Newborn pig ovarian tissue xenografted into Severe Combined Immunodeficient (SCID) mice acquires limited responsiveness to gonadotropins

In the pig ovary, the transition from primordial to primary and secondary ovarian follicles begins before birth, but antral follicles can be observed, for the first time, at ∼60-90 d of age. At approximately the same time, secondary follicles become responsive to gonadotropins, leading to the formation of antral follicles. Placing pieces of ovarian tissue under the kidney capsule of immunodeficient (SCID) mice allows the requirements for follicular recruitment and development to be studied. The objective of this study was to investigate if primordial follicles contained in ovarian fragments isolated from newborn piglets (36 ± 12 h old) and immediately transplanted under the kidney capsule of SCID mice, are able to become responsive to gonadotropins after 60 d (as in an unaltered animal). Ovarian fragments were transplanted under the kidney capsule of three groups of four female and four male SCID mice. The first group did not receive any hormonal treatment for 12 wk. The second group was treated from the 9th week with 1 IU of FSH/LH on alternating days for 3 wk, and the third group was treated with 5 IU Pregnant Mare Serum Ganadotropin (PMSG) 48 h before euthanasia. Primordial follicles contained in ovarian fragments isolated from newborn piglets developed only to the secondary stage. Therefore, development of gonadotropin responsiveness in ovarian fragments xenotransplanted in SCID mice was delayed compared to what occurs in the unaltered animal, and there was minimal response to exogenous gonadotropins.     

Effect of bcl-2 on the primordial follicle endowment in the mouse ovary

Little is known about the embryonic factors that regulate the size of the primordial follicle endowment at birth. A few studies suggest that members of the B-cell lymphoma/leukemia-2 (bcl-2) family of protooncogenes may be important determinants. Thus, the purpose of this study was to test whether bcl-2 regulates the size of the primordial follicle pool at birth. To test this hypothesis, three lines of transgenic mice (c-kit/bcl-2 mice) were generated that overexpress human bcl-2 in an effort to reduce prenatal oocyte loss. The overexpression was targeted to the ovary and appropriate embryonic time period with the use of a 4.8-kilobase c-kit promoter. This promoter provided two to three times more expression of bcl-2 in the ovaries with minimal or no overexpression in most nongonadal tissues. On Postnatal Days 8-60, ovaries were collected from homozygous c-kit/bcl-2 and nontransgenic littermates (controls) and processed for histological evaluation of follicle numbers. All lines of c-kit/bcl-2 mice were born with significantly more primordial follicles than control mice (P < or = 0.05). By Postnatal Days 30-60, however, there were no significant differences in follicle numbers between c-kit/bcl-2 and control mice. These results indicate that bcl-2 overexpression increases the number of primordial follicles at birth, but that the surfeit of primordial follicles is not maintained in postnatal life. These data suggest that it is possible that the ovary may contain a census mechanism by which excess numbers of primordial follicles at birth are detected and removed from the ovary by adulthood.     

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 infantile rat ovaries autotransplanted after cryopreservation by vitrification

We cryopreserved infantile rat ovaries by vitrification and assessed their viability by autotransplantation. Hemilateral ovarian transplantation was performed on rats on postnatal Days 10 to 12. The left ovary of each rat was dissected out, cryopreserved by vitrification using a modified vitrification solution (VS1), and then autotransplanted under the capsule of the right kidney. The right ovary of each rat was removed. For the control, the left ovary was dissected out from each rat and was immediately transplanted by the same procedure, without cryopreservation. Rats were nursed until weaning, and then the day of vaginal opening, estrous cyclicity from the day of vaginal opening until postnatal Day 84, and histology of ovarian grafts at postnatal Day 84 were examined. The time course of development of endocrine function of cryopreserved grafts was similar to that of fresh grafts. In ovarian transplants recovered on postnatal Day 84, antral follicles and corpora lutea (CL) were observed in addition to small follicles, although the number of antral follicles in cryopreserved grafts was smaller than in the fresh grafts. These results indicate that cryopreservation of ovarian tissue by vitrification can be used for the preservation of fertility and endocrine function of ovaries.     

