Profiling of E-cadherin, beta-catenin and Ca(2+) in embryo-uterine interactions at implantation

Establishment of early pregnancy is promoted by a complex network of signalling molecules that mediate cell-to-cell and cell-to-extracellular matrix communications between the receptive endometrium and the invasive trophectoderm. In this study, we have attempted to evaluate the expression profiles of cadherin and catenin during embryo implantation in the mouse. Western blotting studies along with immunocytochemical analysis revealed that E-cadherin is expressed rather ubiquitously in the uterine epithelial cells, distinct enrichment is observed on the apical membrane in the endometrium of peri-implantation uterus specifically at the implantation sites and not at the inter-implanation sites. beta-Catenin also is upregulated and is specifically restricted to apical membrane of epithelial cells of implantation sites. Progesterone induced expression of E-cadherin and 17beta-estradiol regulated the expression of catenin in implantation-delayed uteri. Interestingly, estradiol imparted negative modulation on cadherin expression when co-administered with progesterone. On the contrary, trophoblast exhibits a striking down regulation of cadherin, catenin and Ca(2+) at peri implanting stage. These observations suggest that the trophoblasts exhibited an invasive phenotype while the endometrial epithelium displayed an adhesive phenotype during the window of implantation. Thus, embryo implantation presents an instance where two interacting surfaces showed mutually complementing interaction phenotypes.     

Regulated expression of osteopontin in the peri-implantation rabbit uterus

Blastocyst attachment to the lining of the mammalian uterus during early implantation involves the initial apposition of the trophoblast to the uterine epithelial surface. Osteopontin (OPN) is a glycoprotein component of the extracellular matrix that is secreted by the glandular epithelium of mammalian uteri at the time of implantation. This protein is recognized by several members of the integrin family and promotes cell-cell attachment and adhesion. In the present study, rabbit uteri were examined using Northern and in situ hybridization to evaluate the temporal and spatial distribution of OPN mRNA during early pregnancy. Northern blot analysis demonstrated a dramatic increase in OPN expression on Days 4-7 of pregnancy, corresponding to the rise in circulating progesterone and the time of initial embryo attachment in this species. In situ hybridization analysis revealed OPN mRNA expression on Day 6.75 of pregnancy, which was most prominent on endometrial epithelium. Using immunofluorescence, OPN protein was present on the glandular epithelium on Day 6.75 of pregnancy, but was absent on blastocysts. Further, no expression of OPN mRNA or protein was found in the nonpregnant endometrium. Induction of endometrial OPN expression was observed in unmated rabbits treated with progesterone alone and was prevented by cotreatment with the antiprogestin ZK137.316. Estradiol-17beta had no effect on OPN expression by itself, and estrogen priming was not necessary to demonstrate the stimulatory effect of progesterone. In The rabbit uterus, as in other mammalian species studied, OPN is expressed in a stage-specific manner by the endometrial glands during the peri-implantation period and is regulated by progesterone.     

Restraint Stress Inhibits Mouse Implantation: Temporal Window and the Involvement of HB-EGF,Estrogen and Progesterone

It is known that psychological stress affects reproduction in women, but it is unknown whether the effect is by impairing implantation. Although studies suggest that long periods of auditory or restraint stress may inhibit implantation in rats and mice, the exact stage of pregnancy at which stress impairs implantation is unclear. Furthermore, whether stress impairs implantation by decreasing the heparin-binding epidermal growth factor-like growth factor (HB-EGF), estrogen and/or progesterone and whether by acting on embryos or on the uterus need further investigations. In this study, a 24-h restraint stress was initiated at 15:30 of day 3 (regimen 1) or at 07:30 (regimen 2) or 15:30 of day 4 (regimen 3) of pregnancy (vaginal plug  =  day 1) to observe effects of restraint stress applied at different peri-implantation stages on implantation. Among the three regimens, whereas regimens 1 and 3 affected neither term pregnancy nor litter size, regimen 2 reduced both. Further observations indicated that regimen 2 of restraint stress also delayed blastocyst hatching and the attachment reaction, decreased serum concentrations of progesterone and estradiol, and down regulated the expression of HB-EGF in both the endometrium and blastocysts. Taken together, the results suggested that restraint stress inhibited mouse implantation in a temporal window-dependent manner and by impairing blastocyst activation and hatching and uterine receptivity via down-regulating HB-EGF, estrogen and progesterone. Thus, the stress applied within the implantation window impaired implantation by acting on both embryos and the uterus.     

