Project description:Comparison of genes associated with the EMT between undifferentiated cytotrophoblast cells (CTB) and differentiated extravillous trophoblast cells (EVT) from third trimester human placenta. Cells isolated from control (placenta previa) and cases (preeclampsia). Cells isolated by immunomagnetic separation using anti-integrin beta4 antibody to purify CTB and anti-HLA-G antibody to purify EVT.

Project description:Comparison of genes associated with the EMT between cytotrophoblast cells (CTB) and extravillous trophoblast cells (EVT) from normal third trimester placenta and abnormally invasive placenta (AIP)

Project description:Trophoblast is the primary epithelial cell type in the placenta, a transient organ required for proper fetal growth and development. We have identified a CDX2+/p63+ cytotrophoblast (CTB) subpopulation in the early post-implantation human placenta, which is significantly reduced later in gestation. CTB differentiate into different trophoblast subtypes, which are responsible for gas/nutrient exchange (syncytiotrophoblast/STB) and invasion and maternal vascular remodeling (extravillous trophoblast/EVT). Study of early human placental development is severely hampered by lack of a representative trophoblast stem cell (TSC) model, with the capacity for self-renewal and the ability to differentiate into both STB and EVT. We describe a reproducible protocol, using defined media containing BMP4, by which human embryonic stem cells (hESC) can be differentiated into CDX2+/p63+ CTB-like cells. These cells can be replated to further differentiate into STB- and EVT-like cells, based on marker expression, hormone secretion and invasive ability. Differentiation of hPSC-derived CTB in hypoxia leads to reduced hCG secretion and STB-associated gene expression, instead inducing EVT differentiation in a hypoxia-inducible factor-dependent manner.

Project description:Preeclampsia (PE) is a hypertensive disorder, which affects up to 10% of pregnancies worldwide. The primary etiology is considered to be abnormal development and function of placental cells called trophoblasts. We previously developed a two-step protocol for differentiation of human pluripotent stem cells, first into cytotrophoblast (CTB) progenitor-like cells, and then into both syncytiotrophoblast (STB)- and extravillous trophoblast (EVT)-like cells, and showed that this protocol can be used to model both normal and abnormal trophoblast differentiation. We have now applied this protocol to differentiate induced pluripotent stem cells (iPSC) derived from placentas of pregnancies with or without PE.  While we did not note any differences in CTB induction, PE-iPSC-derived CTB showed a defect in syncytialization, and had a >180-fold reduction in expression of PSG4, a mature STB marker (p<0.02). While EVT formation did not appear to be altered, the invasive capacity of PE-iPSC-derived EVT was non-responsive to a decrease in oxygen tension, while that of non-PE-iPSC-derived EVT was enhanced 3.8-fold. RNA sequencing analysis showed gene expression changes consistent with defects in STB formation and response to hypoxia in PE-iPSC derived trophoblast. However, differences in DNA methylation were minimal, with only documented differences consistent with part of the response to hypoxia. Overall, PE-associated iPSC recapitulated multiple defects associated with placental dysfunction, with their lack of response to decreased oxygen tension emphasizing the importance of the interface with the maternal microenvironment in normal placentation.

Project description:Preeclampsia (PE) is a hypertensive disorder, which affects up to 10% of pregnancies worldwide. The primary etiology is considered to be abnormal development and function of placental cells called trophoblasts. We previously developed a two-step protocol for differentiation of human pluripotent stem cells, first into cytotrophoblast (CTB) progenitor-like cells, and then into both syncytiotrophoblast (STB)- and extravillous trophoblast (EVT)-like cells, and showed that this protocol can be used to model both normal and abnormal trophoblast differentiation. We have now applied this protocol to differentiate induced pluripotent stem cells (iPSC) derived from placentas of pregnancies with or without PE.  While we did not note any differences in CTB induction, PE-iPSC-derived CTB showed a defect in syncytialization, and had a >180-fold reduction in expression of PSG4, a mature STB marker (p<0.02). While EVT formation did not appear to be altered, the invasive capacity of PE-iPSC-derived EVT was non-responsive to a decrease in oxygen tension, while that of non-PE-iPSC-derived EVT was enhanced 3.8-fold. RNA sequencing analysis showed gene expression changes consistent with defects in STB formation and response to hypoxia in PE-iPSC derived trophoblast. However, differences in DNA methylation were minimal, with only documented differences consistent with part of the response to hypoxia. Overall, PE-associated iPSC recapitulated multiple defects associated with placental dysfunction, with their lack of response to decreased oxygen tension emphasizing the importance of the interface with the maternal microenvironment in normal placentation.

