INTERACTION OF ESTROGEN AND PROGESTERONE IN CHICK OVIDUCT DEVELOPMENT : II. Effects of Estrogen and Progesterone on Tubular Gland Cell Function

The effects of estrogen and progesterone on the function of chick oviduct tubular gland cells have been studied. Such function, as measured by the increase in specific cell products such as lysozyme and ovalbumin, requires the continuous presence of estrogen or progesterone. Withdrawal of hormone results in a rapid cessation of function and an involution of the oviduct accompanied by rapid decreases in total weight, lysozyme, and RNA. During such involution, tubular gland cells per se persist, as evidenced by a lack of comparable decrease in total DNA content and by histological demonstration of tubular gland cells. When estrogen administration is reinstituted, preexisting tubular gland cells rapidly synthesize ovalbumin and lysozyme without requiring new DNA synthesis. Administration of progesterone also stimulates the function of such cells. Furthermore, the effects of estrogen and progesterone are synergistic on the synthesis of lysozyme and ovalbumin, whereas progesterone antagonizes the estrogen-evoked formation of tubular gland cells. It is suggested that such complex interactions of estrogen and progesterone on oviduct development and function result from differences in responsiveness of the various cell types present in the tissue.     

Sex-steroid-sensitive stromal cells and oviduct differentiation

The chick oviduct differentiates during sexual maturation before the age of 20 weeks. In the present work we used immunohistochemistry to study sexual maturation associated progesterone receptor (PR) expression in the chick oviduct as an indication of progesterone sensitivity. Since the PR is estrogen inducible protein, its expression also reflects the effects of endogenous estrogens. Thus PR expression can be used as a marker for action and sensitivity of cells to these sex steroids. In the luminal epithelium and mesothelium (peritoneal epithelium) the PR was expressed in high concentrations from the time before hatching (the constitutive PR). The PR was not detectable in stromal cells of immature chicks. At the age of 7-10 weeks the PR was detected in submucosal but not in mucosal stromal cells (the inductive PR). The appearance of these PR-expressing cells was associated with an increase in luminal epithelial cell proliferation. At the age of 14-16 weeks the mucosal plicae increased in height and the PR-expressing stromal cells were seen in the center of these mucosal plicae. There were also areas in the mucosal plicae where a large number of stromal cells expressing the PR were seen in the mucosal layer. Thereafter the size of the oviduct increased rapidly and the gland formation commenced. In the fully matured oviduct (over 18 weeks of age) virtually all stromal cells both in mucosa and submucosa expressed the PR. It is concluded that the PR expression in the luminal epithelium and mesothelium was constitutive (independent of sexual maturation). In stromal cells this was expressed during sexual maturation (probably induced by endogenous estrogen) and was associated with histological changes in the oviduct. We propose that direct effects of estrogen and progesterone in the oviduct growth and glandular formation are mediated through these stromal cells.     

INTERACTION OF ESTROGEN AND PROGESTERONE IN CHICK OVIDUCT DEVELOPMENT : I. Antagonistic Effect of Progesterone on Estrogen-Induced Proliferation and Differentiation of Tubular Gland Cells

Daily administration of estrogen to immature female chicks results in marked oviduct growth and appearance of characteristic tubular gland cells which contain lysozyme. Although a rapid increase in total DNA and RNA content begins within 24 hr, cell specific protein, lysozyme, is first detectable after 3 days of estrogen. Progesterone administered concomitantly with estrogen antagonizes the estrogen-induced tissue growth as well as appearance of tubular gland cells and their specific products, lysozyme and ovalbumin. When the initiation of progesterone administration is delayed for progressively longer periods (days) during estrogen treatment, proportionally greater growth occurs with more lysozyme and tubular gland cells after 5 days of total treatment. Progesterone does not inhibit the estrogen-stimulated increase in uptake of α-aminoisobutyric acid and water by oviduct occurring within 24 hr or the estrogen-induced increase in total lipid, phospholipid, and phosphoprotein content of serum. The above results of progesterone antagonism can best be explained by the hypothesis that progesterone inhibits the initial proliferation of cells which become tubular gland cells but does not antagonize the subsequent cytodifferentiation leading to the synthesis of lysozyme and ovalbumin once such cell proliferation has occurred.     