In utero exposure of mice to diethylstilbestrol alters neonatal ovarian follicle growth and development

The prenatal exposure of mice to diethylstilbestrol (DES, 10 micrograms/kg on day 15 of gestation) caused both quantitative and structural alterations in ovarian follicles within the neonatal ovary. At birth, control ovaries consisted of small type 1 and 2 ovarian follicles located in the ovarian cortex. By postnatal day 7, ovarian follicle development had advanced to the type 4 stage with larger follicles located within the ovarian medulla. In DES-exposed animals, ovarian follicle maturation was advanced with type 3b and 4 follicles appearing 24 h prior to their appearance in control animals. Also, type 5 ovarian follicles were present on postnatal day 6 in experimental animals but were never seen in control animals. In addition to an alteration in ovarian follicle dynamics, the diameter of individual ovarian follicles was transit time between the various stages of follicular development which results in a greater number of developmentally advanced ovarian follicles being present during neonatal ovarian development. The mechanism by which prenatal exposure to DES alters ovarian follicle dynamics during neonatal development is not known.     

Age-related changes in ovarian morphology from birth to menopause in the Japanese monkey,Macaca fuscata fuscata

Age-related changes in ovarian morphology were studied in female Japanese monkeys,Macaca fuscata fuscata. A total of 47 nonlactating females of various ages ranging from new-born to >28 yr old were used. Ovarian size increased during the first decade of life, reached a plateau at around 10 yr. This was followed by a gradual decline throughout the remaining life span. The ovarian cortex of new-born animals consisted of numerous clusters of mitotic primordial germ cells. Such mitotic germ cells were observed even in the ovary of 28-day-old animal, but were not found in any animal after 1.5 yr of age. Numbers of primordial follicles decreased exponentially with the advance of age, and only a few primordial follicles were observed after about 16 yr of age. The numbers of primary and tertiary follicles increased from ages 4 to 16 yr, with a peak at 8 to 10 yr, and then decreased gradually. Developing tertiary follicles were observed as early as 1.5 yr of age. About 40% of tertiary follicles were atretic follicles throughout life, and their size was similar to that of developing tertiary follicles. Corpora lutea or corpora albicantia were found in ovaries more than 4 yr old. Remnants of corpora lutea and corpora albicantia, together with thick-walled blood vessels and fibrosis, became apparent in ovaries after 16 yr, and were observed characteristically in ovaries over 26 yr of age. There was no significant difference in the number or in the size of tertiary follicles between the breeding and nonbreeding seasons.     

The capacity of primordial follicles in fetal bovine ovaries to initiate growth in vitro develops during mid-gestation and is associated with meiotic arrest of oocytes

In cattle and other species in which the pool of resting, primordial follicles is formed during fetal life, little is known about the regulation of the early stages of ovarian follicular development. We used histological morphometry and a combination of observations in vivo and experiments in vitro to study the timing and regulation of follicle formation and the acquisition of the capacity of primordial follicles to initiate growth in cattle. In vivo, primordial, primary, and secondary follicles were first observed around Days 90, 140, and 210 of gestation, respectively. The long interval between the first appearance of primordial and primary follicles suggests that primordial follicles are not capable of activating when they are first formed, or they are inhibited from activating. This hypothesis was confirmed by the finding that most primordial follicles in pieces of ovarian cortex obtained from fetal ovaries older than 140 days activated (i.e., initiated growth) after 2 days in vitro, whereas follicles in cortical pieces from 90- to 140-day-old fetal ovaries did not. We tested the hypothesis that the oocytes of newly formed primordial follicles are not in meiotic arrest and found that before Day 141, most oocytes ( approximately 73%) were in prediplotene stages of prophase I, whereas after Day 140, the majority of oocytes ( approximately 85%) had arrested at the diplotene stage. This observation was further confirmed by the finding that levels of mRNA for YBX2, a protein associated with meiotic arrest, were 2.3 times higher in ovarian cortical pieces isolated after versus before Day 141. Primordial follicles in cortical pieces from 90- to 140-day-old fetal ovaries did activate during a longer, 10-day culture, but activation could be inhibited by adding estradiol or progesterone, but not dihydrotestosterone (all at 10(-6) M). Fetal ovaries secreted estradiol in vitro, and secretion by ovaries from 83 to 140-day-old fetuses declined precipitously ( approximately 30-fold) with age, consistent with the hypothesis that estradiol inhibits activation of newly formed primordial follicles in vivo. In summary, the results show that newly formed primordial follicles do not activate in vivo or within 2 days in vitro and that capacity to activate is correlated with achievement of meiotic arrest by the oocyte and can be inhibited by estradiol, which fetal ovaries actively produce around the time of follicle formation.     

