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:We aimed to examine differences between c-kit+ progenitor cells (CPCs) and CPC-derived extracellular vesicles (EV) RNA content. We isolated CPCs from cardiac biopsies of patients with congenital heart disease using magnetic bead sorting. We expanded CPCs, reduced serum for 24hrs, and collected secreted EVs from conditioned media with sequential ultracentrifugation. We isolate RNA from CPCs and CPC-EVs and sequence total RNA and miRNA. Sequencing was performed in at two different facilities: "E" and "N".

Project description:We aimed to examine differences between c-kit+ progenitor cells (CPCs) and CPC-derived extracellular vesicles (EV) RNA content. We isolated CPCs from cardiac biopsies of patients with congenital heart disease using magnetic bead sorting. We expanded CPCs, reduced serum for 24hrs, and collected secreted EVs from conditioned media with sequential ultracentrifugation. We isolate RNA from CPCs and CPC-EVs and sequence total RNA and miRNA. Sequencing was performed in at two different facilities: "E" and "N".

Project description:We aimed to examine differences between c-kit+ progenitor cells (CPCs) and CPC-derived extracellular vesicles (EV) RNA content. We isolated CPCs from cardiac biopsies of patients with congenital heart disease using magnetic bead sorting. We expanded CPCs, reduced serum for 24hrs, and collected secreted EVs from conditioned media with sequential ultracentrifugation. We isolate RNA from CPCs and CPC-EVs and sequence total RNA and miRNA. Sequencing was performed in at two different facilities: "E" and "N".

Project description:Baseline gene expression of mouse Cardiac Progenitor Cells (CPC) We used microarrays to analyze the global gene expression of mouse CPCs.

Project description:The regulation of multipotent cardiac progenitor cell (CPC) expansion and subsequent differentiation into cardiomyocytes, smooth muscle, or endothelial cells is a fundamental aspect of basic cardiovascular biology and cardiac regenerative medicine. However, the mechanisms governing these decisions remain unclear. Here, we show that Wnt/β-Catenin signaling, which promotes expansion of CPCs, is negatively regulated by Notch1-mediated control of phosphorylated β-Catenin accumulation within CPCs, and that Notch1 activity in CPCs is required for their differentiation. Notch1 positively, and β-Catenin negatively, regulated expression of the cardiac transcription factors, Isl1, Myocd and Smyd1. Surprisingly, disruption of Isl1, normally expressed transiently in CPCs prior to their differentiation, resulted in expansion of CPCs in vivo and in an embryonic stem (ES) cell system. Furthermore, Isl1 was required for CPC differentiation into cardiomyocyte and smooth muscle cells, but not endothelial cells. These findings reveal a regulatory network controlling CPC expansion and cell fate that involve unanticipated functions of β-Catenin, Notch1 and Isl1 that may be leveraged for regenerative approaches involving CPCs.

Project description:The regulation of multipotent cardiac progenitor cell (CPC) expansion and subsequent differentiation into cardiomyocytes, smooth muscle, or endothelial cells is a fundamental aspect of basic cardiovascular biology and cardiac regenerative medicine. However, the mechanisms governing these decisions remain unclear. Here, we show that Wnt/β-Catenin signaling, which promotes expansion of CPCs, is negatively regulated by Notch1-mediated control of phosphorylated β-Catenin accumulation within CPCs, and that Notch1 activity in CPCs is required for their differentiation. Notch1 positively, and β-Catenin negatively, regulated expression of the cardiac transcription factors, Isl1, Myocd and Smyd1. Surprisingly, disruption of Isl1, normally expressed transiently in CPCs prior to their differentiation, resulted in expansion of CPCs in vivo and in an embryonic stem (ES) cell system. Furthermore, Isl1 was required for CPC differentiation into cardiomyocyte and smooth muscle cells, but not endothelial cells. These findings reveal a regulatory network controlling CPC expansion and cell fate that involve unanticipated functions of β-Catenin, Notch1 and Isl1 that may be leveraged for regenerative approaches involving CPCs. YFP+ cells marking precardiac mesoderm (Isl1-cre domain) were FACS-sorted (w/wo stabilized Beta-catenin). Their total RNA was amplified with the WT-Ovation Pico RNA Amplification System, fragmented and labeled with the FL-Ovation cDNA Biotin Module V2 (Nugen). The hybridization, staining and scanning of the Affymetrix GeneChips were performed in the Gladstone Genomics Core Lab. Raw data generated from at least three independent experiments were further analyzed by the group of Dr. Ru-Fang Yeh at the Center for Informatics and Molecular Biostatistics, UCSF.