Progesterone action and responses in the alphaERKO mouse

Ovarian steroids have important inter-related roles in many systems and processes required for mammalian reproduction. The female reproductive tract, ovaries, and mammary glands are all targets for both estrogen and progesterone. In addition, the actions of these hormones are intertwined in that, for example, progesterone attenuates the proliferative effect of estrogen in the uterus, whereas estrogen also induces the progesterone receptor (PR) mRNA and protein, thus enhancing progesterone actions. The generation of mice that lacks the progesterone receptor (PRKO) or the estrogen receptoralpha (alphaERKO) has provided numerous insights into the interacting roles of these hormones. The mammary glands of the PRKO mice develop with full epithelial ducts that lack side branching and lobular alveolar structures, whereas the alphaERKO mice develop only an epithelial rudiment. This indicates that estrogen is important for ductal morphogenesis, whereas progesterone is required for ductal branching and alveolar development. Both the alphaERKO and PRKO mice are also anovulatory, but exhibit different causal pathologies. The alphaERKO ovary seems to possess follicles up to the preantral stage and shows a polycystic phenotype as a result of chronic hyperstimulation by LH. The PRKO follicles seem to develop to an ovulatory stage, but are unable to rupture, indicating a role for progesterone in ovulation. The uteri of these two strains seem to develop normally; however, the function and hormone responses are abnormal in each. Because estrogen is known to induce PRs in the uterus, the progesterone responsiveness of the alphaERKO uterus was characterized. PR mRNA was detected but was not up-regulated by estrogen in the alphaERKO tissue. PRs are present in the alphaERKO tissue at 60% of the level in wild-type tissue and show a similar amount of A and B isoforms when measured by R5020 binding and detected by Western blotting. The PRs were able to mediate induction of two progesterone-responsive uterine genes: calcitonin and amphiregulin. The alphaERKO uterine tissue was also able to undergo a decidual reaction in response to hormonal and intraluminal treatments to mimic implantation; however, unlike normal wild-type uteri, this response was estrogen independent in the alphaERKO uterine tissue.     

Metabolism of progesterone in rat uterus

The in vitro metabolism of progesterone was studied in uteri of untreated and estrogen stimulated immature rats. In intact uteri the rate of metabolism varied with the hormonal status of the animal in a concentration dependent manner. At a low (3 × 10^?9M) progesterone concentration the rate of ring A reduction was decreased in estrogen stimulated uteri. At a high progesterone concentration (3 × 10^?6M) the rate of ring A reduction was increased after estrogen treatment. The rate of reduction of the C20 ketone was increased after estrogen treatment at all concentrations of incubated progesterone. In dilute homogenates of uterus, estrogen stimulation always increased the rate of progesterone metabolism.Estrogen stimulation results in increased concentration of progesterone receptor in the uterus. It is proposed that increased activity of ring A reductases also occurs. The relative influence of these two factors on the metabolism of progesterone is dependent on the progesterone concentration in the incubation medium.     

Hormonal regulation of uterine natural killer cells in mouse preimplantation uterus

Uterine Natural Killer (uNK) cells are the most abundant lymphocyte population recruited in the uteri during murine and human pregnancy. Previous investigation on uNK cells during mouse pregnancy focused more on its accumulation in postimplantation periods, which were believed to play important roles in regulating trophoblast invasion and angiogenesis towards successful placentation. However, by using recently developed methods of Dolichos biflorus agglutinin (DBA) lectin, a closer examination during mouse preimplantation revealed that there were also dynamic regulations of uNK cell, suggesting a major regulation by steroid hormones. Here we provide a detailed examination of uNK cells distribution during mouse early pregnancy by DBA lectin reactivity, with emphasis on preimplantation period and its hormonal regulation profiles. Our results showed that uNK precursor cells or its cell membrane specific components could be recruited in the uterus by estrogen or/and progesterone, and the effects could be completely abolished by specific antagonists of their nuclear receptors (estrogen and progesterone receptor). These results suggested that the preimplantation uterus, through concerted hormone regulation, could recruit uNK precursor cell or its specific cellular component, which might be conducive for uterine receptivity and further uNK construction/function during postimplantation.     

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.     

