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.     

Activation of follicle development: the primordial follicle

Investigations of primordial follicle formation and growth are fundamental to our understanding of female gamete production. In all mammalian females the full complement of oocytes is established during fetal development. This store of primordial follicles is not renewable and serves the entire reproductive life span of the adult. The correct programming of fetal ovarian development and the number of primordial follicles formed will therefore limit the fecundity of the ovary. Primordial follicles are characterized by the presence of a single oocyte surrounded by a varying number of pregranulosa cells. The relatively small size, undifferentiated status and large numbers of primordial follicles make them prime candidates for use in basic and applied research in animal production, gene transfer and cloning. Furthermore, the development of cell culture systems that use primordial follicles as a source of oocytes for in vitro growth and maturation will enable us to maximize the potential of high genetic merit females and to shorten generation intervals. Despite these possibilities, primordial follicles are the least understood of all stages of follicle development. The factor(s) responsible for maintaining the primordial pool or, conversely, for activating primordial follicle growth remain elusive.     

Culture and Co-Culture of Mouse Ovaries and Ovarian Follicles

The mammalian ovary is composed of ovarian follicles, each follicle consisting of a single oocyte surrounded by somatic granulosa cells, enclosed together within a basement membrane. A finite pool of follicles is laid down during embryonic development, when oocytes in meiotic arrest form a close association with flattened granulosa cells, forming primordial follicles. By or shortly after birth, mammalian ovaries contain their lifetime’s supply of primordial follicles, from which point onwards there is a steady release of follicles into the growing follicular pool.The ovary is particularly amenable to development in vitro, with follicles growing in a highly physiological manner in culture. This work describes the culture of whole neonatal ovaries containing primordial follicles, and the culture of individual ovarian follicles, a method which can support the development of follicles from an immature through to the preovulatory stage, after which their oocytes are able to undergo fertilization in vitro. The work outlined here uses culture systems to determine how the ovary is affected by exposure to external compounds. We also describe a co-culture system, which allows investigation of the interactions that occur between growing follicles and the non-growing pool of primordial follicles.     

Development of primordial and prenatal follicles from undifferentiated somatic cells and oocytes in the hamster prenatal ovary in vitro: effect of insulin

Fetal hamster ovaries were cultured for up to 16 days in the presence or absence of various dosages of insulin to evaluate the induction of folliculogenesis in vitro. In the absence of insulin, a few primordial follicle-like structures appeared by the 4th day, and distinct primary follicles (stage 1) appeared by the 12th day of culture. The organelles in the oocytes and adjacent granulosa cells developed along with follicular growth. Moreover, gap junctions between the oocyte and somatic cell plasma membrane also developed as early as 8 days in culture. In the presence of 0.2 microg/ml insulin, primary follicles developed after 8 days, and approximately 4% secondary follicles with 2-3 layers of granulosa cells appeared after 16 days of culture. However, higher dosages (> 0.2 microg/ml) of insulin retarded primary follicle formation and induced the formation of primordial follicles with larger oocytes. An increased number of larger oocytes with a few granulosa cells accumulated at the periphery of the ovary. The results indicate that although primordial and primary follicles can develop after 12 days in vitro in the absence of exogenous insulin, the latter is required for timely progression of follicular development through primary and secondary stages.     

Neonatal genistein treatment alters ovarian differentiation in the mouse: inhibition of oocyte nest breakdown and increased oocyte survival

