Establishment of a primary culture model of mouse uterine and vaginal stroma for studying in vitro estrogen effects

Effects of 17beta-estradiol (E2) on uterine and vaginal epithelial cell proliferation could be mediated by stromal cell-derived paracrine factors. To study the epithelial-stromal interactions in mice, an in vitro model of uterine and vaginal stromal cells of immature mice is essential. Therefore, we established a primary culture model of stromal cells both from uterus and vagina and examined the effect of E2 on proliferation of cultured stromal cells. We found that E2 stimulated proliferation of stromal cells from both organs in vitro, showing an increase in the number of cells and the percentage of 5-bromo-2'-deoxyuridine (BrdU)-labeled cells. Interestingly, vaginal stromal cells responded to lower E2 than uterine stromal cells in proliferation (10(-12) M vs. 10(-8) M) and BrdU labeling (10(-14) - 10(-10) M vs. 10(-10) - 10(-6) M). To examine the effect of E2 in vivo, cells were grafted into the subrenal capsule of the host mice and grown for 2 weeks. The BrdU labeling in cultured stromal cells was increased by E2 in vivo. To examine the effect of cultured stromal cells on epithelial cell proliferation, uterine and vaginal epithelium of adult mice were separated, recombined with the cultured stromal cells, and grafted under the renal capsule of hosts for 3 weeks. Epithelial cells recombined with cultured stromal cells showed simple columnar morphology in uterine grafts and stratified and keratinized morphology in vaginal grafts under the influence of the hormonal environment of the hosts. The BrdU labeling in epithelial cells was increased by E2, suggesting that cultured stromal cells can stimulate epithelial cell proliferation. In conclusion, we established a primary culture model of uterine and vaginal stromal cells, which can be mitogenically stimulated by E2 in vitro and in vivo after being grafted under the renal capsule. This culture system will be useful for investigating the underlying molecular mechanisms of uterine and vaginal epithelial-stromal interactions.     

Uterine gland development begins postnatally and is accompanied by estrogen and progesterone receptor expression in the dog

During neonatal and juvenile life, mammalian uteri undergo extensive structural and functional changes, including uterine gland differentiation and development. In sheep and mice, inhibition of neonatal uterine gland development induced by progestin treatment led to a permanent aglandular uterine phenotype and adult infertility, suggesting that this strategy might be useful for sterilizing dogs and other companion animals. The goal of this study was to define temporal patterns of adenogenesis (gland development), cell proliferation, and progesterone and estrogen receptor expression in uteri of neonatal and juvenile dogs as a first step toward determining whether neonatal progestin treatments might be a feasible contraceptive approach in this species. Uteri obtained from puppies at postnatal wk 1, 2, 4, 6, or 8 were evaluated histologically and immunostained for MKI67, a marker of cell proliferation, estrogen receptor-1, and progesterone receptor. Adenogenesis was under way at 1 wk of age, as indicated by the presence of nascent glands beginning to bud from the luminal epithelium, and rapid proliferation of both luminal epithelial and stromal cells. By Week 2, glands were clearly identifiable and proliferation of luminal, glandular, and stromal cells was pronounced. At Week 4, increased numbers of endometrial glands were evident penetrating uterine stroma, even as proliferative activity decreased in all cell compartments as compared with Week 2. Whereas gland development was most advanced at Weeks 6 to 8, luminal, glandular, and stromal proliferation was minimal, indicating that the uterus was nearly mitotically quiescent at this age. Both estrogen receptor-1 and progesterone receptor were expressed consistently in uterine stromal and epithelial cells at all ages examined. In summary, canine uterine adenogenesis was underway by 1 wk of age and prepubertal glandular proliferation was essentially complete by Week 6. These results provided information necessary to facilitate development of canine sterilization strategies based on neonatal progestin treatments designed to permanently inhibit uterine gland development and adult fertility.     

Endometrial development and adenogenesis in the neonatal pig: effects of estradiol valerate and the antiestrogen ICI 182,780.