In vitro canine oocyte nuclear maturation in homologous oviductal cell co-culture with hormone-supplemented media

The aim of the present research was to verify the influence of oviductal cell co-culture previously supplemented with steroids (estrogen, progesterone, or both) on IVM rates for oocytes from anestrous bitches that were cultured in vitro for 48, 72 and 96 h. Oocytes harvested from anestrous bitches were selected and allocated into four groups: Group 1 (co-culture in oviductal epithelial cells without hormonal supplementation-control); Group 2 (estrogen supplementation); Group 3 (progesterone supplementation); Group 4 (estrogen+progesterone supplementation). The oviductal epithelial cell culture was established 72 h prior to oocyte co-culture. After periods of 48, 72 and 96 h, the degree of oocyte nuclear maturation was assessed. Co-culture in oviductal epithelial cells with estrogen was not as beneficial for canine IVM as supplementation with progesterone and estrogen, or progesterone supplementation alone. Therefore, it was feasible to use co-culture with oviductal epithelial cells obtained from anestrous bitches for IVM (monolayer culture with oviduct cells previously supplemented with progesterone). Final stages of oocyte maturation were achieved at 72 and 96 h of culture; therefore, the duration of maturation for oocytes obtained from bitches in different stages of the estrous cycle should be taken into account.     

In situ hybridization of ovalbumin mRNA in the chick oviduct reveals target cell specificity for estrogen and progesterone

An in situ hybridization method using paraffin-embedded sections was used to characterize the chicken oviduct cells synthesizing ovalbumin mRNA due to the action of estrogen and progesterne. The cytodifferentiation of the oviduct cells was induced by 17β-estradiol administration to newly hatched female chicks. To avoid possible effect of estrogen on the action of progesterone the chicks were withdrawn from the estrogen by six days withdrawal period without hormone treatment. Ovalbumin mRNA was not synthesized after a period of estrogen withdrawal. Administration of estrogen induced ovalbumin mRNA in the tubular gland cells. Administration of progesterone induced the expression of ovalbumin mRNA in the surface epithelial cells. It was also found that progesterone induced mucus producing goblet cells in the surface epithelium. Estrogen did not have an effect on the mucus production, which suggests that progesterone could induce the terminal differentiation of the goblet cells. We conclude that the expression of ovalbumin in the surface epithelial cells and in the tubular gland cells is specific for progesterone and estrogen, respectively.     

Estrogen Receptor Is Not Primarily Responsible for Altered Responsiveness of Ovalbumin mRNA Induction in the Oviduct From Genetically Selected High- and Low-Albumen Chicken Lines

The role of estrogen receptor on ovalbumin mRNA induction by steroid hormones was investigated in primary cultures of oviduct cells from estrogen-stimulated immature chicks of genetically selected high- and low-albumen egg laying lines (H- and L-lines). In experiment 1,the extent of ovalbumin mRNA induction and changes in estrogen and progesterone receptors were compared between the oviduct cells from H- and L-lines with or without steroid hormones in the culture medium. In experiment 2, the effect of estrogen receptor gene transfection on the induction of ovalbumin mRNA was studied in the oviduct cells from the L-line chicks. The results showed a close correlation of the changes in ovalbumin mRNA with the numbers of nuclear and total estrogen receptors in the oviduct cells but not with the numbers of nuclear and total progesterone receptors. Estrogen receptor gene transfection induced ovalbumin mRNA to a moderate extent in the absence of the steroid hormones. To our surprise, however, estrogen receptor gene transfection apparently suppressed the ovalbumin mRNA responsiveness to estrogen to a considerable extent. It was concluded, therefore, that the extent of estrogen receptor expression might not be primarily responsible for the differences in responsiveness to steroid hormones of oviduct cells from genetically selected H- and L-line chickens.     