Early in ovarian differentiation, female mouse germ cells develop in clusters called oocyte nests or germline cysts. After birth, mouse germ cell nests break down into individual oocytes that are surrounded by somatic pregranulosa cells to form primordial follicles. Previously, we have shown that mice treated neonatally with genistein, the primary soy phytoestrogen, have multi-oocyte follicles (MOFs), an effect apparently mediated by estrogen receptor 2 (ESR2, more commonly known as ERbeta). To determine if genistein treatment leads to MOFs by inhibiting breakdown of oocyte nests, mice were treated neonatally with genistein (50 mg/kg per day) on Days 1-5, and the differentiation of the ovary was compared with untreated controls. Mice treated with genistein had fewer single oocytes and a higher percentage of oocytes not enclosed in follicles. Oocytes from genistein-treated mice exhibited intercellular bridges at 4 days of age, long after disappearing in controls by 2 days of age. There was also an increase in the number of oocytes that survived during the nest breakdown period and fewer oocytes undergoing apoptosis on Neonatal Day 3 in genistein-treated mice as determined by poly (ADP-ribose) polymerase (PARP1) and deoxynucleotidyl transferase mediated deoxyuridine triphosphate nick end-labeling (TUNEL). These data taken together suggest that genistein exposure during development alters ovarian differentiation by inhibiting oocyte nest breakdown and attenuating oocyte cell death.     

Mouse oocytes derived from fetal germ cells are competent to support the development of embryos by in vitro fertilization

Mouse oocyte development in vitro has been studied in the past several years, but no evidence showed that the fertilizable oocytes could be obtained from the fetal mouse germ cells before the formation of the primordial follicles. In this study, an efficient and simple method has been established to obtain the mature oocytes from the fetal mouse germ cells at 16.5 days post-coitum (dpc). For the initial of follicular formation, fetal mouse 16.5 dpc ovaries were transplanted to the recipient under the kidney capsule, and the ovaries were recovered after 14 days. Subsequently, the growing preantral follicles in the ovarian grafts were isolated and cultured in vitro for 12 days. Practically, the mature oocytes ovulated from the antral follicles were able to be fertilized in vitro and support the embryonic development. The results demonstrate that the fetal mouse 16.5 dpc germ cells are able to form primordial follicles with the ovarian pregranulosa cells during the period of transplantation in the ectopic site, and the oocytes within the growing follicles are able to mature in vitro, then are able to support the embryonic development.     

Advanced methods of isolation and identification of porcine primordial follicles

An effective isolation and identification method of primordial follicles would greatly benefit the animal production practice, transgenic animal production and endangered species conservation in the future. This study has not only advanced the isolation method but also developed an identification marker of primordial follicles. After enzymatic digestion, Percoll gradient centrifugation and mesh filtrations, the obtained follicular separations were then subjected to a cell sorter in order to collect primordial follicles. The study greatly improved the yield of primordial follicles (from about 1.85 x 10(5) to 7.79 x 10(5) per prepubertal ovary) by means of increasing cell layer number from 1 ml to 2.5 ml after Percoll gradient centrifugation. Based on traditional morphological criteria, the purity of recovered primordial follicles was averagely about 82.43+/-9.41% (n=5) because of their similar size and appearance with somatic cells. To further exactly appreciate the purity of sorted primordial follicles, a germ cell-specific protein, MSY2, was used to recognize the oocytes of primordial follicles. The results of repeat experiments showed that about 98.31+/-0.73% (n=4) of the primordial follicles cluster was MSY2-positive, which indicated the identification method of primordial follicles was more effective and high-yielded than the previous methods because of its higher purity.     

Tumor necrosis factor (TNF) receptor type 2 is an important mediator of TNF alpha function in the mouse ovary

It is believed that a finite pool of primordial follicles is established during embryonic and neonatal life. At birth, the mouse ovary consists of clusters of interconnected oocytes surrounded by pregranulosa cells. Shortly after birth these structures, termed germ cell cysts or nests (GCN), break down to facilitate primordial follicle formation. Tumor necrosis factor alpha (TNF) is a widely expressed protein with myriad functions. TNF is expressed in the ovary and may regulate GCN breakdown in rats. We investigated whether it participates in GCN breakdown and follicle formation in mice by using an in vitro ovary culture system as well as mutant animal models. We found that TNF and both receptors (TNFRSF1A and TNFRSF1B) are expressed in neonatal mouse ovaries and that TNF promotes oocyte death in neonatal ovaries in vitro. However, deletion of either receptor did not affect follicle endowment, suggesting that TNF does not regulate GCN breakdown in vivo. Tnfrsf1b deletion led to an apparent acceleration of follicular growth and a concomitant expansion of the primordial follicle population. This expansion of the primordial follicle population does not appear to be due to decreased primordial follicle atresia, although this cannot be ruled out completely. This study demonstrates that mouse oocytes express both TNF receptors and are sensitive to TNF-induced death. Additionally, TNFRSF1B is demonstrated to be an important mediator of TNF function in the mouse ovary and an important regulator of folliculogenesis.     