In the pig, appearance of endometrial glands between birth (postnatal day [PND] 0) and PND 14 involves development of estrogen receptor-alpha-positive (ER+) phenotype by, and increased DNA synthesis in, nascent glandular epithelium (GE). To determine whether ER activation is required for this process, gilts were treated daily with either vehicle, the antiestrogen ICI 182,780 (ICI), estradiol-17beta valerate (EV), or both ICI and EV. Treatments began on PND 0, before onset of adenogenesis, or on PND 7, after onset of gland proliferation. Uteri obtained on PNDs 7 and 14 (study one) or on PND 14 (study two) were weighed; uterine histology was evaluated; DNA synthesis in luminal epithelium and GE was characterized by determining 5-bromo-2'-deoxyuridine (BrdU) labeling index; and patterns of ER mRNA expression were evaluated in situ (study one). Gland genesis was inhibited by ICI, which decreased gland penetration depth by PND 14 in study one, both endometrial thickness and BrdU-labeling index in GE in study two, and increased stromal cell compaction in both studies. Uterotropic effects of EV included increased gland development and epithelial BrdU labeling and decreased stromal compaction. These effects were inhibited by coadministration of ICI. Treatments did not alter ER mRNA expression, which remained limited to stroma and GE. Data indicate that endometrial maturation and adenogenesis in the neonatal pig require expression and activation of a functional ER system.     

Altered morphogenesis of the immature hamster uterus following neonatal exposure to diethylstilbestrol

Abstract. In previous studies, we found that a single neonatal exposure to diethylstilbestrol (DES) resulted in severe hyperplasia and a high incidence of endometrial adenocarcinoma in the uterus of adult hamsters. These observations prompted us to investigate the consequences of DES exposure on earlier stages of uterine morphogenesis. After neonates were treated within 6 h of birth (day 1) with 100 μg of DES or oil vehicle, uterine tissue morphometry plus cell labelling indices following in vivo pulse labeling with [³H]thymidine were determined on days 3–21 of life. The sequential findings were: (1) a precocious (day 3) burst of cellular proliferation throughout the uterus, (2) an early period (days 3–9) of hypertrophy and increased cell density in the luminal epithelium, (3) an extreme acceleration of uterine growth resulting in a persistent increase in total uterine mass (threefold enhancement on days 5–21), (4) precocious development of endometrial glands (day 9) that were sites of intense but transient proliferative activity, (5) a middle period (days 9–15) when the percentage of stromal cells engaged in proliferative activity was reduced, (6) a second wave (days 15–21) of enhanced proliferative activity in the luminal epithelium, and (7) later development (day 21) of reduced cell density in the uterine stroma, apparently due to increased intercellular collagen accumulation. These results support our working hypothesis that the acute uterotropic response to neonatal DES treatment initiates a change in the developing hamster uterus, and later estrogenic stimulation promotes neoplastic progression in the DES-altered adult organ, perhaps due to disruption of stromal-epithelial interactions.     