Progesterone abbreviates the nuclear retention of estrogen receptor in the rat oviduct and counteracts estrogen action on egg transport

Progesterone has synergistic or antagonistic effects on several estrogenic actions. The effects of progesterone on estrogen-induced accelerated ovum transport and on the dynamics of estrogen receptors in the rat oviduct were examined. The involvement of the progesterone receptors in these phenomena was assessed. On Day 1 of pregnancy, rats were treated with estradiol, estradiol plus progesterone, or either one plus the progesterone receptor-blocking agent RU486. Control animals received the oil vehicle alone. The number of eggs remaining in the oviduct was assessed 24 h after treatment. Cytoplasmic and nuclear estrogen receptor levels in the oviduct, as well as plasma concentrations of estradiol and progesterone, were measured at various intervals--up to 11 h and 24 h after treatment, respectively. Accelerated oviductal egg transport induced by estrogen was blocked by the concomitant administration of progesterone. This effect of progesterone was not associated with changes in estrogen circulating levels and was preceded by a reduction in the total amount of estrogen receptors and by a shortened retention of estrogen receptors in the nucleus. The effects of progesterone on egg transport and on the levels of estrogen receptors were reversed by blocking the progesterone receptor with RU486, suggesting that both effects were receptor-mediated. These findings demonstrate that progesterone antagonizes the effect of estrogen on oviductal egg transport in the rat, and suggest that this antagonism is mediated by a reduction both in the amount of estrogen receptors and in their retention time in the nucleus.     

Characterization of newly established clonal oviductal cell lines and differential hormonal reculation of gene expression

Summary Oviductal functions have been studied mainly in primary epithelial cell culture and organ culture. However, secretory cells and ciliated cells coexist in the epithelium, and the small size of the oviduct limits the sources of both epithelial and stromal cells. To circumvent the limits, we attempted to establish clonal cell lines from an oviduct of a p53-deficient mouse. An oviduct was enzymatically digested and cultured in medium containing 10% fetal calf serum supplemented with estradiol-17β. Morphologically distinct clones (10 epithelial and 4 fibroblastic clones) were established, and all clones expressed estrogen receptor α and progesterone receptor. Expression of a mouse oviduct-specific glycoprotein gene as a marker of secretory cells was limited in one clone and was stimulated by estrogens and suppressed by progesterone. Expression of helix factor hepatocyte nuclear factor/forkhead homologue-4 gene as a marker of ciliated cells was limited in two clones and was suppressed by estrogens. The two genes were never coexpressed in any clones. The results strongly suggest that the oviductal epithelium consists of two functionally determined populations. To our knowledge, this is the first establishment of functional clonal cell lines of the oviduct and makes it possible to study independently two oviductal functions, secretion and ciliogenesis.     

Estrogen and progesterone receptors in the oviduct during egg transport in cyclic and pregnant rats

We investigated the temporal relationships between ovum transport and changes in the concentration of nuclear steroid receptors in the oviduct of cyclic and pregnant rats. A lack of parallelism between estrogen and progesterone fluctuations in plasma and their respective nuclear receptor concentrations in the oviduct predominated during egg transport. In pregnant animals, oviductal egg transport took 24 h longer than in nonpregnant animals. In both conditions, transport was initiated while the action of estrogen and progesterone on the oviduct--measured as nuclear receptor accumulation--was decreasing. Three or four days later, depending on whether the animal was pregnant, the eggs entered the uterus shortly after an increase in the nuclear receptor accumulation of both hormones. Treatment with RU486, a progesterone receptor-blocking agent known to cause premature arrival of eggs in the uterus, advanced estrogen receptor accumulation in the oviduct of pregnant rats. These data suggest that the arrival of eggs in the uterus is timed by a transitory increase in nuclear estrogen receptor in the oviduct that does not necessarily reflect a similar change of circulating estradiol. Moreover, in pregnant rats, the onset of this estrogenic action is delayed by a progesterone receptor-mediated effect that hinders nuclear estrogen receptor accumulation.     

