Atrial Cardiomyocytes Research Articles

Calcitonin signalling system regulates function and arhythmogenicity of atrial cardiomyocytes

Abstract Background Atrial fibrillation (AF) poses a significant therapeutic challenge due to myocardial remodelling, involving both structural and electrical alterations. Recent investigations have shed light on the role of atrial cardiomyocytes (CMs) in secreting Calcitonin (CT), a factor crucial for maintaining atrial tissue integrity. Dysregulated CT secretion in AF showed to contribute to fibrotic tissue production by atrial fibroblasts, exacerbating arrhythmogenesis [1]. However, the direct impact of CT on CM function and arrhythmogenicity remains unclear, driving the objectives of our study. Methods/Results Serum samples from 20 cardiac surgery patients revealed a noteworthy association between higher pre-operative CT levels and a significant ~2.8-fold reduction in the incidence of post-operative AF (poAF). Using freshly isolated atrial guinea pig CMs, confirmed (by qPCR and immunofluorescence) that CMs express CT-receptor (CTR) to enable CT actions in the cell. Functional studies found that CT administration inhibits spontaneous calcium (Ca2+)-release events induced by pacing and decreases the Ca2+ transients amplitude (at 2 Hz; IonOptix μstep system) in fura2-loaded CMs (n=22 cells) in a concentration-dependent manner. Atrial iPSC-CMs transduced with global RGECO sensor (Genetically encoded Ca2+ indicator) and treated with 15 pM CT showed a reduction in the beat rate when paced at 2Hz, and a significantly increased the time to 50% baseline. Evaluation of the expression and phosphorylation of selected Ca2+ handling proteins, which may potentially account for the observed changes in Ca2+ transients, showed no differences in total or phospho-(ser2808) ryanodine receptor, and SERCA2α in response to CT but an increase in phospho-(Ser16) Phospholamban. Conclusion Our findings highlight the effects of CT on atrial CM function. Maintaining physiological CT levels offer a promising approach for managing AF clinically, potentially through the use of already in clinical use CT-analogues.

Impact of glucose fluctuation on the paracrine secretome profile of human epicardial adipocyte

Abstract Background Glucose fluctuations (GF) is known to be the significant factor related to poor cardiovascular outcome in the diabetic patients. We investigated the potential impact of GF on paracrine effect of human epicardial adipocyte on cardiomyocyte. Methods Human EAT biopsies obtained during surgery and isolated preadipocyte/adipocytes were used to evaluate the direct impact of GF on the adipocytes. Matured adipocytes were exposed to the media containing normal glucose (100 mg/dl, NG), high glucose (300 mg/dl, HG), or high-low glucose (75-300 mg/dl, GF) for 1 week. Transcriptomic profiling of the cultured matured adipocyte was performed using microarray analysis. The impact of GF on the paracrine effect of adipocyte was evaluated using a co-culture with human iPS-derived atrial cardiomyocytes and the adipocytes. Clinical association study verified the validity of the findings. Results GF for 1 week altered the expression of 595 differentially expressed genes (up-regulated or down-regulated) with an effect size of >50% or `−50% and a significant statistical difference (P < 0.05) in human epicardial adipocytes, while the continuous HG for 1 week altered the expression of only 182 differentially expressed genes. Of the genes affected by GF, top 3 most affected genes included IL1β, IL33, IL8. Regarding the other major pro-inflammatory cytokines, IL1α, CCL2 and IL6 were also significantly increased in the adipocyte treated with GF, however these were not increased in the adipocyte treated with HG. Co-culture of human iPS cell-derived atrial cardiomyocytes and adipocytes treated with NG, HG and GF revealed that GF-treated adipocyte strikingly increased oxidative stress in the cardiomyocyte through the paracrine effect. In the real-world clinical association study, IL1β mRNA expression in human epicardial adipose tissue showed significant positive correlation with the severity of GF during hospitalization and oxidative stress in the left atrial myocardium. Conclusions GF adversely affect the paracrine secretome profile of human epicardial adipocyte. IL1β may be a critical epicardial adipocyte-derived adipokine that is enhanced by GF.

Combined class I and class III antiarrhythmic effects of sotagliflozin - insights from heterologous expressions systems and atrial cardiomyocytes