Effect of estradiol on estrogen receptor expression in rat uterine cell types

In rodent uterus, both up- and down-regulation of estrogen receptor alpha (ERalpha) messenger ribonucleic acid (mRNA) and protein levels by estradiol has been demonstrated; however, it is not known which of the uterine compartments (endometrial epithelium, stroma, myometrium) respond to estradiol with autoregulation of ERalpha. The purpose of the present study was to investigate and compare the kinetics and cell type-specific effects of estradiol on uterine ERalpha expression in immature and adult rats. Ovariectomized female rats were injected s.c. with sesame oil or estradiol-17beta. Uteri were collected and analyzed for changes in ERalpha mRNA using RNase protection assays (RPA) and in situ hybridization using radiolabeled probes specific for ERalpha. Immunohistochemical analysis was performed with a polyclonal antibody specific to ERalpha. Expression of ERalpha in the uterine epithelial cells decreased at 3 and 6 h after estradiol administration to immature and adult rats, respectively. At 24 h, ERalpha mRNA levels in the immature and mature rat uterus were higher than pretreatment levels but returned to baseline by 72 h. Pretreatment with cycloheximide did not block the 3-h repressive effect of estradiol, suggesting that the estradiol-induced decrease in ERalpha mRNA occurs independent of new protein synthesis. A decrease in ERalpha mRNA and protein was also observed in uterine epithelia at 3 and 6 h after an estradiol injection to immature and adult rats, and intensity of both the in situ hybridization signal and the immunostaining in the epithelium increased at 24 and 72 h. However, the periluminal stromal cells in the adult uterus and the majority of stromal cells of the immature uterus appeared to have increased ERalpha expression. The results indicate that down-regulation of ERalpha in the epithelia and up-regulation of stromal ERalpha play a role in early events associated with estradiol-induced cell proliferation of the uterine epithelia.     

Investigation of the representativeness of a single endometrial sample and the use of trichrome staining to aid in the detection of endometrial fibrosis in the mare

The uteri of five mares were removed and endometrial samples were procured from 12 specific locations in the uteri and the samples were processed and duplicate sections were stained with hematoxylin and eosin (H&E) or Masson's trichrome stains. The samples were interpreted in a blind manner by one person, and pathologic changes were classified according to Kenney (1). An assessment of stromal fibrous connective tissue and focal periglandular fibrosis or fibrotic nests was made. There were no significant differences in luminal epithelial cell heights or in the occurrence and severity of stromal fibrous connective tissue, focal periglandular fibrosis, or lymphatic lacunae among locations (P > 0.05). There was an effect of location on the occurrence and severity of inflammation (P < 0.05). If only inflammation was considered in categorization, this would have resulted in changing the category in 9 of 60 samples. There was no increase in tendency for inflammation, fibrosis or lymphatic lacunae to occur in the horns versus the body of the uterus, nor of the dorsal versus the ventral uterus (P > 0.05). There was no effect (P > 0.05) of type of stain on the ability to detect incidence and severity of focal periglandular fibrosis. There was an effect (P < 0.05) of type of stain on the ability to detect the incidence and severity of stromal fibrous connective tissue. The use of the trichrome stain showed slightly increased distribution of stromal fibrous connective tissue.     

Detection of estrogen alpha and progesterone receptors and cell proliferation in the uterus during early pregnancy in the goat

The objectives of this study were to investigate in the goat uterus the expression of estrogen-alpha (ER alpha) and progesterone receptors (PR) and their relationship to proliferation indices (Ki-67) during peri-implantation on Days 22 to 30 post coitum (pc). Immunohistochemical methods were used to quantify ER alpha and PR for luminal and deep regions of the endometrium and of the myometrium. On Day 22 pc cell proliferation was only observed in the luminal epithelium. On Day 24 pc, high cell proliferation indices were seen in luminal epithelium and proliferation began in the luminal stroma and glands. There was a positive correlation between Ki-67 and total ER alpha score in the luminal epithelium (r = 0.53, P < 0.01). Levels of PR scores were highly correlated with Ki-67 indices in luminal epithelium (r = 0.74, P < 0.01) and stroma (r = 0.70, P < 0.01). No Ki-67 expression was observed in deep glands, stroma or myometrium on any of the days studied. Results indicate that patterns of ER alpha and PR expression differ markedly, and that there was a high correlation between PR expression and cell proliferation in the caprine uterus during the peri-implantation period.     

