Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Soon after release from stemness, a relevant portion of mouse embryonic stem cells (mES), kept in naïve state by MEK inhibitor, GSK3 inhibitor and LIF (2i/L), expresses endothelial nitric oxide synthase (eNOS) and endogenously synthesizes nitric oxide (NO). In this condition, an eNOS/NO-positive subpopulation (ESNO+) has been recognized by 4-amino-5-methylamino-2′,7′-difluorescein (DAF) fluorescence. Sorted ESNO+ cells expressed high levels of mesendodermal markers and efficiently generated cardiovascular precursors compared to eNOS/NO-negative cells (ESNO-). Mechanistically, the endogenous NO production deter- mined a rapid S-nitrosylation of Hdac2, a post-translational modification that compromised Hdac2 association with the transcription repression factor Zeb1. This condition destabilized Zeb1/chromatin interaction with genomic loci encoding for mesendodermal genes. Remarkably, Zeb1 or Hdac2 targeting activated an unscheduled transcription of mesendodermal lineage-associated genes in naïve mES revealing the Hdac2-Zeb1 pathway important for stemness maintenance in 2i/L. In contrast, eNOS targeting significantly reduced the endogenous NO production preventing the activation of mesendodermal gene transcription.

Project description:Soon after release from stemness, a relevant portion of mouse embryonic stem cells (mES), kept in naïve state by MEK inhibitor, GSK3 inhibitor and LIF (2i/L), expresses endothelial nitric oxide synthase (eNOS) and endogenously synthesizes nitric oxide (NO). In this condition, an eNOS/NO-positive subpopulation (ESNO+) has been recognized by 4-amino-5-methylamino-2′,7′-difluorescein (DAF) fluorescence. Sorted ESNO+ cells expressed high levels of mesendodermal markers and efficiently generated cardiovascular precursors compared to eNOS/NO-negative cells (ESNO-). Mechanistically, the endogenous NO production deter- mined a rapid S-nitrosylation of Hdac2, a post-translational modification that compromised Hdac2 association with the transcription repression factor Zeb1. This condition destabilized Zeb1/chromatin interaction with genomic loci encoding for mesendodermal genes. Remarkably, Zeb1 or Hdac2 targeting activated an unscheduled transcription of mesendodermal lineage-associated genes in naïve mES revealing the Hdac2-Zeb1 pathway important for stemness maintenance in 2i/L. In contrast, eNOS targeting significantly reduced the endogenous NO production preventing the activation of mesendodermal gene transcription.

Project description:A Zeb1 Hdac2 eNOS feedback circuitry identifies early cardiovascular precursors in naïve mouse embryonic stem cells

Project description:A Zeb1 Hdac2 eNOS feedback circuitry identifies early cardiovascular precursors in naïve mouse embryonic stem cells (RNA-Seq)

Project description:A Zeb1 Hdac2 eNOS feedback circuitry identifies early cardiovascular precursors in naïve mouse embryonic stem cells (ChIP-Seq)

Project description:Directed differentiation of embryonic stem cells indicates that mesodermal lineages in the mammalian heart (cardiac, endothelial, and smooth muscle cells) develop from a common, multipotent cardiovascular precursor. To isolate and characterize the lineage potential of a resident pool of cardiovascular progenitor cells (CPcs), we developed BAC transgenic mice in which enhanced green fluorescent protein (EGFP) is placed under control of the c-kit locus (c-kit(BAC)-EGFP mice). Discrete c-kit-EGFP(+) cells were observed at different stages of differentiation in embryonic hearts, increasing in number to a maximum at about postnatal day (PN) 2; thereafter, EGFP(+) cells declined and were rarely observed in the adult heart. EGFP(+) cells purified from PN 0-5 hearts were nestin(+) and expanded in culture; 67% of cells were fluorescent after 9 days. Purified cells differentiated into endothelial, cardiac, and smooth muscle cells, and differentiation could be directed by specific growth factors. CPc-derived cardiac myocytes displayed rhythmic beating and action potentials characteristic of multiple cardiac cell types, similar to ES cell-derived cardiomyocytes. Single-cell dilution studies confirmed the potential of individual CPcs to form all 3 cardiovascular lineages. In adult hearts, cryoablation resulted in c-kit-EGFP(+) expression, peaking 7 days postcryolesion. Expression occurred in endothelial and smooth muscle cells in the revascularizing infarct, and in terminally differentiated cardiomyocytes in the border zone surrounding the infarct. Thus, c-kit expression marks CPc in the neonatal heart that are capable of directed differentiation in vitro; however, c-kit expression in cardiomyocytes in the adult heart after injury does not identify cardiac myogenesis.

