The successful establishment and maintenance of pregnancy is achieved by well-coordinated interactions between the maternal uterus and the implanting conceptus. In pigs, the conceptus undergoes dramatic morphological and functional changes, and secretes various biological products such as estrogens and cytokines, interleukin-1beta (IL1B), interferon-gamma (IFNG), and IFN-delta (IFND) during the implantation period. The uterine endometrium in response to the conceptus-derived molecules and ovarian progesterone becomes receptive to the conceptus by changing cell adhesion molecule expression, epithelial cell depolarization and secretory activity. Conceptus-derived estrogen acts as the maternal pregnancy recognition signal which changes the direction of endometrial prostaglandin (PG) F2 secretion from the uterine vasculature into the uterine lumen. Estrogen also induces the expression of a variety of endometrial genes, including AKR1B1, FGF7, LPAR3, and SPP1. The function of cytokines, IL1B, IFNG, and IFND, in the endometrium is not fully understood, but some recent work shows that IL1B is involved in the synthesis and transport of endometrial PGs by regulating endometrial expression of PG-synthetic enzymes, PTGS1, PTGS2, and AKR1B1, and PG transporters, ABCC4 and SLCO2A1. Estrogen and IL1B also stimulate endometrial expression of IFN signaling molecules, suggesting that estrogen and IL1B act cooperatively on priming the endometrial function of conceptus IFNG and IFND. In turn, IFNG derived from the elongating conceptuses, induces many endometrial genes, including CXCL9, CXCL10, CXCL12, and SLA-DQ. The role of IFND at the maternal-conceptus interface is not well understood yet. Further analysis of the molecules derived from the endometrium and conceptus will provide insights into the cellular and molecular basis of maternal-conceptus interactions for the establishment of successful pregnancy in pigs.
The process of embryo implantation requires physical contact and physiological communication between the conceptus trophectoderm and the maternal uterine endometrium. During the peri-implantation period in pigs, the conceptus undergoes significant morphological changes and secretes estrogens, the signal for maternal recognition of pregnancy. Estrogens secreted from the conceptus act on uterine epithelia to redirect , luteolysin, secretion from the uterine vasculature to the uterine lumen to prevent luteolysis as well as to induce expression of endometrial genes that support implantation and conceptus development. In addition, conceptuses secrete cytokines, interferons, growth factors, and proteases, and in response to these signals, the uterine endometrium produces hormones, protease inhibitors, growth factors, transport proteins, adhesion molecules, lipid molecules, and calcium regulatory molecules. Coordinated interactions of these factors derived from the conceptus and the uterus play important roles in the process of implantation in pigs. To better understand mechanism of implantation process in pigs, this review provides information on signaling molecules at the conceptus-uterine interface during early pregnancy, including recently reported data reported.
