Proteinase Activated Receptors Mediate the Trypsin-Induced Ca2 + Signaling in Human Uterine Epithelial Cells

Embryo implantation is a complex and tightly regulated process. In humans, uterine luminal epithelium functions as a biosensor gauging the embryo quality and transmitting this information to the underlying endometrial stromal cells. This quality control ensures that only high quality embryos are implanted, while aberrant ones are rejected. The mechanisms of the embryo-uterine mucosa crosstalk remain incompletely understood. Trypsin, a serine protease secreted by the blastocyst, has been implicated in the cross-signaling. Here we address the mechanisms by which trypsin triggers the intracellular calcium signaling in uterine epithelium. We found that protease-activated G-protein coupled receptors are the main mechanism mediating the effects of trypsin in human uterine epithelium. In addition, trypsin activates the epithelial sodium channels thus increasing the intracellular Na+ concentration and promoting Ca2+ entry on the reverse mode of the sodium/calcium exchanger.

ADAMTS-1: a novel target gene of an estrogen-induced transcription factor, EGR1, critical for embryo implantation in the mouse uterus

Background Recently, we demonstrated that estrogen (E2) induces early growth response 1 (Egr1) to mediate its actions on the uterine epithelium by controlling progesterone receptor signaling for successful embryo implantation. EGR1 is a transcription factor that regulates the spectrum of target genes in many different tissues, including the uterus. E2-induced EGR1 regulates a set of genes involved in epithelial cell remodeling during embryo implantation in the uterus. However, only few target genes of EGR1 in the uterus have been identified. Result The expression of ADAM metallopeptidase with thrombospondin type 1 motif 1 (Adamts-1) was significantly downregulated in the uteri of E2-treated ovariectomized (OVX) Egr1(−/−) mice. Immunostaining of ADAMTS-1 revealed its exclusive expression in the uterine epithelium of OVX wild-type but not Egr1(−/−) mice treated with E2. The expression profiles of Adamts-1 and Egr1 were similar in the uteri of E2-treated OVX mice at various time points tested. Pre-treatment with ICI 182, 780, a nuclear estrogen receptor (ER) antagonist, effectively inhibited the E2-dependent induction of Egr1 and Adamts-1. Pharmacologic inhibition of E2-induced ERK1/2 or p38 phosphorylation interfered with the induction of EGR1 and ADAMTS-1. Furthermore, ADAMTS-1, as well as EGR1, was induced in stroma cells surrounding the implanting blastocyst during embryo implantation. Transient transfection with EGR1 expression vectors significantly induced the expression of ADAMTS-1. Luciferase activity of the Adamts-1 promoter containing EGR1 binding sites (EBSs) was increased by EGR1 in a dose-dependent manner, suggesting functional regulation of Adamts-1 transcription by EGR1. Site-directed mutagenesis of EBS on the Adamts-1 promoter demonstrated that EGR1 directly binds to the EBS at -1151/-1134 among four putative EBSs. Conclusions Collectively, we have demonstrated that Adamts-1 is a novel target gene of E2-ER-MAPK-EGR1, which is critical for embryo implantation in the mouse uterus during early pregnancy.

Tumor susceptibility gene 101 is required for the maintenance of uterine epithelial cells during embryo implantation

Background The tumor susceptibility gene 101 (Tsg101), a component of the endosomal sorting complex required for transport (ESCRT) complex I, is involved in multiple biological processes involving endomembranous structures and the plasma membrane. The role of Tsg101 in the uterine epithelium was investigated in Tsg101 floxed mice crossed with Lactoferrin-iCre mice (Tsg101d/d). Methods Tsg101d/d mice were bred with stud male mice and the status of pregnancy was examined on days 4 and 6. Histological analyses were performed to examine the uterine architecture. Immunofluorescence staining of several markers was examined by confocal microscopy. Uterine epithelial cells (UECs) were isolated from Tsg101f/f and Tsg101d/d mice, and the expression of necroptosis effectors was examined by RT-PCR, western blotting, and immunofluorescence staining. UECs were also subjected to RNA expression profiling. Results Tsg101d/d female mice were subfertile with implantation failure, showing unattached blastocysts on day 6 of pregnancy. Histological and marker analyses revealed that some Tsg101d/d day 4 pregnant uteri showed a disintegrated uterine epithelial structure. Tsg101d/d UECs began to degenerate within 18 h of culture. In UECs, expression of necroptosis effectors, such as RIPK1, RIPK3, and MLKL were first confirmed. UECs responded to a stimulus to activate necroptosis and showed increased cell death. Conclusions Tsg101 deficiency in the uterine epithelium causes implantation failure, which may be caused by epithelial defects. This study provides evidence that UECs harbor a necroptotic machinery that responds to death-inducing signals. Thus, Tsg101 expression in the uterine epithelium is required for normal pregnancy in mice.

