Project description:Metabolic reprogramming plays important roles in embryo development. However, the metabolic network has still not been systematically investigated during the processes. In this study, we develop MFE, a metabolites flux estimation tool, to predict metabolite abundances and their regulons, highlighting the role of Fe(II) and its regulon-ISCA2, in the inner cell mass (ICM) of human and mouse blastocysts. By introducing Isca2-/-, Isca2G77S/G77S and Isca2C144S/C144S mice, we find ISCA2 binding with iron, but not Fe-S cluster, is indispensable for mouse peri-implantation development. Mechanistically, nuclear ISCA2 interacts with TET, and Fe(II) is important for the interaction by triggering the enzymatic activity of TET. The partnership safeguards promoters of epiblast-specific genes from hypermethylation and is essential for epiblast development in mouse peri-implantation embryos. The study provides insights into how iron metabolism modulates embryo development, and suggests a manner of Fe(II)-dependentenzymes to achieve activity under physiological conditions.

Project description:Metabolic Reprogramming of Iron Endows the Function of ISCA2-TET Interaction During Peri-implantation Development

Project description:The mammalian TET dioxygenases contribute to global waves of DNA demethylation in the zygote and in primordial germ cells, but their involvement during de novo DNA methylation at peri/post-implantation development is unknown. Here, we show novel physiological functions of Tet1 in the pre-primitive streak stage mouse embryo, where it is expressed not only in the primed-state epiblast, but also in the extra-embryonic ectoderm. In the epiblast, Tet1 contributes to DNA methylation patterning, which indirectly results in dominant transcriptional repression involving a Jumonji-family gene Jmjd8. In the extra-embryonic ectoderm, Tet1 suppresses expression of metabolic genes involved in oxidative phosphorylation. These lineage-specific gene repressive functions, involving distinct modes of regulation by DNA methylation, counteract precocious differentiation of the embryo prior to the onset of gastrulation. Such dysregulation in the absence of Tet1 are surprisingly tolerated in an inbred strain but results in full embryonic lethality in non-inbred mice, thus implicating a complex but essential role of Tet1 in normal gestational development.

Project description:The mammalian TET dioxygenases contribute to global waves of DNA demethylation in the zygote and in primordial germ cells, but their involvement during de novo DNA methylation at peri/post-implantation development is unknown. Here, we show novel physiological functions of Tet1 in the pre-primitive streak stage mouse embryo, where it is expressed not only in the primed-state epiblast, but also in the extra-embryonic ectoderm. In the epiblast, Tet1 contributes to DNA methylation patterning, which indirectly results in dominant transcriptional repression involving a Jumonji-family gene Jmjd8. In the extra-embryonic ectoderm, Tet1 suppresses expression of metabolic genes involved in oxidative phosphorylation. These lineage-specific gene repressive functions, involving distinct modes of regulation by DNA methylation, counteract precocious differentiation of the embryo prior to the onset of gastrulation. Such dysregulation in the absence of Tet1 are surprisingly tolerated in an inbred strain but results in full embryonic lethality in non-inbred mice, thus implicating a complex but essential role of Tet1 in normal gestational development.

Project description:Metabolic Reprogramming of Iron Endows the Function of ISCA2-TET Interaction During Peri-implantation Development (EM-Seq)

Project description:The embryo instructs the allocation of cell states to spatially regulate growth and functions. In the blastocyst, the formation and divergence of the trophoblast lineage ensures successful implantation and placental development. Here, we defined an optimal set of molecules secreted by the inner epiblast cells (inducers) that captures stable, highly self-renewing, pre-implantation-like mouse trophectoderm stem cells (TESCs). When exposed to suboptimal inducers, these stem cells form interconvertible subpopulations with reduced self-renewal, known as trophoblast stem cells (TSCs), and resembling peri-implantation progenitors. TECSs have an enhanced capacity to form blastoids that implant more efficiently in utero. We find that this enhanced capacity is due to epiblast inducers not only controlling trophoblast growth but also trophoblast secretion of WNT6/7B that stimulates uterine decidualization. Thus, the embryo leverages epiblast inductions to drive both the growth and decidualization potential of trophoblasts required for implantation and development.

