Up-regulation of alpha-inhibin expression in the fetal ovary of estrogen-suppressed baboons is associated with impaired fetal ovarian folliculogenesis

We recently demonstrated that the number of primordial follicles was significantly reduced in the ovaries of near-term baboon fetuses deprived of estrogen in utero and restored to normal in animals administered estradiol. Although the baboon fetal ovary expressed estrogen receptors alpha and beta, the mechanism(s) of estrogen action remains to be determined. It is well established that inhibin and activins function as autocrine/paracrine factors that impact adult ovarian function. However, our understanding of the expression of these factors in the primate fetal ovary is incomplete. Therefore, we determined the expression of alpha-inhibin, activin beta(A), activin beta(B), and activin receptors in fetal ovaries obtained at mid and late gestation from untreated baboons and at late gestation from animals in which fetal estrogen levels were reduced by >95% by maternal administration of the aromatase inhibitor CGS 20267 or restored to 30% of normal by treatment with CGS 20267 and estradiol benzoate. Immunocytochemical expression of alpha-inhibin was minimal to nondetectable in fetal ovaries from untreated baboons. In contrast, in baboons depleted of estrogen, alpha-inhibin was abundantly expressed in pregranulosa cells of interfollicular nests and granulosa cells of primordial follicles. Thus, the number (mean +/- SEM) per 0.08 mm2 of fetal ovarian cells expressing alpha-inhibin, determined by image analysis, was similar at mid and late gestation and increased approximately 8-fold (P < 0.01) near term in baboons treated with CGS 20267 and was restored (P < 0.01) to normal in baboons treated with CGS 20267 plus estradiol. Activin beta(A) was detected in oocytes and pregranulosa cells at midgestation and in oocytes and granulosa cells of primordial follicles at late gestation. Activin beta(B) was also expressed in pregranulosa cells and granulosa cells at mid and late gestation, respectively, but was not detected in oocytes. Neither the pattern nor the apparent level of expression of activin beta(A) or beta(B) were altered in fetal ovaries of baboons treated with CGS 20267 or CGS 20267 and estrogen. Activin receptors IA, IB, IIA, and IIB were detected by Western blot analysis in fetal ovaries at mid and late gestation, and expression was not altered by treatment with CGS 20267 or CGS 20267 and estrogen. Activin receptors IB and IIA were localized to oocytes and pregranulosa cells at midgestation and to granulosa cells and oocytes of primordial follicles at late gestation. Thus, the decrease in the number of follicles in the primate fetal ovary of baboons deprived of estrogen in utero was associated with increased expression of alpha-inhibin. Therefore, we propose that estrogen regulates fetal ovarian follicular development by controlling alpha-inhibin expression and, thus, the intraovarian inhibin:activin ratio.     

Developmental regulation of baboon fetal ovarian maturation by estrogen

Ovarian function in adult human and nonhuman primates is dependent on events that take place during fetal development, including the envelopment of oocytes by granulosa (i.e., folliculogenesis). However, our understanding of fetal ovarian folliculogenesis is incomplete. During baboon pregnancy, placental production and secretion of estradiol into the fetus increases with advancing gestation, and the fetal ovary expresses estrogen receptors alpha and beta in mesenchymal-epithelial cells (i.e., pregranulosa) as early as midgestation. Therefore, the current study determined whether estrogen regulates fetal ovarian follicular development. Pregnant baboons were untreated or treated with the aromatase inhibitor CGS 20267, or with CGS 20267 plus estradiol benzoate administered s.c. to the mother on Days 100-164 (term = Day 184). On Day 165, baboon fetuses were delivered by cesarean section and the number of total follicles and interfollicular nests consisting of oocytes and mesenchymal-epithelial cells in areas (0.33 mm(2)) of the outer and inner cortices of each fetal ovary were quantified using image analysis. Maternal and umbilical serum estradiol levels were decreased by >95% with CGS 20267. Treatment with CGS 20267 and estrogen restored maternal estradiol to normal and fetal estradiol to 30% of normal. Although fetal ovarian weight was unaltered, the mean number of follicles +/- SEM/0.33 mm(2) in the inner (59.0 +/- 1.7) and outer (95.3 +/- 2.4) cortical regions of fetal ovaries in untreated animals was 35%-50% lower (P < 0.01) in estrogen-depleted baboons (25.9 +/- 1.4, inner cortex; 62.5 +/- 2.7, outer cortex) and was restored to normal by treatment with CGS 20267 and estrogen. In contrast, the number of interfollicular nests was 2-fold greater (P < 0.01) in fetal ovaries of estrogen-suppressed animals, a change that was prevented by treatment with estrogen. In summary, fetal ovarian follicular development was significantly altered in baboons in which estrogen was depleted during the second half of gestation and restored to normal by estradiol. We propose that estrogen plays an integral role in regulating, and perhaps programming, primate fetal ovarian development.     