Fxna, a novel gene differentially expressed in the rat ovary at the time of folliculogenesis, is required for normal ovarian histogenesis

In rodents, the formation of ovarian follicles occurs after birth. In recent years, several factors required for follicular assembly and the growth of the newly formed follicles have been identified. We now describe a novel gene, Fxna, identified by differential display in the neonatal rat ovary. Fxna encodes an mRNA of 5.4 kb, and a protein of 898 amino acids. Fxna is a transmembrane metallopeptidase from family M28, localized to the endoplasmic reticulum. In the ovary, Fxna mRNA is expressed in granulosa cells; its abundance is maximal 48 hours after birth, i.e. during the initiation of follicular assembly. Reducing Fxna mRNA levels via lentiviral-mediated delivery of short hairpin RNAs to neonatal ovaries resulted in substantial loss of primordial, primary and secondary follicles, and structural disorganization of the ovary, with many abnormal follicles containing more than one oocyte and clusters of somatic cells not associated with any oocytes. These abnormalities were not attributable to either increased apoptosis or decreased proliferation of granulosa cells. The results indicate that Fxna is required for the organization of somatic cells and oocytes into discrete follicular structures. As an endoplasmic reticulum-bound peptidase, Fxna may facilitate follicular organization by processing precursor proteins required for intraovarian cell-to-cell communication.     

Expression of activin subunits and receptors in the developing human ovary: activin A promotes germ cell survival and proliferation before primordial follicle formation

The formation of the essential functional unit of the ovary, the primordial follicle, occurs during fetal life in humans. Factors regulating oogonial proliferation and interaction with somatic cells before primordial follicle formation are largely unknown. We have investigated the expression, localisation and functional effects of activin and its receptors in the human fetal ovary at 14-21 weeks gestation. Expression of mRNA for the activin betaA and betaB subunits and the activin receptors ActRIIA and ActRIIB was demonstrated by RT-PCR. Expression of betaA mRNA increased 2-fold across the gestational range examined. Activin subunits and receptors were localised by immunohistochemistry. The betaA subunit was expressed by oogonia, and the betaB subunit and activin receptors were expressed by both oogonia and somatic cells. BetaA expression was increased in larger oogonia at later gestations, but was low in oocytes within newly formed primordial follicles. Treatment of ovary fragments with activin A in vitro increased both the number of oogonia present and oogonial proliferation, as detected by bromodeoxyuridine (BrdU) incorporation. These data indicate that activin may be involved in the autocrine and paracrine regulation of germ cell proliferation in the human ovary during the crucial period of development leading up to primordial follicle formation.     

Assembly of ovarian follicles in the caecilians Ichthyophis tricolor and Gegeneophis ramaswamii: light and transmission electron microscopic study

