Do progesterone receptor membrane components (PGRMC)s play a role in the chorions refractoriness to epithelial-to-mesenchymal transition (EMT)?

Fetal membrane inflammation is one of the drivers of adverse pregnancy outcomes. One of the reported pathways of inflammation is epithelial-mesenchymal transition (EMT) of amniotic epithelial cells. EMT is resisted during gestation via signaling initiated by the binding of progesterone (P4) to progesterone receptor membrane components (PGRMC1/PGRMC2).

Fetal microchimeric cells influence maternal lung health following term and preterm births.

Fetal microchimerism, the presence of fetal cells in maternal tissues, has garnered interest for its potential role in maternal physiology. In this study, we aimed to explore the impact of fetal microchimeric cells on maternal lung health following term and preterm delivery, particularly in the context of infection-induced preterm birth and subsequent allergic challenges. We characterized the immune cells in maternal lungs using a transgenic mouse model (mT+ Ve, Td Tomato) and high dimensional mass cytometry (CyTOF) techniques.

PGRMC2 and HLA-G regulate immune homeostasis in a microphysiological model of human maternal-fetal membrane interface.

Chorion trophoblasts (CTCs) and immune cell-enriched decidua (DECs) comprise the maternal-fetal membrane interface called the chorio-decidual interface (CDi) which constantly gets exposed to maternal stressors without leading to labor activation. This study explored how CTCs act as a barrier at CDi. The roles of human leukocyte antigen (HLA)-G and progesterone receptor membrane component 2 (PGRMC2) in mediating immune homeostasis were also investigated.

Culture and Maintenance of Immune Cells to Model Innate Immune Status at the Feto-maternal Interface.

The inflammatory process leading to human labor is mostly facilitated by immune cells, which can be studied by isolating and characterizing primary immune cells from the feto-maternal interface. However, difficulty and inconsistency in sampling approaches of immune cells and short lifespan in vitro prevent their usage in mechanistic studies to understand the maternal-fetal immunobiology. To address these limitations, existing cell line models can be differentiated into immune-like cells for use in reproductive biology experiments.

Immune cells at the feto-maternal interface: Comprehensive characterization and insights into term labor.

Immune cells at the feto-maternal interface play an important role in pregnancy; starting at implantation, maintenance of pregnancy, and parturition. The role of decidual immune cells in induction of labor still needs to be understood. Published reports on this topic show heterogeneity in methods of cell isolation, assay, analysis and cellular characterization making it difficult to collate available information in order to understand the contribution of immune cells at term leading to parturition.