Project description:Trophoblast is the primary epithelial cell type in the placenta, a transient organ required for proper fetal growth and development. We have identified a CDX2+/p63+ cytotrophoblast (CTB) subpopulation in the early post-implantation human placenta, which is significantly reduced later in gestation. CTB differentiate into different trophoblast subtypes, which are responsible for gas/nutrient exchange (syncytiotrophoblast/STB) and invasion and maternal vascular remodeling (extravillous trophoblast/EVT). Study of early human placental development is severely hampered by lack of a representative trophoblast stem cell (TSC) model, with the capacity for self-renewal and the ability to differentiate into both STB and EVT. We describe a reproducible protocol, using defined media containing BMP4, by which human embryonic stem cells (hESC) can be differentiated into CDX2+/p63+ CTB-like cells. These cells can be replated to further differentiate into STB- and EVT-like cells, based on marker expression, hormone secretion and invasive ability. Differentiation of hPSC-derived CTB in hypoxia leads to reduced hCG secretion and STB-associated gene expression, instead inducing EVT differentiation in a hypoxia-inducible factor-dependent manner. Human embryonic stem cells (hESC) (WA09/H9) were maintained on Geltrex-coated plates (BD Biosciences ) in StemPro (Thermo Fisher) + bFGF (12 ng/ml). Undifferentiated hESC (D-2) were switched to minimal media (EMIM (Erb et al., 2011) containing KO DMEM/F12 (Gibco), 1% Insulin-Transferrin-Selenium Mix (Sigma-Aldrich), 1% NEAA (Gibco), 2mM L-Glutamine (Corning), 0.1mM 2-mercaptoethanol (Gibo), and 2% BSA (Gemini Bio Products)) for 2 days then treated with BMP4 (StemRD, 10ng/ml) for 3 days in minimal media+BMP4 (D3). At D3, cells were replated onto Geltrex in Feeder Conditioned Media +BMP4 and cultured in normoxia (20% O2) or hypoxia (2% O2) for 2 days (D3+2) to assess the effect of hypoxia. Cells were infected with lentiviral shRNA for shScramble (control) or shARNT, the beta subunit of the Hypoxia Inducible Factor (HIF) complex to assess the effect of ARNT knockdown. Each sample includes biological triplicates.

Project description:During pregnancy, normal extravillous trophoblast (EVT) invade the endomyometrium of the maternal uterus and remodel the spiral arteries to control blood supply and nutrient transfer. Recent reports have described first trimester EVT as polyploid and senescent. Here we extend these earlier reports by performing comprehensive profiling of the genomic organization and transcriptome of first trimester EVT and term EVT. We define pathways and gene regulatory networks involved in both initial differentiation and maturation of this important trophoblast lineage at the maternal-fetal interface. Our results suggest that like first trimester EVT, term EVT undergo senescence and endoreduplication, are primarily tetraploid, and lack high rates of copy number variations. Additionally, we have highlighted senescence and polyploidy-related genes, pathways, networks, and transcription factors that appeared to be important in normal EVT differentiation and maturation and have validated a critical role for the unfolded protein response in EVT differentiation.

Project description:During pregnancy, normal extravillous trophoblast (EVT) invade the endomyometrium of the maternal uterus and remodel the spiral arteries to control blood supply and nutrient transfer. Recent reports have described first trimester EVT as polyploid and senescent. Here we extend these earlier reports by performing comprehensive profiling of the genomic organization and transcriptome of first trimester EVT and term EVT. We define pathways and gene regulatory networks involved in both initial differentiation and maturation of this important trophoblast lineage at the maternal-fetal interface. Our results suggest that like first trimester EVT, term EVT undergo senescence and endoreduplication, are primarily tetraploid, and lack high rates of copy number variations. Additionally, we have highlighted senescence and polyploidy-related genes, pathways, networks, and transcription factors that appeared to be important in normal EVT differentiation and maturation and have validated a critical role for the unfolded protein response in EVT differentiation.

Project description:Invasion of cytotrophoblasts into uterine tissues is essential for placental development. To identify molecules regulating trophoblast invasion, mRNA signatures of purified villous (CTB, poor invasiveness) and extravillous (EVT, high invasiveness) trophoblasts isolated from first trimester human placentae and villous explant cultures, respectively, were compared using GeneChip analyses yielding 991 invasion/migration related transcripts. Several genes involved in physiological and pathologic cell invasion, including ADAM-12,-19,-28 as well as Spondin-2, were upregulated in EVT. Pathway prediction analyses identified several functional modules associated with either the invasive or the non-invasive trophoblast phenotype. One of the genes which were downregulated in the invasive mRNA pool, heme oxygenase-1 (HO-1), was selected for functional analyses. Real-time PCR analyses, Western blottting, and immunofluorescene of first trimester placentae and differentiating villous explant cultures demonstrated downregulation of HO-1 in invasive EVT as compared to CTB. Modulation of HO-1 expression in loss-of as well as gain-of function cell models (BeWo and HTR8/SVneo, respectively) demonstrated an inverse relationship of HO-1 expression with trophoblast migration in transwell and wound healing assays. Importantly, HO-1 expression led to an increase in protein levels and activity of the nuclear hormone receptor PPARgamma. Pharmacological inhibition of PPARgamma abrogated the inhibitory effects of HO-1 on trophoblast migration. Collectively, our results demonstrate that gene expression profiling of EVT and CTB can be used to unravel novel regulators of cell invasion. Accordingly, we identify heme oxygenase-1 as a negative regulator of trophoblast motility acting via upregulation of PPARgamma. Experiment Overall Design: To identify genes potentially regulating cell invasion trophoblast cells of early human gestation with distinct invasive properties were profiled. Experiment Overall Design: Distinct gene expression signatures of highly invasive EVT (n = 6) and poorly invasive CTB (n = 5) of different first trimester placentae using Affymetrix U133A GeneChips interrogating >20,000 genes were determined.

Project description:During pregnancy, trophoblast cells in the placenta are the only fetal cells in direct contact with the maternal blood and decidua. They have many functions, including transport of nutrients and oxygen, remodelling the uterine arteries, and communicating with maternal cells. Despite their importance in development and in the success of pregnancy, little is known about human trophoblast progenitors and their differentiation. We identify a proliferative trophoblast niche at the base of cytotrophoblast cell columns in first trimester placentas that is characterised by integrin α2 (ITGA2) expression. Pulse-chase experiments with 5-Iodo-2′-deoxyuridine (IdU) imply that these cells can contribute to both villous and extravillous lineages. Importantly, these cells can be isolated by ITGA2 using flow cytometry and express genes from both VCT and EVT. Microarray shows that they display a unique gene signature including NOTCH signalling and mesenchymal characteristics. ITGA2 allows for the first time the study of a pure population of trophoblast progenitor cells.