Successful pregnancy requires well-coordinated interactions between the maternal uterus and the developing embryo in pigs. In pigs, implantation begins around Day 12 of pregnancy. During this period, conceptus undergoes a dramatic morphological change and secretes various factors such as estrogens, interleukin-1 beta (IL1B), and interferons. Estrogens produced by conceptuses act as the signal for maternal recognition of pregnancy, and the mechanism of estrogen action is explained by the endocrine and exocrine theory. The uterine endometrium becomes receptive to the conceptus by changing cell adhesion molecules, polarizing epithelial cells and increasing secretory activity. Some changes of uterine activity are affected by the ovarian hormone, progesterone, but the presence of conceptus in the uterus also induces changes of endometrial functions, including most importantly maternal recognition of pregnancy. Many factors, such as hormones, cytokines, enzymes, extracellular matrix proteins, and transport proteins are reported to be present at the maternal-fetal interface and function in the establishment of pregnancy in pigs. However, understanding of the cellular and molecular events occurring in the endometrium is not complete. In recent studies we made some progress on understanding of expression and function of genes involved in maternal-fetal interaction for the establishment and maintenance of pregnancy in the uterine endometrium in pigs. Firstly, we found that lysophosphatidic acid (LPA) was present at the maternal-and fetal interface at the time of implantation and LPA receptor 3 was uniquely expressed in the endometrium during early pregnancy. Secondly, we observed that salivary lipocalin (SAL1), a lipid-binding protein, was uniquely expressed in the uterine endometrium at the time of embryo implantation, and its expression was regulated by IL1B. Furthermore, expression of IL1B receptors are regulated by estrogen and IL1B, and IL1B functions in expression of genes related to prostaglandin synthesis and transport. Thirdly, we found that calcium regulatory molecules TRPV6 and S100G were dynamically regulated in the uterine endometrium during pregnancy, suggesting that regulation of calcium ion concentration may important for the embryo implantation and the maintenance of pregnancy. Finally, we observed that an MHC class II molecule, SLA-DQ, is expressed in the uterine endometrium at the time of conceptus implantation and its expression is essential for successful pregnancy, indicating that appropriate maternal-fetal immune interaction is required for the maintenance of pregnancy. Further analysis of these molecules will provide insights into the cellular and molecular basis of maternal-and fetal interaction during pregnancy in pigs.
Development of placenta is a complex process that is critical for the pregnancy and controlled by many factors including cytokines, hormones, growth factors and apoptotic molecules. Recently, it has been shown that progranulin (PGRN) functions in growth of embryo and trophectoderm as well as cell migration. To initiate understanding the role of PGRN in human placental development, we investigated the expression of PGRN mRNA and protein in early and late gestation human placentas, term cytotrophoblast cells and two choriocarcinoma cell lines, JEG-3 and Jar. Reverse transcriptase polymerase chain reaction identified mRNAs derived from the PGRN gene in all samples. Immunoblot analysis showed that PGRN proteins are present in early and late gestation human placentas with decreasing levels over gestation and that PGRN proteins are present in normal and transformed trophoblast cells. Immunohistochemical analysis using paraformaldehyde-fixed tissue sections taken from early and late stages of pregnancy showed that PGRN proteins are present in cytotrophoblast cells, syncytiotrophoblast and extravillous cytotrophoblast cells and that expression pattern of PGRN differed according to the stage of cell differentiation. The results of this study are consistent with the hypothesis that PGRN proteins have critical roles in placental development and suggest that PGRN may function in trophoblast cell growth and differentiation.
Tumor necrosis factor-related apoptosis inducing ligand (TRAIL) is a well-known inducer of apoptotic cell death in many tumor cells. 1RAIL is expressed in human placenta, and cytotrophoblast cells express 1RAIL receptors. However, the role of TRAIL in human placentas and cytotrophoblast cells is not. well understood. In this study a trophoblast cell line, JEG-3, was used as a model system to examine the effect of TRAIL. on key intracellular signaling pathways involved in the control of trophoblastic cell apoptosis and survival JEG-3 cells expressed receptors for 1RAIL, death receptor (DR) 4, DR5, decoy receptor (OcR) 1 and DeR2. Recombinant human TRAIL (rhTRAIL) did not have a cytotoxic effect determined by MIT assay and did not induce apoptotic cell death determined by poly-(ADP-ribose) polymerase cleavage assay. rhTRAIL induced a rapid and transient nuclear translocation of nuclear factor-kB(NF-kB) determined by immunoblotting using nuclear protein extracts. rhTRAIL rapidly activated extracellular signal-regulated protein kinase (ERK) 1/2 as determined by immnoblotting for phospho-ERK1/2. However, c-Jun N-terminal kinase (JNK), p38 mitogen-activated protein kinase (p38MAPK) and Akt (protein kinase B) were not activated by rhTRAIL. The ability of 1RAIL to induce NF-kB and ERK1/2 suggests that interaction between TRAIL and its receptors may play an important role in trophoblast cell function during pregnancy.