Identification of monoclonal nonspecific suppressor factor beta (mNSFbeta) as one of the genes differentially expressed at implantation sites compared to interimplantation sites in the mouse uterus

Successful implantation requires synchronous development of and active dialogue between the maternal endometrium and the implanting blastocyst. While it is well established that appropriate maternal steroid hormones are essential for endometrial preparation for implantation, the molecular events at the actual site of implantation are still little understood. The aims of our studies were to identify genes explicitly expressed or repressed at the sites of implantation by utilising RNA differential display (DDPCR), and to establish the roles of these genes in the implantation process in a mouse model. Ten bands unique in implantation sites compared to interimplantation sites were identified by DDPCR and subsequently confirmed by Northern blotting. One of these bands contained a cDNA fragment that was highly homologous to mouse monoclonal nonspecific suppressor factor beta (MNSFbeta) or Fau. The full cDNA sequence of this gene, obtained by screening a lambdagt11 cDNA library, was essentially the same as MNSFbeta, except that it had much longer 5' untranslated region. Interestingly, both Northern and immunohistochemical analysis showed that the expression of this gene was much lower in implantation sites compared to interimplantation sites on day 4.5 of pregnancy, when embryos first attach to the uterus and initiate implantation, and on day 5.5, when implantation has advanced. These results suggest a role for MNSF during implantation and early pregnancy, possibly through regulating the proliferation and/or differentiation of uterine stromal cells. It may also be involved in the selective production of TH2-type cytokines in implantation sites to regulate the immune system at the maternal-fetal interface.     

单克隆非特异性抑制因子—β（MNSFβ）在大肠杆菌中的表达、抗体的制备及在小鼠子宫内膜上的组织定位

为了获得足够量的单克隆非特异性抑制因子-β蛋白（monoclonal nonspecific supressor factorβ,MNSFβ）及其抗体用于探讨MNSFβ在着床中的作用机理,本研究构建了表达质粒pBV220/MNSFβ-hCCβ,在大肠杆菌中表达了融合蛋白MNSFβ-hCCβ,用抗hCGβ抗体对表达产物进行鉴定,结果表明融合蛋白MNSFβ-hCGβ得到了正确表达,且分子量和理论值相近,表达产物MNSFβ-hCGβ经初步纯化后用于免疫Balb/C小鼠,制备抗体,同时,我们还构建了表达质粒pGEX-4T-2/MNSFβ,在大肠杆菌中表达了融合蛋白GST-MNSFβ,用融合蛋白GST-MNSFβ对融合前的免疫小鼠回忆刺激并进行检测,制备了抗MNSFβ多克隆抗体和单克隆抗体,应用所制备的多克隆抗体进行免疫组化研究,对MNSFβ在小鼠子宫内膜上进行了组织定位,结果显示,MNSFβ在着床日（受精后第4.5天）小鼠子宫非着床位点的表达和着床位点相比明显提高。     

Deregulation of the serum- and glucocorticoid-inducible kinase SGK1 in the endometrium causes reproductive failure

Infertility and recurrent pregnancy loss (RPL) are prevalent but distinct causes of reproductive failure that often remain unexplained despite extensive investigations. Analysis of midsecretory endometrial samples revealed that SGK1, a kinase involved in epithelial ion transport and cell survival, is upregulated in unexplained infertility, most prominently in the luminal epithelium, but downregulated in the endometrium of women suffering from RPL. To determine the functional importance of these observations, we first expressed a constitutively active SGK1 mutant in the luminal epithelium of the mouse uterus. This prevented expression of certain endometrial receptivity genes, perturbed uterine fluid handling and abolished embryo implantation. By contrast, implantation was unhindered in Sgk1-/- mice, but pregnancy was often complicated by bleeding at the decidual-placental interface and fetal growth retardation and subsequent demise. Compared to wild-type mice, Sgk1-/- mice had gross impairment of pregnancy-dependent induction of genes involved in oxidative stress defenses. Relative SGK1 deficiency was also a hallmark of decidualizing stromal cells from human subjects with RPL and sensitized these cells to oxidative cell death. Thus, depending on the cellular compartment, deregulated SGK1 activity in cycling endometrium interferes with embryo implantation, leading to infertility, or predisposes to pregnancy complications by rendering the feto-maternal interface vulnerable to oxidative damage.     