Interacting effects of estrogen, progesterone and catecholamines on rat uterine cyclic AMP and glycogen phosphorylase.

Ovariectomized rats were treated with estrogen, progesterone or a combination of estrogen plus progesterone. Rats were anesthetized with sodium pentobarbital and uteri were frozen $\text{in situ}$, uterine extracts were prepared and assayed for cyclic AMP and phosphorylase. Uterine cyclic AMP levels were highest in estrogen treated uteri and were significantly reduced when estrogen was withdrawn for two days. Addition of progesterone to the estrogen regimen for two days or changing from estrogen to progesterone for two days produced results comparable to those obtained when estrogen was withdrawn. Similar experiments were done except that 30 seconds before tissue freezing epinephrine was injected intravenously. Both cyclic AMP and glycogen phosphorylase increased markedly in response to epinephrine. The magnitude of the responses were greatest in the uteri pretreated with estrogen. The magnitudes of both the cyclic AMP and phosphorylase responses were significantly reduced by withdrawing estrogen for two days, by adding progesterone to the estrogen treatment or by changing to progesterone from estrogen. Isoproterenol-stimulated cyclic AMP responses were affected by the steroid state of the uterus in the same way as the epinephrine responses.     

Temporal relationships among uterine pituitary adenylate cyclase-activating polypeptide, decidual prolactin-related protein and progesterone receptor mRNAs expressions during decidualization and gestation in rats

Pituitary adenylate cyclase-activating peptide (PACAP), a novel compound with vasoactive intestinal polypeptide-like activity, was recently shown to be localized in the neuronal endings of the human uterus. The purpose of the present study was to assess the functional presence of PACAP mRNA in the decidual endometrium and its relationship to the expression levels of decidual prolactin-related protein (dPRP) and the progesterone receptor mRNAs during decidualization and pregnancy in Sprague-Dawley rats. PACAP was constitutively and temporally expressed in the decidual endometrium and gravid uterus. The time-dependent correlated expression levels of PACAP, dPRP and the progesterone receptor were induced by the neurogenic reproductive signals, i.e. the vagino-cervical/deciduogenic stimuli of decidualization and by the normal equivalent stimuli of mating/blastocyst implantation of gestation. Correlation among the mRNA expression levels of PACAP, dPRP and the progesterone receptor and the coordinated inhibitory actions of the anti-progesterone (RU-486) suggest that there is also correlated time-dependent steroid regulation of the mRNA levels of PACAP, dPRP and the progesterone receptor in the decidual and pregnant uteri. One possible functional meaning for the time-related localization of endometrial/uterine PACAP could be to facilitate endometrial blood flow and increase the availability of metabolic substrates to the developing deciduoma or embryo. The study demonstrates the potential importance of PACAP expression in the regulation of the maternal feto-placental component and suggests a prominent reproductive role for the neuropeptide in mammalian pregnancy.     

Characteristics of the nuclear translocation of progesterone receptor in fetal guinea pig uterus "in vivo", "in vitro" and in organ culture

The translocation of progesterone receptor from the cytosol into the nucleus was studied under "in vivo" and "in vitro" conditions in the uteri of guinea pig fetuses exposed to progesterone or a synthetic progestin, R5020. Progesterone treatment of estrogen-primed fetuses leads to a rapid (before 1h) transfer of cytosol progesterone receptor into the nucleus which is, however, short-lived (less than 3h). A rapid decrease in the retention of the estrogen receptor in the nucleus also occurs. In the "in vitro" incubations of whole fetal uteri, translocation of progesterone receptor is temperature-dependent and specific for progesterone and R5020; estradiol and cortisol have no effect. Putative progesterone receptors can also be induced in explants of fetal guinea pig uteri in organ culture which translocate from the cytosol into the nucleus under the same "in vitro" conditions as in whole uteri. Fetal uterine progesterone receptor, either stimulated "in vivo" by estrogen-priming or induced in organ culture, translocates from the cytosol into the nucleus and this process seems to be accompanied by a decrease in retention of the estrogen receptor in the nucleus which appears to be the mechanism by which progesterone antagonises estrogen action in fetal guinea pig uterus.     

