Project description:Bone marrow (BM)-derived progenitor cells (BMDPCs) are known to migrate and give rise to endometrial cells however their functional contribution to implantation and pregnancy are unknown . Here we show that implantation and pregnancy are strong stimuli for BMDPCs recruitment to the uterine decidua where BMDPCs differentiate into functional non-hematopoietic prolactin-producing decidual cells. Transcriptome analysis of implantation sites demonstrated that Hoxa11+/- mice transplanted with WT BM clustered hierarchically more closely with normal WT mice than with control Hoxa11+/- mice, showing normalized expression of numerous implantation-related genes. These findings reveal that BMDPCs have a major non-hematopoietic physiologic contribution to the decidual stroma, and thereby play an essential and previously unproven role in the establishment and maintenance of pregnancy.

Project description:Endometrial decidualization connecting embryo implantation and placentation is transient, but essential for successful pregnancy, which however is not systematically investigated. Here, by using a novel single-cell spatial transcriptomic profiling technology (scStereo-seq), we were able to visualize and define key and dynamic functional decidual hubs assembled by distinct immune, endothelial, trophoblast and decidual stromal cells (DSCs) during early pregnancy in mice. We classified DSC subclusters and described their transdifferentiation trajectory controlled by transcription factor cascades. Interestingly, we discovered a novel type of DSCs expressing immune cell-specific genes, termed immune DSCs (iDSCs). Whereas immature DSCs attracted immune cells and induced decidual angiogenesis at the mesenchymal-to-epithelial transition (MET) hub during decidualization initiation, iDSCs enabled immune cell recruitment, angiogenesis facilitation and cytotoxic effect induction to form immune cell assembling and angiogenesis hubs, which eventually allow decidual homeostasis maintenance and decidualization-to-placentation transition. We spatiotemporally decode mouse early pregnancy events controlled by immune DSCs.

Project description:Endometrial decidualization connecting embryo implantation and placentation is transient, but essential for successful pregnancy, which however is not systematically investigated. Here, by using a novel single-cell spatial transcriptomic profiling technology (scStereo-seq), we were able to visualize and define key and dynamic functional decidual hubs assembled by distinct immune, endothelial, trophoblast and decidual stromal cells (DSCs) during early pregnancy in mice. We classified DSC subclusters and described their transdifferentiation trajectory controlled by transcription factor cascades. Interestingly, we discovered a novel type of DSCs expressing immune cell-specific genes, termed immune DSCs (iDSCs). Whereas immature DSCs attracted immune cells and induced decidual angiogenesis at the mesenchymal-to-epithelial transition (MET) hub during decidualization initiation, iDSCs enabled immune cell recruitment, angiogenesis facilitation and cytotoxic effect induction to form immune cell assembling and angiogenesis hubs, which eventually allow decidual homeostasis maintenance and decidualization-to-placentation transition. We spatiotemporally decode mouse early pregnancy events controlled by immune DSCs.

Project description:Proper decidualization is a critical determinant of pregnancy success. Deficiencies in decidualization are associated with a variety of pregnancy disorders, including female infertility, recurrent implantation failure, and miscarriage. However, the mechanism for triggering decidualization of human endometrium is largely unknown. Here we characterized the transcriptomes of four major cells in human endometrium and decidua at single-cell resolution. We discovered the dynamic change characteristics of six major stromal cells. More importantly, a dialogue between IGF1+ stromal cells and IGF1R+ stromal cells initiates endometrial decidualization under regulation of progesterone and estrogen, and IL1B+ stromal cells trigger the apoptosis of epithelial cells and functional remodeling during decidualization. We defined a unique AREG+ NK cell for accelerating decidualization by interacting with IGF1+ stromal cells, and observed that extravillous trophoblasts promote decidualization possibly by multiply pathways. Additionally, we developed a systematic repository of cell-cell communication for decidualization via the ligand-receptor complexes interactions. Our study provides deeper insights into the molecular and cellular characterizations during decidualization.

