palmitoyl carnitine to pyruvate-dependent mitochondrial respiration in cKO relative to control animals. Metabolomic, proteomic, and Western blot data support the activation of ancillary glucose metabolism, including pentose phosphate and hexosamine biosynthesis pathways. Physiologically, cKO animals exhibited impaired systolic function and left ventricular dilation, represented by reduced fractional shortening and increased left ventricular internal diameter, respectively. This was accompanied by electrophysiological alterations including increased QT interval and other metrics of delayed ventricular conduction. Loss of PFKFB2 results in metabolic remodeling marked by cardiac ancillary pathway activation. This could delineate an underpinning of pathologic changes to mechanical and electrical function in the heart.

Adipocyte-mediated electrophysiological remodeling of human stem cell - derived cardiomyocytes

Adipocytes normally accumulate in the epicardial and pericardial layers around the human heart, but their infiltration into the myocardium can be proarrhythmic. Methods and resultsHuman adipose derived stem/stromal cells and human induced pluripotent stem cells (hiPSC) were differentiated, respectively into predominantly white fat-like adipocytes (hAdip) and ventricular cardiomyocytes (CMs). Adipocytes cultured in CM maintenance medium (CM medium) maintained their morphology, continued to express adipogenic markers, and retained clusters of intracellular lipid droplets. In contrast, hiPSC-CMs cultivated in adipogenic growth medium displayed abnormal cell morphologies and more clustering across the monolayer. Pre-plated hiPSC-CMs co-cultured in direct contact with hAdips in CM medium displayed prolonged action potential durations, increased triangulation, slowed conduction velocity, increased conduction velocity heterogeneity, and prolonged calcium transients. When hAdip-conditioned medium was added to monolayer cultures of hiPSC-CMs, results similar to those recorded with direct co-cultures were observed. Both co-culture and conditioned medium experiments resulted in increases in transcript abundance of SCN10A, CACNA1C, SLC8A1, and RYR2, with a decrease in KCNJ2. Human adipokine immunoblots revealed the presence of cytokines that were elevated in adipocyte-conditioned medium, including MCP-1, IL-6, IL-8 and CFD that could induce electrophysiological changes in cultured hiPSC-CMs. ConclusionsCo-culture of hiPSC-CMs with hAdips reveals a potentially pathogenic role of infiltrating human adipocytes on myocardial tissue. In the absence of structural changes, hAdip paracrine release alone is sufficient to cause CM electrophysiological dysfunction mirroring the co-culture conditions. These effects, mediated largely by paracrine mechanisms, could promote arrhythmias in the heart.

Computational analysis of long QT syndrome type 2 and the therapeutic effects of KCNQ1 antibodies.

Long QT interval syndrome (LQTS) is a highly dangerous cardiac disease that can lead to sudden cardiac death; however, its underlying mechanism remains largely unknown. This study is conceived to investigate the impact of two general genotypes of LQTS type 2, and also the therapeutic effects of an emerging immunology-based treatment named KCNQ1 antibody. A multiscale virtual heart is developed, which contains multiple biological levels ranging from ion channels to a three-dimensional cardiac structure with realistic geometry. Critical biomarkers at different biological levels are monitored to investigate the remodeling of cardiac electrophysiology induced by mutations. Simulations revealed multiple important mechanisms that are hard to capture via conventional clinical techniques, including the augmented dispersion of repolarization, the increased vulnerability to arrhythmias, the impaired adaptability in tissue to high heart rates, and so on. An emerging KCNQ1 antibody-based therapy could rescue the prolonged QT interval but did not reduce the vulnerable window. Tiny molecular alterations can lead to cardiac electrophysiological remodeling at multiple biological levels, which in turn contributes to higher susceptibility to lethal arrhythmias in long QT syndrome type 2 patients. The KCNQ1 antibody-based therapy has proarrhythmic risks notwithstanding its QT-rescuing effects.