Though much is known about various aspects of reproductive biology of amphibia, there is little information on the cellular and mechanistic basis of assembly of ovarian follicles in this group. This is especially true of the caecilians. Therefore, taking advantage of the abundant distribution of caecilians in the Western Ghats of India, two species of caecilians, Ichthyophis tricolor and Gegeneophis ramaswamii, were subjected to light and transmission electron microscopic analysis to trace the sequential changes during the assembly of ovarian follicles. The paired ovaries of these caecilians are elongated sac-like structures each including numerous vitellogenic follicles. The follicles are connected by a connective tissue stroma. This stroma contains nests of oogonia, primary oocytes and pregranulosa cells as spatially separated nests. During assembly of follicles the oocytes increase in size and enter the meiotic prophase when the number of nucleoli in the nucleus increases. The mitochondrial cloud or Balbiani vitelline body, initially localized at one pole of the nucleus, disperses through out the cytoplasm subsequently. Synaptonemal complexes are prominent in the pachytene stage oocytes. The pregranulosa cells migrate through the connective tissue fibrils of the stroma and arrive at the vicinity of the meiotic prophase oocytes. On contacting the oocyte, the pregranulosa cells become cuboidal in shape, wrap the diplotene stage oocyte as a discontinuous layer and increase the content of cytoplasmic organelles and inclusions. The oocytes increase in size and are arrested in diplotene when the granulosa cells become flat and form a continuous layer. Soon a perivitelline space appears between the oolemma and granulosa cells, completing the process of assembly of follicles. Thus, the events in the establishment of follicles in the caecilian ovary are described.     

Formation of ovarian follicles during fetal development in sheep

The origin of follicle (i.e., pregranulosa) cells that become the somatic component of primordial follicles is obscure. In addition, information regarding the structural changes that accompany the concomitant regression of ovigerous cords and the appearance of primordial follicles is lacking. In the present study, ovine ovaries collected at frequent time intervals between Day 38 and Day 100 of fetal life were examined by light and electron microscopy. To gain new information regarding the origin of follicular cells, incorporation of 5-bromo-2'-deoxyuridine was used to identify proliferating cells at selected stages of development. Based on the location and identity of proliferating cells, apoptotic cells, and sequential changes in histoarchitecture, we hypothesize 1) that most (i.e., >95%) of the granulosal cells in newly formed primordial follicles originate from the ovarian surface epithelium; 2) that the sequential events leading to follicle formation take place entirely within ovigerous cords, with the first follicles forming at the interface of the cortex and medulla; and 3) that the loss (i.e., >75%) of germ cells, but not of somatic cells, within the ovigerous cords is a means by which each surviving oocyte gains additional pregranulosal cells before follicle formation. Conceptual models detailing the chronology of developmental events involved in the formation of primordial follicles in sheep are discussed.     

Localization and developmental expression of the activin signal transduction proteins Smads 2, 3, and 4 in the baboon fetal ovary

We recently demonstrated that the reduction in the number of primordial follicles in ovaries of near-term baboon fetuses deprived of estrogen in utero was associated with increased expression of alpha-inhibin, but not activin betaA and betaB or the activin receptors. Therefore, we proposed that estrogen regulates fetal ovarian follicular development by controlling the intraovarian inhibin:activin ratio. As a prelude to conducting experiments to test this hypothesis, in the current study we determined whether the primate fetal ovary expressed Smads 2/3 and 4 and whether expression of these activin-signaling proteins was altered in fetal ovaries of baboons in which estrogen production was suppressed. Western blot analyses demonstrated that the 59 kDa Smad 2, 54 kDa Smad 3, and 64 kDa Smad 4 proteins were expressed in fetal ovaries of untreated baboons at both mid and late gestation and that the level of expression was not significantly altered in late gestation by in vivo treatment with CGS 20267 or CGS 20267 and estrogen. Immunocytochemistry localized Smads 2/3 and 4 to cytoplasm of oocytes and pregranulosa cells at midgestation and oocytes and granulosa cells of primordial follicles in late gestation. Smad 4 was also detected in granulosa cell nuclei in late gestation, and nuclear expression appeared to be decreased in fetal ovaries of baboons deprived of estrogen. The site of localization of Smads correlated with localization of the activin receptors IA and IIB, which we previously showed were abundantly expressed in oocytes and (pre)granulosa cells at both mid and late gestation and unaltered by estrogen deprivation. In summary, the results of the current study are the first to show that the intracellular signaling molecules required to transduce an activin signal are expressed in the baboon fetal ovary and that expression was not altered by estrogen deprivation in utero. These findings, coupled with our previous observations showing that estrogen deprivation reduced follicle numbers and upregulated/induced expression of inhibin but not activin or the activin receptors, lend further support to the hypothesis that estrogen regulates fetal ovarian folliculogenesis by controlling the intraovarian activin:inhibin ratio.     

