Androgen inhibition of FSH-stimulated progesterone production by granulosa cells of prepubertal pigs

Androgens have been reported to stimulate progesterone production by granulosa cells of several species, and to act synergistically with FSH in stimulation of progesterone accumulation by rat granulosa cells. Studies were undertaken to examine the effect of androgens on FSH-stimulated progesterone production in culture by granulosa cells derived from prepubertal pig ovaries. When included in 24-h culture with FSH, both androstenedione and testosterone caused a reduction in progesterone accumulation, but dihydrotestosterone and androsterone did not. Granulosa cells were cultured for 24 h with FSH and [14C]progesterone with or without testosterone; testosterone did not affect the rate of overall metabolism of [14C]progesterone and it was therefore concluded that testosterone inhibited progesterone synthesis, rather than enhancing its catabolism. 17 beta-Estradiol also inhibited FSH-stimulated progesterone accumulation. To determine whether the action of testosterone was mediated by conversion to estradiol, granulosa cells were cultured with FSH and testosterone with or without an aromatase inhibitor (4-acetoxy-androstenedione). The aromatase inhibitor failed to prevent the testosterone-induced reduction in progesterone accumulation, although it markedly inhibited estradiol accumulation. These results indicate that theca-derived androgens can inhibit FSH-stimulated progesterone production by granulosa cells in the prepubertal pig, independently of estradiol.     

The source of follicular androgens in the hamster follicle

The comparative ability of granulosa cells and theca of the hamster preovulatory follicle to produce androgens in vitro from endogenous and exogenous substrates was assessed. The results indicate that theca are the major source of follicular androstenedione, but that the granulosa cells may be the major source of follicular testosterone. Theca and granulosa cells accumulate comparable amounts of dihydrotestosterone from exogenous androstenedione and testosterone and both may be a significant source of follicular DHT. LH stimulates the conversion of progesterone and 17 alpha-OH progesterone to androstenedione, testosterone and DHT in theca. LH does not stimulate the conversion of androstenedione to testosterone or DHT, and that of testosterone to DHT in either granulosa cells or theca. FSH, in granulosa cells but not in theca, stimulates the conversion of adrostenedione to testosterone but it has no effect in DHT accumulation from exogenous testosterone.     

Source of immunoreactive inhibin in the chicken ovary.

High concentrations of immunoreactive inhibin were detected in the plasma of the laying domestic hen using a heterologous RIA validated for use in the chicken. Cessation of egg production induced by restricting the intake of nutrients decreased circulating inhibin to approximately 20% of its original concentration within 8 days, indicating that the ovary is the major source of the measured material. Dissection of ovarian follicles revealed that inhibin is nearly exclusively produced in the granulosa cell layer. When expressed per milligram cell protein the concentration of inhibin decreased significantly in granulosa layers of follicles of succeeding order in the hierarchy (F4 to F1). The concentration of progesterone increased in the granulosa layers of the same follicles whereas oestradiol in the surrounding theca layers decreased. In vitro culture of granulosa cells derived from follicles at different stages of development confirmed the decrease in inhibin secretion as a function of follicular growth observed in vivo. The granulosa cell inhibin secretion is stimulated by LH as well as by FSH, the former being the most effective one. The physiological significance of these changes in inhibin concentration during follicular maturation requires further investigation. It may be concluded, however, that the chicken presents a useful model for the study of the endocrine as well as the paracrine function of ovarian inhibin.     

Granulosa cell steroidogenesis before in vitro fertilization

Endocrine and gametogenic functions of the ovulatory follicle may be linked. To verify this, we studied granulosa cell steroidogenesis in relation to oocyte fertilization and preimplantation embryo development in vitro. Multiple follicles were stimulated in in vitro fertilization patients with clomiphene citrate and ovulation was induced with human chorionic gonadotropin (hCG). Oocytes were fertilized with husband's sperm and normal embryos were replaced 48 h later. Granulosa cells were separated from follicular fluid from 64 follicles and incubated for 3 h with and without aromatase substrate (1 microM testosterone). Progesterone and estradiol levels were measured in follicular fluid and incubation medium. Follicular fluid steroid levels and granulosa cell steroidogenesis showed no significant differences for oocytes which cleaved normally and those which did not. Granulosa cell aromatase activity was high in all follicles, suggesting that the low periovulatory follicular fluid estradiol level is not explained by a fall in granulosa cell aromatase after hCG. High granulosa cell progesterone production and follicular fluid progesterone were consistent with advanced granulosa cell luteinization. Oocytes undergoing polyspermic activation were from larger follicles with elevated follicular fluid progesterone levels, suggesting that follicular size and follicular fluid progesterone are correlated with "over-ripeness" and polyspermy. No simple relationship exists between oocyte function and the present indices of granulosa cell steroid metabolism.     