Steroidal control of rat uterine 17β-hydroxysteroid dehydrogenase activity

The interconversion of estradiol-17β and estrone in the rat uterus is due to the action of 17β-hydroxysteroid dehydrogenase. Whole uteri or 800 × g supernatant fractions of the uteri were incubated in the presence of [³H] estradiol-17β and NAD at 37°C for 3 h or 1 h, respectively. In the mature rat uterus the oxidation of estradiol-17β and estrone was dependent on the stage of the estrous cycle, suggesting hormonal control. The 17β-hydroxysteroid dehydrogenase activity was highest at estrus (200 fmol estrone) and lowest at diestrus (80 fmol estrone). An enhancement of activity occurred when adult rats at each stage of the estrous cycle were administered estradiol-17β, while progesterone administration at each stage resulted in decreased enzyme activity. The uterine 17β-hydroxysteroid dehydrogenase activity of estradiol-17β treated ovariectomized rats was time and dose dependent but decreased when progesterone was administered with or without estradiol-17β administration. These results suggest that estradiol-17β caused an increase in enzyme activity that was inhibitable by progesterone in the rat uterus. The increased 17β -hydroxysteroid dehydrogenase activity may reflect a specific response of the rat uterus to estradiol-17β.     

Progesterone and oestrogen receptors in the female genital tract throughout pregnancy in tammar wallabies

The tammar, Macropus eugenii, is a monovular macropodid marsupial which has a post-partum oestrus and an 11 month embryonic diapause. Progesterone and oestradiol cytosol receptors were measured by Scatchard analyses and single point analysis in the lateral vagina, endometrium and myometrium of the gravid and contralateral non-gravid uterus throughout pregnancy, immediately after parturition and during seasonal reproductive quiescence. In endometrial tissues, both progesterone and oestradiol receptors doubled in concentration in both gravid and non-gravid uteri between day 0 and day 5 of pregnancy, coinciding with previously described peak values in peripheral plasma progesterone and oestrogen. Receptor concentrations in endometrial tissue during seasonal quiescence were not significantly different from those immediately after reactivation. After day 12 of pregnancy, downregulation of both progesterone and oestradiol cytosolic receptors occurred concomitant with the increase in progesterone in the peripheral plasma. However, there was a unilateral increase in oestradiol receptor concentrations in endometrium obtained from the non-gravid uterus between day 25 of the 26.5 day gestation and immediately after parturition. Myometrial receptor concentrations mirrored those of the endometrium but were lower. Concentrations of progesterone receptor in the lateral vaginae were at the lower limit of detection, while the oestradiol cytosol receptor concentrations were even lower in this tissue. Thus, the steroid receptor concentrations provide another example of local unilateral endocrine responses in the reproductive tract of the tammar. These results also indicate that the downregulation of progesterone and oestradiol receptors that occurs in both uteri in mid- and late-pregnancy is selectively and locally reversed before parturition in the non-gravid endometrium in response to the local effects of follicular oestradiol from the ipsilateral ovary.     

Spatio-temporal expression and regulation of dermatopontin in the early pregnant mouse uterus

During endometrial differentiation the extracellular matrix (ECM) changes dramatically to prepare for implantation of the embryo. However, the genes regulating the ECM build-up in the uterine endometrium during early pregnancy are not well known. Using the PCR-select cDNA subtraction method, dermatopontin was identified in the uterus of a pregnant mouse on day 4 of gestation. Dermatopontin mRNA increased dramatically on day 3, and was at its highest level at the time of implantation. Administration of RU 486 significantly inhibited mRNA expression by day 4 of gestation, but ICI 182,780 did not. Progesterone markedly induced dermatopontin expression in ovariectomized uteri within 4 h of administration, whereas estrogen had little effect. In silico analysis revealed progesterone receptor binding sites in the dermatopontin promoter region. Decidualization did not induce expression of dermatopontin; instead dermatopontin mRNA became strongly localized at the interimplantation site. In situ hybridization revealed that expression gradually decreased in the luminal epithelial cells as pregnancy progressed, whereas it increased in the stromal cells. The pattern of localization and the changes of intensity of dermatopontin mRNA coincided with those of collagen. Collectively, these results strongly suggest that dermatopontin expression is steroid-dependent. They also suggest that, at the time of implantation, dermatopontin expression is primarily regulated spatio-temporally by progesterone via progesterone receptors, and is modulated by the decidual response during implantation. Dermatopontin may be one of the regulators used to remodel the uterine ECM for pregnancy.     