Early Crypt Formation Defects in the Uterine Epithelia of Sox17 Heterozygous Mice

SOX17 activity in the uterine epithelium is essential for the implantation of mouse embryos. Previously, we demonstrated that female Sox17 heterozygous mutant mice are subfertile, and 2 active copies of Sox17 are required for the proper implantation of mouse embryos. To understand which implantation step is most sensitive to the Sox17 gene dosage, we comprehensively investigated the phenotypes and RNA transcriptomes of Sox17 heterozygous mutant mice. Uterine Sox17 expression drastically changed according to estrous cycle and during early pregnancy. The highest Sox17 expression was observed during the receptive period for blastocyst implantation. Sox17 heterozygous uterine epithelia showed ectopic high-level expression of SOX9, another SOX factor that is normally expressed in the uterine gland. Three-dimensional analysis of the uterus on day 5 of pregnancy revealed no crypt formation near the healthy blastocysts in the Sox17 heterozygous uterine epithelium, suggesting that early defects in embryo homing had occurred. Global transcriptional analysis revealed that the expression of Amphiregulin (Areg), a gene encoding a heparin-binding epidermal growth factor receptor ligand, was decreased drastically in Sox17+/− uterine epithelia. These data imply that full Sox17 activity is required to promote early crypt formation through proper regulation of SOX9 and AREG expression at the implantation site.

Tumor Susceptibility Gene 101 Is Required for the Maintenance of Uterine Epithelial Cells During Embryo Implantation

Background: The tumor susceptibility gene 101 (Tsg101), a component of the endosomal sorting complex required for transport (ESCRT) complex I, is involved in multiple biological processes involving endomembranous structures and the plasma membrane. The role of Tsg101 in the uterine epithelium was investigated in Tsg101 floxed mice crossed with Lactoferrin-iCre mice (Tsg101d/d).Methods: Tsg101d/d mice were bred with stud male mice and the status of pregnancy was examined on days 4 and 6. Histological analyses were performed to examine the uterine architecture. Immunofluorescence staining of several markers was examined by confocal microscopy. Uterine epithelial cells (UECs) were isolated from Tsg101f/f and Tsg101d/d mice, and the expression of necroptosis effectors was examined by RT-PCR, western blotting, and immunofluorescence staining. UECs were also subjected to RNA expression profiling.Results: Tsg101d/d female mice were subfertile with implantation failure, showing unattached blastocysts on day 6 of pregnancy. Histological and marker analyses revealed that some Tsg101d/d day 4 pregnant uteri showed a disintegrated uterine epithelial structure. Tsg101d/d UECs began to degenerate within 18 h of culture. In UECs, expression of necroptosis effectors, such as RIPK1, RIPK3, and MLKL were first confirmed. UECs responded to a stimulus to activate necroptosis and showed increased cell death. Conclusions: Tsg101 deficiency in the uterine epithelium causes implantation failure, which accompanies epithelial defects. This study provides evidence that UECs harbor a necroptotic machinery that responds to death-inducing signals. Thus, Tsg101 expression in the uterine epithelium is required for normal pregnancy in mice.

