Endometrial adhesion G protein-coupled receptors are dynamically expressed across the menstrual cycle and expression is altered by ovarian stimulation

Ovarian stimulation (OS), utilized for the development of multiple ovarian follicles for IVF, induces supraphysiologic levels of E2 and an early rise in P4 that disrupt endometrial differentiation and decreases implantation rates or result in placental insufficiency and pregnancy complications. To improve pregnancy rates and reduce the risk of pregnancy complications associated with IVF, it is crucial to advance our molecular understanding of the molecular regulation of endometrial differentiation. Previous studies from our laboratory suggest G protein-coupled receptors (GPCRs) are important regulators of endometrial differentiation. To investigate this further, using a retrospective dataset, we identified all GPCRs expressed across the proliferative and secretory phase of the menstrual cycle and found that many members of the adhesion G protein-coupled receptor (ADGR) family are dynamically expressed. For each ADGR subfamily exhibiting differentially-expressed genes across the cycle, their expression was investigated by RT-PCR in the non-pregnant mouse uterus and decidua on E7.5 of pregnancy. For those genes expressed in the E7.5 decidua, their expression was further quantified by qPCR across early mouse pregnancy. The RT-PCR screen revealed expression of 13 ADGRs (4 of the 9 subfamilies) in E7.5 decidua and among these genes, many were differentially expressed between E0.5 and E5.5 or 6.5 and between E5.5 and E6.5. The dynamic expression of the ADGRs across the menstrual cycle and in early mouse pregnancy, suggests these ADGRs are E2- and/or P4-regulated genes. We therefore hypothesized that for these ADGR genes, mRNA expression would be disrupted in an OS cycle. This hypothesis was tested on endometrial biopsies collected in the secretory phase from prospective cohorts of women in natural and OS cycles. Consistent with the retrospective dataset, our data revealed that members of the ADGR gene family are expressed in the secretory phase of the natural menstrual cycle and for the first time, we show that their expression is altered by ovarian stimulation.