Developmental maturation of primate placental trophoblast: placental cytosolic and secretory phospholipase A2 expression after estrogen suppression of baboons

We have demonstrated that the baboon placenta expressed the mRNAs and proteins for secretory and cytosolic phospholipase A2 (PLA2) enzymes and that cPLA2 expression increased with advancing gestation in association with the increase in placental estrogen production. To determine whether estrogen regulates placental PLA2 expression, as it does other aspects of syncytiotrophoblast functional differentiation, we compared sPLA2 and cPLA2 mRNA levels in placentas obtained on day 165 of gestation (term = day 184) from baboons that were untreated or treated during the second half of gestation with the aromatase inhibitor CGS 20267 or CGS 20267 and estradiol. Maternal saphenous and uterine vein estradiol levels were reduced (P < 0.05) by approximately 95% by treatment with CGS 20267 and restored by concomitant administration of CGS 20267 and estrogen. However, sPLA2 and cPLA2 mRNA levels expressed as a ratio of beta-actin were similar in whole villous placenta from baboons that were untreated or treated with CGS 20267 or CGS 20267 plus estrogen. PLA2 expression in an enriched fraction of nontrophoblast cells of the baboon placenta was also not altered by CGS 20267 treatment. Collectively these findings indicate that placental cPLA2 and sPLA2 expression is not estrogen-dependent. Because estrogen has been shown to regulate other aspects of placental steroidogenesis, we suggest that the regulatory role of estrogen on syncytiotrophoblast functional maturation is specific.     

Expression of estrogen receptors alpha and beta in the baboon fetal ovary

In adult mammals, estrogen regulates ovarian function, and estrogen receptor (ER) is expressed in granulosa cells of antral follicles of the adult baboon ovary. Because the foundation of adult ovarian function is established in utero, the present study determined whether ERalpha and/or ERbeta were expressed in fetal ovaries obtained on Days 100 (n = 3) and 165-181 (n = 5) of baboon gestation (term = Day 184). On Day 100, ERalpha protein was detected by immunocytochemistry in surface epithelium and mesenchymal-epithelial cells but not oocytes in germ cell cords. ERbeta protein was also detected by immunocytochemistry on Day 100 of gestation and was abundantly expressed in mesenchymal-epithelial cells in germ cell cords, lightly expressed in the germ cells, but was not detected in the surface epithelium. On Days 165-180 of gestation, ERalpha expression was still intense in the surface epithelium, in mesenchymal-epithelial cells throughout the cortex, and in nests of cells between follicles. ERalpha expression was lighter in granulosa cells and was not observed in all granulosa cells, particularly in follicles close to the cortex. In contrast, ERbeta expression was most intense in granulosa cells, especially in flattened granulosa cells, was weaker in mesenchymal-epithelial cells and nests of cells between follicles, and was absent in the surface epithelium. Using an antibody to the carboxy terminal of human ERbeta, ERbeta protein was also detected by Western immunoblot with molecular sizes of 55 and 63 kDa on Day 100 and primarily 55 kDa on Day 180. The mRNAs for ERalpha and ERbeta were also detected by Northern blot analysis in the baboon fetal ovary. These results are the first to establish that the ERalpha and ERbeta mRNAs and proteins are expressed and exhibit changes in localization in the primate fetal ovary between mid and late gestation. Because placental estrogen production and secretion into the baboon fetus increases markedly during advancing pregnancy, we propose that estrogen plays an integral role in programming fetal ovarian development in the primate.     

