Project description:Embryonic stem cell (ESC) self-renewal and pluripotency is controlled by the coordinated action of transcription factors and chromatin regulators. Compared to the pluripotency transcription factors, the function of the chromatin regulators, especially the ATP-dependent chromatin remodelers, remains poorly understood in ESCs. Here, we show that INO80, a SWI/SNF family chromatin remodeling complex, is essential for ESC self-renewal, pluripotency, somatic cell reprogramming, and embryonic development. Ino80, the ATPase of the complex, forms an auto-regulatory loop with the ESC master transcription factors Oct4, Nanog, and Sox2. More importantly, it co-occupies the enhancer regions of most key pluripotency genes with the master transcription factors, and positively regulates their expression by maintaining an open chromatin structure. Our data suggests that INO80 is an integral component of the pluripotency transcription network, and plays a critical role in both the maintenance and establishment of pluripotency Mouse J1 cells were transfected with non-targeting (NT), Ino80, Ino80b, Ino80c or Ino80e siRNAs, and RNA was isolated 96 hours after transfection. agent: non-targeting siRNA: Mock_1, Mock_2 agent: Ino80 siRNA: Ino80a_1, Ino80a_2 agent: Ino80b siRNA: Ino80b_1, Ino80b_2 agent: Ino80c siRNA: Ino80c_1, Ino80c_2 agent: Ino80e siRNA: Ino80e_1, Ino80e_2 cell line: mouse J1 ESC: Mock_1, Mock_2, Ino80a_1, Ino80a_2, Ino80b_1, Ino80b_2, Ino80c_1, Ino80c_2, Ino80e_1, Ino80e_2 time: 96 hours: Mock_1, Mock_2, Ino80a_1, Ino80a_2, Ino80b_1, Ino80b_2, Ino80c_1, Ino80c_2, Ino80e_1, Ino80e_2 biological replicate: Ino80a_1, Ino80a_2 biological replicate: Ino80b_1, Ino80b_2 biological replicate: Ino80c_1, Ino80c_2 biological replicate: Ino80e_1, Ino80e_2 biological replicate: Mock_1, Mock_2

Project description:Embryonic stem cell (ESC) self-renewal and pluripotency is controlled by the coordinated action of transcription factors and chromatin regulators. Compared to the pluripotency transcription factors, the function of the chromatin regulators, especially the ATP-dependent chromatin remodelers, remains poorly understood in ESCs. Here, we show that INO80, a SWI/SNF family chromatin remodeling complex, is essential for ESC self-renewal, pluripotency, somatic cell reprogramming, and embryonic development. Ino80, the ATPase of the complex, forms an auto-regulatory loop with the ESC master transcription factors Oct4, Nanog, and Sox2. More importantly, it co-occupies the enhancer regions of most key pluripotency genes with the master transcription factors, and positively regulates their expression by maintaining an open chromatin structure. Our data suggests that INO80 is an integral component of the pluripotency transcription network, and plays a critical role in both the maintenance and establishment of pluripotency Mouse J1 cells were infected with lentiviral-shNT or lentiviral-Ino80, RNA was extracted at 2, 4 or 6 days after infection. agent: non-targeting shRNA: NS_Day_2_1, NS_Day_2_2, NS_Day_4_1, NS_Day_4_2, NS_Day_6_1, NS_Day_6_2 agent: Ino80 shRNA: shIno80_Day_2_1, shIno80_Day_2_2, shIno80_Day_4_1, shIno80_Day_4_2, shIno80_Day_6_1, shIno80_Day_6_2 time: 48 hours: NS_Day_2_1, NS_Day_2_2, shIno80_Day_2_1, shIno80_Day_2_2 time: 96 hours: NS_Day_4_1, NS_Day_4_2, shIno80_Day_4_1, shIno80_Day_4_2 time: 144 hours: NS_Day_6_1, NS_Day_6_2, shIno80_Day_6_1, shIno80_Day_6_2 cell line: mouse J1 ESC: NS_Day_2_1, NS_Day_2_2, shIno80_Day_2_1, shIno80_Day_2_2, NS_Day_4_1, NS_Day_4_2, shIno80_Day_4_1, shIno80_Day_4_2, NS_Day_6_1, NS_Day_6_2, shIno80_Day_6_1, shIno80_Day_6_2 biological replicate: shIno80_Day_2_1, shIno80_Day_2_2 biological replicate: shIno80_Day_4_1, shIno80_Day_4_2 biological replicate: shIno80_Day_6_1, shIno80_Day_6_2 biological replicate: NS_Day_2_1, NS_Day_2_2 biological replicate: NS_Day_4_1, NS_Day_4_2 biological replicate: NS_Day_6_1, NS_Day_6_2

Project description:Embryonic stem cell (ESC) self-renewal and pluripotency is controlled by the coordinated action of transcription factors and chromatin regulators. Compared to the pluripotency transcription factors, the function of the chromatin regulators, especially the ATP-dependent chromatin remodelers, remains poorly understood in ESCs. Here, we show that INO80, a SWI/SNF family chromatin remodeling complex, is essential for ESC self-renewal, pluripotency, somatic cell reprogramming, and embryonic development. Ino80, the ATPase of the complex, forms an auto-regulatory loop with the ESC master transcription factors Oct4, Nanog, and Sox2. More importantly, it co-occupies the enhancer regions of most key pluripotency genes with the master transcription factors, and positively regulates their expression by maintaining an open chromatin structure. Our data suggests that INO80 is an integral component of the pluripotency transcription network, and plays a critical role in both the maintenance and establishment of pluripotency Identification of Ino80 localization in mouse embryonic stem cells