Abstract Background The demand for more effective treatment options for atrial fibrillation (AF), the most common sustained arrhythmia, is driven by its direct impact on morbidity and mortality. Current therapies, such as antiarrhythmic drugs and catheter ablation, are limited by suboptimal efficacy and adverse effects or periinterventional complications. Therefore, safe and effective treatment of AF remains a major unmet clinical need. Sodium-glucose cotransporter (SGLT) inhibitors have shown promise in reducing the incidence of AF in large cardiovascular endpoint trials. However, the exact mechanisms of action remain unclear. While only two SGLT2 inhibitors are approved and clinically used in Europe, sotagliflozin, which inhibits both SGLT1 and SGLT2, might also have potential for the treatment of AF. Purpose This study aims to elucidate the effects of sotagliflozin on cardiac action potential formation. This understanding could optimise its clinical use, identify new targets for the treatment of atrial fibrillation and ultimately improve the quality of life of patients suffering from AF. Methods The effects of sotagliflozin on cardiac ionic currents were assessed using two-electrode voltage clamp measurements of several sodium and potassium channels heterologously expressed in Xenopus laevis oocytes. Subsequently, ascending concentrations of sotagliflozin were administered to isolated human atrial cardiomyocytes during patch-clamp measurements to investigate its effect on atrial action potential morphology. Results At a concentration of 100 µM, sotagliflozin showed significant inhibitory effects on three out of ten ion channels tested: NaV1.5 sodium channel current was reduced by 22,3 % %, hERG and KV4.3 potassium currents were reduced by 30,4 % and 22,5 % respectively. Patch-clamp experiments, performed on isolated human atrial cardiomyocytes showed a dose-dependent reduction in upstroke velocity and action potential amplitude by 20,8 % and 13,8 % at a concentration of 20 µM, reflecting class-I-antiarrhythmic effects. Furthermore, a prolongation of AP duration measured at 50 % (APD50) and 90 % (APD90) of repolarization by 57,7 % and 27,9 % at a sotagliflozin concentration of 20 µM was noted, implying additional class-III-antiarrhythmic action. Conclusions Sotagliflozin exerts direct inhibitory effects on heterologously expressed NaV1.5, hERG and KV4.3 channels, resulting in a reduction in upstroke velocity and action potential amplitude, as well as a prolongation of APD50 and APD90 levels in isolated human atrial cardiomyocytes. These results extend the pharmacological profile of sotagliflozin and suggest a potential role for the clinical use of combined SGLT1/SGLT2 inhibitors in the treatment of AF.

Macrophage-mediated interleukin-6 signaling drives ryanodine receptor-2 calcium leak in postoperative atrial fibrillation

Abstract Background Postoperative atrial fibrillation (poAF) is self-limited AF that occurs within days after cardiac surgery in one-third of patients. Clinical and preclinical studies have demonstrated that the magnitude of the perioperative increase in systemic inflammation, in particular mediated by interleukin (IL)-6, correlates with poAF risk. However, no studies to-date have mechanistically linked IL-6 signaling to fundamental arrhythmia mechanisms or identified the specific cell types driving postoperative atrial IL-6 signaling. Methods We performed single-cell RNA sequencing (scRNAseq), followed by pseudotime trajectory and cell-cell communication analyses on atrial non-myocytes comparing mice with and without poAF. We followed up our scRNAseq findings with pharmacologic and genetic approaches in mice to validate pathways related to macrophage-mediated IL-6 signaling. We used confocal imaging to assess calcium-signaling mechanisms at the single atrial cardiomyocyte (ACM) level and performed parallel patch-clamp studies in isolated human ACMs as well as biochemical analyses of human atrial tissue to assess the translational relevance of our findings. Results Our scRNAseq results demonstrated macrophages to be the most prominently altered cell type in the atria of mice with poAF. Pseudotime trajectory analyses revealed IL-6 to be one of the top inflammatory pathways implicated in macrophage transcriptional state. Indeed, both macrophage depletion and conditional knockout of IL-6 receptors in macrophages were sufficient to prevent poAF. We found that inhibition of STAT3, which is downstream of the IL-6Ra, with FDA-approved phospho-STAT3 inhibitor TTI-101 prevented poAF in mice. Lastly, we demonstrate that enhanced STAT3 activity in poAF promotes arrhythmogenic Ca2+ sparks and waves through ryanodine receptor-2 dysfunction, and that CaMKII inhibition is sufficient to ameliorate Ca2+ mishandling at the single atrial myocyte level. Conclusions Taken together, we use an integrated approach incorporating mouse and human biochemical, functional, and single-cell sequencing data to demonstrate that infiltrating atrial macrophages are fundamentally required for poAF. IL-6 was found to be a critical pathway upregulated in poAF leading to downstream ryanodine receptor-2 dysfunction and atrial arrhythmogenesis. Our findings portend significant therapeutic utility by providing robust mechanistic evidence that targeting the IL-6 axis may be used for poAF prevention and treatment in a clinically amenable timeframe.

Novel role of human epicardial adipocyte-derived SPARCL1 in suppression of postoperative atrial fibrillation in patients undergoing cardiovascular surgery

