Project description:The pregnant decidua is infiltrated by many immune cells which are thought to originate in the bone marrow (BM) promoting pregnancy. CXCR4 is a key regulator of the development of NK cells and dendritic cells, both of which play an important role in early placental development and immune tolerance at the maternal-fetal interface. However, the role of CXCR4 in pregnancy is not well understood. To generate tamoxifen-inducible CXCR4 knockout mice, we used the Cre/LoxP tamoxifen-inducible system. For animal experiments, Cre+/CXCR4fl/fl mice and their Cre-/CXCR4fl/fl littermates were used. After tamoxifen treatment, we refer to Cre-/CXCR4fl/wt mice as WT (wild type), and Cre+/CXCR4fl/null mice as CXCR4 KO (knockout). For adoptive bone marrow transplant (BMT) experiments, BMT was performed from either WT GFP transgenic male donor mice into WT or CXCR4 KO females, or from CXCR4 KO male donors into CXCR4 KO females as negative control. Collectively, our study found an important role for maternal CXCR4 expression in immune cell function, placental development and pregnancy maintenance.

Project description:Loss of the Maternal Effect Gene Nlrp2 Impairs Embryonic and Extra-Embryonic Development, Unveiling a Novel Cause of Congenital Anomalies

Project description:The placenta is critical for mammalian embryonic development because the embryo’s supply of nutrients, including amino acids, depends solely on mother-to-embryo transport through the placenta. However, the molecular mechanisms underlying this amino acid supply are poorly understood. In this study, we focused on the system A amino acid transporters, Slc38a1/SNAT1, Slc38a2/SNAT2, and Slc38a4/SNAT4, which carry neutral, short-side-chain amino acids, to determine their involvement in placental or embryonic development. A triple-target CRISPR screen identified Slc38a4/SNAT4 as the critical amino acid transporter for placental development in mice. We established mouse lines from the CRISPR founders with large deletions in Slc38a4 and found that, consistent with the imprinted paternal expression of Slc38a4/SNAT4 in ther placenta, paternal knockout (KO), but not maternal KO, of Slc38a4/SNAT4 caused placental hypoplasia associated with reduced fetal weight. Immunostaining revealed that SNAT4 was widely expressed in differentiating cytotrophoblasts and maturing trophoblasts at the maternal–fetal interface. A blood metabolome analysis revealed that amino acid concentrations were globally reduced in Slc38a4/SNAT4 mutant embryos. These results indicated that, in mice, SNAT4-mediated amino acid transport plays a major role in both placental and embryonic development. Given that expression of Slc38a4 in placentas is conserved in other species, our Slc38a4/SNAT4 mutant mice could be a promising model for the analysis of placental defects leading to intrauterine growth restriction in mammals.

Project description:The placenta regulates maternal-fetal communication, and its defect leads to significant pregnancy complications. The maternal and embryonic circulations are primitively connected in early placentation, but the function of the placenta during this developmentally essential period is relatively unknown. We thus performed a comparative proteomic analysis of the placenta before and after primary placentation and found that the metabolism and transport of lipids were characteristically activated in this period. The placental fatty acid (FA) carriers in specific placental compartments were upregulated according to gestational age, and metabolomic analysis also showed that the placental transport of FAs increased in a time-dependent manner. Further analysis of two mutant mice models with embryonic lethality revealed that lipid-related signatures could reflect the functional state of the placenta. Our findings highlight the importance of the nutrient transport function of the primary placenta in the early gestational period and the role of lipids in embryonic development.

Project description:Embryonic and fetal development can be affected during gestation by exposure to xenobiotics that cross the placenta. Liquid crystal monomers (LCMs) are emerging contaminants commonly found in indoor environments; however, whether they can cross the placenta and affect placental development remains unexplored. Here, we developed an evaluation system that integrates human biomonitoring, uterine perfusion in pregnant rats, and placental cells. We found fourteen out of the fifty-six LCMs that were detected in maternal and cord serum samples from ninety-three healthy pregnant women, at median levels of 13.9 and 18.1 ng/mL, respectively. Subsequent exploration of in utero exposure in rats indicated that aromatic amino acid transporter 1 (SLC16A10) mediated transplacental transportation of the LCMs. Placental cells exposed to LCMs exhibited delayed placental development and reduced progesterone release. These findings showed that SLC16A10-mediated transplacental transportation of LCMs inhibits placental development and progesterone release, highlighting the importance of gestational exposure to emerging contaminants.

Project description:DNA demethylation of paternal genome in zygotes takes place in various mammals including mice and human. Recent studies have revealed that this is achieved through Tet3-mediated iterative oxidation of 5-methylcytosine (5mC) coupled with replication-dependent dilution. Tet3-mediated paternal DNA demethylation is believed to be required for mouse development given that Tet3 heterozygous embryos, derived by fertilizing Tet3 knockout (KO) oocytes with wild-type (WT) sperms, exhibit 5mC oxidation defects and embryonic sublethality, Here we demonstrate that the sublethality phenotype of the maternal KO mice is caused by haploinsufficiency of Tet3, but not by defective paternal 5mC oxidation. We found that Tet3 heterozygous mice derived from crosses of heterozygous father or mother with WT mice also exhibit sublethality phenotype similarly to Tet3 maternal KO mice. Importantly, embryos reconstituted with WT paternal nuclei that bypassed 5mC oxidation develop to term and grow to adulthood normally. Genome-scale DNA methylation analysis of the maternal KO zygotes and blastocysts demonstrated that hypermethylation caused by the depletion of maternal Tet3 is largely diminished by the blastocyst stage. Our study thus not only demonstrates that Tet3-mediated paternal 5mC oxidation is dispensable for mouse development but also suggests the existence of a compensation mechanism in preimplantation embryos that can compensate for the defective 5mC oxidation in zygotes. This data set includes RRBS data of wild-type and maternal Tet3 KO zygotes and blastocysts (C57BL/6J x CAST/EiJ)

