Project description:Objectives: We studied the signal transduction of atrial structural remodelling that contributes to the pathogenesis of atrial fibrillation (AF). Backround: Fibrosis is a hallmark of arrhythmogenic structural remodelling but the underlying molecular mechanisms are incompletely understood. Methods: We performed transcriptional profiling of left atrial myocardium (LA) from patients with AF and sinus rhythm (SR) and applied cultured primary cardiac cells and transgenic mice with overexpression of constitutively active V12Rac1 (RacET) who develop AF at old age to characterize mediators of the signal transduction of atrial remodeling. Results: LA from patients with AF showed a marked upregulation of connective tissue growth factor (CTGF) expression compared SR patients. This was associated with increased fibrosis, NADPH-oxidase-, Rac1- and RhoA activity, upregulation of N-cadherin and connexin 43 (Cx43) expression and increased angiotensin II tissue concentration. In neonatal rat cardiac myocytes and -fibroblasts, a specific small molecule inhibitor of Rac1 or simvastatin completely prevented the angiotensin II induced upregulation of CTGF, Cx43 and N-cadherin expression. Transfection with small-inhibiting CTGF RNA blocked Cx43 and N-cadherin expression. RacET mice showed upregulation of CTGF, Cx43 and N-cadherin protein expression. Inhibition of Rac1 by oral statin treatment prevented these effects, identifying Rac1 as a key regulator of CTGF in vivo. Conclusion: The data identify CTGF as an important mediator of atrial structural remodelling during AF. Angiotensin II activates CTGF via activation of Rac1 and NADPH oxidase, leading to upregulation of Cx43, N-cadherin and interstitial fibrosis and therefore contributing to the signal transduction of atrial structural remodelling. Array design study consists of 5 Atrial Fibrillation patients and matched 5 samples of patients in sinus rhythm (controls).

Project description:Mesenchymal stem cells (MSCs) are one of most promising stem cell sources for regenerative medicine. MSCs have a differention ability into several tissues. However, their differentiation efficiency is considered quite limited. Especially, the differentiation efficiency into cardiomyocytes is very low. N-cadherin is one of the cell surface protein that is expressed in developing and adult cardiomyocytes. We found that cell surface expression of N-cadherin in MSCs shows good correlation with the cardiomyogenic differentiation ability. We also analyzed the expression profiles of N-cadherin-positive and N-cadherin-negative fraction by microarray. We found that N-cadherin-positive MSCs show higher expression of some of the cardiomyogenesis-related genes than N-cadherin-negative MSCs.

Project description:Phosphorylation of sarcomeric proteins has been implicated in heart failure with preserved ejection fraction (HFpEF); such changes may contribute to diastolic dysfunction by altering contractility, cardiac stiffness, Ca2+-sensitivity and mechanosensing. Treatment with cardiosphere-derived cells (CDCs) restores normal diastolic function, attenuates fibrosis and inflammation, and improves survival in a rat HFpEF model. Here, we quantified the phosphorylation changes that underlie HFpEF and those reversed by CDC therapy, with a focus on the sarcomeric subproteome.

Project description:Mesenchymal stem cells (MSCs) are one of most promising stem cell sources for regenerative medicine. MSCs have a differention ability into several tissues. However, their differentiation efficiency is considered quite limited. Especially, the differentiation efficiency into cardiomyocytes is very low. N-cadherin is one of the cell surface protein that is expressed in developing and adult cardiomyocytes. We found that cell surface expression of N-cadherin in MSCs shows good correlation with the cardiomyogenic differentiation ability. We also analyzed the expression profiles of N-cadherin-positive and N-cadherin-negative fraction by microarray. We found that N-cadherin-positive MSCs show higher expression of some of the cardiomyogenesis-related genes than N-cadherin-negative MSCs. The ASCs were maintained in MesenPRO RSTM Medium. The ASCs were harvested in a cell dissociation buffer. The ASCs were incubated with biotinylated anti N-cadherin antibody and next incubated with streptavidin M-bM-^@M-^SAPC. Subsequently cells were incubated with anti-APC microbeads. Immunomagnetic separation of N-cadherin+ cells were performed with autoMACSTMPro separator applying the separation program M-bM-^@M-^Xdepl025M-bM-^@M-^Y

Project description:Objectives: We studied the signal transduction of atrial structural remodelling that contributes to the pathogenesis of atrial fibrillation (AF). Backround: Fibrosis is a hallmark of arrhythmogenic structural remodelling but the underlying molecular mechanisms are incompletely understood. Methods: We performed transcriptional profiling of left atrial myocardium (LA) from patients with AF and sinus rhythm (SR) and applied cultured primary cardiac cells and transgenic mice with overexpression of constitutively active V12Rac1 (RacET) who develop AF at old age to characterize mediators of the signal transduction of atrial remodeling. Results: LA from patients with AF showed a marked upregulation of connective tissue growth factor (CTGF) expression compared SR patients. This was associated with increased fibrosis, NADPH-oxidase-, Rac1- and RhoA activity, upregulation of N-cadherin and connexin 43 (Cx43) expression and increased angiotensin II tissue concentration. In neonatal rat cardiac myocytes and -fibroblasts, a specific small molecule inhibitor of Rac1 or simvastatin completely prevented the angiotensin II induced upregulation of CTGF, Cx43 and N-cadherin expression. Transfection with small-inhibiting CTGF RNA blocked Cx43 and N-cadherin expression. RacET mice showed upregulation of CTGF, Cx43 and N-cadherin protein expression. Inhibition of Rac1 by oral statin treatment prevented these effects, identifying Rac1 as a key regulator of CTGF in vivo. Conclusion: The data identify CTGF as an important mediator of atrial structural remodelling during AF. Angiotensin II activates CTGF via activation of Rac1 and NADPH oxidase, leading to upregulation of Cx43, N-cadherin and interstitial fibrosis and therefore contributing to the signal transduction of atrial structural remodelling.

