Project description:Background: The placenta is vital for fetal development and its contributions to various developmental issues, such as pregnancy complications, fetal growth restriction, and maternal exposure, have been extensively studied in mice. Contrary to popular belief, the placenta forms mainly from fetal tissue; therefore, it has the same biological sex as the fetus it supports. However, while placental function is linked to increased risks of pregnancy complications and neurodevelopmental diseases in male offspring in particular, the sex-specific epigenetic (e.g., DNA methylation) and transcriptomic features of the late-gestation mouse placenta remain largely unknown.Methods: We collected male and female mouse placentas at late gestation (E18.5, n = 3/sex) and performed next-generation sequencing to identify genome-wide sex-specific differences in transcription and DNA methylation. Results: Our sex-specific analysis revealed 358 differentially expressed genes (DEGs) on autosomes, which were associated with signaling pathways involved in transmembrane transport and the responses to viruses and external stimuli. X chromosome DEGs (n = 39) were associated with different pathways, including those regulating chromatin modification and small GTPase-mediated signal transduction. Sex-specific differentially methylated regions (DMRs) were more common on the X chromosomes (n = 3756) than on autosomes (n = 1705). Interestingly, while most X chromosome DMRs had higher DNA methylation levels in female placentas and tended to be included in CpG dinucleotide-rich regions, 73% of autosomal DMRs had higher methylation levels in male placentas and were distant from CpG-rich regions. Several sex-specific DEGs were correlated with sex-specific DMRs. A subset of the sex-specific DMRs present in late-stage placentas were already established in mid-gestation (E10.5) placentas, while others were acquired later in placental development.Conclusion: Our study provides comprehensive lists of sex-specific DEGs and DMRs that collectively cause profound differences in the DNA methylation and gene expression profiles of late-gestation mouse placentas. Our results demonstrate the importance of incorporating sex-specific analyses into epigenetic and transcription studies to enhance the accuracy and comprehensiveness of their conclusions and help address the significant knowledge gap regarding how sex differences influence placental function.

Project description:Background : The placenta is vital for fetal development and its contributions to various developmental issues, such as pregnancy complications, fetal growth restriction, and maternal exposure, have been extensively studied in mice. The placenta forms mainly from fetal tissue and therefore has the same biological sex as the fetus it supports. Extensive research has delved into the placenta’s involvement in pregnancy complications and future offspring development, with a notable emphasis on exploring sex-specific disparities. However, despite these investigations, sex-based disparities in epigenetic (e.g., DNA methylation) and transcriptomic features of the late-gestation mouse placenta remain largely unknown. Methods : We collected male and female mouse placentas at late gestation (E18.5, n = 3/sex) and performed next-generation sequencing to identify genome-wide sex differences in transcription and DNA methylation. Results Our comparison between male and female revealed 358 differentially expressed genes (DEGs) on autosomes, which were associated with signaling pathways involved in transmembrane transport and the responses to viruses and external stimuli. X chromosome DEGs (n = 39) were associated with different pathways, including those regulating chromatin modification and small GTPase-mediated signal transduction. Differentially methylated regions (DMRs) were more common on the X chromosomes (n = 3756) than on autosomes (n = 1705). Interestingly, while most X chromosome DMRs had higher DNA methylation levels in female placentas and tended to be included in CpG dinucleotide-rich regions, 73% of autosomal DMRs had higher methylation levels in male placentas and were distant from CpG-rich regions. Several DEGs were correlated with DMRs. A subset of the DMRs present in late-stage placentas were already established in mid-gestation (E10.5) placentas (n = 348 DMRs on X chromosome and 19 DMRs on autosomes), while others were acquired later in placental development. Conclusion : Our study provides comprehensive lists of DEGs and DMRs between male and female that collectively cause profound differences in the DNA methylation and gene expression profiles of late-gestation mouse placentas. Our results demonstrate the importance of incorporating sex-specific analyses into epigenetic and transcription studies to enhance the accuracy and comprehensiveness of their conclusions and help address the significant knowledge gap regarding how sex differences influence placental function.

Project description:Preimplantation alcohol exposure can negatively impact embryonic development through disruption of molecular profiles and lead to fetal alcohol spectrum disorder (FASD). Despite the central role of the placenta in proper embryonic development and successful pregnancy, studies on the placenta in a FASD context are markedly lacking. Here, preimplantation binge-like alcohol exposure was implemented on pregnant C57BL/6 female mice through subcutaneous injection with two doses of either 2.5 g/kg 50% ethanol or an equivalent volume of saline at 2-h intervals on embryonic day 2.5 corresponding to the 8-cell stage. The placental morphology, DNA methylation and gene expression patterns in male and female late-gestation (E18.5) placentas were assessed. While overall placental morphology was not affected, we found a significant decrease in male ethanol-exposed embryo weights. When looking at molecular profiles, we uncovered numerous differentially methylated regions (DMRs ≥10% difference; 991 in males; 1309 in females) and differentially expressed genes (DEGs; 1046 in males; 340 in females) in the placentas. Remarkably, only 21 DMRs and 54 DEGs were common to both sexes, which were enriched for genes involved in growth factor response pathways. Preimplantation alcohol exposure had a greater impact on imprinted genes expression in male placentas (imprinted DEGs: 18 in males; 1 in females). Finally, by using L1-regularized linear regression, we were able to precisely discriminate control and ethanol-exposed placentas based on their specific DNA methylation patterns. This is the first study demonstrating that preimplantation alcohol exposure alters the DNA methylation and transcriptomic profiles of late-gestation placentas in a sex-specific manner. Importantly, it reveals a placental DNA methylation signature that can detect prenatal alcohol exposure in early life in order to provide appropriate support to attenuate and prevent eventual impact.

