Stage of ovarian follicular development associated with the initiation of steroidogenic competence in avian granulosa cells.

Previously described models for avian ovarian steroidogenesis, using mature, 25-40-mm preovulatory follicles as the source of tissues, were based on the assumption that interaction of the granulosa layer, as the predominant source of progesterone, with adjacent theca cells is required for maximal production of C21, C19, and C18 steroids. In the present study, we evaluated the steroidogenic capacity of ovarian cells isolated from less mature, 6-8-mm and 9-12-mm follicles in the chicken ovary (representative of a stage of development 2-3 wk prior to ovulation) to determine at which stage of follicular development granulosa and/or theca cells become steroidogenically competent. Granulosa cells collected from 6-8-mm follicles were found to be virtually incompetent to produce steroids, containing extremely low basal levels of progesterone (12 pg/5 x 10(5) cells) and failing to respond with increased steroid output following a 3-h exposure to ovine LH (oLH; 0.1 and 100 ng/0.5 ml), ovine FSH (oFSH; 100, 500, and 1,000 ng/0.5 ml), 8-bromo-cyclic adenosine monophosphate (8-bromo-cAMP; 0.33 and 3.33 mM) or 25-hydroxycholesterol (250 and 2,500 ng/0.5 ml). However, addition of pregnenolone (20 and 200 ng/0.5 ml) to granulosa incubations resulted in significantly increased progesterone levels. Granulosa cells of 6-8-mm follicles also failed to increase cAMP formation in the presence of oLH (10, 100, and 1,000 ng/0.5 ml) and 3-isobutyl-1-methylxanthine (IBMX; 10 microM), but responded to stimulation with 1,000 ng oFSH (4.4-fold increase over basal) or 10 microM forskolin (32-fold increase over basal) in the presence of IBMX. In contrast, granulosa cells isolated from 9-12-mm follicles and incubated for 3 h in vitro were found to contain basal progesterone levels 200-fold higher than those found in granulosa cells of 6-8-mm follicles. Furthermore, granulosa cells of 9-12-mm follicles markedly increased progesterone production following incubation in the presence of oFSH (100-1,000 ng/0.5 ml), 8-bromo-cAMP (0.33 and 3.33 mM), or 25-hydroxycholesterol (250 and 2,500 ng/0.5 ml). However, these granulosa cells remained unresponsive to oLH (0.1, 10, and 100 ng/0.5 ml), failing to increase cAMP accumulation (in the presence of IBMX) and progesterone output. Theca cells of small yellow follicles were found to produce measurable basal levels of progesterone, androstenedione, and estradiol, and levels of each steroid were significantly increased following a 3-h challenge with oLH, 8-bromo-cAMP, 25-hydroxycholesterol, and pregnenolone.(ABSTRACT TRUNCATED AT 400 WORDS)     

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)     

Hormonal requirements for the growth and differentiation of hamster preantral follicles in long-term culture

Preantral follicles from pro-oestrous and oestrous hamsters were isolated enzymically (Stages 1-5) and by microdissection (Stage 6) and cultured for up to 168 h in the absence or presence of 100 ng ovine FSH or LH separately or combined or 1 or 10 micrograms progesterone or estradiol-17 beta in serum-free defined medium and exposed to 1 muCi [3H]thymidine for 24 h before termination. In the presence of insulin and hydrocortisone but not gonadotrophins, the morphology of follicles from pro-oestrous animals at Stages 1-4 (1-4 layers granulosa cells; no theca) were unaffected for up to 48 h whereas for Stages 5 (5-6 layers granulosa cells and developing theca) and 6 (7-8 layers granulosa cells and theca), atresia was prominent by 24 h. FSH significantly reduced the percentage of atretic follicles in Stages 1-5 throughout the culture period; but was effective only up to 96 h for Stage-6 follicles. LH was also effective, albeit to a lesser extent. FSH increased follicular labelling indexes during every 24-h labelling period and, during a pulse-chase period, follicular DNA content and granulosa cell numbers. FSH, but not LH, induced differentiation by 96 h of preantral follicles at Stage 6 into small antral stages (Stages 7-8). FSH and LH together induced almost the same effect as FSH alone. However, neither progesterone nor oestradiol had any significant long-term effects on DNA synthesis and oestradiol induced atresia beyond 24 h. Both FSH and LH induced follicular maturation in vitro as evident from increases in progesterone, androstenedione and oestradiol production. Follicles (Stages 1-4) collected from oestrous hamsters responded to FSH to a lesser extent than did those from pro-oestrous animals, possibly because of in-vivo exposure to periovulatory changes in gonadotrophins; however, an antrum formed in Stage-6 follicles by 72 h.     

