Project description:HMGN3 ChIP-seq in AC16 cells and Bulk-RNAseq in AC16 cell with and without HMGN3 knockdown

Project description:Heterozygous mutations in GATA4 cause congenital heart defects and cardiomyopathy through unknown mechanisms. To gain insights into the trancriptome perturbations during human cardiac development due to GATA4 heterozygosity, we performed RNA-seq of isogenic wildtype and GATA4-G296S diseased cardiac progenitors (CPCs) and cardiomyocytes (CMs).

Project description:Heterozygous mutations in GATA4 cause congenital heart defects and cardiomyopathy through unknown mechanisms. To gain insights into the genome-wide localization perturbations during human cardiac development due to GATA4 heterozygosity, we performed ChIP-seq of wildtype and GATA4-G296S diseased cardiomyocytes.

Project description:Cardiovascular diseases are associated with an altered cardiomyocyte metabolism. Due to a shortage of human heart tissue, experimental studies mostly rely on alternative approaches including animal and cell culture models. Since the use of isolated primary cardiomyocytes is limited, immortalized cardiomyocyte cell lines may represent a useful tool as they closely mimic human cardiomyocytes. This study is focused on the AC16 cell line generated from adult human ventricular cardiomyocytes. Despite an increasing number of articles employing AC16 cells, the comprehensive proteomic, bioenergetic and oxygen-sensing characterization of proliferating versus differentiated cells is still lacking. Here, we provide a comparison of these two stages, particularly emphasizing cell metabolism, mitochondrial function, and hypoxic signalling. The label-free quantitative mass spectrometry revealed a decrease in autophagy and cytoplasmic translation in differentiated AC16, confirming their phenotype. Cell differentiation led to the global increase in mitochondrial proteins (e.g. OXPHOS proteins, TFAM, VWA8, etc.) reflected by elevated mitochondrial respiration. Fatty acid oxidation proteins were increased in differentiated cells, while the expression levels of proteins associated with fatty acid synthesis were unchanged, and glycolytic proteins were decreased. There was a profound difference between proliferating and differentiated cells in their response to hypoxia and anoxia/reoxygenation. We conclude that AC16 differentiation leads to proteomic and metabolic shifts and altered cell response to oxygen deprivation. This underscores the requirement for proper selection of particular differentiation state during experimental planning.

Project description:RNA sequencing of AC16 and AC16-CAR cells

Project description:To explore potential functional implications of isoform usage shifts, we examined the effect of PCBP1/PCBP2 expression in human AC16 cardiac cells. PCBP1/PCBP2 are KH-domain-containing RNA-binding proteins (RBP) that have been implicated in transcriptional, post-transcriptional and translational regulations. How PCBP1 and PCBP2 are functionally differentiated remains a subject of interest and few reports have outlined their function in cardiac cells. The two paralogs share close homology (~85% identical sequences) and partially overlapping RNA binding targets, suggesting they may form mutually regulatory relationships. Human and mouse PCBP1 sequences share 100.0% identity, whereas human and mouse PCBP2 are identical except in 5 positions; therefore we expressed the human/mouse PCBP1 and human PCBP2 coding sequences in human AC16 cardiac cells. Immunofluorescence imaging confirms broad cytonuclear localization of both paralogs under overexpression. The cells were then subjected to RNA sequencing to determine the effects of PCBP1/2 on gene expression.

Project description:AC16 cells were transfected with a plasmid designed to overexpress TRIM38, along with a negative control plasmid. After confirming successful transfection, the cells were stimulated with phenylephrine (PE) to induce a cardiac hypertrophy model. Subsequently, ubiquitination analysis was performed on both groups of cells

Project description:Heterozygous mutations in GATA4 cause congenital heart defects and cardiomyopathy through unknown mechanisms. To gain insights into the open chromatin status during human cardiac development due to GATA4 heterozygosity, we performed ATAC-seq of wildtype and GATA4-G296S diseased cardiac progenitors.

Project description:YAP transcriptional regulator controls cell mechanics by activating genes involved in cell-matrix interaction following extracellular matrix (ECM) remodelling and stiffening. YAP is needed for cardiogenesis in mouse but is repressed in adult cardiomyocytes. The protein is reactivated following ischemic insults, although the timing and mechanisms underlying YAP depletion during heart development and the reason for its reactivation are unclear. Here, we combine pluripotent stem cell (PSC) cardiac differentiation, mouse embryo development and human heart tissue analysis to demonstrate that the fine-tuning of cell mechanics, as controlled by YAP multiphasic activation through TEAD transcription, is crucial for mesoderm commitment and cardiac progenitor specification. Finally, by adopting induced PSC models of dilated cardiomyopathy, we prove that YAP-TEAD reactivation in diseased cardiomyocytes empowers calcium handling apparatus and increases cell contractility. Given YAP prompt activation following myocardial infarction, we unveil a novel role for mechanosensing in connecting ECM remodelling to cardiomyocyte function in pathological heart.

Project description:YAP transcriptional regulator controls cell mechanics by activating genes involved in cell-matrix interaction following extracellular matrix (ECM) remodelling and stiffening. YAP is needed for cardiogenesis in mouse but is repressed in adult cardiomyocytes. The protein is reactivated following ischemic insults, although the timing and mechanisms underlying YAP depletion during heart development and the reason for its reactivation are unclear. Here, we combine pluripotent stem cell (PSC) cardiac differentiation, mouse embryo development and human heart tissue analysis to demonstrate that the fine-tuning of cell mechanics, as controlled by YAP multiphasic activation through TEAD transcription, is crucial for mesoderm commitment and cardiac progenitor specification. Finally, by adopting induced PSC models of dilated cardiomyopathy, we prove that YAP-TEAD reactivation in diseased cardiomyocytes empowers calcium handling apparatus and increases cell contractility. Given YAP prompt activation following myocardial infarction, we unveil a novel role for mechanosensing in connecting ECM remodelling to cardiomyocyte function in pathological heart.