Project description:How maternal factors in oocytes trigger zygotic genome activation (ZGA) is a long-standing question in developmental biology. Recent studies in 2-cell like embryonic stem cells (2C-like cells) implicate that the DUX family transcription factors are key regulators of ZGA in placental mammals. To characterize the role of DUX in ZGA, we generated Dux cluster knockout (KO) mouse lines. Unexpectedly, we found both Dux zygotic KO (Z-KO) and maternal/zygotic KO (MZ-KO) embryos can survive to adulthood despite showing reduced developmental potential. Furthermore, transcriptome profiling of the MZ-KO embryos revealed that loss of DUX has minimal effect on ZGA and most DUX targets in 2C-like cells are normally activated in MZ-KO embryos. Thus, contrary to the key function in inducing 2C-like cells, our data indicate that DUX only has a minor role in ZGA and loss of DUX is compatible with mouse development.

Project description:In this study, we identify SYDE1 as a novel GCM1 target gene. We demonstrate that SYDE1 promotes placental cell migration and invasion and that the GCM1-SYDE1 axis is crucial for placental development. Importantly, retarded placental and fetal growth with defective spongiotrophoblast layer, compromised vasculogenesis, and abnormal maternal-trophoblast interface are noted in the Syde1 homozygous knockout (KO) placenta. Along this line, decreased SYDE1 expression is observed in human IUGR placentas. We further demonstrated that components of the renin-angiotensin system (RAS) and Syde2 are differentially expressed in Syde1-KO placenta, which might contribute to normal neonatal delivery in Syde1-KO mothers

Project description:Selective serotonin reuptake inhibitors (SSRIs) are commonly prescribed drugs to pregnant women experiencing depression. While such drugs might be beneficial in combating depression by competitively binding to serotonin transporter (SERT), they can adversely affect the placenta and fetal brain development. Parietal trophoblast giant cells (pTGCs) in the mouse placenta are postulated to internalize maternal serotonin (5-HT) via transport through SERT, encoded by Slc6a4. The placenta provides the initial source of 5-HT to the emerging brain via the placental-brain axis. Disruption of 5-HT acquisition by pTGCs due to genetic deletion of Slc6a4 is hypothesized to impact placental and fetal brain development. A transgenic mouse line with the SERT transporter selectively deleted was created by pairing mice with Cre-recombinase linked to proliferin (Prl2c2) with LoxP sites flanking the Slc6a4 gene. Proliferin is solely expressed by pTGCs and other giant cells of the placenta. To compare placental and fetal brain development in selective Sl6a4 KO and WT mice, 5-HT content in the placenta and fetal brains of the mice was measured. No significant differences in 5-HT content were evident between knockout (KO) and wild-type (WT) placenta and fetal brain. However, there was significantly lower average number of pTGCs in KO placentas compared to WT (p ≤ 0.05). Sexually dimorphic differences in gene expression were evident in the placenta and fetal brain between KO and WT counterparts with female conceptuses showing the most dramatic responses. Findings suggest that ablation of SERT in pTGC disrupts the placenta-brain axis in a sex-dependent manner. These results might have important clinical ramifications for pregnant women being treated with SSRIs.

Project description:DNA demethylation of paternal genome in zygotes takes place in various mammals including mice and human. Recent studies have revealed that this is achieved through Tet3-mediated iterative oxidation of 5-methylcytosine (5mC) coupled with replication-dependent dilution. Tet3-mediated paternal DNA demethylation is believed to be required for mouse development given that Tet3 heterozygous embryos, derived by fertilizing Tet3 knockout (KO) oocytes with wild-type (WT) sperms, exhibit 5mC oxidation defects and embryonic sublethality, Here we demonstrate that the sublethality phenotype of the maternal KO mice is caused by haploinsufficiency of Tet3, but not by defective paternal 5mC oxidation. We found that Tet3 heterozygous mice derived from crosses of heterozygous father or mother with WT mice also exhibit sublethality phenotype similarly to Tet3 maternal KO mice. Importantly, embryos reconstituted with WT paternal nuclei that bypassed 5mC oxidation develop to term and grow to adulthood normally. Genome-scale DNA methylation analysis of the maternal KO zygotes and blastocysts demonstrated that hypermethylation caused by the depletion of maternal Tet3 is largely diminished by the blastocyst stage. Our study thus not only demonstrates that Tet3-mediated paternal 5mC oxidation is dispensable for mouse development but also suggests the existence of a compensation mechanism in preimplantation embryos that can compensate for the defective 5mC oxidation in zygotes.