Project description:Feeders make necessary contributions to maintaining pluripotency and have been widely used for culturing embryonic stem cells (ESCs). Here, we showed p53 in feeders is required for ESC self-renewal. Following ablation of p53 in feeders, ESCs attenuated their pluripotent characteristics, with hyperactivation of ERK. We established that p53 in feeders transcriptionally actives MMP-2 or -9, thereby promoting degradation of fibronectin, preventing its interaction with integrins in ESCs and subsequent activation of integrin/FAK/ERK pathway. Based on these, we developed a new 2i or 1i system for ESC culture. Moreover, treatment of human pluripotent stem cells, or tissue stem cells with a fibronectin-integrin inhibitor strongly increased Sox2 and Oct4 levels. Our findings demonstrate a cross-cell function for p53 in regulating pluripotency, reveal a novel feeder-action mechanism beneficial for developing new stem cell culture conditions.

Project description:p53 regulates pluripotency of embryonic stem cells via microenvironmental fibronectin-integrin interaction

Project description:p53 regulates pluripotency of embryonic stem cells via microenvironmental fibronectin-integrin interaction

Project description:Pluripotent Embryonic Stem Cells (ESCs) can be captured in vitro in different states, ranging from unrestricted ‘naïve’ to more developmentally constrained ‘primed’ pluripotency. Complexes involved in epigenetic regulation and key transcription factors have been shown to be involved in specifying these distinct states. In this study, we use proteomic profiling of the chromatin landscape in naive pluripotent ESCs, Epistem cells (EpiSCs) and early differentiated ESCs to survey the chromatin in naïve and primed pluripotency and during differentiation. We provide a comprehensive overview of epigenetic complexes situated on the chromatin and identify proteins associated with the maintenance and loss of pluripotency. The findings presented here indicate major compositional alterations of epigenetic complexes starting from ESC priming onwards. Our results contribute to the understanding of ESC differentiation and provide a framework for future studies of lineage commitment of ESCs.

Project description:The objective of this study was to identify genes regulated by canonical Wnt signaling in mouse embryonic stem cells (ESCs).Canonical Wnt signaling supports the pluripotency of mouse ESCs but also promotes differentiation of early mammalian cell lineages. To explain these paradoxical observations, we explored the gene regulatory networks at play. Canonical Wnt signaling is intertwined with the pluripotency network comprising Nanog, Oct4, and Sox2 in mouse ESCs. In defined media supporting the derivation and propagation of mouse ESCs, Tcf3 and ?-catenin interact with Oct4; Tcf3 binds to Sox motif within Oct-Sox composite motifs that are also bound by Oct4-Sox2 complexes. Further, canonical Wnt signaling up-regulates the activity of the Pou5f1 distal enhancer via the Sox motif in mouse ESCs. When viewed in the context of published studies on Tcf3 and ?-catenin mutants, our findings suggest that Tcf3 counters pluripotency by competition with Sox2 at these sites, and Tcf3 inhibition is blocked by ?-catenin entry into this complex. Wnt pathway stimulation also triggers ?-catenin association at regulatory elements with classic Lef/Tcf motifs associated with differentiation programs. The failure to activate these targets in the presence of a MEK/ERK inhibitor essential for mouse ESC culture suggests that MEK/ERK signaling and canonical Wnt signaling combine to promote mouse ESC differentiation. Triplicates of mouse embryonic stem cells cultured with GSK3 inhibitor CHIR99021 or with Wnt pathway inhibitor XAV939.

Project description:The objective of this study was to investigate the roles of GSK3 inhibitor CHIR99021 and MEK inhibitor PD0325901 on 2i-adapted mouse embryonic stem cells (ESCs) in serum-free conditions.Canonical Wnt signaling supports the pluripotency of mouse ESCs but also promotes differentiation of early mammalian cell lineages. To explain these paradoxical observations, we explored the gene regulatory networks at play. Canonical Wnt signaling is intertwined with the pluripotency network comprising Nanog, Oct4, and Sox2 in mouse ESCs. In defined media supporting the derivation and propagation of mouse ESCs, Tcf3 and β-catenin interact with Oct4; Tcf3 binds to Sox motif within Oct-Sox composite motifs that are also bound by Oct4-Sox2 complexes. Further, canonical Wnt signaling up-regulates the activity of the Pou5f1 distal enhancer via the Sox motif in mouse ESCs. When viewed in the context of published studies on Tcf3 and β-catenin mutants, our findings suggest that Tcf3 counters pluripotency by competition with Sox2 at these sites, and Tcf3 inhibition is blocked by β-catenin entry into this complex. Wnt pathway stimulation also triggers β-catenin association at regulatory elements with classic Lef/Tcf motifs associated with differentiation programs. The failure to activate these targets in the presence of a MEK/ERK inhibitor essential for mouse ESC culture suggests that MEK/ERK signaling and canonical Wnt signaling combine to mouse promote ESC differentiation. Triplicates of mouse embryonic stem cells cultured under the following conditions: 1) CHIR99021+PD0325901+LIF; 2) CHIR99021+PD0325901; 3) CHIR99021; 4) PD0325901; 5) DMSO