Regulation of gonadal androgen secretion

The various mechanisms regulating testicular and ovarian androgen secretion are reviewed. Testicular androgen secretion is controlled by luteinizing hormone (LH) and follicle stimulating hormone (FSH), which influence the Leydig cell response to the LH. The contribution of prolactin, growth hormone and thyroid hormones to the Leydig cell function is discussed. The ovarian androgen secretion is regulated in a very similar fashion as the Leydig cell of testis. Prolactin, however, has an inhibitory effect on androgen secretion in the ovary. The intratesticular action of androgens is linked to spermatogenesis. Sertoli cells, by producing the androgen-binding protein, contribute to the intratubular androgen concentration. Inhibin production of the Sertoli cell is stimulated by androgens. In the ovary, androgens produced by the theca interna are used as precursors for the aromatization of estradiol, which stimulates together with FSH the mitosis of granulosa cells. The feedback control of androgen secretion is complicated, as the direct feedback mechanisms are joined by indirect feedback regulations like the peptide inhibin, which can be stimulated by androgens. Intragonadal mechanisms regulating androgen production are the cybernins for testicles and ovaries. In the testicle, estrogens from the Sertoli cells regulate the Leydig cell testosterone biosynthesis. In the ovary, nonaromatizable androgens are potent inhibitors of the aromatization activity in the granulosa cell. A peptide with a FSH receptor binding inhibiting activity is found in male and female gonads. Finally, LH-RH-like peptides have been found in the testicle, which are capable of inhibiting steroidogenesis. These gonadocrinins are similarly produced in granulosa cells of the ovary.     

In vitro effects of dihydrotestosterone on granulosa cell production of estrogen and progesterone

To investigate the direct effects of androgens on follicle development, intact, immature female rats were given 8 IU PMSG (0 hour) and four injections of either vehicle or dihydrotestosterone (DHT), 1 mg/kg body weight, at 0, 12, 24, and 36 hours after PMSG. Granulosa cells from small (less than 200 microns), medium (200 to 400 microns), and large (greater than 400 microns) follicles were isolated and cultured in the presence or absence of 0.5 microM DHT in vitro for 48 hours, and the medium was assayed for progesterone and estrogen. Results show that DHT caused an increase in progesterone accumulation in all granulosa cells, regardless of follicle size. However, DHT inhibited estrogen accumulation in granulosa cells from different-size follicles and the inhibition varied depending on the duration of androgen exposure in vivo. The inhibition of estrogen accumulation was seen in granulosa cells from small follicles without prior exposure to DHT in vivo, while an inhibition of estrogen accumulation was seen in granulosa cells from medium and large follicles exposed to DHT treatment in vivo. Taken together, the results of experiments with in vivo and/or in vitro DHT treatment show that the androgen increases granulosa cell progesterone synthesis regardless of follicle size. However, the estrogen accumulation by granulosa cell is dependent on follicle size and duration of DHT exposure.     

Role of ovarian theca and granulosa cell interaction in hormone productionand cell growth during the bovine follicular maturation process

We have investigated the possible role of theca and granulosa cell interaction in the control of the hormone-producing activity and growth of granulosa and theca cells during bovine ovarian follicular development, using a coculture system in which granulosa and theca cells were grown on opposite sides of a collagen membrane. When follicular cells were isolated from small follicles (3-5 mm), theca cells reduced estradiol, progesterone, and inhibin production by granulosa cells to 14 +/- 5%, 64 +/- 6%, and 27 +/- 4%, respectively, of the production by granulosa cells cultured alone. On the other hand, when the cells were isolated from large follicles (15-18 mm), theca cells increased these levels to 253 +/- 34%, 156 +/- 24%, and 287 +/- 45%, respectively. Theca cells did not affect the growth of granulosa cells. Androstenedione production by theca cells was augmented by granulosa cells to 861 +/- 190% (in small follicles) and 1298 +/- 414% (in large follicles), respectively. The growth of theca cells was also augmented by granulosa cells (small follicle, 210 +/- 43%, and large follicle, 194 +/- 24%, respectively). These results indicate that theca cells secrete factor(s) inhibiting the differentiation of immature while promoting that of matured granulosa cells; they also suggest that granulosa cells secrete factor(s) promoting both the differentiation and growth of theca cells throughout the follicular maturation process.     