Physiological and molecular determinants of embryo implantation

Embryo implantation involves the intimate interaction between an implantation-competent blastocyst and a receptive uterus, which occurs in a limited time period known as the window of implantation. Emerging evidence shows that defects originating during embryo implantation induce ripple effects with adverse consequences on later gestation events, highlighting the significance of this event for pregnancy success. Although a multitude of cellular events and molecular pathways involved in embryo–uterine crosstalk during implantation have been identified through gene expression studies and genetically engineered mouse models, a comprehensive understanding of the nature of embryo implantation is still missing. This review focuses on recent progress with particular attention to physiological and molecular determinants of blastocyst activation, uterine receptivity, blastocyst attachment and uterine decidualization. A better understanding of underlying mechanisms governing embryo implantation should generate new strategies to rectify implantation failure and improve pregnancy rates in women.     

A genomic approach to identify novel progesterone receptor regulated pathways in the uterus during implantation

The cellular actions of steroid hormone progesterone (P) are mediated via its nuclear receptors, which regulate the expression of specific target genes. The identity of gene networks that are regulated by the P receptors (PRs) in the uterus at various stages of the reproductive cycle and pregnancy, however, remain largely unknown. In this study, we have used oligonucleotide microarrays to identify mRNAs whose expression in the pregnant mouse uterus is modulated by RU486, a well-characterized PR antagonist, which is also an effective inhibitor of implantation. We found that, in response to RU486, expression of mRNAs corresponding to 78 known genes was down-regulated at least 2-fold in the preimplantation mouse uterus. The PR regulation of several of these genes was ascertained by administering P to ovariectomized wild-type and PR knockout (PRKO) mice. Detailed spatio-temporal analysis of these genes in the pregnant uterus indicated that their expression in the epithelium and stroma could be correlated with the expression of PR in those cell types. Furthermore, time-course studies suggested that many of these genes are likely primary targets of PR regulation. We also identified 70 known genes that were up-regulated at least 2-fold in the pregnant uterus in response to RU486. Interestingly, initial examination of a number of RU486-inducible genes reveals that their uterine expression is also regulated by estrogen. The identification of several novel PR-regulated gene pathways in the reproductive tract is an important step toward understanding how P regulates the physiological events leading to implantation.     

Expression of maspin in the early pregnant mouse endometrium and its role during embryonic implantation

Maspin (serpin B5), a tumor-suppressing member of the serine protease inhibitor family, participates in cell migration, adhesion, invasion, and apoptosis. These processes are also critical for embryo implantation, but the role of maspin in embryo implantation remains poorly understood. The aim of the present study was to investigate the spatiotemporal expression of maspin in early pregnant mouse endometrium and its role in embryo implantation. Real-time quantitative PCR analysis, immunohistochemistry, and Western blotting were used to detect mRNA and protein expression of maspin in the endometria of nonpregnant and early pregnant (days 0 to 7) mice. On day 3 of pregnancy, mice in the treated group (n = 20) were injected in the left uterine horn with antimaspin polyclonal antibody and in the right horn with purified rabbit IgG; control mice (n = 20) were injected only with purified rabbit IgG in the right uterine horn. Implanted embryos were counted on pregnant day 8. The mRNA and protein expressions of maspin were higher in the endometria of pregnant mice than nonpregnant mice; these levels gradually increased from day 1 of pregnancy, peaked on day 5, and then decreased on days 6 and 7. The mice treated with antimaspin polyclonal antibody group had far fewer implanted embryos than did the control group. Taken together, these results suggest that maspin, a tumor suppressor, may play an important role in embryo implantation.     

GM-CSF regulation of embryo development and pregnancy

The reproductive tissues undergo profound structural changes and major immune adaptation to accommodate pregnancy. Granulocyte-macrophage colony-stimulating factor (GM-CSF) is one of an array of cytokines with pivotal roles in embryo implantation and subsequent development. Several cell lineages in the reproductive tract and gestational tissues synthesise GM-CSF under direction by ovarian steroid hormones and signalling agents originating in male seminal fluid and the conceptus. The pre-implantation embryo, invading placental trophoblast cells and the abundant populations of leukocytes controlling maternal immune tolerance are all subject to GM-CSF regulation. GM-CSF deficiency in pregnancy adversely impacts fetal and placental development, as well as progeny viability and growth after birth, highlighting this cytokine as a central maternal determinant of pregnancy outcome with clinical relevance in human fertility.     

