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. Mouse single cardiomyocytes (Ctl) and their derievd single CPCs were captured using microfluidic deviced and cDNA synthesized and amplified and labelled using NuGENE kits, and regular Affymetrix hybridization and wash protocols were used to process the mouse whole-genome array GeneChip 430 2.0.

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.

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.

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.

Project description:We generated i4F (Heart) mice which has cardiac-specific and doxycycline (DOX) controllable OSKM expression system. Using next generation sequencing (NGS), we analyzed the whole transcriptomic profiles in isolated adult cardiomyocytes from i4F (Heart) mice, which were under different DOX-treatments. We found the i4F (Heart) mice upon 6 days and 12 days DOX their cardiomycytes had remarkable change of transcriptome to be like neonatal and embryonic cardiomyocytes, which exhibited dedifferentiation, significant change in metabolism, and cell-cycle reactivation. While cardiomyocytes showed molecular re-differentiation when DOX withdrawn after 6 days treatment.

Project description:Baseline gene expression of mouse Cardiac Progenitor Cells (CPC) We used microarrays to analyze the global gene expression of mouse CPCs. Compare the gloable gene expression of mouse CPCs and Cardiomyocytes. Although the chip is two color, we only used Cy5 as the data channel.

Project description:Human cardiomyocytes can be generated from human embryonic stem cells (hESCs) in vitro by a variety of methods, including co-culture with visceral endoderm-like cell lines and growth factor directed differentiation as monolayers or three-dimensional embryonic bodies. To enable the identification, purification and characterisation of human embryonic stem cell derived cardiomyocytes (CMs) and cardiac progenitor cells (CPCs), we introduced sequences encoding GFP into the NKX2-5 locus by homologous recombination. We found that NKX2-5GFP hESCs facilitate quantification of cardiac differentiation, purification of hESC-derived committed cardiac progenitor cells and cardiomyocytes and the standardization of differentiation protocols.

Project description:TLDA miRNA profiling on purified rat cardiomyocytes (Myo) (Ctl) and myocyte-derived progenitor cells (MDCs) demonstrated significant dedifferentiation of myocytes and identity of stemness, cell cycle progression and proliferation in MDCs after continuous culture in mitogen-rich medium for about 2 weeks. Total RNA was extracted from 3 batches of myocytes or MDCs; 100ug each was subjected to TLDA microRNA profiling after preamplification using ABI's kit. Cardiomyocyte (Myo, Ctl) was used as calibrator sample.

Project description:NimbleGen Mouse DNA Methylation 3x720K CpG Islands Pus RefSeq Promoter Array was used to perform a DNA methylome analysis to unravel the molecular mechanism underlying the dedifferentiation and cell cycle reentry of mouse adult cardiomyocytes (ACMs). A total of six DNA samples (10 ng each) derived from the population cells from either control adult cardiomyocytes or mCPCs were subject to whole genome amplification and then 2.5 µg of amplified products were used for DNA methylome analysis. There were three biological replicates in each group (both ACM controls and mCPCs). The whole genome methylome data using NimbleGen Mouse 2.1M array and genomic DNA derived from population cells for both control adult cardiomyocytes and mCPC can be found in E-MTAB-3984. Single-cell whole-transcriptome microarray data using Affymetrix Mouse Genome 430 2.0 Array can be found in E-MTAB-3981.