Influences of prenatal and postnatal fraternity size on ovarian development in the mouse

An experiment was conducted to test effects of prenatal and postnatal fraternity size (size of litter in which an individual develops prenatally or is reared postnatally) on ovarian development in mice. Fraternity size treatments were created by standardizing sizes of prenatal and postnatal fraternities in which mice were gestated and reared. Prenatal fraternity size was standardized by surgery on Day 9 of gestation to 6, 10, and 14 fetuses. Postnatal fraternity size was standardized by randomly assigning pups to litters of 5, 10, or 15 pups within 24 h of birth. Female pups were killed at either 3 or 20 wk of age and right ovaries were prepared for histology. Follicles were classified by size and morphology, and numbers of follicles in each class were tabulated. Interaction of postnatal fraternity size and age was observed for number of antral follicles (p less than 0.05). Mice reared in small postnatal fraternities had more antral follicles at weaning (3 wk) and fewer antral follicles at maturity (20 wk of age) than mice reared in large postnatal fraternities. No effect of either prenatal or postnatal fraternity size on other follicle populations was observed (p greater than 0.20). Numbers of Type 2 (primordial), Type 3a, and Type 3b follicles changed with age (p less than 0.01); numbers of primordial follicles declined with age, but numbers of Type 3a and 3b follicles increased. A hypothesis of a negative association between postnatal fraternity size and number of antral follicles at 3 wk of age was supported, but a hypothesis of a positive association between fraternity size and number of primordial follicles was not supported.     

Comparison of the total ovarian follicular populations at day 140 of pregnancy and at day 5 postpartum in ewes

The total ovarian follicular populations were determined in ewes at Day 140 of pregnancy and at Day 5 postpartum. The right and left ovaries of five pregnant and five non-suckling ewes of the Préalpes-du-Sud breed were used in this study. All the ovaries were serially sectioned at a thickness of 7 μm, and every section was examined microscopically.The mean numbers of preantral follicles per ovary increased (P<0.005) at Day 5 postapartum as compared to Day 140 of pregnancy. The distribution of preantral non-atretic follicles into different size classes clearly showed a sharp increase in the mean number of follicles per size class at Day 5 postpartum, especially those leaving the reserve of primordial follicles.No difference was detected between both groups of ewes in the mean number of antral follicles. The diameter of the largest antral follicle at Day 140 of pregnancy does not exceed 1.5 mm. However, at Day 5 postpartum, a population of large follicles ≥ 1.5 mm was observed, reaching 2–4 mm in diameter.We conclude that although the pattern of normal follicular development is inhibited during late pregnancy, the ovary at this time is not quiescent, and ovarian follicular development starts well before parturition. The increasing number of preantral follicles, as well as the enlargement of antral follicle diameter observed at Day 5 postpartum, may be correlated with increasing secretion of FSH after lambing.     

Ovarian sympathectomy in the guinea pig

Summary The role of ovarian adrenergic nerves in follicular growth was studied in prepubertal guinea pigs by determining the effect of sympathectomy on 1) follicle populations and 2) follicular development following exogenous gonadotropin administration. Selective unilateral ovarian sympathectomy was achieved by injecting 6-hydroxydopamine into a surgically closed periovarian bursa on day 20 postpartum. The contralateral surgically closed ovarian bursa was injected with the vehicle used for 6-hydroxydopamine. On day 25, animals were injected with pregnant mare serum or saline followed by human chorionic gonadotropin or saline 48 h later. All animals were laparotomized on day 28 and blood from utero-ovarian veins was collected bilaterally for androstenedione determination. Ovaries were processed for morphometric analysis of follicles. The sympathectomized ovary in saline-injected animals had a significant decrease in preantral follicles (characterized by 2 layers of granulosa cells without antrum formation), an increase in 310–500 m diameter atretic follicles and an increase in follicles 700 um compared to the contralateral control ovary. There were no differences in androstenedione levels from the two sides, ovarian weights or the total number of follicles per ovary. Neither ovary had corpora lutea. The sympathectomized ovary in animals injected with gonadotropins was not different from the contralateral ovary in any of the parameters measured. Both control and sympathectomized ovaries had newly formed corpora lutea in response to the exogenous gonadotropins. These results suggest that ovarian adrenergic nerves normally participate in follicular development in the prepubertal guinea pig. However, exogenous gonadotropins may override neural influences on the prepubertal ovary.     