Effect of 32/67 kDa laminin-binding protein antibody on mouse embryo implantation

Mouse embryo implantation depends on the complex interaction between the embryo trophoblast cells and the uterine environment, which deposits an extracellular matrix with abundant amounts of laminin. Intrauterine injection and blastocyst or ectoplacental cone culture models were used to study the effect of 32/67 kDa laminin-binding protein antibody on mouse embryo implantation in vivo and in vitro. Intrauterine injection of 32/67 kDa laminin-binding protein antibody (0.4 mg in 1 ml Ham's F-10 medium, 5 microl per mouse) into the left uterine horns of mice (n = 22) on day 3 of pregnancy inhibited embryo implantation significantly (P < 0.001) compared with the contralateral horns that had been injected with normal rabbit IgG. A continuous section study on day 5 after injection showed that the embryos in the control uteri implanted normally and developed healthily, but there were no embryos or the remaining embryos had disintegrated in the uteri injected with 32/67 kDa laminin-binding protein antibody. Blastocysts or ectoplacental cones were cultured in media containing 32/67 kDa laminin-binding protein antibody (0.2 mg ml(-1)) on laminin-coated dishes with normal rabbit IgG at the same concentration as in the controls. The 32/67 kDa laminin-binding protein had no effect on blastocyst or ectoplacental cone attachment, but prohibited the blastocyst or ectoplacental cone outgrowth and primary or secondary trophoblast giant cell migration. These results indicate that 32/67 kDa laminin-binding protein antibody blocked mouse embryo implantation by preventing embryo trophoblast cell invasion and migration through the uterine decidual basement membrane-like extracellular matrix which has a high laminin content.     

Dynamic distribution of epidermal growth factor during mouse embryo peri-implantation

Embryo implantation depends on the synchronized development of the blastocyst and the endometrium. This process is highly controlled by the coordinated action of the steroid hormones: estrogen and progesterone. By autocrine, paracrine or juxtacrine routes, some growth factors or cytokines are involved in this steroidal regulation pathway. Here we report the effects of epidermal growth factor (EGF) on embryo implantation in the mouse, the expression and distribution patterns of EGF protein in the mouse blastocyst, ectoplacental cone (EPC) and peri-implantation uterus on days 1-8 of gestation.By RT-PCR and dot blot, we found that EGF and its receptor (EGFR) are co-expressed in the blastocyst and peri-implantational uteri of pregnant days 2-8 (D2-D8) mice. Injection of EGF antibody into a uterine horn on the third day of pregnancy (D3) significantly reduced the number of mouse embryos that implanted on D8, indicating EGF have a function in the mouse embryo implantation.Further investigation by using indirect immunofluorescence and confocal microscope was made to trace EGF and EGFR protein localization during the mouse embryo implantation. EGF and EGFR are co-localized in the blastocyst, and in the secondary trophoblastic giant cells (SGC) of the EPC. At the pre-implantation stage, the distribution of EGF protein in the mouse uterus changes from epithelium to stroma. On D1 of pregnancy, EGF is mainly distributed in uterine stroma and myometrium. On D2, it is present in the uterine epithelium. On D3, it changes again from the uterine epithelium to the stroma. By D4, EGF is predominantly in the stroma. This dynamic distribution correlates with the proliferation activity of uterine cells at each period. On D6-D8 of embryo implantation, EGF 3 protein accumulates at the uterine mesometrial pole, a region that contributes to the trophoblastic invasiveness and placentation.This temporal and spatial localization of EGF protein in the mouse uterus implicates the cytokine in the regulation of trophoblastic invasiveness and uterine receptiveness.     

Uterine NK cells mediate inflammation-induced fetal demise in IL-10-null mice

Specialized NK cells are recruited in high numbers to the mammalian embryo implantation sites, yet remain pregnancy compatible. It is not well understood whether uterine NK (uNK) cells become adversely activated and mediate fetal demise, a common complication of early pregnancy. In this study we show that mating of IL-10(-/-) mice resulted in fetal resorption or intrauterine growth restriction in response to very low doses of LPS. Pregnancy in congenic wild-type mice was normal even at 10-fold higher LPS doses. Fetal resorption in IL-10(-/-) mice was associated with a significant increase in uNK cell cytotoxic activation and invasion into the placenta. Depletion of uNK cells, TNF-alpha neutralization, or IL-10 administration rescued pregnancy in LPS-treated IL-10(-/-) animals. Our results identify an immune mechanism of fetal demise involving IL-10 deficiency, NK cells, and inflammation. These results may provide insight into adverse pregnancy outcomes in humans.     