Significance of the delta 5 and delta 4 steroidogenic pathways in the hamster preovulatory follicle

Isolated hamster granulosa cells and theca from preovulatory follicles were incubated in vitro for 2 and 6 h in the absence/or presence of LH and steroid substrates. The purpose of the experiments was to determine, in theca, the relative activities of the delta 5 and delta 4 pathways under controlled conditions, and to compare the ability of granulosa cells and theca to form progesterone from exogenous pregnenolone. The results of the experiments show that the delta 5 pathway in theca predominates before and up to 2 h after LH stimulation. The delayed effect of LH after 2 h is a switch from delta 5 to delta 4 as the major metabolic pathway. Progesterone formation from exogenous pregnenolone is 7 to 10 times greater in unstimulated granulosa cells than in theca. Acute effects of LH lead to increased conversion of exogenous pregnenolone to progesterone in granulosa cells but not theca. LH does, however, acutely stimulate the thecal conversion of DHEA to androstenedione. The longer term effect of LH in both cell types is to increase pregnenolone conversion to progesterone.     

Evidence for interaction between granulosa cells and theca in early progesterone synthesis

The temporal characteristics of steroidogenesis in vitro by hamster preovulatory follicles, were compared to granulosa cells and theca incubated separately. Gonadotropin-stimulated intact follicles or recombined granulosa cells and theca synthesized increased amounts of progesterone by 30-120 minutes of incubation. The granulosa cells and theca, when incubated separately, did not begin to accumulate progesterone until 4 to 6 hours. The relatively rapid rise in follicular progesterone synthesis after in vitro gonadotropin stimulation follows the same time course as the rapid rise in vivo of hamster and rat preovulatory progesterone after the gonadotropin surge. The sharp differences in the temporal characteristics of progesterone synthesis between follicles and separated follicular cell types suggest an interaction between granulosa cells and theca in at least one phase of progesterone synthesis.     

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.     

Alteration of follicular steroid secretion and thecal morphology after in-vitro exposure of individual pig follicles to follicle regulatory protein

Medium-sized (4-6 mm) pig follicles were incubated for 10 h and then examined via light microscopy. Treatment with pig FSH resulted in significantly increased concentrations of oestradiol, testosterone, androstenedione and progesterone in the medium. Follicle regulatory protein (FRP) alone (1 micrograms/ml) decreased follicular secretion of oestradiol (56%) and progesterone (53%) but stimulated the secretion of testosterone (226%) and androstenedione (139%). In the presence of 1 ng FSH/ml, the inhibitory effect of FRP on oestradiol secretion was enhanced (74%), progesterone values were unaffected and secretion of testosterone and androstenedione were reduced by 66% and 53%, respectively. All effects of FRP were fully overcome by 1 micrograms FSH/ml. The incidence of atresia, as defined by granulosa cell pycnosis, was similar in all treatment groups (1-3 of 10 follicles per group). The remaining follicles had intact granulosa cells. However, follicles treated with FRP (1 micrograms/ml) + FSH (1 ng/ml) had pycnotic nuclei in the theca interna cells, in the presence of an intact stratum granulosum. External exposure of follicles to FRP may not reflect physiological conditions since, in vivo, thecal pycnosis is never observed before granulosa cell pycnosis. However, the present results indicate that FRP is potentially capable of altering both follicular morphology and steroidogenesis. We suggest that FSH and FRP interact to affect follicular development.     

Ovarian steroid production in vitro during gonadal regression in the turkey. II. Changes induced by forced molting.