Project description:Although recent studies support regenerative potential based on cardiac progenitor cells (CPCs), it remains unclear what cues regulate CPC fate. Using 2- and 3D-culture models, we demonstrate that the two most abundantly expressed matrix proteins in the heart, laminin and fibronectin, have opposite roles in CPC fate decision. CPCs on fibronectin showed predominantly nuclear localization of the transcriptional co-activator YAP and maintained proliferation. In contrast, seeding on laminin induced cytosolic retention and degradation of YAP and altered gene expression, which preceded decreased proliferation and enhanced lineage commitment. RNA-sequencing identified Plk2 as candidate target gene of YAP. Plk2 expression depended on YAP stability, was rapidly downregulated on laminin, and its regulation was sufficient to rescue and/or mimic the CPC response to laminin and fibronectin, respectively. These findings propose a novel role of Plk2 and identify an early molecular mechanism in matrix-instructed CPC fate with potential implications for therapeutic cardiac regeneration.

Project description:Mouse embryonic stem cells can differentiate in vitro into spontaneously contracting cardiomyocytes. The main objective of this study was to investigate cardiogenesis in cultures of differentiating embryonic stem cells (ESCs) and to determine how closely it mimics in vivo cardiac development. We identified and isolated a population of cardiac progenitor cells (CPCs) through the use of a reporter DNA construct that allowed the expression of a selectable marker under the control of the Nkx2.5 enhancer. We proceeded to characterize these CPCs by examining their capacity to differentiate into cardiomyocytes and to proliferate. We then performed a large-scale temporal microarray expression analysis in order to identify genes that are uniquely upregulated or downregulated in the CPC population. We determined that the transcriptional profile of the mESC derived CPCs was consistent with pathways known to be active during embryonic cardiac development. We conclude that in vitro differentiation of mESCs recapitulates the early steps of mouse cardiac development. Keywords: embryonic stem cell, differentiation, cardiac progenitor, cardiogenesis

Project description:Rationale: Cardiogenesis is regulated by a complex interplay between transcription factors and chromatin-modifying enzymes. However, little is known about how these interactions regulate the transition from mesodermal precursors to cardiac progenitor cells (CPCs). Objective: To identify novel regulators of mesodermal cardiac lineage commitment. Methods and Results: We performed a bioinformatic-based transcription factor-binding site analysis on upstream promoter regions of genes that are enriched in ES cell-derived CPCs. From 32 candidate transcription factors screened, we found that YY1, a repressor of sarcomeric gene expression, is present in CPCs in vivo. Interestingly, we uncovered the ability of YY1 to transcriptionally activate Nkx2.5, a key marker of early cardiogenic commitment. YY1 regulates Nkx2.5 expression via a 2.1 kb cardiac-specific enhancer as demonstrated by in vitro luciferase-based assays and in vivo chromatin immunoprecipitation (ChIP) and genome-wide sequencing analysis. Furthermore, the ability of YY1 to activate Nkx2.5 expression depends on its cooperative interaction with GATA4 at a nearby chromatin. Cardiac mesoderm-specific loss-of-function of YY1 resulted in early embryonic lethality. This was corroborated in vitro by ES cell-based assays where we show that the over-expression of YY1 enhanced the cardiogenic differentiation ES cells into CPCs in a cell autonomous manner. Conclusion: These results demonstrate an essential and unexpected role for YY1 to promote cardiogenesis as a transcriptional activator of Nkx2.5 and other CPC-enriched genes. We report the identification of putative YY1 target genes in cardiac progenitor cells (CPCs). Two samples of independently FACS-purified eGFP+ CPCs were examined against the input.