Regulation and molecular mechanisms of calcium transport genes: do they play a role in calcium transport in the uterine endometrium?

Maintenance of calcium (Ca) balance in the uterus is critically important for many physiological functions, including smooth muscle contraction during embryo implantation. Ca transport genes, i.e., transient receptor potential cation channel subfamily V members 5/6 (TRPV5/6), calbindins, plasma membrane Ca(2+)-ATPase 1 (PMCA1), and NCX1/NCKX3, may play roles in the uterus for Ca transport and reproductive function. Although these Ca transport genes may have a role in Ca metabolism, their role(s) and molecular mechanisms require further elucidation. In this review, we highlight the expression and regulation of Ca transport genes in the uterus to clarify their potential role(s). Since Ca transport genes are abundantly expressed in reproductive tissues in a distinct manner, they may be involved in specific uterine functions including fetal implantation, Ca homeostasis, and endometrial cell production.     

Effects of E-cadherin on mouse embryo implantation and expression of matrix metalloproteinase-2 and -9

E-cadherin is a cell surface glycoprotein, which is responsible for adhesion between epithelial cells. Whether it is involved in embryo implantation is still unknown. In a mouse intrauterine horn injection model, one uterine horn in each mouse was injected with different doses of E-cadherin antibody on day 3 of pregnancy. The results showed that embryo implantation was significantly inhibited in the mice injected with 3 microg E-cadherin antibody. The mouse uteri in this group were collected on days 5, 6, and 7 of pregnancy and expressions of MMP-2 and -9 were studied. In situ hybridization and RT-PCR results showed that the expression of MMP-2 and -9 mRNAs in uteri of E-cadherin antibody treated group was increased on days 5-7. The results of gelatin zymography of MMPs showed that the activities of pro-MMP-2, MMP-2, and pro-MMP-9 were increased significantly on days 5 and 6, and pro-MMP-9 activity was increased on day 7. The present study suggested that E-cadherin was involved in embryo implantation through decreasing the expressions and activities of MMP-2 and -9.     

Progesterone and DNA damage encourage uterine cell proliferation and decidualization through up-regulating ribonucleotide reductase 2 expression during early pregnancy in mice

Embryo implantation into the maternal uterus is a crucial step for the successful establishment of mammalian pregnancy. Following the attachment of embryo to the uterine luminal epithelium, uterine stromal cells undergo steroid hormone-dependent decidualization, which is characterized by stromal cell proliferation and differentiation. The mechanisms underlying steroid hormone-induced stromal cell proliferation and differentiation during decidualization are still poorly understood. Ribonucleotide reductase, consisting of two subunits (RRM1 and RRM2), is a rate-limiting enzyme in deoxynucleotide production for DNA synthesis and plays an important role in cell proliferation and tumorgenicity. Based on our microarray analysis, Rrm2 expression was significantly higher at implantation sites compared with interimplantation sites in mouse uterus. However, the expression, regulation, and function of RRM2 in mouse uterus during embryo implantation and decidualization are still unknown. Here we show that although both RRM1 and RRM2 expression are markedly induced in mouse uterine stromal cells undergoing decidualization, only RRM2 is regulated by progesterone, a key regulator of decidualization. Further studies showed that the induction of progesterone on RRM2 expression in stromal cells is mediated by the AKT/c-MYC pathway. RRM2 can also be induced by replication stress and DNA damage during decidualization through the ATR/ATM-CHK1-E2F1 pathway. The weight of implantation sites and deciduoma was effectively reduced by specific inhibitors for RRM2. The expression of decidual/trophoblast prolactin-related protein (Dtprp), a reliable marker for decidualization in mice, was significantly reduced in deciduoma and steroid-induced decidual cells after HU treatment. Therefore, RRM2 may be an important effector of progesterone signaling to induce cell proliferation and decidualization in mouse uterus.     