Abstract Background Postoperative atrial fibrillation (POAF) occurs in 20-50% after cardiovascular surgery and is associated with the short and long-term morbidity/mortality. The epicardial adipose tissue (EAT) may have a potential role to regulate the incidence of POAF. Purpose We explored the possible role of human epicardial adipocyte-derived adipokines in the regulation of the myocardial redox state and POAF. Methods We prospectively evaluated 149 patients without known AF who underwent scheduled open-heart cardiovascular surgery between May 2020 and November 2022. They were divided into POAF or Non-POAF group and followed up after discharge (476.6 ± 290.0 days). POAF was defined as AF lasting more than 30 seconds after the surgery. Human EAT samples were obtained from these patients during surgery and the preadipocytes were isolated. Preadipocytes were terminally differentiated to mature adipocytes and mRNAs were extracted. Genome-wide expression profiling of 6 vs. 6 matched samples of the POAF and Non-POAF groups was performed using Microarray analysis, and the results were validated with qPCR in all the cohort samples. The effects of secreted adipokines on the cardiomyocytes were assessed in terms of oxidative stress. Superoxide and whole reactive oxygen species (ROS) were evaluated with luminometry and live-cell fluorescent probes respectively. As the oxidative stress associated signalling, the phosphorylation of ERK and p38-MAPK were evaluated with western blotting. Angiotensin II (Ang-II) was used to induce oxidative stress and phosphorylation of MAPK. Results POAF was observed in 53 patients (36%). Microarray analysis (n = 6) revealed that there were 132 down- or up-regulated cording genes in epicardial adipocytes of the POAF group compared to the Non-POAF group. Of these genes, 11 genes cording secretable molecules were validated by qPCR (n = 69), showing that only SPARCL1 had significantly downregulated in the POAF group compared to the Non-POAF group (P = 0.005). Superoxide and ROS were induced by Ang II (P < 0.01) and attenuated by SPARCL1 dose-dependent manner (P < 0.01) in neonatal rat cardiomyocytes. The phosphorylation of ERK and p38-MAPK were induced by Ang II (P < 0.01) and attenuated by SPARCL1 (P < 0.01) dose-dependently. Co-culture of human induced pluripotent stem cell-derived atrial cardiomyocytes (iPS-ACM) and human epicardial adipocytes revealed that the adipocytes derived from Non-POAF group suppressed the superoxide (P = 0.002) and ROS (P = 0.02) in iPS-ACM compared to POAF group. Kaplan-Meier survival analysis revealed that the POAF group (P = 0.01) and low SPARCL1 expression in epicardial adipocytes (P = 0.018) were associated with a higher incidence of long-term adverse cardiovascular events after surgery. Conclusion: SPARCL1 derived from epicardial adipocytes may play an important role in the suppression of POAF and long-term cardiovascular events via improving the myocardial redox state.

Serum exosomal long non-coding RNA H19 as a theragnostic target for atrial fibrillation

Abstract Background/Introduction Exosomes are membrane vesicles of 30- to 150-nm secreted by most cell types that can mediate intercellular communication by transmitting various forms of RNAs. Long non-coding RNAs (lncRNAs, ≥ 200 nucleotides length) have been reported to play important roles in the pathophysiological processes that promote the development and progression of many diseases. Interestingly, recent studies have shown that exosomal lncRNAs exhibit different expression profiles in various diseases and are being extensively studied in the medical field as an ideal target for the diagnosis and treatment. However, there is still little known about their role in atrial fibrillation (AF). Purpose The aim of this study was to identify a novel theragnostic target exosomal lncRNA for AF. Methods First, serum exosomes from controls and patients with persistent AF were isolated and characterized by transmission electron microscopy, nanoparticle tracking analysis, and western blot. Next, serum exosomal lncRNA expression profiles were explored using RNA-sequencing analysis. In addition, the expression levels of candidate exosomal lncRNAs were confirmed using qRT-PCR (n = 50 per group). Finally, AF-related pathophysiological mechanisms of exosomal lncRNA were investigated in angiotensin II (Ang II)-treated human induced pluripotent stem cell-derived atrial cardiomyocytes (iPSC-atrial CMs). Results After RNA-sequencing analysis, we identified 27 differentially expressed lncRNAs (i.e., 4 upregulated and 23 downregulated lncRNAs with a |fold change| ≥ 2 and p < 0.05) in serum exosomes from patients with persistent AF compared with the controls. In fact, qRT-PCR reveled that exosomal lncRNA H19 was consistently downregulated in the serum of patients with persistent AF compared with the controls (p < 0.01). In addition, exosomal lncRNA H19 exhibited significant diagnostic validity for AF. Notably, we confirmed that exosomal lncRNA H19 was involved in AF-related pathophysiological mechanisms. In Ang II-treated iPSC-atrial CMs, inhibition of lncRNA H19 significantly aggravated Ang II-induced increases in levels of hypertrophic markers (ANP, BNP and β-MHC), cell surface area and inflammation (p < 0.05). Mechanistically, we found that loss of lncRNA H19 weakens the inhibition of its direct target microRNAs, miR-141-3p and miR-200a-3p, leading to downregulation of their target PTEN, thereby promoting the atrial remodeling and the consequent AF. Conclusion In conclusion, serum-derived exosomal lncRNA H19 could serve as a potential target for the diagnosis and treatment of AF.

Atrial cardiomyopathy resulting from loss of plakophilin-2 expression: Response to adrenergic stimulation and implications for the exercise response.