Project description:Preimplantation alcohol exposure can negatively impact embryonic development through disruption of molecular profiles and lead to fetal alcohol spectrum disorder (FASD). Despite the central role of the placenta in proper embryonic development and successful pregnancy, studies on the placenta in a FASD context are markedly lacking. Here, preimplantation binge-like alcohol exposure was implemented on pregnant C57BL/6 female mice through subcutaneous injection with two doses of either 2.5 g/kg 50% ethanol or an equivalent volume of saline at 2-h intervals on embryonic day 2.5 corresponding to the 8-cell stage. The placental morphology, DNA methylation and gene expression patterns in male and female late-gestation (E18.5) placentas were assessed. While overall placental morphology was not affected, we found a significant decrease in male ethanol-exposed embryo weights. When looking at molecular profiles, we uncovered numerous differentially methylated regions (DMRs ≥10% difference; 991 in males; 1309 in females) and differentially expressed genes (DEGs; 1046 in males; 340 in females) in the placentas. Remarkably, only 21 DMRs and 54 DEGs were common to both sexes, which were enriched for genes involved in growth factor response pathways. Preimplantation alcohol exposure had a greater impact on imprinted genes expression in male placentas (imprinted DEGs: 18 in males; 1 in females). Finally, by using L1-regularized linear regression, we were able to precisely discriminate control and ethanol-exposed placentas based on their specific DNA methylation patterns. This is the first study demonstrating that preimplantation alcohol exposure alters the DNA methylation and transcriptomic profiles of late-gestation placentas in a sex-specific manner. Importantly, it reveals a placental DNA methylation signature that can detect prenatal alcohol exposure in early life in order to provide appropriate support to attenuate and prevent eventual impact.

Project description:Background: Maternal iron deficiency (ID) is associated with poor pregnancy and fetal outcomes. The effect is thought to be mediated by the placenta but there is no comprehensive assessment of placental response to maternal ID. Additionally, whether the influence of maternal ID on the placenta differs by fetal sex is unknown. Objectives: Our primary aim was to identify gene and protein signatures of ID mouse placentas at mid-gestation. A secondary objective was to profile the expression of iron genes in mouse placentas across gestation. Methods: We used a real-time PCR based array to determine the mRNA expression of all known iron genes in mouse placentas at embryonic day (E) 12.5, E14.5, E16.5, and E19.5 (n=3 placentas/time point). To determine the effect of maternal ID, we performed RNA sequencing and proteomics in male and female placentas from ID and iron adequate mice at E12.5 (n=8 dams/diet). Results: In female placentas, six genes including transferrin receptor (Tfrc) and solute carrier family 11 member 2 were significantly changed by maternal ID. An additional 154 genes were altered in male ID placentas. Proteomic analysis quantified 7662 proteins in the placenta. Proteins translated from iron responsive element (IRE) containing mRNAs were altered in abundance; ferritin and ferroportin 1 decreased while TFRC increased in ID placenta. Less than 4% of the significantly altered genes in ID placentas occurred both at the transcriptional and translational levels. Conclusions: Our data demonstrate that the impact of maternal ID on placental gene expression in mice is limited in scope and magnitude at mid-gestation. We provide strong evidence for IRE-based transcriptional and translational coordination of iron gene expression in the mouse placenta. Finally, we discover sexually dimorphic effects of maternal ID on placental gene expression, with more genes and pathways altered in male compared with female mouse placentas.

Project description:Placenta-specific DMRs maintain methylation across gestation.

Project description:One possible mechanism leading to the apparent polymorphic placenta-specific DMRs would be the failure to maintain allelic methylation during gestation. For a temporal comparison, we performed methylation profiling on first trimester chorionic villus sampling (CVS) and compared it with corresponding samples at term. This revealed that DNA methylation level at placenta-specific DMRs is highly stable between the two points. In addition, to ensure that the methylation profiles were uniform across the placental plate, we determined the placenta-specific DMR profiles from multiple biopsies from the same term placentas. Biopsies collected from the opposite sides of the cord insertion site also showed high correlations, suggesting that methylation does not vary greatly between sampling sites. Finally, we compared placenta samples from dizygotic twins and triplets. As in the other cases, this revealed that the correlations between samples of the same gestations (sharing the same in utero environment and maternal exposures) were also higher than between unrelated samples.

