Project description:Appropriate neural initiation of the pluripotent stem cells in the early embryos is critical for the development of the central nervous system. This process is regulated by the coordination of extrinsic signals and intrinsic programs. However, how the coordination is achieved to ensure proper neural fate commitment is largely unknown. Here, taking advantage of genome-wide ChIP-sequencing (ChIP-seq) and RNA-sequencing (RNA-seq) analyses, we demonstrate that the transcriptional factor Pou3f1 is an upstream activator of neural-promoting genes, and it is able to repress neural-inhibitory signals as well. Further studies revealed that Pou3f1 could directly bind neural lineage genes like Sox2 and downstream targets of neural inhibition signaling such as BMP and Wnt. Our results thus identify Pou3f1 as a critical dual-regulator of the intrinsic transcription factors and the extrinsic cellular signals during neural fate commitment. ChIP-seq assay was ultilized to characterize the targets of Pou3f1 on ESC differentiation day 2.

Project description:The neural fate commitment of pluripotent stem cells requires repression of extrinsic inhibitory signals and activation of intrinsic positive transcription factors. However, it remains elusive how these two events are integrated to ensure appropriate neural conversion. Here, we show that Oct6 functions as an essential positive factor for neural differentiation of mouse embryonic stem cells (ESCs), specifically during the transition from epiblast stem cells (EpiSCs) to neural progenitor cells (NPCs). Chimera analysis showed that Oct6 knockdown leads to markedly decreased incorporation of ESC in neuroectoderm. By contrast, Oct6-overexpressing ESC derivatives preferentially contribute to neuroectoderm. Genome-wide ChIP-seq and RNA-seq analyses indicate that Oct6 is an upstream activator of neural lineage genes, and also a repressor of BMP and Wnt signalings. Our results establish Oct6 as a critical regulator that promotes neural commitment of pluripotent stem cells through a dual role: activating internal neural induction programs and antagonizing extrinsic neural inhibitory signals.

Project description:The nucleoprotein Geminin (Gmnn) promotes neural cell fate acquisition of embryonic stem cells, while knockdown reduces the efficiency of neural gene activation. This occurs, at least in part, through Geminin’s ability to promote histone hyperacetylation at neural genes, to activate their expression. In mouse models in vivo, Geminin deficiency in the embryonic neural tube between embryonic days 8.5-10.5 also reduces the expression of genes controlling neural specification and/or differentiation, contributing to neural tube defects. To determine where Geminin binding and Gmnn-dependent acetylation occurs throughout the genome, we performed ChIP-chip analysis (these data) and ChIP-seq analysis (GSE77246) to define Geminin-bound chromatin locations in mouse embryonic stem cells (ESCs) and in ESC-derived neuroectoderm. We also performed ChIP-chip analysis of H3K9 acetylation in ESC-derived neuroectoderm, with or without Doxycycline-dependent Gmnn knockdown, to define the requirements for Geminin activity for histone acetylation of promoters during neural fate specification.

Project description:Epigenetic modifications play a crucial role in learning, memory and neurogenesis, but the study of its role in early neuroectoderm commitment from pluripotent inner cell mass is relatively lack. Here we utilized the system of directed neuroectoderm differentiation from human embryonic stem cells and identified KDM6B, an enzyme responsible to erase H3K27me3, was the most upregulated enzyme of histone methylation during neuroectoderm differentiation by transcriptome analysis. We then constructed KDM6B-null embryonic stem cells and found strikingly, the cells with KDM6B knockout exhibited much higher neuroectoderm induction efficiency. Furthermore, we constructed a serial of embryonic stem cell lines knocking out the other H3K27 demethylase KDM6A, and depleting both KDM6A and KDM6B, respectively. These cell lines together confirmed KDM6 impeded early neuroectoderm commitment. By RNA-seq, we found a panel of WNT activation genes significantly downregulated while WNT inhibiting genes significantly upregulated upon depletion of KDM6. Functional rescue assayed that WNT agonist could abolish the differential neuroectoderm induction due to manipulating KDM6 demonstrated WNT was the major downstream of KDM6 during early neural induction. Taken together, our findings illustrated the important role of histone methylation modifier KDM6A and KDM6B in neuroectoderm differentiation and provided additional insights into the precise epigenetic regulation in different stage of neurogenesis.

Project description:The transcriptional landscape in embryonic stem cells (ESCs) and during ESC differentiation has received considerable attention in recent years, but reports have so far been confined to the polyadenylated fraction of RNA, while the non-polyadenylated (NPA) fraction remained largely unexplored. Notwithstanding, the NPA RNA super-family, which is mainly comprised of fundamental components of the RNA translational machinery, the RNA splicing machinery, and RNA-RNA or RNA-DNA interacting complexes, has every potential to participate in the regulation of pluripotency and stem cell fate. We conducted a comprehensive analysis of NPA RNA in murine ESCs and ESC-derived Neural Progenitor Cells (NPCs) using a combination of whole genome tiling arrays and Next Generation Sequencing technologies. This strategy allowed for the transcriptional characterization of already well-defined NPA RNA subclasses in this unique biological context as well as the identification of many new members of these functional ncRNA classes. In addition, we describe a group of novel, conserved RNAs (snacRNAs: small, non-polyadenylated conserved), some of which are differentially expressed between ESC and NPCs, providing the first evidence of a novel group of potentially functional ncRNAs involved in the regulation of pluripotency and stem cell fate. We further show that minor spliceosomal snRNAs, which are non-polyadenylated, are almost completely absent in ESCs and are upregulated in differentiation. Finally, we show differential processing of the minor intron of the polycomb group gene Eed. Our data suggest that non-polyadenylated RNA, both known and novel, play important roles in embryonic stem cells. We extracted total RNA from undifferentiated ESCs and 7 day NPCs. Total RNA was divided into poly(A+) and poly(A-) enriched fractions using a modified version of Oligotex extraction (Qiagen). Briefly, after the hybridization of the total RNA to oligo(dT) beads, supernatants were saved rather than discarded and then subjected to isopropanol-ethanol extraction to obtain the Poly(A-) fraction. This submission represents RNA-Seq component of study.

