Project description:Atrial fibrillation (AF) is the most common sustained arrhythmia in humans, yet the molecular basis of AF remains incompletely understood. To determine the cell type-specific transcriptional changes underlying AF, we performed single-nucleus RNA-seq (snRNA-seq) on age- and sex-matched left atrial (LA) samples from 18 patients with AF and 16 controls without AF. From more than 175,000 nuclei we identified 15 cell types but found that only cardiomyocytes (CMs) and macrophages (MΦs) had a significant number of differentially expressed genes in patients with AF. Attractin Like 1 (ATRNL1) was strongly overexpressed in CMs among patients with AF and localized to the intercalated discs. Further, in both knockdown and overexpression experiments in atrial human embryonic stem cell-derived CMs (hESC-aCMs) we identified a potent role for ATRNL1 in cell stress response, cardiac conduction, cell junction organization and in modulation of the cardiac action potential. Finally, we prioritized genes at the known genetic loci for AF and identified an unexpected expression for a leading AF candidate gene, KCNN3. In sum, we have identified a role for ATRNL1 and other differentially regulated genes that may serve as potential therapeutic targets for this common arrhythmia.

Project description:Atrial fibrillation (AF), the most common arrhythmia, is occasionally associated with cardiac developmental defects, but causal relationships are poorly defined. Importantly, functional compensation for developmental defects may mask increased risk of arrhythmia in adults. Here, we deleted 9 amino acids (Δ9) within a highly conserved A-band region of titin, a giant protein that serves as a molecular spring in cardiomyocytes, in both zebrafish and human induced pluripotent stem cell-derived atrial cardiomyocytes (hiPSC-aCMs). We find that the cardiac morphology of ttnaΔ9/Δ9 homozygous zebrafish embryos is perturbed and accompanied by reduced functional output, but ventricular function recovers within a few days of embryonic development, with most embryos reaching adulthood. Despite normal ventricular function, ttnaΔ9/Δ9 adults exhibit AF and atrial cardiomyopathy, with a striking absence of fibrosis, and these findings are recapitulated in TTNΔ9/Δ9-hiPSC-aCMs. Electrophysiological and proteomics analyses reveal atrial action potential shortening and increased expression and function of the cardiac potassium channel Kv7.1 and the slow delayed rectifier potassium current (IKs). Pharmacological suppression of IKs in both models prevents AF and improves atrial contractility. Collectively, these findings reveal how a small internal deletion in a large structural protein causes developmental abnormalities that functionally recover but increase the risk of adult cardiac disease via ion channel remodeling. The observed rescue with targeted antiarrhythmic therapy may have broader implications for the treatment of patients who harbor disease-causing rare variants in sarcomeric proteins.

Project description:Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia treatable with antiarrhythmic drugs, but patient responses are highly variable. Human induced pluripotent stem cell-derived atrial cardiomyocytes (iPSC-aCMs) are useful for discovering precision therapeutics, but current platforms yield an immature cellular phenotype and are not easily scalable for high-throughput screening. Here, we report that primary adult atrial, but not ventricular, fibroblasts induced greater functional iPSC-aCM maturation, partly through connexin-40 and ephrin-B1 signaling. We developed a protein patterning process within industry-standard multiwell plates to engineer patterned co-culture (PC) of iPSC-aCMs and atrial fibroblasts that significantly enhanced iPSC-aCM structural, electrical, contractile, and metabolic maturation for 6+ weeks versus conventional mono-/co-cultures. PC displayed greater sensitivity for detecting drug efficacy than monocultures, and enabled the modeling and pharmacological or gene editing treatment of an AF-like electrophysiological phenotype due to a sodium channel mutation. In conclusion, PC is useful to elucidate heterotypic cell signaling in the atria, drug screening, and to model AF.

Project description:Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia treatable with antiarrhythmic drugs, but patient responses are highly variable. Human induced pluripotent stem cell-derived atrial cardiomyocytes (iPSC-aCMs) are useful for discovering precision therapeutics, but current platforms yield an immature cellular phenotype and are not easily scalable for high-throughput screening. Here, we report that primary adult atrial, but not ventricular, fibroblasts induced greater functional iPSC-aCM maturation, partly through connexin-40 and ephrin-B1 signaling. We developed a protein patterning process within industry-standard multiwell plates to engineer patterned co-culture (PC) of iPSC-aCMs and atrial fibroblasts that significantly enhanced iPSC-aCM structural, electrical, contractile, and metabolic maturation for 6+ weeks versus conventional mono-/co-cultures. PC displayed greater sensitivity for detecting drug efficacy than monocultures, and enabled the modeling and pharmacological or gene editing treatment of an AF-like electrophysiological phenotype due to a sodium channel mutation. In conclusion, PC is useful to elucidate heterotypic cell signaling in the atria, drug screening, and to model AF.

Project description:Atrial fibrillation (AF), the most common cardiac arrhythmia, is a major contributor to population mortality and morbidity. The goal of this study is to explore molecular mechanisms of the AF-induced profibrotic remodelling in human atrial fibroblasts (ACFs). Specifically, we assessed single-cell transcriptome of cultured human ACFs treated with calcitonin(CT) or vehicle (from 6 individual patients) and of freshly-isolated ACFs from patients with AF (4 individual patients) vs controls (4 individual patients). We found that ACF transcriptome was unaltered by CT in cultured ACFs, and identified 5 transcriptional clusters with 23 differentially expressed transcripts in AF in freshly-ioslated ACFs.