Lanosterol 14alpha-demethylase expression in the mouse ovary and its participation in cumulus-enclosed oocyte spontaneous meiotic maturation in vitro

The expression of lanosterol 14alpha-demethylase (LDM) in the mouse ovary after gonadotrophin administration was examined and the action of follicle fluid meiosis activating sterol (FF-MAS), derived from lanosterol by the action of LDM, on oocyte spontaneous maturation was also evaluated in cumulus cell enclosed oocytes (CEOs). Expression of LDM was primarily in oocytes in primordial and secondary follicles prior to administration of gonadotrophins, but obvious LDM expression was apparent in ovarian somatic cells 48 h after administration of equine chorionic gonadotrophin (eCG), especially in luteal and cumulus cells 54 h after eCG or 48 h after eCG plus 6 h after human chorionic gonadotrophin (hCG). The LDM expression in oocytes was only slightly elevated in larger growing follicles after eCG treatment. On the contrary, 48 h after hCG treatment, the elevated expression of LDM was only detected in interstitial cells. Therefore, eCG may be the primary gonadotrophin for LDM expression, and furthermore for production of FF-MAS in mouse cumulus cells (which are indispensable for oocyte maturation in vivo). Conversely, inhibitors of LDM, either 40 microM azalanstat or 50 microM RS-21745, significantly inhibited oocyte germinal vesicle breakdown (GVB) after 4h of in vitro culture; GVB rates decreased to 14 or 20%, compared to 90% in spontaneous maturation, respectively. There was no significant increase in GVB in CEOs following specific inhibitor of sterol Delta14-reductase and Delta7-reductase, AY9944-A-7 (5-100 microM), until marked oocytes degeneration appeared (50 microM). The phenomena may be ascribed to slow, passive accumulation of FF-MAS by AY9944-A-7, which cannot be associated with fast spontaneous progression. Furthermore, in spontaneous-matured CEOs, LDM was expressed preferentially in cumulus cells instead of oocytes. Therefore, FF-MAS may have a positive role in the spontaneous maturation of CEOs. In conclusion, there was an eCG-dependent dual LDM expression pattern on both oocytes and somatic cells in growing follicles in vivo, which may increase LDM expression and FF-MAS production in cumulus cells for oocyte maturation. For the first time, the inhibitory effect of LDM inhibitors on spontaneous maturation, together with the strong LDM expression in spontaneous matured CEOs, indicated that FF-MAS produced by cumulus cells might participate in spontaneous maturation of mouse CEOs.     

Heterogeneity of cell populations that contribute to the formation of primordial follicles in rats.

To study the events that lead to the formation of primordial follicles, pregnant rats were given continuous infusions of [3H]thymidine (3H-TdR) beginning on Days 14-19 of pregnancy (e14-e19) and continuing for 48-120 h. Ovaries from the pups were collected and plastic-embedded histological sections were prepared for autoradiography. The autoradiographs revealed that within the core of the developing ovary were a large number of cells that remained mitotically inactive (failed to incorporate label) from e14 through the day of birth. These unlabeled cells gave rise to the granulosa cells of the first follicles that formed, were located in the medulla of the ovary, and were the first to begin growth. The unlabeled cells did not appear to contribute to the formation of the follicles that formed later in the cortical region of the ovary. When 3H-TdR infusion was begun during late pregnancy, a small subset of the germ cells incorporated label, although the vast majority did not. The labeled germ cells are presumed to represent those that were lagging in their development (had not yet entered meiosis). After ovarian histogenesis was completed during the first week postpartum, the unlabeled ocytes were found concentrated in the core of the ovary, enclosed in the earliest growing follicles; labeled oocytes were found exclusively in the cortex of the ovary, within tiny, quiescent primordial follicles. These observations provide some empirical support for long-held, but heretofore untested, hypotheses concerning early folliculogenesis: that the first follicles that begin to grow are qualitatively different from the remaining follicles in the ovary and that primordial follicles begin to grow in the order in which they were first formed.     

