Regulatory role of human endometrial gland secretome on macrophage differentiation.

The human endometrial gland plays a vital role in maternal immune tolerance and placental development. Decidual macrophages are the major phagocytic cells that regulate tissue remodeling during pregnancy. This study examines the regulatory effect of endometrial gland secretome on macrophage polarization and functions using endometrial organoid. We demonstrated that endometrial organoids treated with hormones mimicking the environment of the secretory phase/early pregnancy polarize macrophages to acquire a decidua-like macrophage phenotype, including higher expressions of decidual macrophage markers, reduced phagocytic capacity and altered cytokine secretion. The results indicated that endometrial gland secretomes are critical for maintaining macrophage homeostasis at the maternal-fetal interface.

Placenta exosomal miRNA-30d-5p facilitates decidual macrophage polarization by targeting HDAC9.

Pregnancy involves a wide range of adaptations in the maternal body. Maternal immune tolerance toward the foreign fetus is critical for a successful pregnancy. Decidual macrophages are the primary antigen-presenting and phagocytic cells responsible for antigen presentation and apoptotic cell removal. Their phenotype changes dynamically during pregnancy. Placenta-derived exosomes are small vesicles carrying active biological molecules such as microRNAs, proteins, and lipids. The placenta-derived exosomes have been implicated in endothelial cell activation, smooth muscle cell migration, and T-cell apoptosis, but it is unknown whether placenta-derived exosomes would affect the development and functions of decidual macrophages. In this study, we reported that placenta-derived exosomes stimulated macrophage polarization into alternatively activated (M2) macrophages. Mechanistically, miRNA-30d-5p from the placenta-derived exosomes induced macrophage polarization to the M2 phenotype by targeting histone deacetylase 9. Furthermore, the conditioned medium of placenta-derived exosome-treated macrophages promoted trophoblast migration and invasion. By contrast, the conditioned medium impaired the ability of endothelial cell tube formation and migration. Placenta-derived exosome-treated macrophages had no impact on T-cell proliferation. Together, we demonstrated that placenta-derived exosomes polarize macrophages to acquire a decidua-like macrophage phenotype to modulate trophoblast and endothelial cell functions.

Human placental exosomes induce maternal systemic immune tolerance by reprogramming circulating monocytes.

BACKGROUND: The maternal immune system needs to tolerate the semi-allogeneic fetus in pregnancy. The adaptation occurs locally at the maternal-fetal interface as well as systemically through the maternal circulation. Failure to tolerate the paternal antigens may result in pregnancy complications, such as pregnancy loss and pre-eclampsia. However, the mechanism that regulates maternal immune tolerance, especially at the systemic level, is still an enigma. Here we report that the first-trimester placenta-derived exosomes (pEXOs) contribute to maternal immune tolerance by reprogramming the circulating monocytes. RESULTS: pEXOs predominantly target monocytes and pEXO-educated monocytes exhibit an immunosuppressive phenotype as demonstrated by reduced expression of marker genes for monocyte activation, T-cell activation and antigen-process/presentation at the transcriptomic level. They also have a greater propensity towards M2 polarization when compared to the monocytes without pEXO treatment. The inclusion of pEXOs in a monocyte-T-cell coculture model significantly reduces proliferation of the T helper cells and cytotoxic T cells and elevates the expansion of regulatory T cells. By integrating the microRNAome of pEXO and the transcriptomes of pEXO-educated monocytes as well as various immune cell functional assays, we demonstrate that the pEXO-derived microRNA miR-29a-3p promotes the expression of programmed cell death ligand-1, a well-known surface receptor that suppresses the adaptive immune system, by down-regulation of phosphatase and tensin homolog in monocytes. CONCLUSIONS: This is the first report to show how human pEXO directly regulates monocyte functions and its molecular mechanism during early pregnancy. The results uncover the importance of pEXO in regulating the maternal systemic immune response during early pregnancy by reprogramming circulating monocytes. The study provides the basis for understanding the regulation of maternal immune tolerance to the fetal allograft.

Placenta-Derived Exosomes as a Modulator in Maternal Immune Tolerance During Pregnancy.

Exosomes are a subset of extracellular vesicles with an average diameter of ~100nm. Exosomes are released by all cells through an endosome-dependent pathway and carry nucleic acids, proteins, lipids, cytokines and metabolites, mirroring the state of the originating cells. The function of exosomes has been implicated in various reproduction processes, such as embryo development, implantation, decidualization and placentation. Placenta-derived exosomes (pEXO) can be detected in the maternal blood as early as 6 weeks after conception and their levels increase with gestational age. Importantly, alternations in the molecular signatures of pEXO are observed in pregnancy-related complications. Thus, these differentially expressed molecules could be the potential biomarkers for diagnosis of the pregnancy-associated diseases. Recent studies have demonstrated that pEXO play a key role in the establishment of maternal immune tolerance, which is critical for a successful pregnancy. To gain a better understanding of the underlying mechanism, we highlighted the advanced studies of pEXO on immune cells in pregnancy.