Immunocytochemical localization of atrial natriuretic factor (ANF) in rat female reproductive tract: evidence for a potential hormonal regulation

In the present studies atrial natriuretic factor (ANF) was characterized immunocytochemically in the reproductive tract of immature female rats, and changes of ANF levels in response to different hormonal conditions were demonstrated. Administration of pregnant mare serum gonadotropin (PMSG) to immature animals has shown to be a useful method to synchronize growth, differentiation and atresia of ovarian follicles. ANF immunoreactivity was investigated in rat uterus and oviduct during follicular growth and estrogenic dominance (48 h after PMSG treatment) and during follicular atresia and progesterone dominance (96 h after PMSG treatment). Our immunocytochemical results showed that in rat uterus ANF was localized in endometrial mucosal and glandular epithelium and smooth muscle cells of the myometrium. In the oviduct ANF immunoreactivity was observed in mucosal cells and muscle layers. Immunocytochemical staining patterns and Western blot analysis revealed that ANF levels in rat uterus and oviduct are modulated by the hormonal status. ANF immunoreactivity was elevated during estrogenic dominance (48 h after PMSG) in uterus and oviduct. However, during progesterone dominance (96 h after PMSG) elevation of ANF immunoreactivity was observed in the uterus only. These results raise the possibility that ANF expression in rat oviduct is positively controlled by estrogen and negatively by progesterone. ANF staining in uterus during progesterone phase provides evidence that both estrogen and progesterone regulate ANF levels in uterus. The observed staining patterns indicate that ANF may have intracellular functions as well as a role in priming the extracellular environment. Accordingly, the possibility that ANF might be an important regulatory molecule for autocrine/paracrine communication within the female reproductive tract should be considered.     

Distribution of estrogen receptor α and progesterone receptor B in the bovine oviduct during the follicular and luteal phases of the sexual cycle: an immunohistochemical and semi-quantitative study

Abstract

The aim of our study was to determine the distribution of estrogen receptor α (ERα) and progesterone receptor B (PR-B) in the bovine oviduct during the follicular and luteal phases. Bovine oviducts from 23 animals were obtained from a local slaughterhouse. Blood samples from these animals also were taken before death to measure estrogen and progesterone levels. The serum levels of estradiol-17β and progesterone changed during the estrous cycle. Tissue distribution of ERα and PR-B was examined using immunohistochemical techniques and the results showed that ERα and PR-B were stained in nuclei of cells and could be detected in all compartments along the entire oviduct during both the follicular and luteal phases. During the follicular phase, no significant differences were found between ERα and PR-B distribution (p < 0.05), while significant differences were found between ERα and PR-B during the luteal phase (p < 0.05). We results indicated that the frequency and intensity of ERα and PR-β immunoreactivity in the oviduct of bovines varied according to the oviductal cell types and the phases of the sexual cycle.     

Immunoelectron microscopic localization of progesterone receptor in the chick oviduct

A peroxidase-anti-peroxidase (PAP) method using polyclonal anti-PR antibodies was used to localize progesterone receptor (PR) electron microscopically in the chick oviduct. The immunoreaction precipitate indicating PR was localized inside the nuclei of epithelial, glandular and stromal cells. In the estrogen withdrawn oviduct cytoplasmic immunoreaction precipitate was not seen. Inside the nucleus unoccupied PR was localized mainly like the heterochromatin. As visualized by the PAP technique, the localization of PR was not systematically changed after progesterone administration. In conclusion, we suggest that progesterone receptor in the chick oviduct is an intranuclear protein.     