Estradiol-17 beta and androgen secretion by isolated porcine ovarian follicular cells in vitro

The cellular sources and gonadotropic regulation of porcine ovarian estrogen and androgen were assessed by culturing isolated granulosa cells and thecal cells from medium size follicles (4-6 mm diameter) separately for 24 h in a chemically defined medium containing gonadotropins and (or) testosterone. At the end of the culture period, estradiol-17 beta (estradiol) and androgens in the media were determined by radioimmunoassays. Production of estradiol by granulosa cells without an exogenous aromatizable androgen was low in the absence or presence of a highly purified preparation of either follicle-stimulating hormone (FSH. 0.25 microgram/mL) or luteinizing hormone (LH. 1 microgram/mL). Addition of testosterone or androstenedione (0.5 microM), but not dihydrotestosterone or pregnenolone, significantly increased estradiol secretion. Additional increases were observed when FSH, LH, prostaglandin E2, or dibutyryl cyclic 3'.5'-adenosine monophosphate was present. Production of estradiol by thecal cells was low in the presence or absence of exogenous testosterone, and was essentially unaffected by the presence of gonadotropins. Thecal cells, however, released large amounts of androstenedione and smaller amounts of testosterone and other androgens during 24-h culture and the production of these androgens was stimulated by LH but not by FSH. Androgen secretion by granulosa cells was negligible when compared with the theca and was unaffected by gonadotropins. It is concluded that the theca is the prime site for follicular androgen biosynthesis by the porcine ovarian follicle, and, upon LH stimulation, may provide androgen precursors for estradiol production by granulosa cells.     

Effect of activin-a on goat granulosa cell steroidogenesis

Growth factors are said to play a significant role in the development of ovarian follicles. We wished to measure the content of one growth factor, activin-A in goat ovarian follicles, and study its effect on goat granulosa cells steroidogenesis. The follicular fluid content of activin-A from small, medium and large antral follicles was determined by two-site enzyme immunoassay. The results showed that activin-A concentration in the follicular fluid increased as the size of the follicle increased and, thus, may act as a local regulator of follicle development. To examine this possibility, the effect of increasing concentration of activin-A (0, 1, 10, 100 ng/mL) on differentiated goat granulosa cells steroidogenesis was evaluated in vitro for 48 hours in a chemically defined medium. Activin-A treatment resulted in a significant inhibition of progesterone production concomitant with a significant stimulation of estradiol production. These results were confirmed by time-effect of 50 ng/mL activin-A on goat granulosa cells steroidogenesis for 24, 48 and 72 hours. Granulosa cells displayed differential steroidogenic responses to activin-A, estradiol production becoming enhanced and progesterone production suppressed. Based on these findings, it appears that activin-A is a local regulator of goat granulosa cell steroidogenesis, and may act to promote granulosa cell differentiation and inhibit its luteinization.     

Decline in circulating estradiol during the periovulatory period is correlated with decreases in estradiol and androgen, and in messenger RNA for p450 aromatase and p450 17alpha-hydroxylase, in bovine preovulatory follicles