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:Embryonic stem cell (ESC) self-renewal and differentiation are governed by a broad-ranging regulatory network. Although the transcriptional regulatory mechanisms involved have been investigated extensively, post-transcriptional regulation is still poorly understood. Here we describe a critical role of the THO complex in ESC self-renewal and differentiation. We show that THO preferentially interacts with pluripotency gene transcripts through Thoc5, and is required for self-renewal at least in part by regulating their export and expression. During differentiation, THO loses its interaction with those transcripts due to reduced Thoc5 expression, leading to decreased expression of pluripotency proteins that facilitates exit from self-renewal. THO is also important for the establishment of pluripotency, as its depletion inhibits somatic cell reprogramming and blastocyst development. Together, our data indicate that THO regulates pluripotency gene mRNA export to control ESC self-renewal and differentiation, and therefore uncover a role for this aspect of post-transcriptional regulation in stem cell fate specification. mouse J1 cells were transfected with non-targeting (NT), Thoc2, and Thoc5 siRNAs. Total RNA was isolated 96 hours after transfection.

Project description:Single-cell transcriptomics has recently emerged as a powerful technology to explore gene expression heterogeneity amongst single cells. Here we identify two major sources of technical variability, sampling noise and global cell-to-cell variation in sequencing efficiency. We propose noise models to correct for this and after validation by single-molecule FISH experiments, we apply these models to demonstrate that growing mES cells in 2i instead of serum/LIF globally reduces gene expression variability. J1 mouse embryonic stem cells (mESCs) were cutured in 2i or in serum medium. Cells were dissociated into a single cell suspension and picked under a stereomicroscope using a 30μm glass capillary and mouth pipette. Picked cells were deposited in the lid of an 0.5ml LoBind eppendorf tube and snap frozen in liquid nitrogen. For the pool and split controls, approximately 1 million cells were lysed, the amount of RNA was quantified on a bioanalyzer (Agilent) using the Eukaryote Total RNA pico kit. 20pg aliquots of total RNA were used for each pool and split control. Single cells and controls were processed using the previously described CEL-seq technique, with a few alterations. A 4bp random barcode as unique molecular identifier (UMI) was added to the primer in between the cell specific barcode and the poly T stretch. Libraries were sequenced on an Illumina HighSeq 2500 using 50bp paired end sequencing. For cells and controls, two libraries were sequenced on two lanes in total for each condition.

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:Embryonic stem cell (ESC) self-renewal and differentiation is governed by a comprehensive regulatory network. Although the transcriptional regulation has been extensively investigated, post-transcriptional mechanisms controlling the ESC state are poorly understood. Here we describe a critical role of the THO complex in ESC self-renewal and differentiation. We show that THO preferentially interacts with pluripotency gene transcripts through Thoc5, and is required for self-renewal by regulating their export and expression. During differentiation, THO loses its interaction with those transcripts due to reduced Thoc5 expression, which leads to decreased expression of pluripotency proteins and facilitates differentiation. Finally, THO is also important for the establishment of pluripotency, as its depletion inhibits somatic cell reprogramming and blastocyst development. Together, our data indicates that THO regulates pluripotency gene mRNA export to control ESC self-renewal and differentiation, and uncovers a novel mechanism of post-transcriptional regulation in stem cell fate specification. RNA IP was conducted by use of antibody against Thoc2, the precipitated RNA was used to generate library using illumina Kit, and subsequently sequenced by miSeq

Project description:Cell type-specific master transcription factors (MTFs) play vital roles in defining cell identity and function. However, the roles ubiquitous factors play in the specification of cell identity remain underappreciated. Here we show that all three subunits of the ubiquitous heterotrimeric CCAAT-binding NF-Y complex are required for the maintenance of embryonic stem cell (ESC) identity, and establish NF-Y as a novel component of the core pluripotency network. Genome-wide occupancy and transcriptomic analyses in ESCs and neurons reveal that not only does NF-Y regulate genes with housekeeping functions through cell type-invariant promoter-proximal binding, but also genes required for cell identity by binding to cell type-specific enhancers with MTFs. Mechanistically, NF-Y's distinctive DNA-binding mode promotes MTF binding at enhancers by facilitating a permissive chromatin conformation. Our studies unearth a novel function for NF-Y in promoting chromatin accessibility, and suggest that other proteins with analogous structural and DNA-binding properties may function in similar ways. Genome-wide mapping of NF-YA, NF-YB, and NF-YC subunits of the NF-Y complex in mouse ESCs, and microarray gene expression profiling of control knockdown (KD), NF-YA KD, NF-YB KD, NF-YC KD, and NF-YA/NF-YB/NF-YC triple KD ESCs.

Project description:This study was undertaken in order to characterize the functions of Rex-1 and identify potential Rex-1 target genes.Both alleles of the Rex-1 gene were disrupted in J1 mouse embryonic stem cells. Gene expression levels in one of the resulting Rex-1 knockout cell lines was compared to that of J1 wild type cells. Experiment Overall Design: Gene expression in Rex-1 knockout mouse embryonic stem cells compared to that of J1 wild type cells. Cells were cultured in the presence and absence of LIF. This series utilized eight samples.There are two biological replicates per cell type cultured under this condition. The J1 samples serve as the control.