Project description:Endometrial decidualization connecting embryo implantation and placentation is transient but essential for successful pregnancy, which, however, is not systematically investigated. Here, we use a scStereo-seq technology to spatially visualize and define the dynamic functional decidual hubs assembled by distinct immune, endothelial, trophoblast, and decidual stromal cells (DSCs) in early pregnant mice. We unravel the DSC transdifferentiation trajectory and surprisingly discover a dual-featured type of immune-featured DSCs (iDSCs). We find that immature DSCs attract immune cells and induce decidual angiogenesis at the mesenchymalepithelial transition hub during decidualization initiation. iDSCs enable immune cell recruitment and suppression, govern vascularization, and promote cytolysis at immune cell assembling and vascular hubs, respectively, to establish decidual homeostasis at a later stage. Interestingly, dysfunctional and spatially disordered iDSCs cause abnormal accumulation of immune cells in the vascular hub, which disrupts decidual hub specification and eventually leads to pregnancy complications in DBA/2-mated CBA/J mice.

Project description:In preeclampsia (PE), cytotrophoblast (CTB) invasion of the uterus and spiral arteries is often shallow. Thus, the placenta’s role has been a focus. We hypothesized that decidual defects are an important determinant of the placental phenotype. We isolated (human) endometrial stromal cells (hESCs) from non-pregnant donors with a prior pregnancy that was complicated by severe PE (sPE). Versus controls, they failed to decidualize as demonstrated by morphological criteria and the analysis of stage-specific antigens. These results were bolstered by showing that they were transcriptionally inert. Additionally, we used laser microdissection to isolate the decidua from tissue sections of the maternal-fetal interface. Transcriptional profiling revealed sPE-associated defects in gene expression. Also, decidual cells from sPE patients, which de-differentiated in vitro, failed to re-decidualize in culture. Immediately following isolation they released factors that inhibited CTB invasion, linking a possible cause to a known effect. These data suggested that failed decidualization is an important contributor to down regulated CTB invasion in sPE. Diagnosis of this defect prior to pregnancy would enable therapies that are designed to improve decidualization, a novel strategy for prevention.

Project description:Uterine receptivity implies a dialogue between the hormonally primed maternal endometrium and the free-floating blastocyst. Endometrial stromal cells proliferate, avert apoptosis, and undergo decidualization in preparation for implantation; however, the molecular mechanisms that underlie differentiation into the decidual phenotype remain largely undefined. The Notch family of transmembrane receptors transduce extracellular signals responsible for cell survival, cell-to-cell communication, and trans-differentiation, all fundamental processes for decidualization and pregnancy. Using a murine artificial decidualization model, pharmacological inhibition of Notch signaling by gamma-secretase inhibition resulted in significantly decreased deciduoma. Furthermore, a progesterone receptor (PR)-Cre Notch1 bigenic (Notch1d/d) confirmed a Notch1-dependant hypomorphic decidual phenotype. Microarray and pathway analysis, following Notch1 ablation, demonstrated significantly altered signaling repertoire. Concomitantly, hierarchical clustering demonstrated Notch1-dependent differences in gene expression. Uteri deprived of Notch1 signaling demonstrated decreased cellular proliferation; namely, reduced proliferation-specific antigen, Ki67, altered p21, cdk6, and cyclinD activity, and increased apoptotic-profile, augmented cleaved caspase-3, Bad, and attenuated Bcl2. Demonstrated here, the pre-implantation uterus relies on Notch signaling to inhibit apoptosis of stromal fibroblasts and regulate cell cycle progression, which together promotes successful decidualization. In summary, Notch1 signaling modulates multiple signaling mechanisms crucial for decidualization and we provide greater perspective to the coordination of multiple signaling modalities required during decidualization RNA samples from 3-5 separate mice were extracted. All mRNA quantities were normalized against 18S gene expression. Gene expression levels were measured by real-time RT-PCR SYBR Green analysis using the ABI Prism 7700 Sequence Detector System according to manufacturer’s instructions (Applied Biosystems).