The preovulatory surge of gonadotropins induces meiotic maturation of the oocyte, the follicular/luteal phase shift in hormone production, and ovulation. This complex and rapid series of developmental changes is difficult to study in large mammals, such as primates and ruminants, because variability in the length of individual reproductive cycles makes it virtually impossible to predict the time of the LH surge. We have validated an experimental model for inducing the LH surge and ovulation in cattle and used it to study the sequence of changes in hormone secretion and some of the mechanisms of these changes. Luteolysis and a follicular phase were induced by injection of prostaglandin F(2alpha); injection of a GnRH analogue 36 h later induced an LH surge and ovulation. The LH surge peaked 2 h after GnRH and ovulation followed 22-31 h after the surge, consistent with the periovulatory interval in natural cycles. The ensuing luteal phase was normal, both in length and in concentrations of circulating progesterone. In experiment I, the uteroovarian effluent was collected, via cannulation of the vena cava, at frequent intervals relative to GnRH injection. Circulating estradiol declined progressively after GnRH, reaching a nadir by 8-10 h before ovulation, whereas concentrations of androstenedione and testosterone remained constant. In experiment II, preovulatory follicles were obtained at 0, 3.5, 6, 12, 18, or 24 h after GNRH: Concentrations of androgens and estradiol were measured in follicular fluid and medium from cultures of follicle wall (theca + granulosa cells); steady-state levels of mRNA for 17alpha-hydroxylase (17alphaOH) and P450 aromatase were measured in follicular tissue. Shortly after the LH surge (3.5 h post-GnRH) there was an acute increase in the capacity of follicular tissue to secrete androstenedione, but not estradiol, in vitro. Thereafter, both androgens and estradiol declined, both in follicular fluid and in medium collected from cultures of follicle wall. Levels of mRNA for 17alphaOH and aromatase in follicle wall decreased significantly by 6 h after GnRH, suggesting that declining levels of these enzymes underlie the decreases in steroid production by follicular cells. These results show that in cattle the preovulatory decrease in follicular estradiol production is mediated by redundant mechanisms, because androgen production and the capacity of granulosa cells to convert androgens to estradiol decline coordinately, in concert with decreases in mRNA for 17alphaOH and P450 aromatase.     

Inhibin production in vitro by granulosa cells from Booroola ewes which were either homozygous or non-carriers of a fecundity gene influencing their ovulation rate

The production of inhibin by granulosa cells was studied in vitro using cells from follicles of various sizes and health. Follicles were recovered on Days 10-13 of the oestrous cycle, from Booroola x Romney ewes which were homozygous (FF) carriers or non-carriers (++) of the fecundity (F) gene. Inhibin was measured using a bioassay based on the suppression of follicle-stimulating hormone (FSH) output by cultured pituitary cells from ovariectomized Romney ewes and, in some instances, for comparative purposes, by radioimmunoassay also. Geometric mean inhibin production by granulosa cells from nonatretic follicles increased with increasing follicle diameter, during the first 24 h of culture, for both genotypes. The geometric mean production of inhibin by cells from nonatretic 3-4.5 mm diameter FF follicles (the largest follicles found in FF ewes), was significantly higher (P less than 0.05) than that by cells from non-atretic 3-4.5 mm diameter ++ follicles, but similar to that of cells from non-atretic greater than or equal to 5 mm diameter ++ follicles. The production of oestradiol-17 beta by cells cultured in the presence of testosterone (1 microgram/ml) followed a pattern similar to cellular inhibin production. There was a positive linear correlation between inhibin and oestradiol-17 beta production during the first 24 h of culture, for both genotypes. In addition to acting as a substrate for oestradiol-17 beta synthesis, testosterone generally had a slight, stimulatory effect on inhibin production.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of stage of estrous cycle and follicular maturation on ovarian inhibin production in sheep

