Project description:The upper Müllerian duct (MD) is patterned and specified into two morphologically and functionally distinct organs, the oviduct and uterus. It is known that this regionalization process is instructed by inductive signals from the adjacent mesenchyme. However, the interaction landscape between epithelium and mesenchyme during upper MD development remains largely unknown. Here, we performed single-cell transcriptomic profiling of mouse neonatal oviducts and uteri at the initiation of MD epithelial differentiation (postnatal day 3). We identified major cell types including epithelium, mesenchyme, pericytes, mesothelium, endothelium, and immune cells in both organs with established markers. Moreover, we uncovered region-specific epithelial and mesenchymal subpopulations and then deduced region-specific ligand-receptor pairs mediating mesenchymal-epithelial interactions along the craniocaudal axis. Unexpectedly, we discovered a mesenchymal subpopulation marked by neurofilaments with specific localizations at the mesometrial pole of both the neonatal oviduct and uterus. Lastly, we analyzed and revealed organ-specific signature genes of pericytes and mesothelial cells. Taken together, our study enriches our knowledge of upper Müllerian duct development, and provides a manageable list of potential genes, pathways, and region-specific cell subtypes for future functional studies.

Project description:This file contains a 136-node modular Boolean network model of EMT triggered by biomechanical and growth signaling crosstalk, linked to a published network of epithelial contact inhibition, proliferation, and apoptosis (MODEL2006170001). This model reproduces the ability of the core EMT transcriptional network to maintain distinct epithelial, hybrid E/M and mesenchymal states, as well as EMT driven by mitogens such as EGF on stiff ECM. We also reproduce the observed lack of stepwise MET, in that our model's dynamics does not pass through the hybrid E/M state during MET. We show that in the absence of strong autocrine signals such as TGFβ (not included in this version), cells cannot maintain their mesenchymal state in the absence of mitogens, on softer matrices, or at high cell density.

Project description:This model is an expansion of the Regan2022 - Mechanosensitive EMT model (MODEL2208050001); it includes a TGFβ signaling module and autocrine signaling in mesenchymal cells. The expanded 150-node (630 link) modular model undergoes EMT triggered by biomechanical and growth signaling crosstalk, or by TGFβ. As its predecessor, this model also reproduces the ability of the core EMT transcriptional network to maintain distinct epithelial, hybrid E/M and mesenchymal states, as well as EMT driven by mitogens such as EGF on stiff ECM. We also reproduce the observed lack of stepwise MET, in that our model's dynamics does not pass through the hybrid E/M state during MET. We show that in the absence of strong autocrine signals such as TGFβ (not included in this version), cells cannot maintain their mesenchymal state in the absence of mitogens, on softer matrices, or at high cell density. In contrast, potent autocrine signaling can stabilize the mesenchymal state in all but very dense monolayers on soft ECM. This expanded model also reproduces the inhibitory effects of TGFβ on proliferation and anoikis resistance in mesenchymal cells, as well as its ability to trigger apoptosis on soft ECM vs. EMT on stiff matrices. The model offers several experimentally testable predictions related to the effect of neighbors on partial vs. full EMT, the tug of war between mitosis and the maintenance of migratory hybrid E/M states, as well as cell cycle defects in dynamic, heterogeneous populations of epithelial, hybrid E/M and mesenchymal cells.

Project description:Tumor hypoxia is relevant for tumor growth, metabolism and epithelial-to-mesenchymal transition (EMT). We report that hyperbaric oxygen (HBO) treatment induced mesenchymal-to-epithelial transition (MET) in a dimetyl-α-benzantracene induced mammary rat adenocarcinoma model, and the MET was associated with extensive coordinated gene expression changes and less aggressive tumors. One group of tumor bearing rats was exposed to HBO (2 bar, pO2 = 2 bar, 4 exposures à 90 minutes), whereas the control group was housed under normal atmosphere (1 bar, pO2 = 0.2 bar). Treatment effects were determined by assessment of tumor growth, tumor vascularisation, tumor cell proliferation, cell death, collagen fibrils and gene expression profile. Tumor growth was significantly reduced (~16%) after HBO treatment compared to day 1 levels, whereas control tumors increased almost 100 % in volume. Significant decreases in tumor cell proliferation, tumor blood vessels and collagen fibrils, together with an increase in cell death, are consistent with tumor growth reduction and tumor stroma influence after hyperoxic treatment. Gene expression profiling showed that HBO induced MET with coordinated expression of gene modules involved in cell junctions and attachments together with a shift towards non-tumorigenic metabolism. This leads to more differentiated and less aggressive tumors, and indicates that oxygen per se might be an important factor in the â??switchesâ?? of EMT and MET in vivo. HBO treatment also attenuated tumor growth and changed tumor stroma, by targeting the vascular system, having anti-proliferative and pro-apoptotic effects.