Project description:The embryo instructs the allocation of cell states to spatially regulate growth and functions. In the blastocyst, the formation and divergence of the trophoblast lineage ensures successful implantation and placental development. Here, we defined an optimal set of molecules secreted by the inner epiblast cells (inducers) that captures stable, highly self-renewing, pre-implantation-like mouse trophectoderm stem cells (TESCs). When exposed to suboptimal inducers, these stem cells form interconvertible subpopulations with reduced self-renewal, known as trophoblast stem cells (TSCs), and resembling peri-implantation progenitors. TECSs have an enhanced capacity to form blastoids that implant more efficiently in utero. We find that this enhanced capacity is due to epiblast inducers not only controlling trophoblast growth but also trophoblast secretion of WNT6/7B that stimulates uterine decidualization. Thus, the embryo leverages epiblast inductions to drive both the growth and decidualization potential of trophoblasts required for implantation and development.

Project description:The mammalian TET dioxygenases contribute to global waves of DNA demethylation in the zygote and in primordial germ cells, but their involvement during de novo DNA methylation at peri/post-implantation development is unknown. Here, we show novel physiological functions of Tet1 in the pre-primitive streak stage mouse embryo, where it is expressed not only in the primed-state epiblast, but also in the extra-embryonic ectoderm. In the epiblast, Tet1 contributes to DNA methylation patterning, which indirectly results in dominant transcriptional repression involving a Jumonji-family gene Jmjd8. In the extra-embryonic ectoderm, Tet1 suppresses expression of metabolic genes involved in oxidative phosphorylation. These lineage-specific gene repressive functions, involving distinct modes of regulation by DNA methylation, counteract precocious differentiation of the embryo prior to the onset of gastrulation. Such dysregulation in the absence of Tet1 are surprisingly tolerated in an inbred strain but results in full embryonic lethality in non-inbred mice, thus implicating a complex but essential role of Tet1 in normal gestational development. This dataset includes the WGBS/oxWGBS: Methylation and hydroxymethylation profiling of epiblast-like cells (EpiLCs) in presence or absence of TET1. Whole genome bisulfite sequencing and oxidative whole genome bisulfite sequencing were performed on two wt EpiLCs (male) and two TET1 knock-out EpiLCs (one male and one female).

Project description:Pig peri-implantation embryo development transcriptional profiling

Project description:Embryo implantation is a complex process which involves biochemical and physiological interactions between an implantation-competent blastocyst and a receptive uterus. However, the exact biochemical changes of uterine fluid, uterus, and plasma during peri-implantation remain unclear. This study aims to characterize the biochemical and metabolic changes that occur during the peri-implantation period of early pregnancy, using mice as an animal model. Gas chromatography-mass spectrometry was used to analyze the metabolite profiles of the uterus, uterine fluid, and maternal plasma at pre-implantation and implantation. The multivariate analyses, ANOVA and Tukey's HSD test, were applied to detect significant changes in metabolites and metabolic pathways. The metabolic networks were reconstructed in silico based on the identified metabolites and KEGG metabolic framework. Between pre-implantation day 1 and day 4, dramatic metabolic changes were observed in the uterine fluid that could be important for blastocyst development and protection against the harsh uterine environment. Palmitoleic acid, fumaric acid, and glutaric acid changed levels at day 4 in the uterus, suggesting that they may be associated with endometrial receptivity. Both the uterus and maternal plasma showed profound changes in cellular metabolism at the early implantation period, including upregulation of branched-chain amino acids and intermediates of one-carbon metabolism, an upregulation of glyoxylate and dicarboxylate metabolism, and downregulation of aerobic respiration; all of which could be involved in the regulation of the maternal-fetal interface, alternative nutrient utilization, and energy preservation for implantation as well as later placentation and fetal development to ensure successful embryo implantation.