Project description:Histone acetylation and the acetyl-lysine reader Brd4 have recently been implicated in embryonic stem cell (ESC) proliferation and self-renewal. We found that naïve pluripotent ESCs exhibit increased incorporation of glucose-derived carbons onto acetylated histones and elevations in H3K9ac and Brd4 recruitment at pluripotency gene promoters. Surprisingly, both H3K9 acetyltransferases, GCN5 and PCAF, and Brd4 recruitment were dispensable for proliferation, self-renewal and pluripotency of naïve ESCs. Naïve ESCs maintain gene expression by stabilizing Mediator at core pluripotency genes in a Brd4-independent manner. Brd4-independent proliferation could also be achieved in metastable ESCs by overexpression of pluripotency transcription factors. Under all conditions, self-renewal required the DNA methylcytosine oxidases Tet1 and Tet2. These data reveal that there is minimal dependence on Brd4 for self-renewal of naïve ESCs. Instead, the relative levels of DNA methylation and transcription factor abundance determine the requirement for bromodomain recognition of histone acetylation to the maintenance of stem cell identity.

Project description:Oct4 is considered a master transcription factor for pluripotent cell self-renewal and embryo development. It primarily collaborates with other transcriptional factors or coregulators to maintain pluripotency. However, it is still unclear how Oct4 interacts with its partners. Here, we show that the Oct4 linker interface mediates competing and balanced Oct4 protein interactions which are crucial for maintaining pluripotency. Linker mutant ESCs maintain the key pluripotency genes expression, but show decreased expression of self-renewal genes and increased expression of differentiation genes which result in impaired ESCs self-renewal and early embryonic lethality. Linker mutation dose not affect Oct4 genomic binding and transactivation potential, but breaks the balanced Oct4 interactome. In mutant ESCs, the interaction between Oct4 and Klf5 was decreased, but interactions between Oct4 and Cbx1, Ctr9, Cdc73 were increased which disrupt the epigenetic state of ESCs. Overexpression of Klf5 or knockdown Cbx1, Cdc73 rescue the cellular phenotype of linker mutant ESCs by rebalancing Oct4 interactome indicating that different partners interact with Oct4 competitively. Thus, by showing how Oct4 interacts with different partners, we provide novel molecular insights to explain how Oct4 contributes to the maintenance of pluripotency.

Project description:The relative contributions of sequence-specific transcription factors and DNA/histone modifications to stem cell maintenance remains controversial. For example, the acetyllysine reader Brd4 has been implicated in stem cell maintenance, but how absolute the role of Brd4 is in maintaining pluripotency remains unclear. Here we show that Brd4 is dispensable for the proliferation, self-renewal and pluripotency of embryonic stem cells. In naive, ground state pluripotent stem cells, Mediator recruitment and transcription factor binding to stem cell-specific genes are maintained in the absence of Brd4 function or expression. Even in metastable embryonic stem cells poised for differentiation, Brd4 independence can be maintained by overexpression of pluripotency transcription factors so long as the DNA methylcytosine oxidases, Tet1 and Tet2, are present to facilitate chromatin accessibility. These data reveal that Brd4 is not essential for self-renewal of embryonic stem cells. Rather, Brd4 contributes to stem cell maintenance only under conditions where the expression of pluripotency transcription factors and/or DNA demethylation machinery is compromised.

Project description:Mouse embryonic stem cells (ESCs) cultured with inhibitors of MEK and GSK3 (2iL) more closely resemble the pre-implantation embryo inner cell mass than cultures in serum/LIF (SL). Unveiling the differences between both systems is important for understanding development and could also assist in isolating an ESC equivalent for other mammalian species. In SL, pluripotency and cell cycle gene transcription is a multistep process requiring release of promoter-proximal paused RNA polymerase II (Pol2) by the histone acetylation reader BRD4 and the Pol2 kinase CDK9. Here, we show that recruitment of co-regulators including Mediator and Cohesin by β-catenin changes the mode of transcriptional regulation at BRD4/CDK9-bound loci in 2iL. This switch renders pluripotency genes more reliant on transcriptional initiation and less on Pol2 pause release for effective gene body elongation. Conversely, cell cycle genes are not bound by β-catenin and are still dependent on Pol2 pause release. Thus, pluripotency is more resistant to BRD4/CDK9 suppression in 2iL while self-renewal remains highly sensitive. Our findings help to explain how pluripotency is shielded in the ground state and provide insight into transcriptional adaptation upon network perturbation in other contexts.

Project description:Mouse embryonic stem cells (ESCs) cultured with inhibitors of MEK and GSK3 (2iL) more closely resemble the pre-implantation embryo inner cell mass than cultures in serum/LIF (SL). Unveiling the differences between both systems is important for understanding development and could also assist in isolating an ESC equivalent for other mammalian species. In SL, pluripotency and cell cycle gene transcription is a multistep process requiring release of promoter-proximal paused RNA polymerase II (Pol2) by the histone acetylation reader BRD4 and the Pol2 kinase CDK9. Here, we show that recruitment of co-regulators including Mediator and Cohesin by β-catenin changes the mode of transcriptional regulation at BRD4/CDK9-bound loci in 2iL. This switch renders pluripotency genes more reliant on transcriptional initiation and less on Pol2 pause release for effective gene body elongation. Conversely, cell cycle genes are not bound by β-catenin and are still dependent on Pol2 pause release. Thus, pluripotency is more resistant to BRD4/CDK9 suppression in 2iL while self-renewal remains highly sensitive. Our findings help to explain how pluripotency is shielded in the ground state and provide insight into transcriptional adaptation upon network perturbation in other contexts.