Keratinocyte growth factor acts as a mesenchymal factor that promotes ovarian primordial to primary follicle transition

An important but poorly understood process in ovarian biology is the transition of the developmentally arrested primordial follicle to the developing primary follicle. Interactions between the epithelial and mesenchymal cells of the follicle are critical for the coordination of ovarian follicle development. The mesenchymal growth factor keratinocyte growth factor (KGF) (i.e., fibroblast growth factor-7) and the epithelial growth factor kit ligand (KITL) are known to interact to coordinate the growth of later-stage antral follicles. The hypothesis tested in the current study is that KGF acts as a mesenchymal factor to promote the primordial to primary follicle transition. A postnatal 4-day-old rat ovary organ culture system was used to investigate the actions of KGF. KGF treatment promoted 65% of follicles to undergo the primordial to primary follicle transition, but only 45% underwent development in control ovaries. Neutralizing antibody for KGF was found to attenuate the stimulatory action of KITL, but neutralizing antibody for KITL was not able to attenuate the stimulatory action of KGF. Further analysis demonstrated that KGF was found to stimulate the expression of KITL (i.e., mRNA levels) by granulosa cells. KITL in turn was found to stimulate the expression of KGF to create a positive feedback loop. Interestingly, KGF expression was localized to selected mesenchymal cells (i.e., precursor theca cells) surrounding the developing primordial follicle. Observations suggest that developing granulosa cells of the primordial follicles produce KITL, which helps recruit precursor theca cells to the follicle; the thecal cells then produce KGF, which acts on the granulosa to amplify KITL expression and support primordial follicle development. KGF appears to be a mesenchymal factor that promotes the primordial to primary follicle transitions.     

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.     

Caspase-2 involvement during ionizing radiation-induced oocyte death in the mouse ovary

In mammals, the pool of primordial follicles at birth is determinant for female fertility. Exposure to IR during oogonia proliferation and the diplotene stages of ovarian development induced the virtual disappearance of primordial follicles in the postnatal ovary, while half the follicular reserve remained present after irradiation during the zygotene/pachytene stages. This sensitivity difference was correlated with the level of caspase-2 expression evaluated by immunohistochemistry. At the diplotene stage, Western blot and caspase activity analysis revealed that caspase-2 was activated 2 h after irradiation and a significant increase in the number of oocytes expressing cleaved caspase-9 and -3 occurred 6 h after treatment. Inhibition of caspase-2 activity prevented the cleavage of caspase-9 and partially prevented the loss of oocytes in response to irradiation. Taken together, our results show that caspase-2-dependent activation of the mitochondrial apoptotic pathway is one of the mechanisms involved in the genotoxic stress-induced depletion of the primordial follicle pool.     

Experimental induction of reduced ovarian reserve in a nonhuman primate model (Macaca fascicularis)

Chronic diseases including coronary heart disease and osteoporosis represent a substantial health burden to postmenopausal women, yet the initiation of these conditions and their relationships with reproductive aging remain poorly understood. This situation is due, in part, to the lack of animal models reflecting ovarian and hormonal characteristics of peri- and postmenopausal women. Ovaries of women approaching menopause are nearly depleted of primordial follicles but retain a pool of larger developing follicles and androgen-producing stroma, a condition known as reduced ovarian reserve (ROR). The long-term goal of the research presented here was to create a monkey model of reproductive aging, beginning with ROR and progressing to perimenopause and finally postmenopause. Here we sought to develop a method to reduce primordial follicles in cynomolgus monkeys (Macaca fascicularis) and document hormonal changes associated with follicle reduction or ROR. At 30 d after surgical placement of a biodegradable fiber containing approximately 200 mg of 4-vinlycyclohexene diepoxide (VCD) next to one ovary in each of 8 monkeys, primordial follicles were reduced by approximately 70%, with a corresponding decrease (83%) in antimüllerian hormone (AMH, a serum marker of ovarian follicle numbers). At 4 mo after VCD-treatment of both ovaries in 29 monkeys (approximately 200 mg VCD per ovary), AMH was reduced 56% from baseline, testosterone was unchanged, and follicular phase estradiol was slightly increased. These data indicate that VCD treatment markedly reduced primordial follicles while preserving larger estradiol- and testosterone-producing follicles and ovarian stroma, a condition that mimics ROR in women.     

