Project description:The Hippo:YAP1 signaling pathway was long considered a master regulator of organ growth. However, recent evidence has challenged this view, showing that the loss of YAP1 does not prevent several organs from reaching their normal size. Hence, resolving the functions of YAP1 in the embryo has become a central question in the field. To shed light into this, we analyzed YAP1’s role in regulating pluripotency of the mammalian epiblast, using scRNAseq approaches. Conditional deletion of Yap1 in the mouse epiblast (Sox2-Cre) altered the expression of signaling and differentiation genes, including Nodal, Wnt3, Fgf8, and Nanog, without impairing cell proliferation. Instead, Yap1 loss led to hyperactivation of Nodal signaling and enhanced differentiation of the epiblast toward mesodermal fate. Furthermore, an unbiased screening in human pluripotent stem cells revealed that YAP1 transcriptionally cooperates with QSER1 protein, to regulate multiple WNT and NODAL signaling genes. Mechanistically, QSER1 represses lineage enhancers of signaling genes by counteracting RNA Polymerase II recruitment on YAP1-targets. Accordingly, QSER1 depletion, similar to YAP1, leads to hyperactive Nodal signaling in human 2D-gastruloids. Overall, our findings not only advance our understanding of YAP1’s role in early development but also open new avenues for exploring how the interplay with QSER1 could influence additional developmental processes.

Project description:YAP1 and QSER1 are Key Modulators of Embryonic Signaling Pathways in the Mammalian Epiblast [scRNA-seq]

Project description:YAP1 and QSER1 are Key Modulators of Embryonic Signaling Pathways in the Mammalian Epiblast [ChIP-seq]

Project description:RNA Sequencing of H1 WT hESCs, H1 QSER1 KO hESCs, H1 TET1 KO hESCs, H1 QSER1/TET1 DKO hESCs, WT Day10 embryoid bodies (EBs), QSER1 KO Day10 EBs, TET1 KO Day10 EBs, QSER1/TET1 DKO Day10 EBs, WT pancreatic progenitors (PP1), QSER1 KO PP1, TET1 KO PP1, and QSER1/TET1 DKO PP1. DNA methylation is essential to mammalian development, and dysregulation can cause serious pathological conditions. Key enzymes responsible for deposition and removal of DNA methylation are known, but how they cooperate to tightly regulate the methylation landscape remains a central question. Utilizing a knockin DNA methylation reporter, we performed a genome-wide CRISPR/Cas screen in human embryonic stem cells to discover DNA methylation regulators. The top screen hit was an uncharacterized gene QSER1, which proved to be a key guardian of bivalent promoters and poised enhancers of developmental genes, especially those residing in DNA methylation valleys (or canyons). We further demonstrate cooperation of QSER1 and TET1 through genetic and biochemical interactions to inhibit DNMT3-mediated de novo methylation and safeguard developmental programs.

Project description:The gastrulation process is controlled by the interplay between morphogenetic signals from BMP, WNT and NODAL pathways. Increasing evidences support an emerging role of the Hippo-YAP signaling in the cell-fate decisions that guide lineage specification in mouse and human Embryonic Stem Cells (hESCs). However, the contribution of YAP to the process of gastrulation in hESCs remains unknown. Here, we show that YAP1 regulates the specification, size and patterning of the three-germ layers. Using hESC-derived 2D-micropatterned gastruloids and directed differentiation approaches we show that YAP maintains a semi-active NODAL signaling during gastrulation essential to regulate the exit of pluripotency. In absence of YAP1, a hyperactive NODAL signaling retains SMAD2.3 in the nuclei, impeding the exit of pluripotency and the acquisition of the ectodermal gene program. Accordingly, the inhibition of NODAL signaling is sufficient to rescue the gastrulation-defective phenotype of the YAP1 KO hESCs. Our work revealed that Hippo-YAP1 signaling is an important component of the developmental network that coordinate hESC pluripotency and gastrulation.

Project description:Functional analysis QSER1

Project description:In this study, we found that QSER1 is a generic anti-apoptosis factor suppressing the p53 target apoptotic genes irrespective of p53 status.

Project description:DNA methylation is essential to mammalian development, and dysregulation can cause serious pathological conditions. Key enzymes responsible for deposition and removal of DNA methylation are known, but how they cooperate to tightly regulate the methylation landscape remains a central question. Utilizing a knockin DNA methylation reporter, we performed a genome-wide CRISPR/Cas screen in human embryonic stem cells to discover DNA methylation regulators. The top screen hit was an uncharacterized gene QSER1, which proved to be a key guardian of bivalent promoters and poised enhancers of developmental genes, especially those residing in DNA methylation valleys (or canyons). We further demonstrate cooperation of QSER1 and TET1 through genetic and biochemical interactions to inhibit DNMT3-mediated de novo methylation and safeguard developmental programs.

Project description:RNA Sequencing of H1 WT hESCs, H1 QSER1 KO hESCs, H1 TET1 KO hESCs, H1 QSER1/TET1 DKO hESCs, WT Day10 EBs, QSER1 KO Day10 EBs, TET1 KO Day10 EBs, QSER1/TET1 DKO Day10 EBs, WT PP1, QSER1 KO PP1, TET1 KO PP1, and QSER1/TET1 DKO PP1.

Project description:The germ cell lineage ensures reproduction and heredity in metazoans. Primordial germ cells (PGCs) in mice are induced in pluripotent epiblast cells by BMP4 and WNT3, yet their mechanism of action remains elusive. Here, using in vitro PGC specification system, we show that WNT3, but not BMP4, induces many transcription factors associated with mesoderm in epiblast-like cells (EpiLCs) through beta-CATENIN. Among these, T (BRACHYURY), a classical and conserved mesodermal factor, was essential for robust activation of Blimp1 and Prdm14, two of the germline determinants. T, but not SMAD1 or beta-CATENIN/TCF1, binds distinct regulatory elements of both Blimp1 and Prdm14, and directly up-regulates these genes without BMP4 and WNT3. Without BMP4, a program induced by WNT3 prevents T from activating Blimp1 and Prdm14, demonstrating that BMP4 is permissive for PGC specification. These findings establish a fundamental role of a mesodermal gene in PGC specification, a potentially evolutionarily conserved mechanism across metazoans. Wnt3 (+/+) and Wnt3 (-/-) mouse embryonic stem cells (mESCs) bearing the BV transgenes expressing membrane-targeted Venus under the control of Blimp1 regulatory elements (Blimp1-mVenus: BV; PMID 18583473) were established and maintained. Epiblast-like cells (EpiLCs) were then induced from the established ES lines, followed by the cytokine stimulation (No cytokines [negative control], BMP4, Wnt3a, BMP4+Wnt3a) for different periods (0h, 12h, 24h, 36h).