Project description:The first lineage decisions during mouse development lead to establishment of embryonic and extraembryonic tissues. The transcription factor Cdx2 plays a central role by repressing pluripotency genes, such as Oct4 and promoting trophoblast fate at the blastocyst stage. Here we show that the transcription factor Gata3 is coexpressed with Cdx2 in the blastocyst and that overexpression of Gata3 in embryonic stem cells is sufficient to induce expression of trophoblast genes. Gata3 expression in the blastocyst does not depend on Cdx2, nor do Gata3 overexpressing cell lines require Cdx2 for expression of a subset of trophoblast genes. In the embryo, expression of Gata3, like Cdx2, depends on Tead4, and expression of both factors becomes restricted to nascent trophoblast by an Oct4-independent mechanism. These observations place Tead4 at the top of a trophoblast hierarchy, with Gata3 and Cdx2 acting downstream to induce expression of common and independent targets in this lineage. This SuperSeries is composed of the following subset Series: GSE12985: Differentiation time course of trophoblast stem cells GSE12986: Expression of Cdx2 or Gata3 in R1 mouse embryonic stem cells

Project description:The first lineage decisions during mouse development lead to establishment of embryonic and extraembryonic tissues. The transcription factor Cdx2 plays a central role by repressing pluripotency genes, such as Oct4 and promoting trophoblast fate at the blastocyst stage. Here we show that the transcription factor Gata3 is coexpressed with Cdx2 in the blastocyst and that overexpression of Gata3 in embryonic stem cells is sufficient to induce expression of trophoblast genes. Gata3 expression in the blastocyst does not depend on Cdx2, nor do Gata3 overexpressing cell lines require Cdx2 for expression of a subset of trophoblast genes. In the embryo, expression of Gata3, like Cdx2, depends on Tead4, and expression of both factors becomes restricted to nascent trophoblast by an Oct4-independent mechanism. These observations place Tead4 at the top of a trophoblast hierarchy, with Gata3 and Cdx2 acting downstream to induce expression of common and independent targets in this lineage. This SuperSeries is composed of the SubSeries listed below.

Project description:Current understandings of the initiation of the trophectoderm (TE) program in mammalian embryonic development lacks evidence of how TE-associated factors such as CDX2 and GATA3 participate in bovine lineage specification. In this study, we describe the effects of TE-associated factors on lineage specification marker genes such as SOX2, OCT4, NANOG, GATA6 and SOX17, assisted by a cytosine base editor system. Interestingly, GATA3 downregulates the NANOG expression in bovine blastocysts. Further analysis of the blastocyst mosaic shows that GATA3 is required for NANOG in TE cells of bovine blastocysts. It is worthy to notice that, unlike mouse embryos where GATA3 and CDX2 did not reciprocally affect each other in bovine embryos.

Project description:It is often desirable to be able to regulate or impair the expression of specific genes to study early developmental events in the mammalian embryo. While DNA and RNA methods are routine, methods using proteins are still in their infancy. When proteins in the cell encounter a specific antibody and the ubiquitin-protein ligase TRIM21, a ternary complex forms with the target protein, leading to its rapid and acute degradation – hence the name ‘Trim-Away'. However, there are many unknowns in this new endeavour. First and foremost, the extent to which endogenous proteins can be depleted depends on their amount in relation to the amount of exogenous antibody, which is limited by the microinjection procedure. Secondly, the depletion of the protein must be sustained over days. Using mass spectrometry and the iBAQ algorithm, we estimate the amount of proteins found in preimplantation mouse embryos. Most of these amounts are tractable with the microinjection method presented here, which supplies 10E-4 picomoles of antibody contained in 100 picolitres, before incurring toxic effects on mouse development. Building on these data, we demonstrate the feasibility of protein knock-down for a gene which is essential in the preimplantation mouse embryo, namely TEA domain family member 4 (Tead4). Knock-down persists long enough to result in a phenotype which is entirely consistent with that of the null mutation and the RNA interference: significantly reduced mRNA expression of TEAD4 target genes Cdx2 and Gata3, failure of CDX2 nuclear translocation and the embryo’s inability to implant. We conclude that at least for a time window of 3-4 days of preimplantation development, protein depletion is on the rise as a valid alternative to DNA and RNA methods.

Project description:In the preimplantation mouse embryo TEAD4 is critical to establishing the trophectoderm (TE)-specific transcriptional program and segregating TE from the inner cell mass (ICM). However, TEAD4 is expressed both in the TE and the ICM. Thus, differential function of TEAD4 rather than expression itself regulates specification of the first two cell lineages. We used ChIP-seq to define genome-wide TEAD4 target genes and asked how transcription of TEAD4 target genes is specifically maintained in the TE. Our analyses revealed an evolutionarily conserved mechanism, in which lack of nuclear localization of TEAD4 impairs the TE-specific transcriptional program in inner blastomeres, thereby allowing their maturation towards the ICM lineage. Restoration of TEAD4 nuclear localization maintains the TE-specific transcriptional program in the inner blastomeres and prevents segregation of the TE and ICM lineages and blastocyst formation. We propose that altered subcellular localization of TEAD4 in blastomeres dictates first mammalian cell fate specification. ChIPseq profiles of TEAD4, IgG, Input in Mouse trophoblast stem cells using Illumina HiSeq 2000 and Illumina Genome Analyzer IIx

Project description:The first lineage differentiation in mammals gives rise to the inner cell mass (ICM) and the trophectoderm (TE). In mice, TEAD4 is a master regulator of TE commitment, as it regulates the expression of other TE-specific genes and its ablation prevents blastocyst formation, but its role in other mammals remains unclear. TEAD4 ablation in bovine embryos did not impede TE differentiation or blastocyst formation, but a transcriptomic analysis was performed to see if there were any transcriptomic anomalies in knockout embryos.