PDE2 is cardioprotective in chronic heart failure

Abstract Background Patients with chronic heart failure (HF) often develop life-threatening arrhythmia due to structural and electrophysiological cardiac remodelling. The chronic activation of the sympathetic nervous system is initially able to compensate the reduced myocardial contraction. Finally, long-term activation of the β-adrenergic pathway leads to deleterious activation of cAMP-dependent kinases and dysregulation of intracellular Ca2+ handling promoting HF progression and development of arrhythmia. Interestingly, phosphodiesterase 2 (PDE2), an enzyme to hydrolyze cAMP, is upregulated in human HF. Thus, PDE2 might reduce enhanced cAMP levels and pro-arrhythmic Ca2+ releases in HF. Purpose We investigated the effects of genetic PDE2 deletion on cardiac function, cellular contraction and arrhythmia occurrence in murine HF model. Methods HF was induced via high fat (60 %) diet (HFD) and the treatment with NO-synthase inhibitor L-NAME (0.5 g/l) for 5 weeks in cardiomyocyte-specific PDE2-knockout mice (KO) and control mice (WT). We characterized cardiac function by echocardiography, arrhythmia development by ECG-telemetry, cellular contraction by video-based analysis of sarcomere-shortening and cellular Ca2+ releases using Ca2+ imaging techniques. Results After 5 weeks HFD and L-NAME, mice gained weight, displayed increased blood pressure and reduced systolic and diastolic cardiac function. Interestingly, PDE2 KO showed reduced contractility and ejection fraction compared to WT mice after 5 weeks HF. On cellular level, the contraction of isolated cardiomyocytes slightly increased in HF indicating cardiac hypertrophy. However, the β-adrenergic stimulation with isoprenaline (ISO) enhanced cellular contraction only in non-failing WT mice, but was blunted in cells from failing WT hearts reflecting a desensitization of the β-adrenergic pathway. In contrast, the ISO-induced increase in cellular contraction was preserved in failing hearts from KO mice. Interestingly, PDE2 inhibition with BAY 60-7550 increased the ISO-induced cellular contraction in HF from WT, which was not observed in cells from non-failing mice. In HF, the expression of Ca2+ cycling proteins like phospholamban (PLB) were affected. Failing PDE2 KO mice showed higher phosphorylation levels of PLB compared to WT mice with HF. In diseased hearts, pro-arrhythmic triggers like spontaneous Ca2+ waves and Ca2+ sparks were increased. Importantly, diseased PDE2 KO mice developed more arrhythmia in-vivo upon arrhythmia provocation than WT animals. Conclusion Cardiac PDE2 deletion was detrimental in HF showing reduced cardiac function and higher number of arrhythmia. PDE2 stimulation might serve as potential therapeutical target in HF limiting the consequences of chronic β-adrenergic hyperactivation.

Atrial fibrosis and local right atrial inflammation are characteristic of strenuous, but not moderate exercise, and underlie increased AF inducibility in heavily trained rats