Project description:At the blastocyst stage, the embryo invades the uterine and the pluripotent epiblast cells get reshaped from an amorphous ball into a polarized cup-shaped epithelium. At the same time, the transiently established naïve pluripotency is dismantled, transforming into a more developmentally advanced post-implantation pluripotent state. The major driver of the differentiation process is the autocrine Fgf/Mek/Erk singling which promotes the exit of naïve pluripotency. However, inhibiting Mek alone is not sufficient to maintain the cells in the naïve state suggesting the contribution of additional, as yet unidentified, pro-differentiation signals. Using a 3D embryonic stem cells (ESC) based model of epiblast development we established an automated pipeline for cell culture and analysis and performed a large-scale functional screen to identify factors regulating the development of the pluripotent lineage. We found that the mitotic kinases – Aurora kinase A (Aurka) and Polo-like kinase (PLK) positively regulate Erk signalling in a Mek-independent manner. We determined that Aurka and Erk form a complex in ESCs and suppression of Aurka activity delays the exit of naïve pluripotency. Moreover, a combination of Aurka and Mek inhibition enabled the de novo derivation of ESC lines from mouse embryos. Interestingly, during cell division, we found that phospho-Erk (pErk) localizes on the spindle poles at prophase and metaphase, gradually decreasing its signal at anaphase and telophase. Proximity biotinylation analysis of the pErk interactome identified the formation of PLK/pErk complex in metaphase cells. Moreover, inhibition of PLK, but not Mek or Aurka, resulted in a substantial decrease in Erk phosphorylation at the mitotic spindle. In summary, our findings demonstrate that the pluripotent cells continuously generate and perceive two types of Erk-mediated pro-differentiation cues - autocrine signals of the Fgf/Mek cascade and cell-intrinsic cues via the mitotic kinase Aurka and PLK. Altogether, these signals promote the exit of naïve pluripotency, driving the transient pace of embryonic development.

Project description:The objective of this study was to identify the direct target genes of M-NM-2-catenin acting downstream of canonical Wnt signaling in mouse embryonic stem cells (ESCs).Canonical Wnt signaling supports the pluripotency of mouse ESCs but also promotes differentiation of early mammalian cell lineages. To explain these paradoxical observations, we explored the gene regulatory networks at play. Canonical Wnt signaling is intertwined with the pluripotency network comprising Nanog, Oct4, and Sox2 in mouse ESCs. In defined media supporting the derivation and propagation of mouse ESCs, Tcf3 and M-NM-2-catenin interact with Oct4; Tcf3 binds to Sox motif within Oct-Sox composite motifs that are also bound by Oct4-Sox2 complexes. Further, canonical Wnt signaling up-regulates the activity of the Pou5f1 distal enhancer via the Sox motif in mouse ESCs. When viewed in the context of published studies on Tcf3 and M-NM-2-catenin mutants, our findings suggest that Tcf3 counters pluripotency by competition with Sox2 at these sites, and Tcf3 inhibition is blocked by M-NM-2-catenin entry into this complex. Wnt pathway stimulation also triggers M-NM-2-catenin association at regulatory elements with classic Lef/Tcf motifs associated with differentiation programs. The failure to activate these targets in the presence of a MEK/ERK inhibitor essential for mouse ESC culture suggests that MEK/ERK signaling and canonical Wnt signaling combine to promote mouse ESC differentiation. bCatenin ChIP-seq using anti-FLAG antibody and Streptavidin were otained from embryonic stem cells treated by CHIR99021 for 24 hours. Input without IP process were used as the control.

Project description:Embryonic stem cell (ESC) fate decisions are regulated by a complex molecular circuitry that requires tight and coordinated gene expression regulations at multiple levels from chromatin organization to mRNA processing. Recently, ribosome biogenesis and translation have emerged as key pathways that efficiently control stem cell homeostasis. However, the molecular mechanisms underlying the regulation of these pathways remain largely unknown to date. Here, we analyzed the expression, in mouse ESCs, of over 300 genes involved in ribosome biogenesis and we identified RSL24D1 as the most differentially expressed between self-renewing and differentiated ESCs. RSL24D1 is highly expressed in multiple mouse pluripotent stem cell models and its expression profile is conserved in human ESCs. RSL24D1 is associated with nuclear pre-ribosomes and is required for the maturation and the synthesis of 60S subunits in mouse ESCs. Interestingly, RSL24D1 depletion significantly impairs global translation, particularly of key pluripotency factors, including POU5F1 and NANOG, as well as components of the polycomb repressive complex 2 (PRC2). Consistently, RSL24D1 is required for mouse ESC self-renewal and proliferation. Taken together, we show that RSL24D1-dependant ribosome biogenesis is required to both sustain the expression of pluripotent transcriptional programs and silence developmental programs, which concertedly dictate ESC homeostasis.

Project description:Pluripotent mouse embryonic stem cells (ESCs) were originally derived and stably maintained on feeder cells such as inactivated mouse embryo fibroblasts, and can generate complete ESC-pups by tetraploid embryo complementation (TEC), the most stringent functional test of naive pluripotency. Remarkably, 2i (inhibitors of Mek and Gsk3β signaling) medium with LIF in the absence of serum and feeders was developed to achieve ground state of mouse ESCs, and also has been successfully used for derivation of germline competent ESCs in other species such as rat. Notably, 2i-culture gives rise to transcriptional profiles and epigenetic landscapes quite distinct from serum-based ESCs. To better understand transcriptional landscape and signal transductions, we performed RNA-seq analysis of ESCs cultured in four different conditions: serum without feeder, serum with feeder, serum with feeder and 2i, and N2B27+2i.