In the turkey, the onset of incubation behavior is associated with altered ovarian steroidogenesis, ovarian regression, decreased, LH secretion, and increased serum prolactin (Prl) levels. To clarify the relative contribution of circulating LH and Prl to the initiation of ovarian regression, laying hens were exposed for 0, 3, 7, or 14 days to a forced molting procedure (exposure to reduced day length of 6L:18D and removal of feed and water for the initial 3 days) that induces ovarian regression and decreased LH levels but does not increase Prl levels. On each of these days, hens were killed and granulosa and theca interna cells from the largest (F1) and fifth largest (F5) preovulatory follicles and total cells from the small white follicles (SWF) were incubated for 5 h in the presence or absence of ovine LH (oLH; 0-1,000 ng/ml). Force-molted hens exhibited diminished levels of circulating LH, Prl, progesterone (P), androgen (A), and estradiol (E) by Day 3 of treatment. Ovarian atresia began in F1 by the third day of treatment, and included F1 and F5 by the seventh day. No preovulatory follicles were present on the fourteenth day. With both F1 and F5 granulosa cells, production of P in the presence of oLH was initially enhanced (Day 3) and later absent (Day 7). In contrast, production of A by F5 theca interna cells in the presence of oLH was initially suppressed (Day 3) and then returned to pretreatment levels (Day 7).(ABSTRACT TRUNCATED AT 250 WORDS)     

Response of porcine theca and granulosa cells to GH during short-term in vitro culture

In Experiment 1, the influence of exogenous GH on steroid secretion by granulosa and theca interna cells recovered from small (1-3 mm), medium (4-6 mm) and large (8-12 mm) follicles was tested. In the second experiment, theca cells (Tc) and granulosa cells (Gc) obtained from large follicles were cultured separately or in two types, Tc/Gc co-culture, where both types of cells were mixed in one well or Gc and Tc were separated by cell culture membrane inserts. In the third experiment, the influence of GH on the morphology of Gc and Tc cells and activity of Delta(5),3beta-hydroxysteroid dehydrogenase (3beta-HSD) was studied. Cells were grown in the control medium (M199+5% of calf serum) or supplemented with 100 ng/ml GH. Testosterone (10(-7) M) was added as the aromatase substrate to granulosa cells cultures. The media were assayed after 48 h of culture for progesterone and oestradiol by RIA. GH added to the culture media had no effect on oestradiol and progesterone secretion by granulosa cells isolated from small and medium follicles while it stimulated both oestradiol and progesterone secretion by Gc isolated from large preovulatory follicles. A stimulatory effect on oestradiol secretion by Tc isolated from all size follicles was observed. GH did not stimulate progesterone secretion by Tc isolated from small follicles but stimulated progesterone secretion by Tc isolated from medium and large preovulatory follicles. Both co-culture systems exhibited synergistic effect on oestradiol secretion. The stimulatory effect on progesterone secretion under the influence of GH was observed in Gc cultured alone and Tc cultured alone. In contrast, the secretion of progesterone was attenuated in both co-culture systems and the addition of GH further augmented this attenuation. A statistically significant increase in oestradiol secretion was observed in all culture conditions. The addition of GH to the culture medium stimulated the activity of 3beta-HSD compared with the control culture from both types of cells. In conclusion, the present studies indicate that there are direct and follicular development stage dependent actions of GH on steroidogenesis of porcine follicular cells.     

Morphological and biochemical characteristics during ovarian follicular development in the pig

Ovaries were recovered from groups of naturally cyclic pigs (N = 5) on each of Days 16, 18, 20 and 21 of the oestrous cycle. Follicular diameter, follicular fluid volume and concentrations of oestradiol, testosterone and progesterone, and granulosa cell number were determined in all follicles greater than or equal to 2 mm in diameter (n = 511). In alternate follicles either granulosa cell aromatase activity and theca testosterone content or 125I-labelled hCG binding to granulosa and theca were determined. The mean total number of follicles recovered per animal decreased as the follicular phase progressed and a strong positive relationship (P less than 0.001) existed between follicular diameter and volume on all days. The number of granulosa cells recovered per follicle was variable, and not related to oestrogenic activity of the follicles. Mean follicular fluid oestradiol, testosterone and 125I-labelled hCG binding all increased until Day 20 and decreased on Day 21, whereas mean theca testosterone content, 125I-labelled hCG binding to theca tissue and aromatase were all maximal on Day 21. On Days 20 and 21 a subset of 14-16 large follicles was readily distinguishable from the remaining smaller, less oestrogenically active population in each animal. Yet, consistently within these subsets there was a difference in follicular diameter of approximately 2.0 mm and also a considerable range of biochemical development even among follicles of equal size. These results indicate asynchrony at the time of recruitment and selection among follicles destined to ovulate and suggest that heterogeneity continues into the immediate preovulatory period.     