Project description:Despite their therapeutic potential, progress in generating fully differentiated forebrain neurons from embryonic stem cells (ESCs) has lagged behind that from more caudal regions of the neuraxis. GABAergic interneuron precursors have the remarkable ability to migrate extensively and survive after transplantation into postnatal cortex, making them an attractive candidate for use in cell-based therapy for seizures or other neuropsychiatric disorders. We have modified a mouse ESC line with an Lhx6-GFP reporter construct that allows for the isolation of newly generated cortical interneuron precursors. When transplanted into postnatal cortex, these cells can migrate into the cortical parenchyma, survive for months, and display morphological, neurochemical, and electrophysiological properties characteristic of mature interneurons. This work demonstrates that forebrain neuronal subtypes with complex traits can be generated from embryonic stem cells, and provides a novel approach to the study of cortical interneuron development and to the establishment of cell-based therapies for neurological disease.

Project description:BackgroundMicroRNAs are required for maintenance of pluripotency as well as differentiation, but since more microRNAs have been computationally predicted in genome than have been found, there are likely to be undiscovered microRNAs expressed early in stem cell differentiation.Methodology/principal findingsSOLiD ultra-deep sequencing identified >10(7) unique small RNAs from human embryonic stem cells (hESC) and neural-restricted precursors that were fit to a model of microRNA biogenesis to computationally predict 818 new microRNA genes. These predicted genomic loci are associated with chromatin patterns of modified histones that are predictive of regulated gene expression. 146 of the predicted microRNAs were enriched in Ago2-containing complexes along with 609 known microRNAs, demonstrating association with a functional RISC complex. This Ago2 IP-selected subset was consistently expressed in four independent hESC lines and exhibited complex patterns of regulation over development similar to previously-known microRNAs, including pluripotency-specific expression in both hESC and iPS cells. More than 30% of the Ago2 IP-enriched predicted microRNAs are new members of existing families since they share seed sequences with known microRNAs.Conclusions/significanceExtending the classic definition of microRNAs, this large number of new microRNA genes, the majority of which are less conserved than their canonical counterparts, likely represent evolutionarily recent regulators of early differentiation. The enrichment in Ago2 containing complexes, the presence of chromatin marks indicative of regulated gene expression, and differential expression over development all support the identification of 146 new microRNAs active during early hESC differentiation.

Project description:Unlike some organs, the heart is unable to repair itself after injury. Human embryonic stem cells (hESCs) grow and divide indefinitely while maintaining the potential to develop into many tissues of the body. As such, they provide an unprecedented opportunity to treat human diseases characterized by tissue loss. We have identified early myocardial precursors derived from hESCs (hMPs) using an ?-myosin heavy chain (?MHC)-GFP reporter line. We have demonstrated by immunocytochemistry and quantitative real-time PCR (qPCR) that reporter activation is restricted to hESC-derived cardiomyocytes (CMs) differentiated in vitro, and that hMPs give rise exclusively to muscle in an in vivo teratoma formation assay. We also demonstrate that the reporter does not interfere with hESC genomic stability. Importantly, we show that hMPs give rise to atrial, ventricular and specialized conduction CM subtypes by qPCR and microelectrode array analysis. Expression profiling of hMPs over the course of differentiation implicate Wnt and transforming growth factor-? signaling pathways in CM development. The identification of hMPs using this ?MHC-GFP reporter line will provide important insight into the pathways regulating human myocardial development, and may provide a novel therapeutic reagent for the treatment of cardiac disease.