Project description:Profiles of H3K4me3, H3K27ac, H3K27me3 and H3K9me3 in bovine GV oocytes and preimplantation embryos, and the characterization of chromatin accessibility in bovine blastocyst, inner cell mass and trophectoderm.

Project description:In order to study early developmental events in the mammalian embryo it is often desirable to be able to impair expression of specific genes. While DNA and RNA methods are routine, protein methods are still at the very beginning. When a specific antibody is supplied to mouse oocytes expressing the ubiquitin-protein ligase TRIM21, a ternary complex forms with the target protein, leading to its rapid and acute degradation - hence the name 'Trim-away' (PMID 29153837). However, there are many unknowns in this new endeavour. First and foremost, the extent to which endogenous proteins can be depleted depends on their amount, in relation to the amount of exogenous antibody, which is limited by the microinjection procedure. Secondly, the depletion of the protein must be sustained over days. Using the iBAQ algorithm we show that proteins found in preimplantation mouse embryos range from 3,5E-10 to 2,6E-02 picomoles. These amounts are tractable with our microinjection method, which supplies up to 100 picoliters and up to 6,7E-4 picomoles antibody before incurring in toxic effects on mouse development. Building on these data, we demonstrate the feasibility of protein knock-down for a gene which is essential in the preimplantation mouse embryo, namely TEAD4 (TEA domain family member 4). Protein knock-down persists for sufficient time to result in a phenotype which is entirely consistent with that of the null mutation (Tead4 -/-) and of the RNA interference, namely: significantly reduced mRNA expression of TEAD4 target genes Cdx2 and Gata3, and embryo’s inability to implant. We conclude that for a time window of 3-4 days of preimplantation development the protein depletion method can be a valid alternative to DNA and RNA methods. After in vivo fertilization and short culture in KSOM(aa) medium, pronuclear-stage oocytes (B6C3F1 x CD1) were microinjected with Trim21 mRNA and dextran beads as tracer (named 'group 4'), or Trim21 mRNA, dextran beads and anti-GFP antibody (named 'group 5'), or Trim21 mRNA, dextran beads and anti-TEAD4 antibody (named 'group 6'), two replicates each ('a' and 'b'). On day 4 after microinjection, the most advanced embryos were examined for phenotype or lysed for transcriptome analysis. TEAD4-depleted embryos formed only 30% blastocysts and these were not able to implant in the outgrowth assay, in contrast to the almost full rates of the embryos injected with Trim21 mRNA or Trim21 mRNA + anti-GFP antibody. Transcriptome analysis revealed that the TEAD4 target genes Cdx2 and Gata3 are significantly reduced in the embryos that received the anti-TEAD4 antibody compared to the embryos that received Trim21 mRNA only, while the embryos that received anti-GFP antibody were much similar to those that received Trim21 mRNA only.

Project description:In the preimplantation mouse embryo TEAD4 is critical to establishing the trophectoderm (TE)-specific transcriptional program and segregating TE from the inner cell mass (ICM). However, TEAD4 is expressed both in the TE and the ICM. Thus, differential function of TEAD4 rather than expression itself regulates specification of the first two cell lineages. We used ChIP-seq to define genome-wide TEAD4 target genes and asked how transcription of TEAD4 target genes is specifically maintained in the TE. Our analyses revealed an evolutionarily conserved mechanism, in which lack of nuclear localization of TEAD4 impairs the TE-specific transcriptional program in inner blastomeres, thereby allowing their maturation towards the ICM lineage. Restoration of TEAD4 nuclear localization maintains the TE-specific transcriptional program in the inner blastomeres and prevents segregation of the TE and ICM lineages and blastocyst formation. We propose that altered subcellular localization of TEAD4 in blastomeres dictates first mammalian cell fate specification.

Project description:Epigenetic modifications, including DNA methylation and histone modifications, are reprogrammed considerably following fertilization during mammalian early embryonic development. Incomplete epigenetic reprogramming is a major factor leading to poor developmental outcome in embryos generated by assisted reproductive technologies, such as somatic cell nuclear transfer. However, the role of histone modifications in preimplantation development is poorly understood. Here, we show that co-knockdown (cKD) of Hdac1 and 2 (but not individually) resulted in developmental failure during the morula to blastocyst transition. This outcome was also confirmed with the use of small-molecule Hdac1/2-specific inhibitor FK228. We observed reduced cell proliferation and increased incidence of apoptosis in cKD embryos, which were likely caused by increased acetylation of Trp53. Importantly, both RNA-seq and immunostaining analysis revealed a failure of lineage specification to generate trophectoderm and pluripotent cells. Among many gene expression changes, a substantial decrease of Cdx2 may be partly accounted for by the aberrant Hippo pathway occurring in cKD embryos. In addition, we observed an increase in global DNA methylation, consistent with increased DNA methyltransferases and Uhrf1. Interestingly, deficiency of Rbbp4 and 7 (both are core components of several Hdac1/2-containing epigenetic complexes) results in similar phenotypes as those of cKD embryos. Overall, Hdac1 and 2 play redundant functions required for lineage specification, cell viability and accurate global DNA methylation, each contributing to critical developmental programs safeguarding a successful preimplantation development.