Follistatin288 Regulates Germ Cell Cyst Breakdown and Primordial Follicle Assembly in the Mouse Ovary

In mammals, the primordial follicle pool represents the entire reproductive potential of a female. The transforming growth factor-β (TGF-β) family member activin (ACT) contributes to folliculogenesis, although the exact mechanism is not known. The role of FST288, the strongest ACT-neutralizing isoform of follistatin (FST), during cyst breakdown and primordial follicle formation in the fetal mice ovary was assessed using an in vitro culture system. FST was continuously expressed in the oocytes as well as the cuboidal granulosa cells of growing follicles in perinatal mouse ovaries. Treatment with FST288 delayed germ cell nest breakdown, particularly near the periphery of the ovary, and dramatically decreased the percentage of primordial follicles. In addition, there was a dramatic decrease in proliferation of granulosa cells and somatic cell expression of Notch signaling was impaired. In conclusion, FST288 impacts germ cell nest breakdown and primordial follicle assembly by inhibiting somatic cell proliferation.     

KIT signaling regulates primordial follicle formation in the neonatal mouse ovary

The pool of primordial follicles determines the reproductive lifespan of the mammalian female, and its establishment is highly dependent upon proper oocyte cyst breakdown and regulation of germ cell numbers. The mechanisms controlling these processes remain a mystery. We hypothesized that KIT signaling might play a role in perinatal oocyte cyst breakdown, determination of oocyte numbers and the assembly of primordial follicles. We began by examining the expression of both KIT and KIT ligand in fetal and neonatal ovaries. KIT was expressed only in oocytes during cyst breakdown, but KIT ligand was present in both oocytes and somatic cells as primordial follicles formed. To test whether KIT signaling plays a role in cyst breakdown and primordial follicle formation, we used ovary organ culture to inhibit and activate KIT signaling during the time when these processes occur in the ovary. We found that when KIT was inhibited, there was a reduction in cyst breakdown and an increase in oocyte numbers. Subsequent studies using TUNEL analysis showed that when KIT was inhibited, cell death was reduced. Conversely, when KIT was activated, cyst breakdown was promoted and oocyte numbers decreased. Using Western blotting, we found increased levels of phosphorylated MAP Kinase when KIT ligand was added to culture. Taken together, these results demonstrate a role for KIT signaling in perinatal oocyte cyst breakdown that may be mediated by MAP Kinase downstream of KIT.     

Growth differentiation factor-9 and stem cell factor promote primordial follicle formation in the hamster: modulation by follicle-stimulating hormone

Growth differentiation factor-9 (GDF-9) and stem cell factor (SCF) influence follicle formation beyond the primary stage; however, factors influencing the formation of primordial follicles remain elusive. To determine whether GDF-9 and SCF promoted primordial follicle formation during ovarian morphogenesis in the hamster, and whether FSH had any modulatory influence, fetal ovaries were collected on Gestation Day 15 from pregnant hamsters treated with or without an FSH antiserum on Gestation Day 12 and cultured in vitro up to Day 9 with SCF, GDF-9, or FSH. The percentages and diameters of primordial, primary, and secondary follicles and their oocytes were determined by morphometric evaluation, and the expression of GDF-9 was detected by immunolocalization. SCF, GDF-9, and FSH promoted primordial and primary follicle formation, but GDF-9 was more efficient. The diameters of the follicles developed under GDF-9 or FSH, but not SCF, compared well with those developed in vivo. FSH- and GDF-9-induced folliculogenesis was attenuated by the SCF antibody. Similarly, in vitro formation of primordial follicles decreased markedly in ovaries exposed to the FSH antiserum in utero, which was reversed by SCF, GDF-9, or FSH; however, GDF-9 had a profound effect on follicular development. GDF-9 protein appeared exclusively in the oocytes on Postnatal Day 4; however, it appeared in vitro by 48 h, and the expression was upregulated by FSH. These results suggest that although SCF-induced primordial follicle formation constitutes primarily somatic cell development, GDF-9 influences both the oocyte and its companion somatic cells. FSH plays an important role in primordial folliculogenesis in the hamster via GDF-9 and SCF.     

