Project description:Arrhythmogenic cardiomyopathy (ACM) is frequently attributed to desmosomal mutations, such as those in the desmoplakin (DSP) gene. Patients with DSP- cardiomyopathy are predisposed to myocardial degeneration and arrhythmias. Despite advancements, the underlying molecular mechanisms remain incompletely understood, thus limiting therapeutic options. Here, we employed spatial transcriptomics on an explanted heart from a patient with a pathogenic DSP variant. Our transcriptional analysis revealed endothelial PAS domain-containing protein 1 (EPAS1) as a potential regulator of mitochondrial homeostasis in stressed cardiomyocytes. Elevated EPAS1 levels were associated with mitochondrial dysfunction and hypoxic stress in both human-relevant in vitro ACM models and additional explanted hearts with genetic cardiomyopathy. Collectively, cardiomyocytes bearing pathogenic DSP variants exhibit mitochondrial dysfunction, increased apoptosis, and impaired contractility, which are linked to the increased EPAS1 levels. These findings implicate EPAS1 as a key regulator of myocardial degeneration in DSP-cardiomyopathy, which expand to other forms of ACM.

Project description:Arrhythmogenic cardiomyopathy (ACM) is an inherited progressive cardiomyopathy. The pathophysiological events are well understood, yet the underlying molecular mechanisms remain undefined. Here, we created a novel research platform comprising of patient originated hiPSC-derived cardiomyocytes bearing a pathological PKP2 mutation (PKP2 c.2013delC/WT), a novel knock-in murine model carrying the equivalent mutation (Pkp2 c.1755delA/WT), and human explanted ACM hearts, to identify disease driving mechanisms. Pkp2 c.1755delA/WT mice displayed reduced desmosomal and adherens junctions protein levels and protein disarray of the intercalated discs in areas of active fibrotic remodeling. These findings were validated in hiPSC-derived cardiomyocytes and human explanted ACM hearts. Led by proteomics data, we demonstrated that the ubiquitin-proteasome system was responsible for the observed desmosomal protein degradation. The research platform presented here provides a strong scientific basis to identify bona fide pathological processes and will aid in the development of potential therapies for the prevention of ACM disease progression.

Project description:Aims Arrhythmogenic cardiomyopathy (ACM) is an inherited cardiac disorder that is characterized by progressive fibro-fatty replacement of the myocardium, arrhythmias, and sudden death. While myocardial degeneration and fibro-fatty replacement occurs in specific locations, the underlying molecular changes remain poorly characterized. Here we aim to delineate local changes in gene expression to help identify new genes or pathways that are relevant for specific remodelling processes occurring during ACM. Methods and Results Using Tomo-Seq, a genome-wide transcriptional profiling with high spatial resolution, we created a transmural epicardial to endocardial gene expression atlas of an explanted ACM heart to gain molecular insights into disease-driving processes. This enabled us to link gene expression profiles to the different regional remodelling responses and allowed us to identify genes that are potentially relevant for disease progression. In doing we revealed BTB (broad-complex, tramtrack, bric-à-brac) domain containing 11 (ZBTB11) to be specifically enriched at sites of active fibrofatty replacement of myocardium. Immunohistochemistry indicated ZBTB11 to be enriched in cardiomyocytes flanking fibrofatty areas, which could be confirmed in multiple cardiomyopathy patients. Forced overexpression of ZBTB11 in iPS-derived cardiomyocytes showed ZBTB11 to function as a potent inducer of cardiomyocyte atrophy. Conclusion By combining spatial transcriptomics with classical histological approaches we identified gene expression changes underlying local remodelling responses in ACM. In doing so we found ZBTB11 to function as a relevant driver of cardiomyocyte atrophy. These data show the power of Tomo-Seq to unveil new molecular mechanisms and indicate ZBTB11 as a potential new target for cardiomyopathy.

Project description:Arrhythmogenic cardiomyopathy (ACM) is an inherited progressive cardiomyopathy. The pathophysiological events are well understood, yet the underlying molecular mechanisms remain undefined. Here we use patient originated hiPSC-derived cardiomyocytes bearing a pathogenic PKP2 mutation (PKP2 c.2013delC/WT), a corresponding knock-in mouse model carrying the equivalent murine mutation (Pkp2 c.1755delA/WT), and human explanted ACM hearts, to identify disease driving mechanisms. Pkp2 c.1755delA/WT mice over time displayed signs of ACM as observed by cardiac dysfunction and pathological remodeling. At a molecular level these mice showed a reduction in desmosomal and adherens junction proteins as well as disarray of the intercalated discs in areas of active fibrotic remodeling. These findings were validated in the mutant hiPSC-derived cardiomyocytes as well as human explanted ACM hearts, indicating both the conservation and relevance of protein degradation in the pathogenesis of the disease. Led by proteomics data, we demonstrated that the ubiquitin-proteasome system was responsible for the observed desmosomal protein degradation. These findings show the importance of appropriate disease modeling and provide means for therapeutic intervention for the prevention of ACM disease progression.