Atrial arrhythmias occur in 20-40% of patients with arrhythmogenic right ventricular cardiomyopathy (ARVC) and are associated with an increased risk of sustained ventricular arrhythmias and inappropriate implantable cardioverter-defibrillator shocks. The pathophysiology of atrial arrhythmias in ARVC remains unclear. Most cases of gene-positive ARVC are linked to pathogenic variants in the desmosomal gene plakophilin-2 (PKP2). Here, we test the hypothesis that loss of PKP2 expression leads to pro-arrhythmic changes in atrial cardiomyocytes. Atrial cells/tissue were obtained from a cardiac-specific, tamoxifen-activated model of PKP2 deficiency (PKP2cKO). By contrast to PKP2cKO ventricular myocytes, PKP2cKO atrial cardiomyocytes presented no significant differences in intracellular calcium (Ca2+ i) transient dynamics, sarcoplasmic reticulum load or action potential morphology. PKP2cKO atrial cardiomyocytes showed elevated reactive oxygen species levels, increased frequency and amplitude of Ca2+ sparks, and increased diastolic [Ca2+]i compared to control; the latter two parameters were further increased by isoproterenol exposure and reversed by exposure to ryanodine receptor blocker dantrolene. We speculate that these isoproterenol-dependent effects may impact on the exercise-related atrial arrhythmia risk in ARVC patients. Despite absence of changes in Ca2+ i transient dynamics, PKP2cKO atrial cardiomyocytes showed enhanced sarcomere shortening and impaired sarcomere relaxation. Orthogonal transcriptomic analysis of human(GTEx) and PKP2cKO atrial tissue led to identification of 41 transcripts depending on PKP2 expression. Biochemical follow-up confirmed reduced abundance of sarcomeric protein myosin binding protein C, potentially playing a role in cellular shortening and relaxation changes observed. Our findings provide novel insights into the role of PKP2 in atrial myocardium with potential implications to therapeutic management of atrial fibrillation in patients with PKP2-related ARVC. KEY POINTS: Atrial arrhythmias occur in a large group of patients with arrhythmogenic right ventricular cardiomyopathy (ARVC), a cardiac disease mostly caused by pathogenic variants in the desmosomal gene plakophilin-2 (PKP2). Exercise is considered to be an independent risk factor for arrhythmias consequent to PKP2 deficiency. Weshow that loss of PKP2 expression affects cellular calcium handling and electrophysiology differently in left atrial vs. ventricular myocardium and causes extensive atrial fibrosis. PKP2-deficient atrial cardiomyocytes present increased spontaneous sarcoplasmic reticulum calcium release events, furtherenhancedby isoproterenol exposure and reversiblebya ryanodine receptor blocker(dantrolene). In addition, PKP2-deficient atrial myocytes exhibit impaired relaxation and enhanced sarcomere shortening, most probably related to reduced abundance of myosin binding protein C. We speculate that cellular effects reported upon isoproterenol impact on the exercise-related atrial arrhythmia risk in ARVC patients. We further propose that therapeutic approaches aimed at mitigating ventricular damage may be effective to treat the atrial disease in ARVC.

M6A reader YTHDF2 governs the onset of atrial fibrillation by modulating Cacna1c translation.

Atrial fibrillation (AF) is the most common arrhythmia, which is tightly associated with the abnormal expression and function of ion channels in the atrial cardiomyocytes. N6-methyladenosine (m6A), a widespread chemical modification in eukaryotic mRNA, is known to play a significant regulatory role in the pathogenesis of heart disease. However, the significance of m6A regulatory proteins in the onset of AF remains unclear. Here, we demonstrate that the m6A reader protein YTHDF2 regulates atrial electrical remodeling and AF onset by modulating the Cav1.2 expression. Firstly, YTHDF2 expression was selectively upregulated in rat atrial cardiomyocytes with AF. Secondly, YTHDF2 knockout reduced AF susceptibility in mice. Thirdly, the knockout of YTHDF2 increased Cav1.2 protein levels in an m6A-in-dependent manner, ultimately prolonging the atrial myocardial refractory period, a critical electrophysiological substrate for the onset of AF. Fourthly, the N-terminal domain of YTHDF2 was identified as critical for Cacna1c mRNA translation regulation. Overall, our findings unveil that YTHDF2 can alter Cav1.2 protein expression in an m6A-independent manner, thereby facilitating the onset of AF. Our study suggests that YTHDF2 may be a potential intervention target for AF.

Senescent CD8+ T cells: a novel risk factor in atrial fibrillation.

Immune cell alterations may play a role in the development of atrial fibrillation (AF). Our objective was to comprehensively characterize immune cells in AF, and investigate the potential mechanisms. Single-cell RNA sequencing and multicolor flow cytometry revealed that T cells constituted the most significant subset alterations in AF, and senescent CD8+ T cells were AF-associated subset. Senescent CD8+ T cells increased in both peripheral veins (p < 0.0001) and the left atria (p < 0.05) in patients with AF compared to non-AF control. Senescent CD8+ T cells were independently associated with AF prevalence (odds ratio = 2.876, p < 0.05) and postprocedural recurrence (hazard ratio = 22.955, p < 0.0001) using a cross-sectional study and a subsequent prospective cohort study. Senescent CD8+ T cells secreted an increased amount of interferon (IFN)-γ, which induces Ca2+ handling abnormalities in human induced pluripotent stem cell-derived atrial cardiomyocytes, and translated into an increased susceptibility to AF assessed by heart optical mapping. An increased amount of senescent CD8+ T cells may be a hallmark of the immune senescence phenotype in AF and potentially serve as a valid biomarker for assessing prevalence and postprocedural recurrence of AF. By connecting immune senescence with electrophysiological disturbances in AF, this research provides a potential mechanism for the involvement of senescent CD8+ T cells in proarrhythmic calcium disorders and suggests novel avenues for developing new immune-modulatory and senolytic therapies for AF.