Project description:Embryonic stem cells (ESCs) can self-renew indefinitely and have the potential to differentiate into all cell types in the adult organism. Although the developmental plasticity of ESCs is mainly controlled by transcription factors, the intrinsic regulation of this process remains elusive. Here, using whole transcriptome RNA-sequencing analysis, we identified branched-chain amino acid aminotransferase-1 (Bcat1) as highly expressed in mouse ESCs. Further, deletion of the Bcat1 gene was found to impair the pluripotency and self-renewal of mouse ESCs and made cells more inclined to differentiate toward epiblast stem cells. Conversely, overexpression of Bcat1 in mouse ESCs resulted in robust self-renewal and the repression of differentiation. Mechanistically, Bcat1 regulates the expression of RAS protein activator like 1 (Rasal1), leading to activation of Ras-Erk/MAPK signaling axis, which controls the expression of a set of core transcription factors that maintain pluripotency and self-renewal. In summary, we identified for the first time that Bcat1 is essential for mouse ESCs self-renewal and pluripotency and that this effect is mediated by the Ras pathway.

Project description:Embryonic stem cells (ESCs) favor glycolysis over oxidative phosphorylation for energy production, and glycolytic metabolism is critical for pluripotency establishment, maintenance and exit. However, how glycolysis regulates the self-renewal and differentiation of ESCs remains elusive. Here, we demonstrated that protein lactylation, regulated by intracellular lactate, contributes to the self-renewal of ESCs. Next, the lactylome profiles of ESCs with and without a lactate dehydrogenase (Ldh) inhibitor, which suppresses the conversion of pyruvate to lactate, were depicted. It was notable that many lactylated proteins are involved in the self-renewal and differentiation of ESCs. We further showed that Esrrb, an orphan nuclear receptor involved in pluripotency maintenance and extraembryonic endoderm stem cell (XEN) differentiation, is lactylated on K228 and K232. Lactylation of Esrrb enhances its activity in promoting ESC self-renewal in the absence of LIF and XEN differentiation of ESCs, through increasing its binding at target genes. Our studies reveal the importance of protein lactation in the self-renewal and XEN differentiation of ESCs, and the underlying mechanism for glycolytic metabolism regulating cell fate choice.

Project description:Embryonic stem cell (ESC) pluripotency is governed by a gene regulatory network centred on the transcription factors Oct4 and Nanog. ESCs fluctuate between states of high and low Nanog expression that direct efficient or inefficient self-renewal. To date, robust self-renewing ESC states have only been attained by chemical inhibition of signalling pathways or enforced transgene expression. Here we show that ESCs expressing a reduced range of Oct4 concentrations, typified by Oct4 heterozygous ESCs exhibit stable robust pluripotency. Despite this reduced Oct4 concentration range, this state is characterised by increased genome-wide binding of Oct4, particularly at pluripotency-associated enhancers, homogeneous expression of pluripotency transcription factors, enhanced self-renewal efficiency and delayed differentiation kinetics. In this state, ESCs exhibit increased wnt expression, enhanced LIF-sensitivity, non-responsiveness to FGF signalling and can clonally maintain pluripotency without BMP but remain dependent upon LIF. Robust pluripotency is destabilised either by alteration of the Oct4 level or by removal of LIF. Our findings suggest that robust pluripotency originates from cells with a reduced Oct4 protein concentration and that the wild-type Oct4 range enables effective differentiation.

Project description:Molecular programs involved in embryogenesis are frequently upregulated in oncogenic dedifferentiation and metastasis. However, their precise roles and regulatory mechanisms remain elusive. Here, we showed that CDK1 phosphorylation of TFCP2L1, a pluripotency-associated transcription factor, orchestrated pluripotency and cell-cycling in embryonic stem cells (ESCs) and was aberrantly activated in aggressive bladder cancers (BCs). In murine ESCs, the protein interactome and transcription targets of Tfcp2l1 indicated its involvement in cell-cycle regulation. Tfcp2l1 was phosphorylated at Thr177 by Cdk1, which affected ESC cell-cycle progression, pluripotency, and differentiation. LC-MS was used to characterize thr177 phosphorylation in TFCP2L1 protein obtained by IP experiment and kinase assay. The CDK1-TFCP2L1 pathway was activated in human BC cells, stimulating their proliferation, self-renewal, and invasion. Lack of TFCP2L1 phosphorylation impaired the tumorigenic potency of BC cells in a xenograft model. In patients with BC, high co-expression of TFCP2L1 and CDK1 was associated with unfavorable clinical characteristics including tumor grade, lymphovascular and muscularis propria invasion, and distant metastasis and was an independent prognostic factor for cancer specific survival. These findings demonstrate the molecular and clinical significance of CDK1-mediated TFCP2L1 phosphorylation in stem-cell pluripotency and in the tumorigenic stemness features associated with BC progression.

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.