Twenty-four Scottish Blackface ewes (mean weight 50.0 +/- 0.1 kg with ovulation rate 1.3 +/- 0.1) were randomly divided into 4 groups of 6 animals. Under general anesthesia, following the collection of a timed sample of ovarian venous blood, the ovaries of these animals were collected either on Day 10 of the luteal phase or 12, 24, and 48 h after a luteolytic dose of a prostaglandin (PG) F2 alpha analogue (cloprostenol 100 micrograms i.m.) administered on Day 10. All follicles greater than 3 mm were dissected from the ovaries and incubated in Medium 199 (M199) at 37 degrees C for 2 h, following which the granulosa cells were harvested and incubated in triplicate for 24 h in M199 with or without ovine FSH or ovine LH. Plasma and culture media samples were assayed for inhibin, estradiol (E2), androstenedione (A4), and testosterone (T) by specific RIA. After correcting for hematocrit, ovarian secretion rates were calculated from the product of the plasma concentration and flow rate. The rate of ovarian inhibin secretion during the luteal phase was similar from ovaries categorized on the basis of presence of luteal tissue (1.0 +/- 0.3 and 0.9 +/- 0.5 ng/min for CL present and absent, respectively), confirming that the ovine CL does not secrete appreciable amounts of inhibin. Inhibin secretion was higher (p less than 0.05) at 12 h after PG-induced luteolysis but not at 24 or 48 h compared to values for luteal phase control ewes. Although ovaries containing large estrogenic follicles (greater than or equal to 4 mm in diameter and classified as estrogenic from in vitro criteria) secreted the most inhibin (55%; p less than 0.05), both ovaries containing large nonestrogenic follicles (33%) and small (11%; less than 4 mm in diameter) follicles secreted appreciable amounts of inhibin. This contrasted strongly with E2 where greater than 80% of the steroid was secreted by large estrogenic follicles. The rate of ovarian inhibin secretion was positively correlated (p less than 0.05) with the rate of E2, A4, and T secretion. Overall, there was no significant effect of stage of cycle on follicular inhibin content after 2 h incubation in vitro, release of inhibin by follicles incubated in vitro, or synthesis of inhibin by granulosa cells cultured in vitro. FSH and LH had no effect on the production of either inhibin or estradiol by cultured granulosa cells. Follicular diameter was positively correlated (p less than 0.001) with follicular inhibin and steroid release. Follicular inhibin content after 2 h incubation in vitro was more highly correlated with inhibin release by incubated follicles (r = 0.7; p less than 0.001) than with inhibin synthesis by granulosa cells in vitro (0.4; p less than 0.01).(ABSTRACT TRUNCATED AT 400 WORDS)     

Transforming growth factor-beta(1) regulates differentiation of porcine granulosa cells in vitro

Transforming growth factor-beta (TGF-beta) is a potential regulator of ovarian function and follicular development. It is speculated that TGF-beta mediates the events in the follicle which culminate in ovulation of the oocyte. The complex processes which ultimately leads to this natural phenomenon must involve interactions between the 2 major follicular cell types, theca and granulosa cells, and the oocyte. Furthermore, a complex local regulatory system must exist to determine which follicles should undergo development and, eventually, which of those should ovulate or undergo atresia. To begin to understand this perplexing process, we must first understand the variables which control the function of each individual cell type. This study investigated the effect of TGF-beta(1) on FSH-induced porcine granulosa cell differentiation in vitro. Transforming growth factor-beta(1) was shown to inhibit progesterone production at high concentrations (0.1 and 10.0 ng/ml) after 12-, 24- and 48-hour treatment. However, TGF-beta(1) produced a biphasic effect on FSH-induced progesterone production during the 12-hour interval between the 36- and 48- hour treatment periods; TGF-beta(1) stimulated progesterone production at a low concentration (0.001 ng/ml) and inhibited production at high concentrations (0.1 and 10.0 ng/ml). The results obtained from the biphasic effect were not observed during any of the other incubation periods or intervals investigated. These results show that TGF-beta(1) has opposing effects on the differentiation of porcine granulosa cells as compared with those on rat granulosa cells. Moreover, TGF-beta(1) can produce opposing effects within the porcine granulosa cell itself which are specific to the concentration and treatment period used. The results of this study seem to suggest that TGF-beta(1) is species- and time-specific in its regulatory actions on FSH-induced porcine granulosa cell differentiation.     

Differential production of steroids by dispersed granulosa and theca interna cells from developing preovulatory follicles of pigs

Dispersed granulosa and theca interna cells were recovered from follicles of prepubertal gilts at 36, 72 and 108 h after treatment with 750 i.u. PMSG, followed 72 h later with 500 i.u. hCG to stimulate follicular growth and ovulation. In the absence of aromatizable substrate, theca interna cells produced substantially more oestrogen than did granulosa cells. Oestrogen production was increased markedly in the presence of androstenedione and testosterone in granulosa cells but only to a limited extent in theca interna cells. The ability of both cellular compartments to produce oestrogen increased up to 72 h with androstenedione being the preferred substrate. Oestrogen production by the two cell types incubated together was greater than the sum produced when incubated alone. Theca interna cells were the principal source of androgen, predominantly androstenedione. Thecal androgen production increased with follicular development and was enhanced by addition of pregnenolone or by LH 36 and 72 h after PMSG treatment. The ability of granulosa and thecal cells to produce progesterone increased with follicular development and addition of pregnenolone. After exposure of developing follicles to hCG in vivo, both cell types lost their ability to produce oestrogen. Thecal cells continued to produce androgen and progesterone but no longer responded to LH in vitro. These studies indicate that several functional changes in the steroidogenic abilities of the granulosa and theca interna compartments occur during follicular maturation.     