Project description:Appropriate neural initiation of the pluripotent stem cells in the early embryos is critical for the development of the central nervous system. This process is regulated by the coordination of extrinsic signals and intrinsic programs. However, how the coordination is achieved to ensure proper neural fate commitment is largely unknown. Here, taking advantage of genome-wide ChIP-sequencing (ChIP-seq) and RNA-sequencing (RNA-seq) analyses, we demonstrate that the transcriptional factor Pou3f1 is an upstream activator of neural-promoting genes, and it is able to repress neural-inhibitory signals as well. Further studies revealed that Pou3f1 could directly bind neural lineage genes like Sox2 and downstream targets of neural inhibition signaling such as BMP and Wnt. Our results thus identify Pou3f1 as a critical dual-regulator of the intrinsic transcription factors and the extrinsic cellular signals during neural fate commitment.

Project description:Stem cell fate is governed by the integration of intrinsic and extrinsic positive and negative signals upon inherent transcriptional networks. To identify novel embryonic stem cell (ESC) regulators and assemble transcriptional networks controlling ESC fate, we performed temporal expression microarray analyses of ESCs following the initiation of commitment and integrated these data with known genome-wide transcription factor binding. Effects of forced under- or over-expression of predicted novel regulators, defined as differentially expressed genes with potential binding sites for known regulators of pluripotency, demonstrated greater than 90% correspondence with predicted function, as assessed by functional and high content assays of self-renewal. We next assembled 43 theoretical transcriptional networks in ESCs, 82% (23 out of 28 tested) of which were supported by analysis of genome-wide expression in Oct4 knockdown cells. By using this integrative approach we have, for the first time, formulated novel networks describing gene repression of key developmental regulators in undifferentiated ESCs and successfully predicted the outcomes of genetic manipulation of these networks. Experiment Overall Design: 1, 3, and 5 days LIF differentiated ESCs, and 1 and 2 days RA differentiated ESCs

Project description:While the transcriptional network of human embryonic stem cells (hESCs) has been extensively studied, relatively little is known about how post-transcriptional modulations determine hESC function. RNA-binding proteins play central roles in RNA regulation, including translation and turnover. Here we show that the RNA-binding protein CSDE1 is highly expressed in hESCs to maintain their undifferentiated state and prevent default neural fate. Notably, loss of CSDE1 accelerates neural differentiation and potentiates neurogenesis. Conversely, ectopic expression of CSDE1 impairs neural differentiation. We find that CSDE1 post-transcriptionally modulates core components of multiple regulatory nodes of hESC identity, neuroectoderm commitment and neurogenesis. Among these key pro-neural/neuronal factors, CSDE1 binds fatty acid binding protein 7 (FABP7) and vimentin (VIM) mRNAs as well as transcripts involved in neuron projection development regulating their stability and translation. Thus, our results uncover CSDE1 as a central post-transcriptional regulator of hESC identity and neurogenesis.

Project description:While the transcriptional network of human embryonic stem cells (hESCs) has been extensively studied, relatively little is known about how post-transcriptional modulations determine hESC function. RNA-binding proteins play central roles in RNA regulation, including translation and turnover. Here we show that the RNA-binding protein CSDE1 is highly expressed in hESCs to maintain their undifferentiated state and prevent default neural fate. Notably, loss of CSDE1 accelerates neural differentiation and potentiates neurogenesis. Conversely, ectopic expression of CSDE1 impairs neural differentiation. We find that CSDE1 post-transcriptionally modulates core components of multiple regulatory nodes of hESC identity, neuroectoderm commitment and neurogenesis. Among these key pro-neural/neuronal factors, CSDE1 binds fatty acid binding protein 7 (FABP7) and vimentin (VIM) mRNAs as well as transcripts involved in neuron projection development regulating their stability and translation. Thus, our results uncover CSDE1 as a central post-transcriptional regulator of hESC identity and neurogenesis. This proteomics dataset contains the data from co-immunopreciptation experiments using CSDE1 antibody in hESCs

Project description:To understand the function of CHD8 in human ESC and neural differentiation, we generated the CHD8 knockout human ESCs and characterize the effect of loss-of-function of CHD8 on pluripotency maintenance and neuroectoderm determination by utilizing an efficient neuroectoderm differentiation protocol. Samples from hESC, CHD8KO_hESC and their derived-neural progenitor cells (hNPC) were collected for high-throughput sequencing with at least two replicates for each sample. Differentially expressed genes analysis showed loss of CHD8 affect the genes in ESC and NPC.