Estrogen inhibits the early development of mouse follicles through regulating the expression of Kit ligand

Estrogen inhibits cyst breakdown and primordial follicle assembling of germ cells, but little is known about the underlying mechanisms. We aimed to analyze the effects of estrogen on the early development of mouse follicles using an in vitro ovary culture system and in vivo injection. Newborn mouse ovarian tissues were cultured in vitro for 2 or 4 days with estrogen of 0 M, 10⁻⁸ M and 10⁻⁴ M, respectively, and neonatal mice were injected with 5 mg/kg/day estrogen. We found that the percentages of different-stage follicles significantly varied between the control and estrogen-treated groups. In vitro experiments showed that the unassembled follicles accounted for 70.5 ± 2.7% and the primordial follicles accounted for 29.5 ± 2.7% in the treatment group, but in the control group, ovaries had 61.7 ± 8.4% unassembled follicles. In vivo experiments showed that the percentages of unassembled follicles and primordial follicles were 37.1 ± 5.2% and 51.6 ± 2.4% in the control group, while they were 72.6 ± 5.2% and 25.1 ± 5.5% in the treatment group. Moreover, we analyzed the expression of Kit ligand in mouse ovaries treated by estrogen with real-time PCR and western blot technology, and found that compared with the control group, both mRNA and protein expression levels were decreased in the treatment group (P < 0.05). These results indicate that estrogen inhibits the development of mouse ovarian follicles by regulating the expression of Kit ligand.     

Age-related changes in ovarian morphology of the South American tamarin Saguinus fuscicollis (Callitrichidae)

The aim of this histological study was to investigate the postnatal ontogeny of the ovaries in Saguinus fuscicollis to provide a detailed knowledge of the ovarian morphology for further endocrinological studies. Gonads from 43 animals between one day and 18 years of age were investigated. Based on the available material the ovarian development is characterized by seven distinct stages. 1. Neonatal stage : Folliculogenesis is still in progress. The ovarian medulla is filled with an intraovarian rete system, which forms open connections between the rete tubules and the cords containing oocytes. 2. Infantile stage : One month after birth the ovarian cortex is mainly composed of primordial follicles and a few primary follicles at the corticomedullary border, which are separated from each other by connective tissue. At two months, folliculogenesis is nearly completed. The first secondary follicles are present. 3. Juvenile stage : In six-month-old females weighing 184±9.5 g, folliculogenesis has reached the stage of secondary follicles with up to six layers of granulosa cells. In females of the same age weighing 251.5±37 g, antral follicles attain a maximum diameter of 925 μm m. 4. Pubertal stage : At the age of 8–10 months, corpora lutea accessoria (CLA) begin to form from atretic antral follicles. 5. Adult stage : The ovaries of all females older than 1.2 years are filled with large patches of interstitial gland tissue (IGT). In breeding females up to 58.4%of the antral follicles are intact. In non-breeding daughters living in the family group only 1.8%are intact, the rest are in various stages of atresia and form CLA. 6. Climacterial stage : With increasing age (8–13 years), the number of intact follicles decreases dramatically and IGT fills nearly the whole ovary. 7. Senile stage : In females older than 14 years, nearly all remaining follicles show signs of atresia.     