Steroidal control mechanism of cell proliferation in mouse uterine epithelium

The percentage of labeled cells in the uterine luminal epithelium of cycling mice showed the different zonal distributions at each stage of estrous cycle after cumulative labeling with 3H-thymidine for 36 hr. It was estimated that the proliferating fraction in the epithelium at proestrus, estrus, metestrus, and diestrus was 100%, 100%, 40% and 5%, respectively. The percentage of labeled cells in the uterine luminal epithelium of cycling mice treated with progesterone remained below 10% level for at least 20 hr after injections of progesterone. Total labeling was attained in the uterine epithelium of castrated mice by the administration of estradiol-17beta. On the other hand, the cell proliferation in the uterine epithelium of castrated mice treated with estradiol and progesterone was markedly suppressed and the percentage of labeled cells remained approximately at 35%. The remaining cell population, however, still showed the mitotic potency when mice received estradiol. It is suggested from this study that the effect of progesterone is to suppress the epithelial cell proliferation and transfer cells into resting cell fraction which is still evoked to proliferate as the effect of estradiol and that a key factor controlling epithelial proliferation in mouse uterus during the estrous cycle is proliferating fraction rather than cell cycle time.     

Light and electron microscopic radioautography of DNA synthesis in the endometria of pregnant-ovariectomized mice during activation of implantation window.

Pregnant mice were ovariectomized at pre-implantation stage and exogenous nidatory estradiol was administered to evaluate the DNA synthesis of the endometrial cells during activation of uterine receptivity for blastocyst implantation. After 0, 3, 6, 12 and 18 hrs. of estradiol treatment, the animals received 3H-thymidine injection, sacrificed 1 hr. later, and the uteri were prepared for light and electron microscopic radioautography. At time 0, no labelled stromal or epithelial cells was found in the endometrium. According to the time-lapse after estradiol induction, a gradual increase of labelled stromal and endothelial cells was seen in the endometrium. The highest labeling index was observed at the antimesometrial side of the implantation sites and the lowest value was found at the interimplantation site. The cells found at mesometrial side of the implantation site showed an intermediate labeling index. Eighteen hrs. after estradiol treatment, the labelled stromal cells found near the implantation chamber resembled the morphology of decidual cells while those labelled cells localized at the interimplantation sites were similar to the fibroblast. The uterine luminal epithelial cells showed low DNA synthesis after estradiol treatment resulting in only a few labelled cells at the interimplantation sites and no labelled cells at the implantation sites. A similar labeling pattern was seen in the glandular epithelium. The distribution of labelled cells seen among the regions of pregnant endometrium under estradiol effect suggest that DNA synthesis related to uterine activation for blastocyst implantation is a focal reaction, where the luminal epithelium does nt proliferate while the stromal and endothelial cells around the conceptus increase the DNA synthesis to prepare the endometrial decidualization.     

Postnatal mammary ductal growth: three-dimensional imaging of cell proliferation,effects of estrogen treatment,and expression of steroid receptors in prepubertal calves

Cows may provide insights into mammary development that are not easily obtained using mouse models. Mammary growth in control and estrogen-treated calves was investigated to evaluate general patterns of proliferation and relationship to estrogen receptor (ER) expression. After in vivo labeling with bromodeoxyuridine (BrdU), serial histological sections of mammary tissue were used to generate three-dimensional reconstructions. BrdU-labeled cells were present throughout the highly branched terminal ducts. ER and progesterone receptors (PR) were colocalized in nuclei of ductal epithelial cells. However, basal cells and epithelial cells that were located in the central region of epithelial cords and those that lined the lumen of patent ducts were ER- and PR-negative, as were stromal cells. Cells along the basal portion of the epithelium were not myoepithelial. ER in mammary epithelial cells but not stromal cells is analogous to patterns in human breast but contrasts with localization in murine mammary gland. After estrogen stimulation, 99% of BrdU-labeled (and Ki67-labeled) epithelial cells were ER-negative. Data suggest that proliferation in response to estrogen treatment was initiated within ER-positive epithelial cells of the developing mammary gland and the signal was propagated in paracrine fashion to stromal elements and ER-negative epithelial cells.     