Regulation of expression of microvillus membrane proteins by estrogen in baboon fetal ovarian oocytes

We previously demonstrated that the number and height of oocyte microvilli were reduced in baboon fetuses deprived of estrogen in utero and restored to normal in animals supplemented with estradiol. Phosphorylated ezrin and Na+/H+ exchange regulatory factor 1 (NHERF, now termed SLC9A3R1) link f-actin bundles to the membrane, whereas alpha-actinin cross-links f-actin to form microvilli. Therefore, we determined whether these proteins were expressed in oocytes of the fetal baboon ovary and whether expression and/or localization were altered between mid and late gestation in association with an increase in estrogen and in late gestation in animals in which estrogen was suppressed (>95%) or restored by treatment with an aromatase inhibitor with or without estradiol. Expression of alpha-actinin was low at mid gestation, increased on the surface of oocytes of primordial follicles in late gestation, and was negligible in the ovaries of estrogen-suppressed fetuses and normal in animals treated with estrogen. Ezrin (total and phosphorylated) and SLC9A3R1 expression was localized to the surface of oocytes at mid and late gestation in estrogen-replete baboons and to the cytoplasm in late gestation after estrogen suppression. These results are the first to show that the fetal baboon oocyte expressed ezrin, SLC9A3R1, and alpha-actinin, and that these proteins were localized to the oocyte surface consistent with their role in microvilli development in epithelial cells. The current study also showed that the developmental increase in oocyte expression of alpha-actinin is regulated by estrogen and correlated with the estrogen-dependent increase in oocyte microvilli demonstrated previously. Therefore, we propose that development of oocyte microvilli requires expression of alpha-actinin and that expression of alpha-actinin and localization of ezrin-phosphate and SLC9A3R1 to the oocyte membrane are regulated by estrogen.     

Localization and secretion of inhibins in the equine fetal ovaries

To clarify the source of inhibins in equine female fetuses, concentrations of immunoreactive (ir-) inhibin, inhibin pro-alphaC, and inhibin A in both fetal and maternal circulation and in fetal ovaries were measured. In addition, the localization of inhibin alpha and inhibin/activin beta(A), and beta(B) subunits and the expression of inhibin alpha(A) and inhibin/activin beta(A) subunit mRNA in fetal ovaries were investigated using immunohistochemistry and in situ hybridization. Concentrations of circulating ir-inhibin, inhibin pro-alphaC, and inhibin A were remarkably more elevated in the fetal than in the maternal circulation between Days 100 and 250 of gestation. Fetal ovaries contained large amounts of ir-inhibin, inhibin pro-alphaC, and inhibin A. In contrast, these inhibin forms were undetectable in both the maternal ovaries and placenta. The inhibin alpha and inhibin/activin beta(A) and beta(B) subunit proteins were localized to enlarged interstitial cells of the equine fetal ovary. Expression of inhibin alpha and inhibin/activin beta(A) subunit mRNAs were also observed in the interstitial cells. We conclude that the main source of large amounts of inhibins in fetal circulation is interstitial cells of fetal ovary and is not of maternal origin. Furthermore, these inhibins may play some important physiological roles in the development of gonads in the equine fetus.     

Stage-specific expression of Smad2 and Smad3 during folliculogenesis

Paracrine and autocrine growth factors can affect many different aspects of ovarian follicle development. Many members of the transforming growth factor beta (TGFbeta) family of growth factors and their receptors are expressed in developing follicles. However, the presence and function of the family of the TGFbeta signaling molecules known as Smads have not been evaluated during follicle development. We have demonstrated that two Smad family members that function as mediators for both activin and TGFbeta are expressed in granulosa cells of preantral follicles but not in large antral follicles. Smad2 expression, but not Smad3 expression, returns in luteal cells. Both Smad2 and Smad3 are translocated to the nucleus of granulosa cells in response to treatment with either TGFbeta or activin. However, Smad2 is more responsive to activin stimulation, and Smad3 is more responsive to TGFbeta stimulation. Stage-specific expression and differing ligand sensitivity of signaling molecules may work together to allow different effects of TGFbeta family ligands using the same signaling pathways over the course of follicular development.     

Localization of an activin/activin receptor system in the porcine ovary.

The aim of this study was to locate a possible activin/activin receptor system within porcine ovaries containing functional corpora lutea. In situ hybridization was used to assess the gene expression of beta(A)- and beta(B)-activin subunits, and immunohistochemical studies were done to detect activin-A protein and activin receptor type II. mRNA expression of the beta(A)- and beta(B)-activin subunits was found in the granulosa from the unilaminar follicle stage onward, in the developing thecal layer of multilaminar and small antral follicles, in the theca interna of mid-sized antral follicles, in corpora lutea, and in the ovarian surface epithelium. Immunoreactive activin A protein could be detected at the same ovarian sites, but in thecal tissue of small antral follicles only. This protein was also demonstrated at the peripheral zone of oocytes from multilaminar and antral follicles. A positive immunoreaction for activin receptor was found in granulosa cells from multilaminar and older follicles and in oocytes from the earliest stages of follicular development onward. In late multilaminar follicles and in antral follicles, the oolemma was stained. Except for small antral follicles, a positive activin receptor immunoreaction was absent in the follicular theca. Activin receptor immunoreaction was furthermore present in corpora lutea and in the ovarian surface epithelium. It is concluded that, within porcine ovaries containing functional corpora lutea, an activin/activin receptor system is present in all intact follicles, the corpora lutea and the surface epithelium. Within follicles, granulosa and theca cells are the main sites of activin synthesis, while oocytes and granulosa cells are the main activin binding sites.     