Follicular development, steroidogenesis and ovulation within ovaries exposed in vitro to hormone levels which mimic those of the rat estrous cycle

In order to more clearly define the hormonal factors responsible for follicular growth, ovulation and steroidogenesis, a perifusion culture system was developed. This culture system was capable of exposing the ovaries to hormonal levels which mimic the 4-day estrous cycle of the rat. Using this culture system, ovaries were exposed to the in vivo levels of luteinizing hormone (LH), follicle-stimulating hormone (FSH), estradiol-17 beta and progesterone to within the mean +/- one standard deviation of the values reported by Butcher et al. (1974a). During the 4-day culture period, the diameter of the follicles gradually increased in a manner similar to that of cycling rats. After 4 days in vitro, the ovaries ovulated 4.3 +/- 0.6 oocytes/ovary as assessed by the presence of ruptured-partially luteinized follicles. This in vitro ovulation rate was not significantly different from the in vivo ovulation rate of 5.0 +/- 0.8 oocytes/ovary (P greater than 0.05). The pattern of follicular growth within cultured ovaries was similar to that of the cycling rat, although the number of small follicles recruited to grow was reduced. The steroid secretory patterns also were slightly different in the cultured ovaries. These data indicate that physiological ovarian responses which are similar to those of cycling rats can be induced within cultured ovaries. With further utilization of this culture technique, the precise role of gonadotropins, ovarian steroids and other hormonal agents can be examined in order to define specific ovarian functions which are controlled by each hormonal agent.     

Cell-specific expression and regulation of soluble guanylyl cyclase alpha 1 and beta 1 subunits in the rat ovary

Soluble guanylyl cyclase (sGC) is activated by nitric oxide (NO) and carbon monoxide, resulting in cGMP production. Recent studies indicate that NO and cGMP influence ovarian functions. However, little information is available regarding the ovarian expression of sGC. The present study examined sGC alpha(1) and beta(1) subunit protein levels in the ovary during postnatal development, gonadotropin-induced follicle growth, ovulation, and luteinization as well as in cultured rat granulosa cells. In postnatal rats, sGC alpha(1) subunit immunoreactivity was high in granulosa cells of primordial and primary follicles on Day 5 but low in granulosa cells of larger follicles on Days 10 and 19. Theca cells of developing follicles, but not stromal cells, also demonstrated moderate sGC alpha(1) immunoreactivity. In gonadotropin- treated immature rats, intense sGC alpha(1) subunit staining was similarly observed in granulosa cells of primordial and primary follicles, but such staining was low in granulosa cells of small antral follicles and undetectable in granulosa cells of large antral and preovulatory follicles. Following ovulation, corpora lutea expressed moderate sGC alpha(1) immunoreactivity. Similar ovarian localization and expression patterns were seen for sGC beta(1), indicating regulated coexpression of sGC subunits. Immunoblot analysis revealed no change in total ovarian sGC alpha(1) and beta(1) subunit protein levels during gonadotropin treatment. Similarly, no effect of FSH on sGC subunit protein levels was apparent in cultured granulosa cells. These findings indicate regulated, cell- specific patterns of sGC expression in the ovary and are consistent with roles for cGMP in modulating ovarian functions.     

Gonadotropin-dependent expression of sterol 14-demethylase P450 (CYP51) in rat ovaries and its contribution to the production of a meiosis-activating steroid.

Immunohistochemical analysis showed that sterol 14-demethylase P450 (CYP51) is expressed in mature follicles and corpus lutea of rat ovaries. In follicles, CYP51 is expressed in granulosa and theca cells but not in oocytes. The ovarian CYP51 activity of hypophysectomized rats is very low and induced by pregnant mares' serum gonadotropin (PMSG) treatment together with ovarian growth. The expression of CYP51 first increases in growing follicles and then appears in the corpus lutea after luteinization. The former event may be due to the follicular-stimulating hormone action of PMSG, and the latter may be caused by the luteinizing hormone effect of PMSG. Sterol analysis indicated that the product of the CYP51-mediated lanosterol 14-demethylation, 4,4-dimethylcholesta-8,14,24-trienol, which has been identified as a meiosis-activating steroid (MAS) in mammals [Byskov et al. (1995) Nature 374, 559-562], accumulates (about 10 pmol/mg of ovary) in mature rat ovaries, and the content is enough to activate the resumption of meiosis. These lines of evidence suggest that the expression of ovarian CYP51 is dependent on gonadotropins, and ovarian CYP51 activity is enough for accumulating MAS. Serum insulin does not affect the ovarian CYP51 level, although it is essential for hepatic CYP51 expression. These findings indicate that expression of CYP51 is regulated differently among organs.