Project description:We profile the transcriptomes of over 20,000 mouse single cells, yielding molecular definitions for mesenchymal and epithelial cell types present in the mouse uterus during post-menstrual tissue repair. We identify a novel population of fibroblasts that express genetic markers associated with both mesenchymal and epithelial phenotypes in the repairing mouse uterus. Further trajectory analysis indictates a differentiation trajectory between mesenchymal and epithelial cells indicative of a putative mesenchymal-to-epithelial transition (MET) event occuring during post-menstrual tissue repair. Our work provides a platform to further understand the roles of these cell populations in uterine physiology and disease and for comparisons between wound healing events in the endometrium and other adult tissue which are prone to fibrosis.

Project description:In postpartum dairy cows, subclinical endometritis (SCE) is characterized by persistent endometrial inflammation, which exerts profound detrimental effects on subsequent reproductive performance. So far, transcriptomic studies related to this condition were either based on biopsy-derived whole endometrium tissue or endometrial swab/cytobrush samples, thus neglecting cell type-specific variations in gene expression. This study tested the hypothesis that different endometrial health statuses are associated with distinct transcription profiles of endometrial stromal, glandular and luminal epithelial cells. In conclusion, this study evidences that endometrial inflammation recovery or persistence is associated with gene expression patterns involved in immune function, tissue remodelling, and uterine receptivity in a cell type-specific manner. Identifying these signatures may prove instrumental to developing novel diagnostic and therapeutic targets, either to prevent persistence or speed recovery from endometrial inflammation, thus restoring the fertility of postpartum dairy cows.

Project description:Aberrant epithelial regeneration and immune remodeling are hallmarks of chronic lung diseases such as idiopathic pulmonary fibrosis (IPF), COPD, and post-viral syndromes. Yet how cellular context shapes these trajectories remains unresolved. We present a tunable, primary rat-derived lung organoid model that systematically varies immune, epithelial, and mesenchymal inputs to reveal how composition alone dictates epithelial plasticity and macrophage polarization. Across conditions, we observed the spontaneous emergence of disease-relevant transitional cell states, including Sox9⁺ stressed progenitors, RAS/AT0-like intermediates, and hillock-like cells, alongside distinct macrophage activation profiles. In mesenchyme-rich contexts, epithelial, immune, and mesenchymal crosstalk appeared to reinforce inflammatory signaling and stabilize transitional persistence, while immune-dominant inputs favored ATI-like repair and squamous remodeling. Notably, hillock-like cells displayed context-specific polarization and expressed immune-regulatory genes, suggesting a role as epithelial orchestrators that help calibrate inflammatory response during regeneration. Connectomic analysis revealed that regenerative outcomes were associated with dynamic multicellular signaling networks that integrate stress sensing, immune coordination, and epithelial fate. This platform provides a tractable system for modeling context-specific repair and regenerative mechanisms and could inform therapeutic strategies aimed at redirecting epithelial fate in chronic lung disease.

Project description:This SuperSeries is composed of the following subset Series: GSE29435: Progesterone inhibits epithelial-to-mesenchymal transition in endometrial cancer: cell line data GSE29436: Progesterone inhibits epithelial-to-mesenchymal transition in endometrial cancer: patient data Refer to individual Series

Project description:Mesenchymal-epithelial transition serves to transiently restore the endometrial epithelium in postpartum murine uterine regeneration

Project description:Extensive trauma disrupts endometrial regeneration by diminishing endometrial stem or progenitor cells. Endometrial epithelial organoids (EEOs) are used for endometrial regeneration. However, how EEOs repair injured endometrial tissues and their advantages over bone marrow mesenchymal stem cells (BMSCs) are unclear. This study explored whether EEOs surpass BMSCs to repair injured endometrium and examined whether endometrial restoration involves integrating EEOs into the endometrial tissue of the recipient. Rat EEOs (rEEOs) mimicking the features of the rat endometrium were developed. An endometrial injury rat model was used to compare the effects of rEEOs and rat BMSCs (rBMSCs) on endometrial regeneration and reproductive recovery. Bulk RNA-sequencing analysis was conducted to investigate the capacity of rEEOs for endometrial regeneration and identify discrepancies between rEEOs and rBMSCs. Green fluorescent protein (GFP)-labeled rEEOs or red fluorescent protein-labeled rBMSCs were transplanted to track the transplanted cells in vivo. Fertility recovery in rats transplanted with rEEOs was more comparable to that of normal rats than in rBMSC-treated rats. rEEOs had a high concentration of endometrial epithelial stem or progenitor cells and secreted vascular endothelial growth factor-A to promote endometrial neovascularization. Cells from GFP-labeled rEEOs integrated and differentiated into functional glands within the injured endometrium. Transplanting EEOs restored the morphology and function of severe endometrial injury better than BMSC transplantation. EEO cells repair the endometrium by differentiating into functional glandular epithelial cells. These findings offer preclinical evidence supporting in vitro expansion and transplanting of EEOs as promising approaches to restore fertility in women with insufficient endometrial regeneration.