Mertens. Beiträge zur normalen und pathalogischen Anatomie der menschlichen Placenta. (Zeitsch. F. Geb. und Gyn., XXX Bd., Hft. 1 and XXXI Bd., Hft. 1). About normal and pathological anatomy of the human placenta

After detailed literary studies on comparative anatomy and based on the preparation of a very young human egg, the author resolves the controversial issue of the nature and origin of the cover of chiral villi in the following way. In humans, as in other animals, the cover of chorial villi of the dancer consists of two layers, one cellular layer originating from the embryo (ectoderm) and the other protoplasmic, which is a modified uterine epithelium (syncytium). Already at the beginning of the insertion of the egg, both of these layers are so tightly interconnected that they form, as it were, one tissue layer, on which it is not difficult, however, to distinguish its initial constituent elements.

Author Correction: Menopause-induced uterine epithelium atrophy results from arachidonic acid/prostaglandin E2 axis inhibition-mediated autophagic cell death

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

ERα-dependent stimulation of LCN2 in uterine epithelium during mouse early pregnancy

Maintenance of a suitable uterine milieu is important for embryo development and subsequent implantation during early pregnancy. High estrogen level in proestrous and estrous stages is essential for uterine anti-bacterial activity during preimplantation period. Lipocalin-2 is an essential molecule which prevents bacterial infection by sequestering iron. In this study, the highest expression of lipocalin-2 is observed in the endometrial epithelium on day 1 of normal pregnancy and pseudopregnancy, which exhibit a similar hormone scenario. By injecting the agonists for estrogen receptor α and estrogen receptor β in ovariectomized mice, we found estrogen receptor α is the dominant member for estrogen regulation on lipocalin-2 expression. Estrogen treatment in estrogen receptor α-knockout mice further confirmed the role of estrogen receptor α. Using published data from whole-genome estrogen receptor α binding site assay, significant estrogen receptor α recruitment peaks are found at the downstream of lipocalin-2 gene after estrogen treatment. Furthermore, to study the anti-bacterial activity of lipocalin-2 in uterus, Escherichia coli is injected to mimic bacterial infection. Our results showed an obvious induction of lipocalin-2 in Escherichia coli-treated group. Taken together, this study indicates estrogen regulation of lipocalin-2 in uterine epithelium is mediated by estrogen receptor α, and lipocalin-2 may have anti-bacterial activity during early pregnancy.

Production of Hyaluronan by the Trophectoderm is a Prerequisite for Mouse Blastocyst Attachment

Embryo implantation requires execution of highly synchronized processes at the feto-maternal interface, initiated by blastocyst attachment to the endometrial epithelium. Hyaluronan is a major ECM component known to regulate adhesion-associated biological processes in various physiological settings. We hypothesized that hyaluronan may facilitate blastocyst attachment. In order to test our hypothesis, we characterized the blastocyst expression of hyaluronan synthesizing and degrading enzymes, as well as the expression of hyaluronan receptors during attachment. The functional impact of hyaluronan was challenged by the use of mouse transgenic blastocysts, in which genes encoding for hyaluronan synthesizing enzymes were deleted using lentiviral incorporation of Cas-9 endonuclease alongside specific short-guide RNAs into the embryonic trophectoderm. Embryos with transgenic trophectoderm were tested for their attachment in vitro, or assessed for implantation in vivo, upon transfer to foster dams. Deletion of the trophectoderm hyaluronan biosynthesis significantly reduced the number of blastocysts attached to human uterine epithelium cells in vitro. Reduced attachment was also observed in vivo, in pregnant mice carrying blastocysts with hyaluronan-depleted trophectoderm. In agreement, trophectoderm expression of osteopontin, was downregulated upon depletion of hyaluronan. MRI measurements revealed a decrease in uterine blood vessels permeability. Uterine expression of VEGF-A, PTGS-2 and uterine osteopontin, which constitute the immediate response to blastocyst attachment was also reduced. Furthermore, impaired implantation, associated with a decrease in hyaluronan synthesis in the mural trophectoderm, obtained upon tamoxifen treatment, has been recovered by LIF administration. These results demonstrate that estrogen-regulated hyaluronan-synthesis in the trophectoderm is indispensable for mouse blastocysts attachment to the uterine epithelium.