Project description:Expression profiling of wild-type and Prdm1 null mouse trophoblast giant cell cultures using Illumina whole genome mouse V2 arrays. The hypothesis tested was that Prdm1/Blimp1 regulates expression of genes required for spiral artery trophoblast giant cell function. Prdm1 null and littermate control wild-type trophoblast stem cell clones were generated from blastocyst outgrowths. Total RNA was obtained from multiple replicates of four wild-type TS cell clones and four Prdm1 null TS cell clones differenitated for zero, two, four and six days by growth factor withdrawal and hybridized to Illumina WG6_V2 arrays

Project description:Expression profiling of wild-type and Prdm1 null mouse trophoblast giant cell cultures using Illumina whole genome mouse V2 arrays. The hypothesis tested was that Prdm1/Blimp1 regulates expression of genes required for spiral artery trophoblast giant cell function.

Project description:Our goal was to transcriptionally profile Prdm1+ cell lineages of maternal and embryonic origin in mid-gestation mouse placenta in order to study vascular mimicry and additional processes in the placenta. Profiling of 61 single cells and 17 clusters of 2 or 3 cells chosen based on expression of Prdm1, a paternally inherited Prdm1-Venus fluorescent reporter, progenitor trophoblast marker Gjb3 and spiral artery trophoblast giant cell marker Prl7b1.

Project description:Expression profiling of Prdm1 mutant E9.5 placenta was performed using Illumina whole genome V2 arrays. The hypothesis tested in the present study was that Blimp1 regulates the transcription of key genes involved in trophoblast differentiation. We demonstrate that the invading SpA-TGCs display robust Blimp1 expression and Blimp1 functional loss selectively disrupts specification of this discrete TGC sub-type. Transcriptional profiling experiments identified additional SpA-TGC lineage restricted marker genes that potentially regulate placental morphogenesis. Prdm1BEH/+ (Vincent et al., 2005) animals were intercrossed to generate null placental tissue. Total RNA obtained from 10 Prdm1+/+ and 11 Prdm1-/- E9.5 placenta samples was hybridized to Illumina WG6_V2 beadchips.

Project description:Expression profiling of Prdm1 mutant E9.5 placenta was performed using Illumina whole genome V2 arrays. The hypothesis tested in the present study was that Blimp1 regulates the transcription of key genes involved in trophoblast differentiation. We demonstrate that the invading SpA-TGCs display robust Blimp1 expression and Blimp1 functional loss selectively disrupts specification of this discrete TGC sub-type. Transcriptional profiling experiments identified additional SpA-TGC lineage restricted marker genes that potentially regulate placental morphogenesis.

Project description:Molecular function of Prdm1/Blimp1 in trophoblast giant cell differentiation.

Project description:Our goal was to survey genomic binding of Blimp1 in differentiating trophoblast giant cells in order to identify direct transcriptional target genes.

Project description:A major population of placenta macrophages represented throughout the pregnancy consists of CD14+ macrophages, but their characteristics remain badly understood. Here we purified from placentas at term CD14+ macrophages using positive selection. The phenotyping of CD14+ macrophages performed using flow cytometry revealed that placenta CD14+ macrophages expressed a series of markers distinct of those of circulating monocytes monocyte-derived macrophages. Placenta CD14+ macrophages spontaneously matured in multinucleated giant cells (MGCs) as demonstrated by size, number of nuclei display and specific cytoskeleton organization. Placenta CD14+ macrophages and MGCs were phagocytic cells but the potential of MGCs to mount an inflammatory response was lower than that of their precursors. Placenta CD14+ macrophages and MGCs stimulated with interferon and interleukin-4 were not polarized into typical M1 or M2 profiles. Placenta macrophages exhibited specific activation transcriptional programs. Indeed, principal component analysis and hierarchical clustering show that placental macrophages formed a distinct group from circulating monocytes and monocyte-derived macrophages. Among placenta macrophages, it was also possible to distinguish CD14+ macrophages and MGCs. In addition, networks based on gene interactions were clearly different in CD14+ macrophages and MGCs. Finally, the microenvironment of placenta CD14+ macrophages governs their differentiation into MGCs because CD14+ macrophages incubated with trophoblasts exhibited exarcerbated characteristics of MGCs and because the co-incubation of circulating monocytes from working women with trophoblast supernatants resulted into the formation of MGCs whereas monocytes from non-pregnant women incubated with trophoblast supernatants did not differentiate into MGCs. Taken together, these results clearly demonstrated specific feaures of placenta CD14+ macrophages. Three replicates of each of the following: 1. Placental macrophages just after isolation (CD14+ macrophages) 2. Placental macrophages after 9 days in culture (MGCs) 3. CD14+ cells isolated from PBMC which are extracted from the whole human blood of healthy donors (Monocytes) 4. Macrophages derived from monocytes (MDMs)

Project description:We characterized regions of underrepresentation that are specific to mouse polyploid trophoblast giant cells. We performed array Comparative Genomics Hybridization (aCGH) to examine copy number variation (CNV) in mouse polyploid trophoblast giant cells (TGCs). We performed the following experiments in duplicates to examine CNV during various stages of in vivo and in vitro TGC development: e9.5 TGCs vs. embryonic controls, e11.5 TGCs vs. embryonic controls, e13.5 TGCs vs. embryonic controls, e16.5 TGCs vs. embryonic controls, as well as TGCs cultured 3, 5 and 7 days vs. 2N trophoblast stem cells. We also performed the following controls to show that underrepresentation is only found in polypoid trophoblast giant cells and not in either 2N placental cell types nor in other types of polyploid cells: 2N placenta disk vs. embryonic controls, 2N trophoblast stem cells vs. embryonic stem cells, and polyploid Megakaryocytes vs. embryonic controls. When possible, we performed arrays with the test and control samples of opposite sex (F-female, M-male), as an internal control for the array.

Project description:Vascular endothelial (VE-)cadherin is a homotypic adhesion protein that is expressed selectively by ECs in which it enables formation of tight vessels and regulation of vascular permeability. Since VE-cadherin is also strongly expressed in placental trophoblasts, it is a prime candidate for a molecular mechanism of vascular mimicry by those cells. Here, we show that the VE-cadherin is required for trophoblast migration and endovascular invasion into the maternal decidua. VE-cadherin deficiency results in loss of spiral artery remodeling due to a lack of invasive trophoblasts, leading to decreased flow of maternal blood into the placenta, fetal growth retardation and death. Loss of trophoblast invasion prevents decidualization, extracellular matrix remodeling, and immune cell clearance. These studies identify VE-cadherin as essential for trophoblast migration and coordination of decidual changes during endovascular invasion. They further suggest endothelial proteins such as VE-cadherin that are expressed by trophoblasts may play functionally distinct roles that do not simply mimic those in ECs.