Project description:The pregnant decidua is infiltrated by many immune cells which are thought to originate in the bone marrow (BM) promoting pregnancy. CXCR4 is a key regulator of the development of NK cells and dendritic cells, both of which play an important role in early placental development and immune tolerance at the maternal-fetal interface. However, the role of CXCR4 in pregnancy is not well understood. To generate tamoxifen-inducible CXCR4 knockout mice, we used the Cre/LoxP tamoxifen-inducible system. For animal experiments, Cre+/CXCR4fl/fl mice and their Cre-/CXCR4fl/fl littermates were used. After tamoxifen treatment, we refer to Cre-/CXCR4fl/wt mice as WT (wild type), and Cre+/CXCR4fl/null mice as CXCR4 KO (knockout). For adoptive bone marrow transplant (BMT) experiments, BMT was performed from either WT GFP transgenic male donor mice into WT or CXCR4 KO females, or from CXCR4 KO male donors into CXCR4 KO females as negative control. Collectively, our study found an important role for maternal CXCR4 expression in immune cell function, placental development and pregnancy maintenance.

Project description:Pausing of RNA polymerase II (Pol II) during early transcription, mediated by the negative elongation factor (NELF) complex, allows cells to coordinate and appropriately respond to signals by modulating the rate of transcriptional pause release. Promoter proximal enrichment of Pol II occurs at uterine genes relevant to reproductive biology; thus, we hypothesized that pausing might impact endometrial response by coordinating hormonal signals involved in establishing and maintaining pregnancy.We deleted the NELF-B subunit in themouse uterus using PgrCre (NELF-B UtcKO).Resulting females were infertile.Uterine response to the initial decidual stimulus of NELF-B UtcKOwas similar to that of control mice; however, subsequent full decidual response was not observed. Cultured NELF-B UtcKO stromal cells exhibited perturbances in extracellular matrix components and also expressed elevated levels of the decidual prolactin Prl8a2, as well as altered levels of transcripts encoding enzymes involved in prostaglandin synthesis and metabolism. Because endometrial stromal cell decidualization is also critical to human reproductive health and fertility, we used small interfering to suppressNELF-B or NELF-E subunits in cultured human endometrial stromal cells, which inhibited decidualization, as reflected by the impaired induction of decidual markers PRL and IGFBP1. Overall, our study indicatesNELF-mediated pausing is essential to coordinate endometrial responses and that disruption impairs uterine decidual development during pregnancy.

Project description:Transforming growth factor β (TGFβ) signaling regulates multifaceted reproductive processes via its transmembrane receptor complex-associated machinery. It has been shown that the type 1 receptor of TGFβ (TGFBR1) is indispensable for female reproductive tract development, pregnancy success, and fertility. However, the role of TGFβ signaling in decidual development and function remains poorly defined. Our objective is to determine the impact of uterine-specific deletion of Tgfbr1 on the differentiation of endometrial stromal cells in pregnant mice, with a focus on the cellular and molecular properties of the decidua. An approach combining histological and immunohistochemical analyses, quantitative PCR, western blot, and RNA-sequencing was utilized. Our results show that decidual development is altered in TGFBR1 conditionally depleted uteri, substantiated by downregulation of genes associated with inflammatory response and uterine natural killer cell abundance, reduced presence of non-decidualized fibroblasts in the antimesometrial region, and impaired decidual cell differentiation. Notably, conditional ablation of TGFBR1 results in the formation of decidua containing more abundant alpha smooth muscle actin (ACTA2)-positive cells at the peripheral region of the antimesometrial side versus controls. This finding is corroborated by upregulation of a subset of smooth muscle marker genes in Tgfbr1 conditionally-deleted decidua. The abnormal cell differentiation is accompanied with increased cell proliferation and enhanced decidual ERK1/2 signaling upon decidual regression. In summary, this study has identified an important role of TGFBR1 in decidual cell differentiation by revealing that conditional ablation of TGFBR1 in the uterus profoundly impacts the cellular and molecular properties of the decidua. Our results suggest that TGFBR1 is required for the development of an integral decidua, a transient but crucial structure that supports embryo development.