Role of progesterone on peri-implantation stage endometrium-embryo interaction in the primate

Progesterone secretion during the luteal phase influences oviductal and endometrial functions which are essential for embryo viability and implantation in a number of species including primates. Luteal phase estrogen is not essential for progesterone-dependent endometrial receptivity towards implantation and pregnancy in the rhesus monkey and in the human. However, synchronous development of embryo and endometrium is an essential prerequisite for evolutive implantation. Progesterone helps to maintain synchronous development of preimplantation embryo through its action on maternal uterus. The anti-nidatory action of mifepristone, a potent progesterone receptor modulator (PRM) with pronounced antiprogestagenic activity, is known to be associated with desynchronization of endometrium along with repression of glandular secretory differentiation and vascular maturation. Thus, it is likely that early luteal phase administration of mifepristone affects paracrine action of the secretory stage endometrium on the preimplantation stage embryo, and thereby inhibits embryonic development and viability. We shall examine this hypothesis using the rhesus monkey as a primate model.     

着床期小鼠子宫内膜Le~y糖蛋白的动态变化

为了解子宫内膜Ｌｅ~ｙ糖蛋白在胚泡着床期间的变化,以及与胚泡表面阶段特异性Ｌｅ~ｙ抗原出现的关系,应用对Ｌｅ~ｙ寡糖特异的ＡＨ－６单抗为探针,通过ＳＤＳ－ＰＡＧＥ和Ｗｅｓｔｅｒｎｂｌｏｔ免疫酶标染色,观察了小鼠子宫内膜Ｌｅ~ｙ糖蛋白在着床期的动态变化和分布特点。结果表明：（１）未孕及着床前后的小鼠子宫内膜均含Ｌｅ~ｙ糖蛋白Ｍｒ５０～２００ｋＤ）,未孕内膜的含量明显高于着床期间的样品;（２）在着床日（Ｄ４）样品可见微量１６ｋＤ的Ｌｅ~ｙ糖蛋白条带;（３）未孕至Ｄ４的子宫内膜均有Ｌｅ~ｙ糖蛋白分泌至宫腔,但呈渐减趋势,未孕样品Ｌｅ~ｙ糖蛋白主要为分泌型,而Ｄ４样品Ｌｅ~ｙ糖蛋白主要存在于子宫内膜,宫腔液含量很少;结果提示子宫内膜Ｌｅ~ｙ糖蛋白在着床期间具有含量、组成和分布上的动态变化,这些变化可能与胚泡着床以及胚泡在宫腔内其表面Ｌｅ~ｙ糖抗原转为阳性密切有关。     

Steroids modulate the expression of alpha4 integrin in mouse blastocysts and uterus during implantation

Blastocyst implantation and successful establishment of pregnancy require delicate interactions between the embryo and the maternal uterine milieu, which are controlled at the embryo-maternal interface by the coordinated interplay of a variety of growth factors, cytokines, hormones, and cell adhesion molecules expressed by both the decidualized endometrium and the trophoblast cells. Proper implantation of the embryo is solely dependent on the initial endometrial receptivity and the preparation of the blastocyst to glue itself to the uterine wall. Both these events are considered to be mediated by cell adhesion molecules and integrins expressed by the blastocyst as well by as the maternal endometrium. Integrin expression by the blastocyst and the uterus is a dynamic process. However, reports on the expression and the hormonal modulation of integrins and their role in blastocyst activation and uterine receptivity during implantation are meager. The present study investigates the expression and hormonal regulation of alpha4beta1 integrin by steroid hormones in the blastocyst and the receptive uterus using an in vivo, delayed-implantation mouse model system. The dormant and activated blastocysts as well as the uteri were recovered from ovariectomized mice after progesterone-alone and progesterone-plus-estrogen therapy, respectively. Immunolocalization of protein expression of alpha4 and beta1 integrin subunits indicate that steroids modulate the expression of alpha4beta1 integrin receptor in the mouse blastocyst as well as the uterus and that a differential expression is observed with exposure to progesterone and estrogen. Intrauterine blocking of alpha4 integrin by specific antibody resulted in implantation failure in normal as well as in delayed-implantation mice. Based on our data, we propose here, to our knowledge for the first time, that alpha4beta1 integrin, which is responsible for binding to fibronectin and vascular cell adhesion molecule-1, is induced by estradiol and is down-regulated by progesterone in mice during implantation. Furthermore, the results also indicate the direct role of alpha4 integrin in the process of implantation.