Medroxyprogesterone acetate: receptor binding and correlated effects on steroidogenesis in rat granulosa cells

Medroxyprogesterone acetate (MPA), a widely used synthetic steroid, was studied to determine both its effects on steroid receptors and steroidogenesis in the well-characterized rat ovarian granulosa cell model. Initial receptor binding studies showed MPA was as potent as progesterone and 10-fold less potent than R-5020 (an active synthetic progestin) in binding to progesterone cytosolic receptors in rat ovarian granulosa cells. MPA was 20-fold less potent than testosterone, and 10-fold less potent than dexamethasone in binding to the androgen and glucocorticoid cytosolic receptors, respectively. The binding of MPA to progestrone, androgen and glucocorticoid receptors predicted direct effects of MPA on FSH-stimulated estrogen (E), progesterone (P), and 20 alpha-dihydroprogesterone (DHP) production by cultured rat ovarian granulosa cells. MPA at 10(-7) to 10(-6) M significantly augmented FSH-stimulated P and DHP production (a previously documented progestin, androgen and glucocorticoid effect). This augmentation was blocked by the concurrent addition to cell culture of 10-fold excess RU-486 (a potent anti-progestin and anti-glucocorticoid). At concentrations greater than 10(-6) M, MPA inhibited the production of P and DHP (a progestin effect), and the production of E (a progestin and glucocorticoid effect). MPA, structurally a progestin, has complex steroid hormone effects predicted by its interaction with progesterone, androgen and glucocorticoid receptors.     

Bovine theca and granulosa cells interact to promote androgen production

Pieces of theca interna or follicle wall (theca interna + attached granulosa cells), obtained from bovine preovulatory follicles prior to the surge of luteinizing hormone (LH) and cultured for 3 days, secreted androstenedione. Luteinizing hormone, but not follicle-stimulating hormone (FSH), increased production of androstenedione 3 to 4-fold. In both the presence and absence of LH, follicle wall preparations secreted about 4-fold more androstenedione than did equivalent amounts of theca interna tissue. Isolated granulosa cells produced only negligible quantities of androstenedione, which suggests that they may contribute to the greater production of androstenedione by follicle wall by supplying progestin precursor to the theca cells. The addition of pregnenolone or progesterone to isolated theca interna increased the secretion of androstenedione, but pregnenolone was by far the more effective precursor. This suggested that the delta 5 (delta 5) pathway is the preferred pathway for androstenedione synthesis by bovine theca cells and that granulosa cells might supply progestin precursor in the form of pregnenolone. Follicle wall and granulosa cell cultures secreted 2 and 7 times more pregnenolone, respectively, than did theca cultures. Luteinizing hormone, but not FSH, increased production of pregnenolone by the follicle wall, whereas the gonadotropins had no effect on secretion by either granulosa or theca cells. Since exogenous testosterone enhanced the production of pregnenolone by granulosa cells, thecal androgen (which is stimulated by LH) may increase the ability of granulosa cells to make pregnenolone and explain the stimulatory effect of LH on pregnenolone secretion by follicle wall.(ABSTRACT TRUNCATED AT 250 WORDS)     

Steroidogenic capabilities of various compartments of rat ovarian follicles in culture