Activation of IP3R in atrial cardiomyocytes leads to generation of cytosolic cAMP.

Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia. Excessive stimulation of the inositol (1,4,5)-trisphosphate (IP3) signaling pathway has been linked to AF through abnormal calcium handling. However, little is known about the mechanisms involved in this process. We expressed the fluorescence resonance energy transfer (FRET)-based cytosolic cyclic adenosine monophosphate (cAMP) sensor EPAC-SH187 in neonatal rat atrial myocytes (NRAMs) and neonatal rat ventricular myocytes (NRVMs). In NRAMs, the addition of the α1-agonist, phenylephrine (PE, 3 µM), resulted in a FRET change of 21.20 ± 7.43%, and the addition of membrane-permeant IP3 derivative 2,3,6-tri-O-butyryl-myo-IP3(1,4,5)-hexakis(acetoxymethyl)ester (IP3-AM, 20 μM) resulted in a peak of 20.31 ± 6.74%. These FRET changes imply an increase in cAMP. Prior application of IP3 receptor (IP3R) inhibitors 2-aminoethyl diphenylborinate (2-APB, 2.5 μM) or Xestospongin-C (0.3 μM) significantly inhibited the change in FRET in NRAMs in response to PE. Xestospongin-C (0.3 μM) significantly inhibited the change in FRET in NRAMs in response to IP3-AM. The FRET change in response to PE in NRVMs was not inhibited by 2-APB or Xestospongin-C. Finally, the localization of cAMP signals was tested by expressing the FRET-based cAMP sensor, AKAP79-CUTie, which targets the intracellular surface of the plasmalemma. We found in NRAMs that PE led to FRET change corresponding to an increase in cAMP that was inhibited by 2-APB and Xestospongin-C. These data support further investigation of the proarrhythmic nature and components of IP3-induced cAMP signaling to identify potential pharmacological targets.NEW & NOTEWORTHY This study shows that indirect activation of the IP3 pathway in atrial myocytes using phenylephrine and direct activation using IP3-AM leads to an increase in cAMP and is in part localized to the cell membrane. These changes can be pharmacologically inhibited using IP3R inhibitors. However, the cAMP rise in ventricular myocytes is independent of IP3R calcium release. Our data support further investigation into the proarrhythmic nature of IP3-induced cAMP signaling.

SNRK regulates TGFβ levels in atria to control cardiac fibrosis.

Atrial fibrosis is central to the pathology of heart failure (HF) and atrial fibrillation (AF). Identifying precise mechanisms underlying atrial fibrosis will provide effective strategies for clinical intervention. This study investigates a metabolic serine threonine kinase gene, sucrose non-fermenting related kinase (SNRK), that we previously reported to control cardiac metabolism and function. Conditional knockout of Snrk in mouse cardiomyocytes ( Snrk cmcKO) leads to atrial fibrosis and subsequently HF. The precise mechanism underlying cardiomyocyte SNRK-driven repression of fibrosis is not known. Here, using mouse, rat, and human tissues, we demonstrate that SNRK expression is high in atria, especially in atrial cardiomyocytes. SNRK expression correlates with lower levels of pro-fibrotic protein transforming growth factor-beta 1 (TGFβ1) in the atrial cardiomyocytes. In HL-1 adult immortalized mouse atrial cells, using siRNA approaches, we show that Snrk knockdown cells show more TGFβ1 secretion, which was also observed in heart lysates from Snrk cardiac-specific knockout mice in vivo. These effects were exacerbated upon infusion of Angiotensin II. Results from Snrk knockdown cardiomyocytes co-cultured with cardiac fibroblasts suggest that SNRK represses TGFβ1 signaling (Smad 2/3) in atrial CMs and prevents paracrine cardiac fibroblast activation (α-SMA marker). In conclusion, high SNRK expression in atria regulates cardiac homeostasis, by preventing the release of TGFβ1 secretion to block cardiac fibrosis. These studies will assist in developing heart chamber-specific fibrosis therapy for non-ischemic HF and AF.

PRDM16 determines specification of ventricular cardiomyocytes by suppressing alternative cell fates.

PRDM16 is a transcription factor with histone methyltransferase activity expressed at the earliest stages of cardiac development. Pathogenic mutations in humans lead to cardiomyopathy, conduction abnormalities, and heart failure. PRDM16 is specifically expressed in ventricular but not atrial cardiomyocytes, and its expression declines postnatally. Because in other tissues PRDM16 is best known for its role in binary cell fate decisions, we hypothesized a similar decision-making function in cardiomyocytes. Here, we demonstrated that cardiomyocyte-specific deletion of Prdm16 during cardiac development results in contractile dysfunction and abnormal electrophysiology of the postnatal heart, resulting in premature death. By combined RNA+ATAC single-cell sequencing, we found that PRDM16 favors ventricular working cardiomyocyte identity, by opposing the activity of master regulators of ventricular conduction and atrial fate. Myocardial loss of PRDM16 during development resulted in hyperplasia of the (distal) ventricular conduction system. Hence, PRDM16 plays an indispensable role during cardiac development by driving ventricular working cardiomyocyte identity.