Expression of GDF-9, BMP-15 and their receptors in mammalian ovary follicles

The synergetic process of folliculogenesis is mainly regulated by GDF-9 and BMP-15 as well as their receptors, such as BMPR2, TβR1 and BMPR1B. Expressions of these factors and the receptors are significant different among species. This study was designed to detect expression of GDF-9, BMP-15 and their receptors in mouse, porcine and human healthy follicles by immunohistochemistry. Three ages of human ovary were studied according to ovarian developmental schedule, i.e. gestational week (GW) 16, puberty (14 year-old) and adult (40 year-old). The results showed that both GDF-9 and BMP-15 were detectable in oocytes from primary follicles onward, besides, BMP-15 also presented in granulosa cells (GCs) and follicular follicle of mature follicles in mouse. However, they were maintained in oocytes and GCs from primordial to mature follicles in porcine except that GDF-9 was undetectable in GCs of mature follicles. For human ovary, GDF-9 presented in oocytes of primordial follicles in all samples, whereas BMP-15 was only observed in primordial follicle of adult ovary. Receptors, BMPR2, TβR1 and BMPR1B were found in oocytes and GCs of all follicles in mouse and porcine. In human, they were stained in oocytes from primordial follices but BMPR1B was not expressed in pubertal primordial follicles. Furthermore, we found that GDF-9, BMP-15 and three receptors distributed in adult corpus lutea. Collectively, our studies suggested that GDF-9, BMP-15 and their receptors might correlate with primordial follicular recruitment in pig and human. Positive expression of the receptors (BMPR2, TβR1 and BMPR1B)in primordial follicles of mouse ovaries indicated that these receptors might interact with others ligands besides GDF-9 and BMP-15 to regulate primordial follicular activity in mouse. Moreover, presence of GDF-9 in oocytes and BMP-15 in oocytes and GCs of mature follicles from mice and porcine elucidated coordinated roles of GDF-9 and BMP-15 in cumulus oophorus expansion. Additionally, expression of these factors in adult human corpus lutea suggested they play roles in corpus luteum activity.     

Development of mouse and rat oocytes in chimeric reaggregated ovaries after interspecific exchange of somatic and germ cell components

The germ cell and somatic cell compartments of newborn rat and mouse ovaries, which contain only primordial stage follicles, were completely exchanged and reaggregated to produce xenogeneic chimeric ovaries. The reaggregated ovaries were grafted beneath the renal capsules of ovariectomized SCID mice to develop for periods up to 21 days. Xenogeneic follicles developed with essentially normal morphological characteristics. Both rat and mouse oocytes with species-specific characteristics grew within follicles that were composed of somatic cells exclusively of the alternative species. Rat oocytes grown in mouse follicles became competent to resume meiosis, and progressed to metaphase II when they were removed from follicles and cultured. In addition, mouse oocytes grown in rat follicles underwent fertilization and preimplantation development in vitro, and developed to term after embryos were transferred to pseudopregnant mouse foster mothers. Therefore, despite an estimated 11 million years of divergent evolution, oocytes and somatic cells of rat and mouse ovaries can be exchanged and can produce functional oocytes. It is concluded that factors involved in oocyte-somatic cell interactions necessary to support oocyte development and appropriate differentiation of the oocyte-associated granulosa cells are conserved between rats and mice. Moreover, although granulosa cells play important roles in oocyte development, the development of species-specific characteristics of oocytes occurs without apparent modification by a xenogeneic follicular environment.