Abstract Introduction The U-shaped relationship between exercise load and atrial fibrillation (AF) risk, where moderate exercise is protective but strenuous training increases the risk of AF, is currently well accepted (1, 2). Clinical and experimental data suggest that atrial fibrosis and parasympathetic tone (PT) enhancement may underlie the excess risk of AF in endurance athletes (3). Delving into the atrial differences between moderate exercise and strenuous training may be important to understand the pathophysiology of exercise-induced AF. Purpose To compare the atrial structural, electrophysiological and molecular remodelling occurring after long-term moderate and strenuous exercise. Methods Male Wistar rats were randomly assigned to sedentary (SED), moderate (MOD, 35 cm/s, 45 minutes) or high intensity exercise (INT, 60 cm/s, 60 minutes) for 16 weeks. An electrocardiogram (ECG) and electrophysiological study (EPS) were performed before sacrifice. Left (LA) and right (RA) atrial samples were collected for fibrosis assessment and a mRNA array. Results After the exercise protocol, weight of SED rats was higher (486±77 g) compared with both the MOD (377±28 g) and INT groups (385±43 g). In the ECG (Figure 1), INT rats presented a prolonged P-wave compared with SED and MOD. Both trained groups presented with significant bradycardia compared with SED, along with enhanced PT (heart rate variability: low to high frequency ratio). The remaining ECG parameters were similar between groups. Consistent with an enhanced PT, the Wenckebach cycle length was similarly prolonged in both trained groups in the EPS. Conversely, the sinus node recovery time was prolonged in INT rats compared with SED and MOD. AF inducibility increased from SED to MOD to INT. Myocardial fibrosis was measured in atrial samples stained with Sirius red. In both the RA and LA, fibrosis was significantly higher in the INT group (6,3±0.8 %) compared with the SED (4,4±0.2 %) and MOD (4,3±0.5 %) groups. An mRNA array showed large differences between atria. 384 and 419 genes were deregulated between INT and MOD (nominal p&amp;lt;0.05) in the RA and LA, respectively. Only 19 genes were consistent between both atria. In pathway analyses, the inflammatory response pathway was enriched (upregulation) in the RA, but not in the LA, of INT rats compared with MOD (Figure 2). Conclusions In healthy rats, strenuous training promoted a differential, pathological remodelling involving atrial fibrosis and sinus node dysfunction, compared with moderate exercise. Local inflammation may play a role in strenuous exercise-induced fibrosis in the RA. PT enhancement was similar in both groups.Figure 1.Figure 2.

In vitro model of atrial fibrillation: investigating the initiation and maintenance mechanisms of atrial remodeling using hiPSC-derived atrial cardiomyocytes

Abstract Despite atrial fibrillation (AF) being a common, clinically important, and economically significant public health problem, the initiation mechanisms of atrial remodeling during AF is still unclear. Furthermore, really few experimental models have the power to investigate these mechanisms in a human invitro two-dimensional (2D) monolayer of atrial cardiomyocytes. The purpose of this work is to use human induced pluripotent stem cell (hiPSC)-derived atrial cardiomyocytes to develop a new human in vitro atrial model of AF able to reproduce and evaluate the arrhythmia initiation and maintenance mechanisms. Two different hiPSC lines were differentiated into atrial cardiomyocytes using 1 µM retinoic acid from day 3 to day 8. Protocol to differentiate atrial cells was compared with the classical method to generate ventricular hiPSC to demonstrate atrial specificity. On day 20 of the differentiation cells were seeded into plates with different sizes: 0.32 cm2 and 9.6 cm2, a larger size that allows rotor formation. After 10 days qPCR and optical mapping experiments were performed at 37˚C. These experiments aimed to evaluate the electrophysiologic and genetic remodeling the Cells undergo during AF initiation and maintenance. The atrial phenotype was assessed by patch clamp recordings that showed cells treated with RA had significantly shorter action potential duration at 90% repolarization compared to the no RA treated, 182.3.5 ± 68 ms and 371.6 ± 82 ms, faster depolarization rate and higher spontaneous beating frequency (n=14, ± SD). Optical mapping experiments allowed the evaluation of activation rate depending on the size of the dish: larger wells activated spontaneously at 1.6 ± 1.9 Hz, whereas smaller wells presented 0.9 ± 0.5 Hz of activation rate. The fast activation rate on larger wells was associated higher number of reentrant wavefronts: 11.0 ± 8.2 reentries/cm2, vs 0.9 ± 0.5 reentries/cm2 in the smaller wells, demonstrating an AF phenotype. In fact, depending on the culture conditions cells showed different reentries occurrence: 100% of large dishes exhibited fibrillation compared to only 10% of small dishes. Furthermore, qPCR studies demonstrated that the spontaneous initiation and maintenance of rotors in the larger well sizes lead to an expression remodeling of the channels SCN5A, KCNJ2, GJA5, ATP2A2, and RYR2 as previously demonstrated on isolated tissue from AF patients. We conclude that atrial cardiomyocytes obtained from hiPSC can recapitulate the remodeling that atrial tissue undergoes during AF initiation in patients. Providing a unique opportunity to study the initiation of fibrillatory activities and their maintenance in a human-relevant in-vitro model.hiPSC-aCM characterizationElectrophysiologic &amp; genetic remodeling