Morphological development and characterization of aromatase and estrogen receptors alpha and beta in fetal ovaries of cattle from days 110 to 250

To better understand the role of estradiol-17β in fetal ovarian development, presence and localization of cytochrome P450 aromatase (P450arom) and estrogen receptors alpha (ERα) and beta (ERβ) proteins were characterized in fetal ovaries of cattle using immunohistochemistry. Fetal cattle ovaries were collected from an abattoir and sorted into fetal age groups (days 110, 130, 150, 170, 190, 210, 230, 250+) based on crown-rump length. In addition to immunohistochemistry, morphological analysis of ovarian and follicular formation was made. Ovaries appeared lobular at day 110, but by the end of gestation (day 250+) ovaries were oval-shaped similar to those found in adult animals. Ovarian structures within different lobes appeared to be at different developmental stages. At day 110, oocytes and pre-granulosa cells were observed in ovigerous cords that were still open to the surface epithelium. Most ovigerous cords appeared to be closed to the surface epithelium on day 130, all closed by day 150 and were no longer present at day 210. Ovarian follicles were classified as follows: Type 1(primordial): single layer of flattened granulosa cells, Type 1a (transitory): single layer of mixed flattened and cuboidal granulosa cells, Type 2 (primary): at least one but less than two layers of cuboidal granulosa cells, Type 3 (small preantral): two to three layers of granulosa cells, Type 4 (large preantral): four to six layers of granulosa, and the theca layer is forming around the follicle, Type 5 (antral): contain greater than six layers of granulosa cells, several layers of theca cells and the antrum has formed. Type 1 follicles were observed in day 110 ovaries. Follicle Types 1a and 2 were first observed on day 130. Type 3 follicles were first observed on day 150 and Types 4 and 5 were first observed on day 170. P450arom protein was localized in granulosa cells of follicle Types 2–5 and cells of rete tubules throughout the experimental period. There was punctate expression within stroma and rete masses. There was ERα protein localization in pre-granulosa cells and germ cells of ovigerous cords and all surface epithelial cells. There was also localization in granulosa cells and oocytes of all follicle types and cells of rete tubules. There was punctate ERα protein expression in stroma and rete masses. ERβ protein was localized in pre-granulosa cells and germ cells of ovigerous cords. Expression was also localized to granulosa cells of all follicle types and cells of rete tubules. ERβ protein was punctate in oocytes of follicles, surface epithelial cells, stroma and rete masses. Thus, the fetal ovary of cattle has the steroidogenic enzyme (P450arom) to convert androgens to estradiol-17β, and estrogen receptors α and β to facilitate an estrogen response within the fetal ovary.     

Local regulation of primate granulosa cell aromatase activity

Granulosa cells produce inhibin and activin, proteins implicated in the local regulation of preovulatory follicular development. To assess interactions among FSH, LH, inhibin and activin on primate granulosa cell aromatase activity, we studied primary granulosa cell cultures from the ovaries of the common marmoset (Callithrix jacchus), a monkey with an ovarian cycle similar in length to the human cycle. The distinctive action of activin was augmentation of gonadotropin-responsive aromatase activity throughout antral follicular development. FSH-stimulated aromatase activity in granulosa cells from immature follicles was augmented many fold by picomolar amounts of activin. In cell cultures from preovulatory follicles, the presence of activin stimulated basal aromatase activity in the absence of gonadotropin, as well as augmenting the action of LH. Thus, locally produced activin has the potential to modulate aromatase activity in developing ovarian follicles. By contrast, inhibin or inhibin -subunit purified from bovine follicular fluid had minimal effects on aromatase activity. The only significant effect was slight suppression of FSH-inducible aromatase activity in granulosa cells from immature follicles at an inhibin concentration of 100 ng/ml. The finding that inhibin has a negligible effect on aromatase activity in granulosa cells from mature follicles suggests that it is unlikely to exert a physiologically significant influence on aromatase activity in vivo. However, evidence from other studies suggests that inhibin might affect aromatization indirectly through acting locally to modulate thecal androgen (aromatase substrate) production. Therefore, both inhibin and activin have the potential to contribute at different levels to paracrine and autocrine regulation of follicular oestrogen synthesis.     

