Uterine endometrial differentiation is essential for developmental continuity and female health. A convenient in vitro model mimicking the physiological status is needed to effectively evaluate implantation and uterine response mechanisms. Thus, we developed a promising in vitro model, the FSS (FSH mimic-stimulated synchronized) model, by using primary mouse uterine stromal cells (mUSCs) obtained from equine chorionic gonadotropin (eCG)-primed mice. These mUSCs could be differentiated into decidualized cells with 17 beta-estradiol (E2) and progesterone (P4). The pregnancy day 4 (PD4) model, in which mUSCs are obtained at day 4 of pregnancy, was used as a control. The cell shape index and polyploidy rates were similar between the two models. The staining intensities of lipids and glycogen were significantly higher in the induced groups in both models but stronger in the FSS model than in the PD4 model. The expression levels of AP-TNAP, cathepsin L, Prl8a2, Gja1, Cebpb, and Igfbp1 were increased at 24 h after decidual induction. PR-alpha and PR-beta levels were also increased at 24 h after decidual induction in both models. These results indicate that the FSS model provides a convenient method for obtaining USCs that are usable for various experimental approaches due to their physiological competence and flexibility for triggering induction. This may serve as a model system for the study of pathogeneses originating from the endometrium or communication with other tissues and lead to a better understanding of embryo implantation mechanisms. Furthermore, the results of this study will be integral for further refinements of 3D uterine culture manipulation techniques.

Summary Sentence

An artificial in vitro decidual induction model with physiologically competent stromal cells is presented to facilitate experimental designs. This will help deepen the study of embryo implantation and aid in exploration of the causes of implantation-related diseases.

Graphical Abstract