Project description:Arrhythmogenic cardiomyopathy (ACM) is an inherited progressive cardiomyopathy. The pathophysiological events are well understood, yet the underlying molecular mechanisms remain undefined. Here we use patient originated hiPSC-derived cardiomyocytes bearing a pathogenic PKP2 mutation (PKP2 c.2013delC/WT), a corresponding knock-in mouse model carrying the equivalent murine mutation (Pkp2 c.1755delA/WT), and human explanted ACM hearts, to identify disease driving mechanisms. Pkp2 c.1755delA/WT mice over time displayed signs of ACM as observed by cardiac dysfunction and pathological remodeling. At a molecular level these mice showed a reduction in desmosomal and adherens junction proteins as well as disarray of the intercalated discs in areas of active fibrotic remodeling. These findings were validated in the mutant hiPSC-derived cardiomyocytes as well as human explanted ACM hearts, indicating both the conservation and relevance of protein degradation in the pathogenesis of the disease. Led by proteomics data, we demonstrated that the ubiquitin-proteasome system was responsible for the observed desmosomal protein degradation. These findings show the importance of appropriate disease modeling and provide means for therapeutic intervention for the prevention of ACM disease progression.

Project description:Desmosomes are specialized cell-cell junctions critically important in the heart, where their disruption promotes arrhythmogenic cardiomyopathy (ACM). Individuals carrying truncating variants in the desmosomal gene desmoplakin (DSP) often show a prominent inflammatory component in the absence of known antigenic stimuli, termed “hot phase” arrythmia. To assess the role of innate immune activation in DSP-cardiomyopathy, we generated engineered heart tissues (EHTs) from two patients with heterozygous DSP truncation variants (DSPtv, p.E1597X and p.R1951X). We also generated EHTs with homozygous DSP deletion (DSP-/-) for modeling. DSP-/- EHTs revealed impaired force production and reduced conduction velocity compared to isogenic controls, features consistent with ACM. RNA sequencing and protein characterization demonstrated a dramatic increase in innate immune activation in DSP-/- EHTs. Similarly, patient-derived DSPtv EHTs show enhanced sensitivity to inflammatory stimuli seen as reduced contractility and greater cytokine release. Inhibition of NFκB signaling improved baseline force production and mechanical response to strain in DSPtv EHTs, indicating that anti-inflammatory modulation may improve mechanical function in DSP deficient hearts. Furthermore, genomic correction of p.R1951X using adenine base editing reduced inflammatory biomarkers in cultured EHTs. Taken together, these data identify that DSPtv promote innate immune activation, creating an arrhythmogenic substrate in the concealed phase of ACM.

Project description:Chronic alcohol exposure can cause myocardial degenerative diseases, manifested as cardiac insufficiency, arrhythmia, etc. These are defined as alcoholic cardiomyopathy (ACM). Alcohol-mediated myocardial injury has previously been studied through metabolomics, and it has been proved to be involved in the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway related to the biosynthesis of unsaturated fatty acids and oxidative phosphorylation, which tentatively explored the mechanism of ACM induced by chronic drinking. To further study the myocardial damage caused by alcohol, the mouse model of ACM successfully established previously was used to perform proteomics analysis on myocardial specimens. Fifty-six differentially expressed proteins (DEPs) were identified, and they are involved in the KEGG pathway related to fatty acid biosynthesis, lipid metabolism, oxidative stress, and the development of dilated cardiomyopathy (DCM). The present study further demonstrated the underlying causes of myocardial damage caused by chronic alcohol consumption and lays the foundation for further research to clarify the underlying mechanism of ACM.

Project description:Mutations in desmosome genes cause arrhyythmogenic cardiomyopathy (ACM). Using desmoplakin haploinsufficient mouse model of ACM, we evaluated the effects of treadmill exercise on cardiac myocyte transcritional profile. Strand specific, ribosome depleted paired end RNA sequencing of cardiac myocytes from wild type and Myh6-Cre:DspW/F were generate using Illumina HiSeq 4000.

Project description:The RNA-Seq studies performed in the endomyocardial biopsy samples from human patients with defined truncating mutations in the DSP gene and normal right ventricular size and function, identified dysregulation of over two-dozen TRs, including the Hippo/cWNT pathways, early in the course of ACM. The findings of the RNA-Seq were corroborated by immunoblotting and immunofluorescence studies showing reduced protein levels of the TRs of the Hippo/cWNT pathways in the ACM hearts. Dysregulation of these pathways early and prior to the onset of cardiac dysfunction suggest their pathogenic role in ACM.

Project description:To delineate the role of the epicardium, the initial site of presentation of the ACM phenotype, the Dsp gene, encoding desmosome protein desmoplakin (DSP) was conditionally deleted in the mouse epicardial cells under the transcriptional regulation of Wilms tumor 1 (Wt1) locus. Single cell RNA sequencing (scRNA-Seq) of ~ 40,000 tagged epicardial-derived cells (EDCs), isolated using the dual reporter R26mT/mG mice, showed an increased number of EDCs expressing unique molecular identifiers of fibroblasts as well as a unique subset of epicardial-derived fibroblasts expressing pro-fibrotic genes in the Wt1-Cre: R26mT/mG: Dsp mice. Analysis of pseudo-bulk RNA-Seq data identified ~ 800 differentially expressed genes (DEGs), which were predominantly involved in epithelial-mesenchymal transition (EMT). The DEGs were the targets of TGFB1 among other trophic/mitotic factors, whose activation was verified by immunohistochemistry and quantification of transcript levels of selected TGBF1 pathway genes. Retro-mapping of the DEGs to the cell clusters, identified by scRNA-Seq, denoted epicardial-derived fibroblasts and to a lesser extent the epithelial cells as the main sources of paracrine factors in the myocardium of Wt1-Cre: R26mT/mG: Dsp mice.