The Abl1 tyrosine kinase is a key player in doxorubicin-induced cardiomyopathy and its p53/p73 cell death mediated signaling differs in atrial and ventricular cardiomyocytes

BackgroundDoxorubicin is an important anticancer drug, however, elicits dose-dependently cardiomyopathy. Given its mode of action, i.e. topoisomerase inhibition and DNA damage, we investigated genetic events associated with cardiomyopathy and searched for mechanism-based possibilities to alleviate cardiotoxicity. We treated rats at clinically relevant doses of doxorubicin. Histopathology and transmission electron microscopy (TEM) defined cardiac lesions, and transcriptomics unveiled cardiomyopathy-associated gene regulations. Genomic-footprints revealed critical components of Abl1-p53-signaling, and EMSA-assays evidenced Abl1 DNA-binding activity. Gene reporter assays confirmed Abl1 activity on p53-targets while immunohistochemistry/immunofluorescence microscopy demonstrated Abl1, p53&p73 signaling.ResultsDoxorubicin treatment caused dose-dependently toxic cardiomyopathy, and TEM evidenced damaged mitochondria and myofibrillar disarray. Surviving cardiomyocytes repressed Parkin-1 and Bnip3-mediated mitophagy, stimulated dynamin-1-like dependent mitochondrial fission and induced anti-apoptotic Bag1 signaling. Thus, we observed induced mitochondrial biogenesis. Transcriptomics discovered heterogeneity in cellular responses with minimal overlap between treatments, and the data are highly suggestive for distinct cardiomyocyte (sub)populations which differed in their resilience and reparative capacity. Genome-wide footprints revealed Abl1 and p53 enriched binding sites in doxorubicin-regulated genes, and we confirmed Abl1 DNA-binding activity in EMSA-assays. Extraordinarily, Abl1 signaling differed in the heart with highly significant regulations of Abl1, p53 and p73 in atrial cardiomyocytes. Conversely, in ventricular cardiomyocytes, Abl1 solely-modulated p53-signaling that was BAX transcription-independent. Gene reporter assays established Abl1 cofactor activity for the p53-reporter PG13-luc, and ectopic Abl1 expression stimulated p53-mediated apoptosis.ConclusionsThe tyrosine kinase Abl1 is of critical importance in doxorubicin induced cardiomyopathy, and we propose its inhibition as means to diminish risk of cardiotoxicity.

Thrombin receptor PAR4 cross-activates the tyrosine kinase c-met in atrial cardiomyocytes.

Thrombin supports coagulation-independent inflammation via protease-activated receptors (PAR). PAR4 is specifically increased in obese human atria, correlating with NLRP3 inflammasome activation. PAR4-mediated NLRP3 inflammasome activation in atrial cardiomyocytes is not known, nor have signaling partners been identified. Thrombin transactivates the hepatocyte growth factor receptor in some cancer cells, so we examined PAR4/c-met cross-talk in atrial cardiomyocytes and its possible significance in obesity. Cardiomyocytes from right atrial appendages (RAA) of obese patients expressed more PAR1 and PAR4 compared to non-obese. In HL-1 atrial cardiomyocytes, thrombin induced caspase-1 auto-activation and IL-1β maturation; IL-1β secretion was evoked by PAR4-activating peptide (AP), but not PAR1-AP. PAR4-AP additionally increased phosphorylated CaMKII-Thr287, mTOR-Ser2481, and Akt-Ser473 while suppressing AMPK-Thr172 phosphorylation. Total kinase levels were largely unaltered. PAR4AP rapidly increased phosphorylated c-met in HL-1 cells and over time also transcriptionally upregulated c-met. The c-met inhibitor SGX-523 abrogated the effects of PAR4-AP on CaMKII/AKT/mTOR phosphorylation but did not affect PAR4-stimulated IL-1β production. Obese human RAA contained more IL-1β, phospho-c-met, and phospho-mTOR than non-obese RAA; CamKII phosphorylation was not modified. Atria from high-fat diet (HFD) versus chow-fed mice also contained more IL-1β, together with higher myeloperoxidase activity, Acta2 mRNA total and phosphorylated c-met; these increases were blunted in PAR4-/- HFD-fed mice. Thrombin cross-activates c-met via PAR4 in atrial cardiomyocytes. Transactivated c-met contributes partially to PAR4-mediated signaling, but NLRP3 inflammasome activation appears to be largely independent of c-met. Abundance of PAR4 and activated c-met increases with obesity, providing therapeutic targets for management of adiposity-driven AF.

Atrial hiPSC-CM as a pharmacological model to evaluate anti-AF drugs: Some lessons from IKur.