Project description:Atrial fibrillation (AF) has an estimated prevalence of 1.5–2%, making it the most common cardiac arrhythmia. The mechanisms that cause and sustain AF are still not completely understood. An association between AF 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 tissue resident macrophages can influence cardiac electrophysiology, the effects of activated pro-inflammatory macrophages have not been described yet. This study investigated the pro-arrhythmic effects of activated macrophages (M1) on human induced pluripotent stem cell (hiPSC)-derived atrial cardiomyocytes (aCM), to propose a mechanistic link between inflammation and AF. Two hiPSC lines from healthy individuals were differentiated to aCMs and M1 macrophages. Electrophysiology characteristics of M1 and aCM cocultures were analysed for beat rate irregularity, electrogram amplitude and conduction velocity. M1 cocultures resulted in a significant increase in beat rate irregularity and decrease in electrogram amplitude compared to other conditions tested, including aCMs treated with activated M1 supernatant, which did not produce an increase in irregularity. Conduction analysis further showed significantly lower conduction homogeneity in M1 cocultures. Immunosuppression through glucocorticoids significantly decreased beat irregularity in aCM+M1 cocultures compared to vehicle. RNA sequencing performed in aCMs, revealed downregulation of various ion channels (SCNA5, KCNA5, ATP1A1), as a result of the M1 coculture. Electrophysiology related transcription changes were reversed by glucocorticoid treatment. This study establishes a causal relationship between M1 activation and the development of subsequent atrial arrhythmia, documented as irregularity in spontaneous electrical activation in aCM cocultured with activated macrophages. Further, beat rate irregularity could be alleviated using anti-inflammatory steroidal glucocorticoids. These results strongly support the relevance of the proposed hiPSC-derived coculture model and point at macrophage mediated inflammation as a potential AF mechanism.

Project description:Atrial fibrillation (AF), the most common cardiac arrhythmia, is a major contributor to population mortality and morbidity. The goal of this study is to explore molecular mechanisms of the AF-induced profibrotic remodelling in human atrial fibroblasts (ACFs). Specifically, we assessed single-cell transcriptome of cultured human ACFs treated with calcitonin(CT) or vehicle (from 6 individual patients) and of freshly-isolated ACFs from patients with AF (4 individual patients) vs controls (4 individual patients) (SR). We found that ACF transcriptome was unaltered by CT in cultured ACFs, and identified 5 transcriptional clusters with 23 differentially expressed transcripts in AF in freshly-ioslated ACFs.

Project description:Atrial fibrillation (AF), the most common sustained cardiac arrhythmia and a major risk factor for stroke, often arises through ectopic electrical impulses derived from the pulmonary veins (PV). Sequence variants in enhancers controlling expression of the transcription factor PITX2, which is expressed in the cardiomyocytes (CMs) of the PV and left atrium (LA), have been implicated in AF predisposition. Single nuclei multiomic profiling of RNA and analysis of chromatin accessibility combined with spectral clustering uncovered distinct PV- and LA-enriched CM cell states. Pitx2 mutant PV and LA CMs exhibited gene expression changes consistent with cardiac dysfunction through cell-type-distinct, PITX2-directed, cis-regulatory grammars controlling target gene expression. The perturbed network targets in each CM were enriched in distinct human AF-predisposition genes, suggesting combinatorial risk for AF-genesis. Our data further reveals that PV and LA Pitx2 mutant CMs signal to endothelial and endocardial cells through BMP10 signaling with pathogenic potential. This work provides a multiomic framework for interrogating the basis of AF-predisposition in the PV of humans.

Project description:Current differentiation protocols for human pluripotent stem cells produce a heterogeneous population of cardiomyocytes (CMs). Here, we identified CD151 as a marker of ventricular CMs (VCMs) and atrial CMs (ACMs) from 212 different cell surface markers. In the VCM induction, CD151high CMs were a homogeneous population of mature VCMs, including binuclear VCMs, and showed enriched cell cycle-related genes based on RNA-seq analysis. As for the ACM induction, CD151low CMs expressed high levels of atrial-related genes and exhibited atrial-type electrophysiological properties. According to RNA-seq analysis, CD151high CMs from the ACM induction had molecular signatures for cell-cell interactions and NOTCH signaling. When treated with a NOTCH signal inhibitor, the same cells showed mature electrophysiological properties consistent of ACMs with an increasing expression of atrial-related genes. Altogether, we found that CD151 is an indicator of subtype specification with distinct mechanisms between VCM and ACM differentiation and that NOTCH signaling inhibition enhances atrial specification.

Project description:Atrial fibrillation (AF) is the most common persistent arrhythmia that affect 1–2% of the general population. People with AF display an array of complications cardiogenic stroke and systemic embolism caused by hemodynamic instability and blood hypercoagulability in clinical practice. However, it’s still unclear whether and how ubiquitylated proteins react to AF in the left atrial appendage of patients with AF and valvular heart disease. This theory focuses on the changes of ubiquitylated proteins in atrial fibrillation associated with heart valve disease. We firstly widely analysis the proteins ubiquitination in patients with atrial fibrillation.