Project description:The labyrinthian fetoplacental capillary network is of vital importance for proper nourishment of the developing embryo. An inadequate function of the maternal-fetal circulation has emerged as one of the primary causes of placental insufficiency. Here, we show that the spatial zonation of the placental labyrinth vasculature is controlled by flow-regulated epigenetic mechanisms. The spatial and temporal analysis of gene transcription revealed a gradual change in the expression of epigenetic enzymes with the de novo DNA methyltransferase 3a (DNMT3A) as primary enzyme introducing DNA methylation in cells of the vascular system. Loss of Dnmt3a resulted in DNA hypomethylation and disturbance of the spatial-zonated placental gene expression. The resulting global DNA hypomethylation impaired the angiogenic capacity of endothelial cells. Global as well as endothelium-predominant deletion of Dnmt3a resulted in impaired placental vascularization and fetal growth retardation. A meta-analysis of human placental endothelial cell gene expression identified an association between preeclampsia and reduction of DNMT3A. Collectively, our study identified DMNT3A as critical methylome-regulator of placental endothelial cell gene expression and function with clinical implications for the pathogenesis of placental dysfunction, as it occurs during preeclampsia or fetal growth retardation.

Project description:The labyrinthian fetoplacental capillary network is of vital importance for proper nourishment of the developing embryo. An inadequate function of the maternal-fetal circulation has emerged as one of the primary causes of placental insufficiency. Here, we show that the spatial zonation of the placental labyrinth vasculature is controlled by flow-regulated epigenetic mechanisms. The spatial and temporal analysis of gene transcription revealed a gradual change in the expression of epigenetic enzymes with the de novo DNA methyltransferase 3a (DNMT3A) as primary enzyme introducing DNA methylation in cells of the vascular system. Loss of Dnmt3a resulted in DNA hypomethylation and disturbance of the spatial-zonated placental gene expression. The resulting global DNA hypomethylation impaired the angiogenic capacity of endothelial cells. Global as well as endothelium-predominant deletion of Dnmt3a resulted in impaired placental vascularization and fetal growth retardation. A meta-analysis of human placental endothelial cell gene expression identified an association between preeclampsia and reduction of DNMT3A. Collectively, our study identified DMNT3A as critical methylome-regulator of placental endothelial cell gene expression and function with clinical implications for the pathogenesis of placental dysfunction, as it occurs during preeclampsia or fetal growth retardation.

Project description:Background: A small number of recent reports have suggested that altered placental DNA methylation may be associated with early onset preeclampsia. It is important that further studies be undertaken to confirm and develop these findings. We therefore undertook a systematic analysis of DNA methylation patterns in placental tissue from 24 women with preeclampsia and 24 with uncomplicated pregnancy outcome. Methods: We analyzed the DNA methylation status of approximately 27,000 CpG sites in placental tissues in a massively parallel fashion using an oligonucleotide microarray. Follow up analysis of DNA methylation at specific CpG loci was performed using the Epityper MassArray approach and high-throughput bisulfite sequencing. Results: Preeclampsia-specific DNA methylation changes were identified in placental tissue samples irrespective of gestational age of delivery. In addition, we identified a group of CpG sites within specific gene sequences that were only altered in early onset-preeclampsia (EOPET) although these DNA methylation changes did not correlate with altered mRNA transcription. We found evidence that fetal gender influences DNA methylation at autosomal loci but could find no clear association between DNA methylation and gestational age. Conclusion: Preeclampsia is associated with altered placental DNA methylation. Fetal gender should be carefully considered during the design of future studies in which placental DNA is analyzed at the level of DNA methylation. Further large-scale analyses of preeclampsia-associated DNA methylation are necessary. Bisulphite converted DNA from the 48 samples were hybridized to the Illumina Infinium 27k Human Methylation Beadchip v1.2

Project description:Background: A small number of recent reports have suggested that altered placental DNA methylation may be associated with early onset preeclampsia. It is important that further studies be undertaken to confirm and develop these findings. We therefore undertook a systematic analysis of DNA methylation patterns in placental tissue from 24 women with preeclampsia and 24 with uncomplicated pregnancy outcome. Methods: We analyzed the DNA methylation status of approximately 27,000 CpG sites in placental tissues in a massively parallel fashion using an oligonucleotide microarray. Follow up analysis of DNA methylation at specific CpG loci was performed using the Epityper MassArray approach and high-throughput bisulfite sequencing. Results: Preeclampsia-specific DNA methylation changes were identified in placental tissue samples irrespective of gestational age of delivery. In addition, we identified a group of CpG sites within specific gene sequences that were only altered in early onset-preeclampsia (EOPET) although these DNA methylation changes did not correlate with altered mRNA transcription. We found evidence that fetal gender influences DNA methylation at autosomal loci but could find no clear association between DNA methylation and gestational age. Conclusion: Preeclampsia is associated with altered placental DNA methylation. Fetal gender should be carefully considered during the design of future studies in which placental DNA is analyzed at the level of DNA methylation. Further large-scale analyses of preeclampsia-associated DNA methylation are necessary.