Interleukin-18 (IL-18) mRNA expression and localization of IL-18 mRNA-expressing cells in the mouse uterus

Interleukin-18 (IL-18) belongs to the interleukin-1 family and was identified as an interferon-gamma inducing factor. We investigated IL-18 mRNA-expressing cells in the mouse uterus. By RNase protection assay, IL-18 mRNA and alpha subunit of IL-18 receptor mRNA were detected in the uterus. In the uterus, IL-18 mRNA levels increased during sexual maturation. In situ hybridization analysis demonstrated IL-18 mRNA-expressing cells in the mouse uterus of different ages. At 21 days of age, IL-18 mRNA-expressing cells were detected in the luminal epithelial cells and stromal cells although the IL-18 mRNA signal was weak. At 42 days of age, IL-18 mRNA signal was mainly detected in the stromal cells located near the myometrium, and in some of the luminal and glandular epithelial cells. In the uterus of 63-day-old adult mice, a strong hybridization signal for IL-18 mRNA was detected at estrus, but was weak at diestrus. IL-18 mRNA was mainly detected in the glandular epithelial cells and stromal cells. The effect of estradiol-17beta (E(2)) on IL-18 mRNA-expressing cells in the uterus was examined in ovariectomized mice. In oil-treated mice IL-18 mRNA signal was localized in luminal epithelial cells and stromal cells, while in E(2)-treated mice IL-18 mRNA signal was localized in stromal cells alone. These results suggest that the mouse uterus has an IL-18 system, and IL-18 exerts a physiological role within the uterus in a paracrine manner, and that IL-18 gene expression is regulated by estrogen.     

Involvement of androgen receptor in 17beta-estradiol-induced cell proliferation in rat uterus

Although it is known that, in the uterus, estrogen receptor alpha (ERalpha) is involved in proliferation and progesterone receptor in differentiation, the role of the two other gonadal-hormone receptors expressed in the uterus, androgen receptor (AR) and estrogen receptor beta (ERbeta), remains undefined. In this study, the involvement of AR in 17beta-estradiol (E(2))-induced cellular proliferation in the immature rat uterus was investigated. AR levels were low in the untreated immature uterus, but 24 h after treatment of rats with E(2), there was an increase in the levels of AR and of two androgen-regulated genes, IGF-I and Crisp (cysteine-rich secretory protein). As expected, E(2) induced proliferation of luminal epithelial cells. These actions of E(2) were all blocked by both the antiestrogen tamoxifen and the antiandrogen flutamide. The E(2)-induced AR was found by immunohistochemistry to be localized exclusively in the stroma, mainly in the myometrium, where it colocalized with ERalpha but not with ERbeta. ERbeta, detected with two different ERbeta-specific antibodies, was expressed in both stromal and epithelial cells either alone or together with ERalpha. Treatment with E(2) caused down-regulation of ERalpha and ERbeta in the epithelium. The data suggest that, in E(2)-induced epithelial cell proliferation, ERalpha induces stromal AR and AR amplifies the ERalpha signal by induction of IGF-I. Because AR is never expressed in cells with ERbeta, it is unlikely that ERbeta signaling is involved in this pathway. These results indicate an important role for AR in proliferation of the uterus, where estrogen and androgen do not represent separate pathways but are sequential steps in one pathway.     

Differential expression and estrogen response of lactoferrin gene in the female reproductive tract of mouse,rat, and hamster

Lactoferrin, an iron-binding glycoprotein, kills bacteria and modulates inflammatory and immune responses. Presence of lactoferrin in the female reproductive tract suggests that the protein may be part of the mucosal immune system and act as the first line of defense against pathogenic organisms. We have discovered that lactoferrin is a major estrogen-inducible protein in the uterus of immature mice and is up-regulated by physiological levels of estrogen during proestrous in mature mice. In the present study, we examined lactoferrin gene expression and its response to estrogen stimulation in the female reproductive tract of several strains of immature mouse, rat, and hamster. The lactoferrin expression in the cycling adult female rat was also evaluated. Lactoferrin gene polymorphism exists among the different mouse strains. In the three inbred mouse strains studied, lactoferrin gene expression is stimulated by estrogen in the immature uterus, although it is less robust than in the outbred CD-1 mouse. We found that the lactoferrin gene is constitutively expressed in the epithelium of the vagina and the isthmus oviduct; however, it is estrogen inducible in the uterus of immature mice and rats. Furthermore, lactoferrin is elevated in the uterine epithelium of the mature rat during the proestrous and estrous stages of the estrous cycle. Estrogen stimulation of lactoferrin gene expression in the reproductive tract of an immature hamster is limited to the vaginal epithelium. The present study demonstrates differential expression and estrogen responsiveness of the lactoferrin gene in different regions of the female rodent reproductive tract and variation among the rodent species studied.     