Activation of bovine and baboon primordial follicles in vitro

Mammalian ovaries contain a large pool of non-growing, primordial follicles. The ability to initiate growth of this pool of resting follicles in vitro and to maintain follicular growth to a stage when the oocyte could be matured and fertilized would increase the reproductive potential of valuable domestic animals, endangered species and infertile women. This paper summarizes our progress to date in activating primordial follicles of cattle and baboons. Pieces of ovarian cortex, rich in primordial follicles, were obtained from fetal bovine and baboon ovaries during late gestation. Pieces were maintained in organ culture in serum-free medium containing ITS+ (insulin-transferrin-selenium-linoleic acid-BSA) for up to 20 days and at various times during culture some pieces were fixed for histological morphometry. As early as 2 days of culture, the number of primordial follicles had decreased by 88% or 55%, whereas the number of primary follicles had increased 2.5- or 5-fold, compared to tissue freshly isolated from bovine or baboon ovaries, respectively (P < 0.01). In baboon cortical pieces a small number of secondary follicles developed during a 20-day culture period. The development of primary and secondary follicles was accompanied by an increase in diameter of both the granulosa cell layer and the oocyte. The addition of FSH (1, 10, or 100 ng/ml) had no effect on the development of follicles in bovine cortical pieces after 7 or 14 days of culture, relative to control cultures without FSH. These results show that a high percentage of primordial follicles from cattle and baboons can be activated to grow in serum-free medium in the absence of gonadotropins. Conditions that will support further growth in vitro of follicles from these species remain to be elucidated. The culture system we have developed could be used to develop such conditions and to explore factors that regulate the movement of primordial follicles into the pool of growing follicles.     

Functional capacity of fetal zone cells of the baboon fetal adrenal gland: a major source of alpha-inhibin.

We have shown that ACTH receptor mRNA expression and steroidogenesis were increased in the transitional zone and decreased in the fetal zone of the baboon fetal adrenal in the second half of gestation. Thus, we proposed that there is a divergence in ACTH receptor-mediated zone-specific steroidogenesis within the fetal adrenal during mid to late gestation. We have also demonstrated that fetal serum alpha-inhibin levels decline with advancing development. It is possible, therefore, that the alpha subunit of inhibin provides a good marker of fetal zone cellular function and that the changes in circulating fetal alpha-inhibin with advancing pregnancy reflect ontogenetic changes in fetal adrenal cortical zone-specific cell function. However, it remains to be determined whether the fetal adrenal is a major source of circulating alpha-inhibin in the fetus and whether alpha-inhibin is expressed in the fetal, definitive, and/or transitional zones. Therefore, the current study compared fetal serum alpha-inhibin levels with immunocytochemical localization of alpha-inhibin in baboon fetal adrenals obtained on Days 60 (early), 100 (mid), and 165 or 182 (late) of gestation (term averages Day 184) from animals untreated or treated with betamethasone, which we previously demonstrated suppressed fetal pituitary ACTH and adrenal weight. Fetal serum alpha-inhibin levels (mean +/- SE) were greater (p < 0.05) at mid (5863 +/- 730 microliter eq/ml) than at late (3246 +/- 379) gestation and were reduced (p < 0. 05) by betamethasone. The inhibin alpha subunit was expressed in abundant quantities in the fetal adrenal cortex, but not in medulla, throughout gestation. At mid and late gestation, alpha-inhibin was expressed throughout the fetal adrenal cortex but most intensely in the innermost area of fetal zone cells. By late gestation, the fetal adrenal exhibited a gradient of alpha-inhibin expression. Thus, the outermost definitive zone cells were devoid of alpha-inhibin, the transitional zone exhibited a relatively low alpha-inhibin content, and fetal zone cells continued to exhibit extensive expression of alpha-inhibin. Betamethasone diminished the intensity of alpha-inhibin expression throughout the fetal adrenal cortex. These results indicate that the fetal adrenal fetal zone is a significant source of circulating alpha-inhibin in the baboon fetus and that alpha-inhibin provides a good marker to study the developmental regulation of fetal zone-specific adrenocortical function.