Project description:The etiology of preeclampsia, a hypertensive disorder of human pregnancy, remains unknown. We addressed fetal sex selection and the suggestive role of fetal HLA-G and related genes, regulating maternal immune responses, in preeclampsia pathogenesis. We assessed birth sex ratios, weights, and seasonality of preeclampsia among 1.79 million births in Finland. We studied haplotypes of HLA-G 3’ untranslated region (UTR), regulating HLA-G expression, in 1000 Genomes series and in a preeclampsia cohort (n=1249). We quantified placental (n=163) mRNA expression of 136 genes, studied HLA-G and IFNα protein expression by immunohistochemistry, and measured maternal and fetal circulating IFNα levels by ELISA. Population-level data showed loss of male fetuses as a characteristic of preeclampsia. As a potential contributor to immune-mediated loss, we found balancing selection at HLA-G 3’UTR modulating sex ratio, and association of HLA-G 3’UTR haplotypes with placental HLA-G expression. HLA-G and its receptors were downregulated in preeclampsia placentas, and surprisingly, interferon alpha-1 (IFNA1) was highly upregulated. IFNA1 and HLA-G distinguished preeclampsia better than placental FLT1 expression. Fetal but not maternal circulating IFNα, produced by trophoblasts, showed association with maternal hypertension and fetal growth restriction. We uncover the link between placental HLA-G expression and human birth sex ratio. We propose that preeclampsia shares, through reduced HLA-G mediated immunotolerance, the mechanism needed to fight placental viral infections and malaria in evolution. IFNα upregulation in preeclampsia placenta, together with its known actions upstream of inflammatory genes, encourages testing IFNα inhibitors and especially the pregnancy-approved antimalarial hydroxichloroquine in treatment of preeclampsia.

Project description:Background: DNA methylation (DNAm) profiling has emerged as a powerful tool for characterizing the placental methylome. However, previous studies have focused primarily on whole placental tissue, which is a mixture of epigenetically distinct cell populations. Here, we present the first methylome-wide analysis of first trimester (n=9) and term (n=19) human placental samples of four cell populations: trophoblasts, Hofbauer cells, endothelial cells, and stromal cells, using the Illumina EPIC methylation array, which quantifies DNAm at >850,000 CpGs. Results: The most distinct DNAm profiles were those of placental trophoblasts, which are central to many pregnancy-essential functions, and Hofbauer cells, which are a rare fetal-derived macrophage population. Cell-specific DNAm occurs at functionally-relevant genes, including genes associated with placental development and preeclampsia. Known placental-specific methylation marks, such as those associated with genomic imprinting, repetitive element hypomethylation, and placental partially methylated domains, were found to be more pronounced in trophoblasts and often absent in Hofbauer cells. Lastly, we characterize the cell composition and cell-specific DNAm dynamics across gestation. Conclusions: Our results provide a comprehensive analysis of DNAm in human placental cell types from first trimester and term pregnancies. This data will serve as a useful DNAm reference for future placental studies, and we provide access to this data via download from dbGAP (phs002013.v1.p1), through interactive exploration from the web browser (https://robinsonlab.shinyapps.io/Placental_Methylome_Browser/), and through the R package planet, which allows estimation of cell composition directly from placental DNAm data.

Project description:The placenta mediates adverse pregnancy outcomes, including preeclampsia, characterized by gestational hypertension and proteinuria. Placental cell type heterogeneity in preeclampsia is not well-understood and limits mechanistic interpretation of bulk gene expression measures. We generated single-cell RNA-sequencing samples for integration with existing data to create the largest deconvolution reference of 19 fetal and 8 maternal cell types from placental villous tissue at term. We deconvoluted eight published microarray case-control studies of preeclampsia. Our findings indicate substantial placental cellular heterogeneity in preeclampsia that predict previously observed bulk gene expression differences. Our deconvolution reference lays the groundwork for cellular heterogeneity-aware investigation into placental dysfunction and adverse birth outcomes.

Project description:Preeclampsia-offspring have increased risks of developing cardiovascular disorders in adulthood, implicating that preeclampsia programs fetal vasculature in utero. Fetal sex is associated with the risk of preeclampsia but the underlying mechanisms are unclear. We hypothesize that preeclampsia alters fetal endothelial gene expression and disturbs cytokines and growth factors-induced endothelial function in a fetal sex-specific manner. Methods: RNAseq analysis was performed with female and male unpassaged (P0) human umbilical vein endothelial cells (HUVECs) from normotensive and preeclamptic (PE) pregnancies and verified by RT-qPCR. Results: PE dysregulate 926 and 172 genes in female and male P0-HUVECs, respectively. PE differentially dysregulates cardiovascular diseases (i.e. heart failure) and endothelial function (i.e. endothelial cell migration, calcium, eNOS, and iNOS signaling)-associated genes in female and male P0-HUVECs. PE also differentially dysregulates TNF-, TGFβ1-, FGF2-, and VEGFA-regulated gene networks in female and male P0-HUVECs. Conclusions: There are sexual dimorphisms of PE-dysregulated cardiovascular diseases and endothelial function-associated genes/pathways in fetal endothelial cells in association with sexual dimorphisms of PE-dysregulated fetal endothelial function.

Project description:Genome wide DNA methylation profiling of normal and preeclampsia placental samples. Illumina Infinium HumanMethylation450 BeadChip (450K array) was used to obtain DNA methylation profiles in placental samples. Samples included 16 samples from healthy uncomplicated pregnancies and 8 samples from pregnancies affected by preeclampsia.

Project description:Placental disorders contribute to pregnancy complications including preeclampsia (PE) and fetal growth restriction (FGR), but debate regarding their specific pathobiology persists. Our objective was to apply transcriptomics with weighted gene correlation network analysis (WGCNA) to further clarify the placental dysfunction in these conditions.