Effect of estradiol and progesterone on phosphatidylinositol metabolism in the uterine epithelium of the mouse

The effect of estradiol and progesterone on uterine phosphatidylinositol (PtdIns) metabolism was examined in whole uteri and separated uterine luminal epithelium of ovariectomized mice. Incorporation of [3H]myo-inositol in vitro, into inositol-containing phospholipids extracted from whole uteri, increased in mice injected with estradiol, with maximal incorporation at 9-12 h. The breakdown of PtdIns to inositol polyphosphates was also stimulated in whole uteri by estrogen, with an abrupt increase between 6 and 9 h. Comparable increases in both processes occurred in the uterine epithelium after estrogen stimulation and were inhibited by progesterone pretreatment which by itself had little or no effect. These results suggest that PtdIns metabolism is involved in the stimulation of uterine epithelial cell proliferation by estrogens, and its inhibition by progesterone.     

Immunohistochemical localization of prostaglandin synthase in the rat uterus and embryo during the peri-implantation period

Prostaglandins (PGs) appear to have a role in the appearance of the increased uterine vascular permeability and subsequent decidualization observed at implantation in many species. However, the sites of production of these PGs have not been clearly established. To clarify the PG synthetic capacity of the blastocyst and the various types of cells in the uterus at implantation, we have studied the immunohistochemical localization of PG synthase in the rat blastocyst on Days 5 to 7 and uterus on Days 1, 4, 5, 6, and 7 of pregnancy. Labeling of PG synthase was negligible in the uterus on Day 1 of pregnancy. On Day 4, there was increased labeling in the luminal and glandular epithelium, in stromal cells adjacent to the luminal epithelium, and in blood vessels and some leukocytes. PG synthase was detected in the blastocysts on Days 5 to 7, but there was a gradual loss of label in the luminal and glandular epithelial cells during this period. Early differentiating stromal cells adjacent to the luminal epithelium in the implantation site on Day 5 showed bright labeling, whereas peripheral stromal cells were only slightly labeled. By Day 7, the differentiated cells of the primary decidual zone showed little or no label, but cells in the secondary decidual zone were brightly labeled. These results indicate that PG synthase is present in the rat blastocyst and in several kinds of uterine cells, and that its localization in uterine cells changed markedly during the implantation process.     

Estrogen induces a systemic growth factor through an estrogen receptor-alpha-dependent mechanism

Estrogen induces proliferation of uterine epithelium through a paracrine action of estrogen receptor (ERalpha) in the underlying stroma. In ovariectomized mice primed with progesterone, estrogen stimulates proliferation in both the epithelium and the stroma. We set out to test whether a paracrine mode of action is involved in estrogen-induced proliferation of the uterine stroma. Epithelial and mesenchymal tissues derived from uteri of neonatal ERalpha null mice (ERalphaKO) or wild-type mice were separated and recombined in all four possible configurations (ERalpha+ or ERalpha- epithelium with ERalpha+ or ERalpha- mesenchyme) and grafted into female athymic mice. After 5 wk, hosts were ovariectomized and challenged with hormone treatment, and cellular proliferation was monitored by thymidine autoradiography. Results showed that, although the full response of the epithelium was dependent on an ERalpha-positive mesenchyme, stromal cell proliferation was independent of tissue ERalpha. This latter observation suggests that the response of the stroma was due to a systemic factor induced in the ERalpha-positive hosts. To test this possibility, pieces of whole uterus from neonatal wild-type or ERalphaKO mice were grafted into syngeneic wild-type or ERalphaKO hosts. In these whole-uterus grafts, estradiol stimulated ERalphaKO uterine stroma when they were grown in wild-type hosts but not when grown in ERalphaKO hosts. The epithelium of whole-uterus ERalphaKO grafts did not respond to estrogen, regardless of the host phenotype. These observations suggest that treatment of progesterone-primed mice with estradiol stimulates production of a systemic factor that is capable of inducing uterine stromal cell proliferation and that this systemic factor is produced by an ERalpha-dependent mechanism.     