Project description:In early embryos, DNA methylation is remodelled to initiate the developmental program. For mostly unknown reasons, methylation marks are acquired unequally between embryonic and placental cells. To better understand this, we generated high-resolution maps of DNA methylation in mouse mid-gestation (E10.5) embryo and placenta. We uncovered specific subtypes of differentially methylated regions (DMRs) that contribute directly to the developmental asymmetry existing between mid-gestation embryo and placenta. We show that the asymmetry between embryonic and placental DNA methylation patterns occurs rapidly during the acquisition of marks in the post-implanted conceptus (E3.5-E6.5), and that these patterns are long-lasting across subtypes of DMRs throughout prenatal development and in somatic tissues. We reveal that at the peri-implantation stages, the de novo methyltransferase activity of DNMT3B is the main driver of methylation marks on asymmetric DMRs, and that DNMT3B can largely compensate for lack of DNMT3A in the epiblast and extraembryonic ectoderm, whereas DNMT3A can only partially palliate for the absence of DNMT3B. However, as development progresses and as DNMT3A becomes the principal de novo methyltransferase, the compensatory DNA methylation mechanism on DMRs becomes less effective.

Project description:From gestation day 75 to gestation day 90, an important stage for the placental and fetal development, the fetuses grow rapidly and need adequate nutrition. The Meishan pigs and the Large White pigs employ different ways in supplying the enough nutrients and oxygen to the fetus. The Meishan pigs increased the vascular density and the Large White pigs have the second increase in the surface of placenta. To understand the molecular basis related to late gestation placenta development in Chinese indigenous and Western breeds with different placental efficiency, samples were collected and used to hybridized. The results offered new data on understanding the molecular basis of placenta efficiency, and indicated that Erhualian pigs had the more efficient than the Large White pigs. Experiment Overall Design: Placenta efficiency (the body weight of a piglet divided by the mass of its placenta) of Erhualian pigs is markedly higher than Large White pigs. so placenta samples (female) from 6 Erhuanlian pregnant gilts at gestation day 75 (E75) and day 90 (E90) and 6 Large White pregnant gilts at gestation day 75 (L75) and day 90 (L90) were collected. RNAs from two female piglet placentas from each gilt were combined to 12 pools and hybridized to the porcine Affymetrix GeneChip.

Project description:Transfer of frozen-thawed embryos leads to sex-specific DNA hypermethylation in both human and mouse placentas. : In humans, frozen ET led to placentas with significant alterations in DNA methylation with most genes demonstrating hypermethylation compared to placentas from fresh ET (4402 CpGs; 1600 genes; p-value < 0.05 in two–tailed unpaired t tests, and a mean methylation difference > 0.05). When compared to control samples, both frozen and fresh samples showed significant differences in methylation.(Frozen vs Control: 5600 CpGs, 2775 genes; Fresh vs Control: 4096 CpGS; 1914 genes; p-value < 0.05, mean methylation difference > 0.05). Paired analysis showed similar trends, despite controlling for maternal environment. Sex specific analysis revealed that these changes were primarily driven by male placentas, as seen by a larger number of CpGs that were differentially methylated, and a larger proportion of genes with at least 2 differentially methylated CpG sites in male placentas as compared to female placentas. (Males: 15572 CpGs, 4399 genes; Females: 7441 CpGs, 3070 genes; p-value < 0.05, mean methylation difference > 0.05). In order to isolate the effects of vitrification we utilized the mouse model, controlling for the effect of the maternal hormonal milieu. In the first genome-wide profiling of DNA methylation in a mouse IVF model, we found that trends in DNA methylation differences paralleled those seen in human placentas. Using similar significance cutoffs as for human samples, and BumpHunter analysis that identifies differentially methylated regions to compensate for a lower number of samples, placentas derived from frozen embryos were predominantly hypermethylated compared to placentas after fresh ET (589 DMRs, 445 genes). Both frozen and fresh embryo transfer samples demonstrated perturbations compared to control samples (Frozen vs Control: 1787 DMRs, 1319 genes; Fresh vs Control: 1119 DMRs, 808 genes). Consistent with the sex-specific trends we observed in human placentas, differences between samples derived from frozen compared to fresh embryo transfer were driven by changes in male placentas (Males: 1069 DMRs, 798 genes; Females:14 DMRs, 11 genes) . When considering the effect of IVF as a whole, murine placentas were predominantly hypomethylated, replicating existing human genome-wide methylation data. As seen previously, IVF led to changes in placental weight, placental morphology and microvessel density in mice, but no persistent changes were seen after embryo vitrification alone. Sexually dimorphic epigenetic changes could indicate differential susceptibility of male and female embryos to IVF-associated perturbations. This observation highlights the importance of sex-specific evaluation of the incidence of adverse outcomes. Similarities between changes seen in mouse and human samples underscore the suitability of the mouse model in evaluating the effect of ART on the epigenetic landscape. This convergence is especially valuable, given limited access to human tissues and the ability to isolate specific interventions in the mouse model.