Human induced pluripotent stem cells (hiPSC) and atrial hiPSC-derived cardiomyocytes (hiPSC-CM) have entered the arena of preclinical AF research. A central question is whether they reproduce the physiological contribution of atrial selective potassium currents (such as the ultrarapid potassium current, IKur) to repolarization. Of note, two studies in single atrial hiPSC-CM reported prolongation of action potential duration by IKur block indicating that IKur might in fact represent a valuable target for the treatment of human AF. However, the results and interpretation are at odds with the literature on IKur block in human atria and the results of clinical studies. We believe that the discrepancies indicate that experiments in single atrial CM (both adult atrial CM and atrial hiPSC-CM) might be misleading. Under particular experimental conditions, atrial hiPSC-CMs may not closely resemble the electrophysiology of the human atrium. Therefore, we recapitulate here methodological issues evaluating potential value of the IKur as an antiarrhythmic target when investigated in animal models, in human atrial tissues and finally in atrial hiPSC-CM.

PPARγ drives mitochondrial stress signaling and the loss of atrial cardiomyocytes in newborn mice exposed to hyperoxia

Diastolic dysfunction is increasingly common in preterm infants exposed to supplemental oxygen (hyperoxia). Previous studies in neonatal mice showed hyperoxia suppresses fatty acid synthesis genes required for proliferation and survival of atrial cardiomyocytes. The loss of atrial cardiomyocytes creates a hypoplastic left atrium that inappropriately fills the left ventricle during diastole. Here, we show that hyperoxia stimulates adenosine monophosphate-activated kinase (AMPK) and peroxisome proliferator activated receptor-gamma (PPARγ) signaling in atrial cardiomyocytes. While both pathways can regulate lipid homeostasis, PPARγ was the primary pathway by which hyperoxia inhibits fatty acid gene expression and inhibits proliferation of mouse atrial HL-1 cells. It also enhanced the toxicity of hyperoxia by increasing expression of activating transcription factor (ATF) 5 and other mitochondrial stress response genes. Silencing PPARγ signaling restored proliferation and survival of HL-1 cells as well as atrial cardiomyocytes in neonatal mice exposed to hyperoxia. Our findings reveal PPARγ enhances the toxicity of hyperoxia on atrial cardiomyocytes, thus suggesting inhibitors of PPARγ signaling may prevent diastolic dysfunction in preterm infants.

Immune response caused by M1 macrophages elicits atrial fibrillation-like phenotypes in coculture model with isogenic hiPSC-derived cardiomyocytes

BackgroundAtrial fibrillation has an estimated prevalence of 1.5–2%, making it the most common cardiac arrhythmia. The processes that cause and sustain the disease are still not completely understood. An association between atrial fibrillation and systemic, as well as local, inflammatory processes has been reported. However, the exact mechanisms underlying this association have not been established. While it is understood that inflammatory macrophages can influence cardiac electrophysiology, a direct, causative relationship to atrial fibrillation has not been described. This study investigated the pro-arrhythmic effects of activated M1 macrophages on human induced pluripotent stem cell (hiPSC)-derived atrial cardiomyocytes, to propose a mechanistic link between inflammation and atrial fibrillation.MethodsTwo hiPSC lines from healthy individuals were differentiated to atrial cardiomyocytes and M1 macrophages and integrated in an isogenic, pacing-free, atrial fibrillation-like coculture model. Electrophysiology characteristics of cocultures were analysed for beat rate irregularity, electrogram amplitude and conduction velocity using multi electrode arrays. Cocultures were additionally treated using glucocorticoids to suppress M1 inflammation. Bulk RNA sequencing was performed on coculture-isolated atrial cardiomyocytes and compared to meta-analyses of atrial fibrillation patient transcriptomes.ResultsMulti electrode array recordings revealed M1 to cause irregular beating and reduced electrogram amplitude. Conduction analysis further showed significantly lowered conduction homogeneity in M1 cocultures. Transcriptome sequencing revealed reduced expression of key cardiac genes such as SCN5A, KCNA5, ATP1A1, and GJA5 in the atrial cardiomyocytes. Meta-analysis of atrial fibrillation patient transcriptomes showed high correlation to the in vitro model. Treatment of the coculture with glucocorticoids showed reversal of phenotypes, including reduced beat irregularity, improved conduction, and reversed RNA expression profiles.ConclusionsThis study establishes a causal relationship between M1 activation and the development of subsequent atrial arrhythmia, documented as irregularity in spontaneous electrical activation in atrial cardiomyocytes cocultured with activated macrophages. Further, beat rate irregularity could be alleviated using glucocorticoids. Overall, these results point at macrophage-mediated inflammation as a potential AF induction mechanism and offer new targets for therapeutic development. The findings strongly support the relevance of the proposed hiPSC-derived coculture model and present it as a first of its kind disease model.

FABP4 Enhances Lipidic and Fibrotic Cardiac Structural and Ca2+ Dynamic Changes.