Structural and hormonal changes during follicular maturation in the ovary of the domestic goose

Follicle maturation in the ovary of sexually mature domestic geese in the spring reproductive cycle was investigated by histological methods and steroid-RIA. The single-layer granulosa of primary follicles temporarily transformed in the growing white follicles into several layers or a simple membrana granulosa with nuclei at several different levels in the cell. In the yolky follicles the granulosa represents a cuboidal epithelium (F4-F3) and subsequently a high cylindrical epithelium (F1). The originally connective tissue-like cells of the theca interna show a glandular proliferation in the largest white (F7) and the small yolky follicles (F6-F5). Glandular cell nests in the theca externa are typical in the generation of small white follicles and are absent in the wall of yolky follicles. Progesterone-content in the follicular wall (granulosa + theca) is the highest in the F1-F2 and F6-F5 types and is low in small white follicles (F8, F9 and F10). E2 concentration shows only slight variations between F1-F10. TEST content shows a slight increase between F1 and F3 and is high in medium-sized white follicles (F8-F9). The results suggest that in addition to the granulosa, the theca interna is also capable of an intensive progesterone synthesis.     

Steroid production by isolated theca and granulosa cells after initiation of atresia in the hamster

Hypophysectomized PMSG-primed hamsters were injected with PMSG antiserum and the theca and granulosa cells of the resulting atretic follicles were incubated in vitro. In the absence of added hormone, 17 alpha-hydroxyprogesterone and oestradiol production was not detectable in granulosa cells collected and incubated at 0, 12 and 24 h after antiserum. Progesterone production was not detected in control incubations at 0 h but was measurable with cells collected at 12 h after PMSG antiserum. When incubated with androstenedione or pregnenolone (10 ng/ml for each) 17 alpha-hydroxyprogesterone and progesterone production by granulosa cells were significantly increased at 0, 12 and 24 h after antiserum. Granulosa cells were capable of aromatizing androstenedione to oestradiol at all times examined. At 0 and 12 h after antiserum to PMSG, isolated thecal shells produced androstenedione. LH stimulation caused increased androstenedione production in all thecae at 0 h, in 50% of the thecae at 12 h and in none at 24 h after antiserum. Thecal shells produced 17 alpha-hydroxyprogesterone in response to LH at 0, 12 and 24 h after antiserum, and produced progesterone at all times examined. Thecae also responded to LH with increased progesterone production up to 72 h after antiserum. These experiments demonstrate that one important steroidogenic event in atresia may be the loss of activity of C 17,20 lyase in the theca leading to loss of substrate (androstenedione) for granulosa cell aromatization, although aromatase activity is present until at least 24 h after the induction of atresia.     

Steroid metabolism in granulosa and theca interna cells from preovulatory follicles of domestic hen (Gallus domesticus)

The capability of granulosa and theca interna cells, from preovulatory follicles of the domestic hen, to metabolize steroid precursors was evaluated. Granulosa and theca interna cells were isolated from ovarian preovulatory follicles at three different developmental stages: F1, F3 and F5. Tritiated pregnenolone (P5), progesterone (P4), dehydroepiandrosterone (DHEA), androstenedione (A4) and testosterone (T) were employed as precursors and their metabolic products were evaluated. The major metabolite of P5 by granulosa cells was P4, but we also observed low amounts of 5β-pregnandione. DHEA metabolism by granulosa cells yielded mainly A4, and minute quantities of 5β-androstan-3,17-dione (5β-dione) were detected. The only significant metabolite obtained in granulosa cells from A4 was 5β-dione, whereas T was only transformed into A4. On the other hand, P5 metabolism by theca interna cells yielded A4 as the main product, also P4, 17α-OHP4, 17α-OHP5, 5β-pregnandione, and DHEA, were found. When DHEA was the precursor A4 was produced in higher amounts than 5β-dione. A4 was mainly transformed into 5β-dione. In similar conditions, T was transformed into A4. These results show that granulosa cells have enzymatic activities of 3β-hydroxysteroid dehydrogenase/5-4 isomerase (3β-HSD from P5 and DHEA), 17β-hydroxysteroid dehydrogenase (17β-HSD from T) and 5β-reductase (from P5, DHEA and A4). Whereas theca interna cells have enzymatic activities of cytochrome P450c17 (from P5 and P4), 3β-HSD (from P5 and DHEA), 17β-HSD (from T) and 5β-reductase (from P4, DHEA and A4). These data support the concept that theca interna cells have the ability to synthesize androgens from progestins produced in granulosa cells. In addition, since theca interna cells did not show the capacity to aromatize androgens suggests that interaction between theca interna and theca externa cells occurs in vivo, thus confirming the three cell model for estrogen production. Furthermore, the fact that other metabolites were produced both in granulosa and theca interna cells, but in a different extent, suggests that complex mechanisms are participating in the regulation of steroid synthesis in avian ovary follicles.     