Project description:Co-IP Experiment Bait: Cx43-Flag Cell line: Hela Related Publication: Gap Junction protein Connexin-43 is a direct transcriptional regulator of N-cadherin in vivo, Maria Kotini, Elias Barriga, Jonathan Leslie, Marc Gentzel, Verena Rauschenberger, Alexandra Schambony, and Roberto Mayor

Project description:Tissue-resident macrophages abound in the distal atrioventricular (AV) node of the heart, electrically couple to conducting cardiomyocytes via Connexin (Cx) 43-containing gap junctions and are implicated in normal and aberrant cardiac conduction. Moreover, conditional deletion of Cx43 in macrophages (tamoxifen-inducible Cx3cr1 Cx43-/- mice) delays AV conduction and acute depletion of macrophages in Cd11bDTR mice induces progressive AV block.

Project description:Blood-brain barrier (BBB) function deteriorates during aging, contributing to cognitive impairment and neurodegeneration. It is unclear what drives BBB leakage in aging and how it can be prevented. Using single-nucleus transcriptomics, we identified decreased connexin 43 (CX43) expression in Cadherin-5+ (Cdh5+) cerebral vascular cells in naturally aging mice and confirmed it in human brain samples. Global or Cdh5+ cell-specific CX43 deletion in mice exacerbated BBB dysfunction during aging. The CX43-dependent effect was not due to its canonical gap junction function but was associated with reduced NAD+ levels and mitochondrial dysfunction through NAD+-dependent sirtuin 3. CX43 interacts with and negatively regulates poly (ADP-ribose) polymerase 1 (PARP1). Pharmacologic inhibition of PARP1 by olaparib or nicotinamide mononucleotide supplementation rescued NAD+ levels and alleviated aging-associated BBB leakage. These findings establish the endothelial CX43-PARP1-NAD+ pathway’s role in vascular aging and identify a potential therapeutic strategy to combat aging-associated BBB leakage with neuroprotective implications.

Project description:Adult cardioyocytes undergo remarkable dedifferentiation and cell cycle reprogramming/reentery when cultured in mitogen-rich medium, continuously, and give rise to cardiac progenitor cells (CPCs). Using microfluidic device for single-cell capture and whole-transcriptomic amplification, we analyze the whole-genome transcriptomic profile in adult mouse cardiomyocytes (Ctl) and in their derived CPCs, and validate the gene expression by single-cell PCR and PCR array. Using two platforms for DNA methylation profiling: NimbleGen DNA methylation array and CHARM array, the whole-genome DNA methylation profile in myocytes (Ctl) and CPCs were compared and their regulations in relationship to the transcriptomics profile were analyzed. The results demonstrated remarkable molecular reprogramming pertaining to dedifferentiation, loss of cardiac contractile, structure, and fucntion molecules, and reactivation of cell cycle and proliferation genes, significant changes in metabolisms. The reduction of cardiac function and structure genes are highly related to their hypermethylation of the promoter regions. GO and Pathway enrichment analysis revealed distinct coordianted transcriptomic and epigenetic regulation in the CPCs derived from cardiomyocytes. Genomic DNA isolated from adult mouse cardiomyocytes (Ctl) or cardiomyocyte-derived progenitor cells (CPCs) was subjected to digestion by methylcytosine-sensitive enzyme McrBC, and subsequently purification and amplification, labeling and hybridization to the NimbleGen 3x720K DNA methylation Promoter array, according to NimbleGen protocol. Percentage methylation, hypermethylation or hypomethylation, and peak enrichment were assessed using CHARM protocol.

Project description:Adult cardioyocytes undergo remarkable dedifferentiation and cell cycle reprogramming/reentery when cultured in mitogen-rich medium, continuously, and give rise to cardiac progenitor cells (CPCs). Using microfluidic device for single-cell capture and whole-transcriptomic amplification, we analyze the whole-genome transcriptomic profile in adult mouse cardiomyocytes (Ctl) and in their derived CPCs, and validate the gene expression by single-cell PCR and PCR array. Using two platforms for DNA methylation profiling: NimbleGen DNA methylation array and CHARM array, the whole-genome DNA methylation profile in myocytes (Ctl) and CPCs were compared and their regulations in relationship to the transcriptomics profile were analyzed. The results demonstrated remarkable molecular reprogramming pertaining to dedifferentiation, loss of cardiac contractile, structure, and function molecules, and reactivation of cell cycle and proliferation genes, significant changes in metabolisms. The reduction of cardiac function and structure genes are highly related to their hypermethylation of the promoter regions. GO and Pathway enrichment analysis revealed distinct coordianted transcriptomic and epigenetic regulation in the CPCs derived from cardiomyocytes. Genomic DNA isolated from adult mouse cardiomyocytes (Ctl) or cardiomyocyte-derived progenitor cells (CPCs) was subjected to digestion by methylcytosine-sensitive enzyme McrBC, and subsequently purification and amplification, labeling and hybridization according to NimbleGen protocol. Percentage methylation, hypermethylation or hypomethylation, and peak enrichment were assessed using CHARM protocol.