In vivo analysis of progesterone receptor action in the uterus during embryo implantation

In order for a successful pregnancy to occur, the embryo must attach to the luminal epithelial cells and invade into the stroma. Then, the surrounding stromal cells need to undergo decidualization in order to establish the vasculature necessary for survival of the embryo. These events in early pregnancy are tightly regulated by the steroid hormones, estrogen (E2) and progesterone (P4), through their cognate receptors, the estrogen receptor (ER) and the progesterone receptor (PR), respectively. Using a mouse model in which the PR has been ablated, it was demonstrated that the PR is necessary for embryo implantation and decidualization. Therefore, understanding the mechanism of PR action in the adult uterus is necessary in order to understand the events of early pregnancy. Insights from both mouse models and human samples have been integral in elucidating uterine PR action. These studies have shown that not only PR target genes, but also mediators of PR action are important for correct PR action in early pregnancy. Many of the genes involved in PR action in early pregnancy have also been shown to have roles in uterine diseases such as endometriosis and endometrial cancer. Therefore, the integration of mouse and human studies on PR action in the uterus will be important for the future understanding of uterine diseases and in the development of treatment for these diseases.     

In vivo analysis of progesterone receptor action in the uterus during embryo implantation

In order for a successful pregnancy to occur, the embryo must attach to the luminal epithelial cells and invade into the stroma. Then, the surrounding stromal cells need to undergo decidualization in order to establish the vasculature necessary for survival of the embryo. These events in early pregnancy are tightly regulated by the steroid hormones, estrogen (E2) and progesterone (P4), through their cognate receptors, the estrogen receptor (ER) and the progesterone receptor (PR), respectively. Using a mouse model in which the PR has been ablated, it was demonstrated that the PR is necessary for embryo implantation and decidualization. Therefore, understanding the mechanism of PR action in the adult uterus is necessary in order to understand the events of early pregnancy. Insights from both mouse models and human samples have been integral in elucidating uterine PR action. These studies have shown that not only PR target genes, but also mediators of PR action are important for correct PR action in early pregnancy. Many of the genes involved in PR action in early pregnancy have also been shown to have roles in uterine diseases such as endometriosis and endometrial cancer. Therefore, the integration of mouse and human studies on PR action in the uterus will be important for the future understanding of uterine diseases and in the development of treatment for these diseases.     

The hamster as a model for embryo implantation: insights into a multifaceted process

Defects in preimplantation embryonic development, uterine receptivity, and implantation are the leading cause of infertility, pregnancy problems and birth defects. Significant progress has been made in our basic understanding of these processes using the mouse model, where implantation is ovarian estrogen-dependent in the presence of progesterone. However, an animal model where implantation is progesterone-dependent must also be studied to gain a full understanding of the embryo and uterine events that are required for implantation. In this regard, the hamster is a useful model and this review summarizes the information currently available regarding mechanisms involved in synchronous preimplantation embryo and uterine development for implantation in this species.     

Estrogen induces expression of secretory leukocyte protease inhibitor in rat uterus

In rodents, the steroid hormone estrogen (E) profoundly influences the early events in the uterus leading to embryo implantation. It is thought that E triggers the expression of a unique set of genes in the endometrium that in turn control implantation. To identify these E-induced genes, we employed a delayed implantation model system in which embryo attachment to rat endometrium is dependent upon E administration. Using a gene expression screen method, we isolated a number of cDNAs representing mRNAs whose expression is either turned on or turned off in response to an implantation-inducing dose of E. We identified one of these cDNAs as that encoding secretory leukocyte protease inhibitor (SLPI), an inhibitor of serine proteases. The expression of SLPI mRNA was induced in the uteri of ovariectomized rats in response to E, confirming the hormonal regulation of this molecule. Spatiotemporal analysis revealed a biphasic pattern of expression of SLPI mRNA during early pregnancy. A considerable amount of SLPI mRNA was detected in the uterine epithelium on Day 1 of pregnancy. The level of this mRNA, however, declined sharply on Days 2 and 3 of gestation. Interestingly, on Day 4 of gestation, there was a marked resurgence in SLPI mRNA expression in the uterine epithelium. This second burst of SLPI expression diminished by Day 6 of pregnancy. The transient induction of SLPI mRNA during Days 4 and 5 overlapped with the window of implantation in the rat. Although the precise function of SLPI in the uterus eludes us presently, its known effects as a serine protease inhibitor in other tissues and its hormone-induced expression in the rat uterus immediately preceding implantation lead us to propose that this gene plays an important role in controlling excessive proteolysis and inflammation during a critical phase of early pregnancy.