Regulation of progesterone receptors and decidualization in uterine stroma of the estrogen receptor-alpha knockout mouse

Regulation of progesterone receptor (PR) in uterine stroma (endometrial stroma plus myometrium) by estrogen was investigated in estrogen receptor-alpha (ERalpha) knockout (alphaERKO) mice. 17 beta-Estradiol (E(2)) increased PR levels in uterine stroma of ovariectomized alphaERKO mice, and ICI 182 780 (ICI) inhibited this E(2)-induced PR expression. Estrogen receptor-beta(ER beta) was detected in both uterine epithelium and stroma of wild-type and alphaERKO mice by immunohistochemistry. In organ cultures of alphaERKO uterus, both E(2) and diethylstilbestrol induced stromal PR, and ICI inhibited this induction. These findings suggest that estrogen induces stromal PR via ERbeta in alphaERKO uterus. However, this process is not mediated exclusively by ERbeta+, because in ERbeta knockout mice, which express ERalpha, PR was up-regulated by E(2) in uterine stroma. In both wild-type and alphaERKO mice, progesterone and mechanical traumatization were essential and sufficient to induce decidual cells, even though E(2) and ERalpha were also required for increase in uterine weight. Progesterone receptor was strongly expressed in decidual cells in alphaERKO mice, and ICI did not inhibit decidualization or PR expression. This study suggests that up-regulation of PR in endometrial stroma is mediated through at least three mechanisms: 1) classical estrogen signaling through ERalpha, 2) estrogen signaling through ERbeta, and 3) as a result of mechanical stimulation plus progesterone, which induces stromal cells to differentiate into decidual cells. Each of these pathways can function independently of the others.     

The effects of sequential administration of 17 beta-estradiol on the synthesis and secretion of specific proteins in the immature rat uterus

We report here results of a study of the effect of sequential administration of 1 microgram 17 beta-estradiol in vivo on the incorporation of L-[35S]methionine into specific proteins in vitro in the immature rat uterus. One-dimensional SDS-PAGE analysis of labeled secreted uterine proteins and cellular proteins extracted from the luminal epithelial and from the stroma plus myometrial uterine fractions revealed that estradiol preferentially stimulated the synthesis of 110 K, 74 K and 66 K secreted proteins, 180 K and 110 K epithelial proteins and a 175 K stroma-myometrial protein among others, while it decreased the relative rate of synthesis of a 32.5 K secreted protein and a 70 K stroma-myometrial protein. The 110 K protein, a secreted luminal epithelial protein whose labeling in vitro dramatically increased greater than 60-fold per mg endometrial DNA after in vivo estrogen stimulation, may be a useful marker for studying estrogen action in the luminal epithelium of the immature rat uterus. Comparison of the secreted proteins labeled at 28 h (4 h after a second injection) and at 54 h (6 h after a third injection) revealed that estradiol effected a sequential change in the pattern of synthesis of secreted uterine proteins in vitro. Comparison of the number and magnitude of changes in the synthesis of specific proteins in the luminal epithelium and the stroma plus myometrium revealed that protein synthesis in the luminal epithelium is clearly more responsive to estradiol and readily distinguishable from the responsiveness of the stroma plus myometrium.