Adipocyte FABP4 (fatty acid-binding protein 4) is augmented in the epicardial stroma of patients with long-standing persistent atrial fibrillation. Because this molecule is released mainly by adipocytes, our objective was to study its role in atrial cardiomyopathy, focusing our attention on fibrosis, metabolism, and electrophysiological changes. These results might clarify the role of adiposity as a mediator of atrial cardiomyopathy. We used several preclinical cellular models, epicardial and subcutaneous stroma primary cell cultures from patients undergoing open heart surgery, human atrial fibroblasts, atrial cardiomyocytes derived from human induced pluripotent stem cells and isolated from adult mice, and Nav1.5 transfected Chinese hamster ovary cells. Fibrosis, glucose, mitochondrial and adipogenesis activity, gene expression, and proteomics were determined by wound healing, enzymatic, colorimetric, fluorescence assays, real-time quantitative polymerase chain reaction, and TripleTOF proteomics. Molecular changes were analyzed by Raman confocal microspectroscopy, calcium dynamics by confocal microscopy, and ion currents by patch clamp. Epicardial, subcutaneous, and atrial fibroblasts and cardiomyocytes were incubated with FABP4 at 100 ng/mL. Our results showed that FABP4 induced fibrosis, glucose metabolism, and lipid accumulation on epicardial and subcutaneous stroma cells and atrial fibroblasts. Besides, it modified lipid content and calcium dynamics in atrial cardiomyocytes without effects on INa. FABP4 exerts fibrotic and metabolic changes on epicardial stroma and modifies lipid content and calcium dynamic on atrial cardiomyocytes. These results suggest its possible role as an atrial cardiomyopathy mediator.

Enhanced Ca2+-Driven Arrhythmogenic Events in Female Patients With AtrialFibrillation: Insights From Computational Modeling.

Substantial sex-based differences have been reported in atrial fibrillation (AF), but the underlying mechanisms are poorly understood. This study sought to gain a mechanistic understanding of Ca2+-handling disturbances and Ca2+-driven arrhythmogenic events in male vs female atrial cardiomyocytes and establish their responses to Ca2+-targeted interventions. We integrated reported sex differences and AF-associated changes (ie, expression and phosphorylation of Ca2+-handling proteins, cardiomyocyte ultrastructural characteristics, and dimensions) into our human atrial cardiomyocyte model that couples electrophysiology with spatially detailed Ca2+-handling processes. Sex-specific responses of atrial cardiomyocytes to arrhythmia-provoking protocols and Ca2+-targeted interventions were evaluated. Simulated quiescent cardiomyocytes showed increased incidence of Ca2+ sparks in female vs male myocytes inAF, in agreement with previous experimental reports. Additionally, our female model exhibited elevated propensity to develop pacing-induced spontaneous Ca2+ releases (SCRs) and augmented beat-to-beat variability in action potential (AP)-elicited Ca2+ transients compared with the male model. Sensitivity analysis uncovered distinct arrhythmogenic contributions of each component involved in sex and/or AF alterations. Specifically, increased ryanodine receptor phosphorylation emerged as the major SCR contributor in female AF cardiomyocytes, whereas reduced L-type Ca2+ current was protective against SCRs for male AF cardiomyocytes. Furthermore, simulated Ca2+-targeted interventions identified potential strategies (eg, t-tubule restoration, and inhibition of ryanodine receptor and sarcoplasmic/endoplasmic reticulum Ca2⁺-ATPase) to attenuate Ca2+-driven arrhythmogenic events in women, and revealed enhanced efficacy when applied in combination. Sex-specific modeling uncovers increased Ca2+-driven arrhythmogenic events in female vs male atria inAF, and suggests combined Ca2+-targeted interventions are promising therapeutic approaches in women.

Exploring SCN5A variants associated with atrial fibrillation in atrial cardiomyocytes derived from human induced pluripotent stem cells: A characterization study

BackgroundAtrial fibrillation (AF) poses a major risk for heart failure, myocardial infarction, and stroke. Several studies have linked SCN5A variants to AF, but their precise mechanistic contribution remains unclear. Human induced pluripotent stem cells (hiPSCs) provide a promising platform for modeling AF-linked SCN5A variants and their functional alterations. ObjectiveThe purpose of this study was to assess the electrophysiological impact of 3 AF-linked SCN5A variants (K1493R, M1875T, N1986K) identified in 3 unrelated individuals. MethodsCRISPR-Cas9 was used to generate a new hiPSC line in which NaV1.5 was knocked out. Following differentiation into specific atrial cardiomyocyte by using retinoic acid, the adult wild-type (WT) and 3 AF variants were introduced into the NaV1.5 knockout (KO) line through transfection. Subsequent analysis including molecular biology, optical mapping, and electrophysiology were performed. ResultsThe absence of NaV1.5 channels altered the expression of key cardiac genes. NaV1.5 KO atrial-like cardiomyocytes derived from human induced pluripotent stem cells displayed slower conduction velocities, altered action potential (AP) parameters, and impaired calcium transient propagation. The transfection of the WT channel restored sodium current density, AP characteristics and the expression of several cardiac genes. Among the AF variants, 1 induced a loss of function (N1986K) while the other 2 induced a gain of function in NaV1.5 channel activity. Cellular excitability alterations and early afterdepolarizations were observed in AF variants. ConclusionOur findings suggest that distinct alterations in NaV1.5 channel properties may trigger altered atrial excitability and arrhythmogenic activity in AF. Our KO model offers an innovative approach for investigating SCN5A variants in an adult human cardiac environment.