Hormone-dependent changes in A and B forms of progesterone receptor

The influence of different estrogen and/or progesterone treatments on concentrations of A and B forms of progesterone receptor (PR-A and PR-B) in the different cell types of chick oviduct was studied. A semiquantitative immunohistochemical assay for cellular PR concentrations was developed using a computer-assisted image analysis system. The staining intensity of nuclear PR in the basal layer of epithelial cells, glandular, smooth muscle and mesothelial cells was analysed separately using two monoclonal antibodies, PR6 and PR22. The measured concentrations of PR varied between different cell types and from cell to cell. A significant decrease in PR concentration, as noted by a decrease in staining intensity, was observed in all cell types studied 2 or 6 h after a single injection of progesterone with or without simultaneous estrogen administration. The decrease was also verified with immunoblotting and an immunoenzymometric assay (IEMA) for chicken PR. After down-regulation the concentration of PR recovered to the control level within 48 h after progesterone or estrogen administration. Estrogen administration alone was observed to cause changes in the concentration of PR-A only, having little or no effect on PR-B concentration depending on the cell type studied.

These findings indicate that estrogen and progesterone cause cell-specific changes not only to the total concentration of PR but also to the cellular ratio of PR-A and PR-B.     

Regulation of nuclear binding of the avian oviduct progesterone receptor. Changes during estrogen-induced oviduct development, withdrawal, and secondary stimulation

The progesterone receptors from various stages of estrogen induced oviduct development, estrogen withdrawal, and secondary stimulation with estrogen were examined. The progesterone receptors were characterized for their biological function (i.e. capacity for nuclear translocation, nuclear binding, and effects on RNA polymerase II activity) as well as certain physical properties. The progesterone receptors from the undeveloped or partially developed oviducts (0 to 8 days of estrogen treatment) displayed little or no nuclear translocation and binding in vivo or in vitro. Similarly, progesterone showed little or no effect in vivo on RNA polymerase II activity at the early stages of development. As development progressed from 8 to 12 days of estrogen treatment, the above parameters rapidly increased to maximal levels and plateaued through day 23 of estrogen treatment. A marked decrease in these parameters occurred within 1 day of estrogen withdrawal. The reverse series of events occurred during secondary estrogen stimulation of 10-day-old withdrawn chicks. While the receptor concentrations increased rapidly to maximum values by 2 days of restimulation, receptor function did not return until day 4. Similarly, the effects of progesterone on RNA polymerase II activity reached maximal values by day 4. The progesterone receptor isolated from oviducts during development, estrogen withdrawal, and restimulation, displayed similar patterns of cell-free binding to chromatin and nucleoacidic protein as that observed in vivo supporting the nativeness of the in vitro binding assay. In contrast, the cell-free binding of these same progesterone receptor to pure DNA were not similar to the in vivo binding, i.e. no patterns (differences) in progesterone receptor binding were observed. These data support that protein DNA complexes and not pure DNA represent the native acceptor sites for oviduct progesterone receptor. Comparison of the progesterone receptor between the functional and nonfunctional states revealed no differences in the steroid affinity for the receptor, in the apparent pI of the species, or in the sedimentation of the receptor under high salt conditions. However, the nonfunctional receptors consistently displayed a deficiency in one of the two monomer molecular species (the B species) as determined by isoelectric focusing. These results suggest that both monomer species of progesterone receptor are required for biological activity. Interestingly, the 7S "aggregate" species of the progesterone receptor was constantly detected even when only one of the monomer species was present.(ABSTRACT TRUNCATED AT 400 WORDS)     

Expression of the avian c-erb B (EGF receptor) protooncogene during estrogen-promoted oviduct growth