The production of progesterone, estrogen and androgen as well as the metabolism of radiolabelled progesterone by various cellular components of rat ovarian follicles were studied. Granulosa (G), theca (T), recombined granulosa plus theca (G+T) and intact follicular wall (FW) of ovaries from immature rats treated with pregnant mare serum gonadotropin (8 IU) were cultured for 24 h in the presence or absence of [4-¹⁴C]progesterone. The estrogen and androgen accumulation when calculated per follicle was several fold greater in FW than in G,T, or G+T preparations. The conversion of radiolabelled progesterone to its identified C₂₁ catabolites (20α-hydroxy-4-pregnen-3-one and 3α-hydroxy-5α-pregnan-20-one) was significantly lower in FW than in G+T incubations. Conversely, the metabolism of radiolabelled progesterone to androsterone was several fold greater in FW than in G+T incubations. Addition of hydroxyflutamide to FW incubations significantly decreased estrogen production and increased the conversion of radiolabelled progesterone to androsterone. Estrogen production by follicular wall may be enhanced by androgenic stimulation of aromatase activity as well as by a structure-dependent factor(s) of a yet unknown nature, both of which may decrease progesterone catabolism to biologically inactive progestins while promoting progesterone conversion to androgens and eventually to estrogens.     

Follicle-stimulating hormone regulation of cytochrome P-450 side-chain cleavage messenger ribonucleic acid accumulation by porcine granulosa cells isolated from small and medium follicles

The experiments described here were conducted to examine regulation of cytochrome P-450 side-chain cleavage (SCC) mRNA accumulation in porcine granulosa cells isolated from small (1-4-mm) and medium (5-6-mm) follicles. Granulosa cells were cultured under the following conditions: 1) for 48 h or 96 h with 0, 50, or 200 ng/ml porcine FSH; 2) for 96 h with 200 ng/ml FSH and aminoglutethimide (100 microM); and 3) for 96 h with forskolin (100 microM). Total RNA was extracted and examined by Northern and dot-blot hybridization analysis, and culture media were assayed for progesterone concentration. Northern blot analysis revealed a single band approximately 2.1 kb in size. Accumulation of SCC mRNA by granulosa cells was both FSH dose- and culture time-dependent (p less than 0.05) with maximal increases approximately 4.5 times control levels. Aminoglutethimide reduced progesterone production by about 80% while having no effect on granulosa cell accumulation of SCC mRNA compared to cells stimulated with 200 ng/ml of FSH. Forskolin-treated cells produced significantly more progesterone than did cells treated with FSH, but accumulation of SCC mRNA was similar. In response to FSH, concentration of SCC mRNA did not vary with follicle size, but granulosa cells from small follicles produced significantly more progesterone than did those from medium follicles. These results demonstrate that concentration of SCC mRNA in cultured porcine granulosa cells is FSH dose-dependent, does not vary significantly in cells from small- and medium-sized follicles, and is correlated with progesterone production, but may not parallel progesterone secretion. This last observation indicates that control at sites other than SCC mRNA can affect progesterone production.     

Effects of angiogenin on granulosa and theca cell function in cattle

Angiogenin is a member of the ribonuclease A superfamily of proteins that has been implicated in stimulating angiogenesis but whether angiogenin can directly affect ovarian granulosa or theca cell function is unknown. Therefore, the objective of these studies was to determine the effect of angiogenin on proliferation and steroidogenesis of bovine granulosa and theca cells. In experiments 1 and 2, granulosa cells from small (1 to 5 mm diameter) follicles and theca cells from large (8 to 22 mm diameter) follicles were cultured to evaluate the dose-response effect of recombinant human angiogenin on steroidogenesis. At 30 and 100 ng/ml, angiogenin inhibited (P<0.05) granulosa cell progesterone production and theca cell androstenedione production but did not affect (P>0.10) granulosa cell estradiol production or theca cell progesterone production, and did not affect numbers of granulosa or theca cells. In experiments 3 and 4, granulosa and theca cells from both small and large follicles were cultured with 300 ng/ml of angiogenin to determine if size of follicle influenced responses to angiogenin. At 300 ng/ml, angiogenin increased large follicle granulosa cell proliferation but decreased small follicle granulosa cell progesterone and estradiol production and large follicle theca cell progesterone production. In experiments 5 and 6, angiogenin stimulated (P<0.05) proliferation and DNA synthesis in large follicle granulosa cells. In experiment 7, 300 ng/ml of angiogenin increased (P<0.05) CYP19A1 messenger RNA (mRNA) abundance in granulosa cells but did not affect CYP11A1 mRNA abundance in granulosa or theca cells and did not affect CYP17A1 mRNA abundance in theca cells. We conclude that angiogenin appears to target both granulosa and theca cells in cattle, but additional research is needed to further understand the mechanism of action of angiogenin in granulosa and theca cells, as well as its precise role in folliculogenesis.