Expression of cellular erb B protooncogene messenger RNAs has been analyzed in the oviducts of immature chicks during estrogen-promoted growth. Hybridization of oviduct total cellular RNA with viral-derived erb B oncogene probes demonstrated significant expression of c-erb B mRNA in oviduct cells of untreated chicks. Daily administration of estrogen (diethylstilbestrol) to chicks results in marked oviduct growth but did not appreciably affect expression levels of c-erb B messenger RNA in oviducts after 2, 4 or 6 days of treatment. Withdrawal of chicks from estrogen treatment resulted in termination of oviduct growth. However, c-erb B messenger RNAs were detectable in the nonproliferative tissue at 5 days after hormone withdrawal. Readministration of diethylstilbestrol, progesterone or diethylstilbestrol plus progesterone to hormone-withdrawn birds (secondary stimulation) also did not affect c-erb B messenger RNA levels in the oviduct. These results demonstrate significant expression of the cellular erb B (epidermal growth factor receptor) gene in the avian oviduct. However, EGF receptor messenger RNA synthesis is not modulated in the oviduct by steroid hormones.     

Sex steroid sensitivity of developing bursa of Fabricius

Sex steroid sensitivity of the bursa of Fabricius (BF) was studied from the early embryonic time until its regression. Expression of progesterone receptor (PR) served as a dual marker: first, as a marker for progesterone sensitivity and second, as a marker for estrogen action, since it is an estrogen-induced protein. The progesterone binding molecule in the bursa was characterized by different chromatography methods and by steroid binding studies. We showed that it fulfils the criteria of a progesterone receptor by binding, structural and immunological properties. With immunohistochemistry and with the combined techniques of immunohistochemistry and autoradiography we demonstrated two cell types which express the PR: smooth muscle cells surrounding the BF and stromal cells located under the bursal epithelium and between the lymphoid follicles. The epithelium and the cells inside the lymphoid follicles were negative. Using immunoelectron microscopy the PR-expressing stromal cells were shown to be fibroblasts. The cloacal mesenchyme, from which the BF develops, was shown to be sensitive to exogenous estrogen very early during the embryonic time. The mesenchyme around and inside the developing BF reached estrogen sensitivity a few days later. The estrogen-sensitive mesenchymal cells were first seen surrounding the bursal primordium and later in the center of the plicae. During a natural sexual maturation without exogenous estradiol an expression of the PR was detected much later, at the age of 10-12 weeks after hatching. This expression correlates with the onset of the bursal regression and with the increase of the sex steroid levels in the blood. In the oviduct stroma PR was undetectable before the onset of sexual maturation. In the oviduct stroma PR becomes detectable a few weeks earlier than in the bursa.     

Establishment and characterization of Xenopus oviduct cells in primary culture

Based on a previously established procedure for Xenopus hepatocytes, we describe tubular oviduct cells in primary culture which continue to secrete substantial quantities of egg jelly for several days, as can be visualized microscopically. Freshly isolated cells exhibited a culture shock response [A. P. Wolffe, J. F. Glover, and J. R. Tata (1984) Exp. Cell Res. 154, 581], from which they recovered by the third day in culture. This recovery was characterized by (a) the diminished synthesis of heat shock proteins hsp 70 and hsp 85, (b) the cessation of the drop in number of estrogen receptor, and (c) the enhanced rate of synthesis of cellular and secreted proteins. The oviduct estrogen receptor had the same characteristics as those in other estrogen target tissues and was present in the same amount as in adult female Xenopus hepatocytes [A. J. Perlman, A. P. Wolffe, J. Champion, and J. R. Tata (1984) Mol. Cell. Endocrinol. 38, 51]. Unlike the latter in primary culture [M. P. R. Tenniswood, P. F. Searle, A. P. Wolffe, and J. R. Tata (1983) Mol. Cell. Endocrinol. 30, 329], oviduct cell cultures did not actively metabolize either estradiol or progesterone (t1/2 approximately equal to 55 and 7 h, respectively). The successful establishment and characterization of primary cultures of both liver and oviduct cells now fulfil the conditions required for investigating the basis for tissue specificity of regulation by estrogen of Xenopus egg protein gene expression in primary cell culture.