Differential regulation of pig theca cell steroidogenesis by LH, insulin-like growth factor I and granulosa cells in serum-free culture

The regulation of pig theca cell steroidogenesis was studied by the development of a physiological serum-free culture system, which was subsequently extended to investigate potential theca-granulosa cell interactions. Theca cells were isolated from antral follicles 6-9 mm in diameter and the effects of plating density (50-150x10(3) viable cells per well), LH (0.01-1.0 ng ml(-1)), Long R3 insulin-like growth factor I (IGF-I) (10, 100 ng ml(-1)) and insulin (1, 10 ng ml(-1)) on the number of cells and steroidogenesis were examined. The purity of the theca cell preparation was verified biochemically and histologically. Co-cultures contained 50x10(3) viable cells per well in granulosa to theca cell ratio of 4:1. Wells containing granulosa cells only were supplemented with 'physiological' doses of androstenedione or 100 ng ml(-1). Oestradiol production by co-cultures was compared with the sum of the oestradiol synthesized by granulosa and theca cells cultured separately. Oestradiol and androstenedione production continued throughout culture. High plating density decreased steroid production (P < 0.01). LH increased androstenedione (P < 0.001) and oestradiol (P < 0.05) synthesis and the sensitivity of the cells increased with time in culture. Oestradiol production was increased by 10 ng IGF-I ml(-1) (P < 0.001) but androstenedione required 100 ng ml(-1) (P < 0.001). Co-cultures produced more oestradiol than the sum of oestradiol synthesized by theca and granulosa cells cultured separately (P < 0. 001), irrespective of the androstenedione dose. This serum-free culture system for pig theca cells maintained in vivo steroidogenesis and gonadotrophin responsiveness. Thecal androstenedione and oestradiol production were differentially regulated and were primarily stimulated by LH and IGF-I, respectively. Theca-granulosa cell interactions stimulated oestradiol synthesis and this interaction was mediated by factors additional to the provision of thecal androgen substrate to granulosa cells.     

Progesterone pretreatment has a direct effect on GnRH-induced preovulatory follicles to determine their ability to develop into normal corpora lutea in anoestrous ewes

In two experiments carried out during seasonal anoestrus, Romney Marsh ewes were treated with small-dose (250 ng) multiple injections of GnRH at 2-h intervals with and without progesterone pretreatment. In Exp. 1, 8/8 progesterone-primed ewes ovulated and produced functionally normal corpora lutea compared with 2/9 non-primed ewes. Follicles were recovered from similarly treated animals 18 or 28 h after the start of GnRH treatment (at least 14 h before the estimated time of the LH peak) and assessed in terms of diameter, granulosa cell number, oestradiol, testosterone and progesterone concentrations in the follicular fluid, oestradiol production in vitro and binding of 125I-labelled hCG to granulosa and theca. There were no significant differences in any of these measures in 'ovulatory' follicles recovered from the progesterone-pretreated compared to non-pretreated animals. In Exp. 2, follicles were removed from similar treatment groups just before and 2 h after the start of the LH surge. Unlike 'ovulatory' follicles recovered from the non-pretreated ewes, those recovered from progesterone-pretreated ewes responded to the LH surge by significantly increasing oestradiol secretion (P less than 0.01) and binding of 125I-labelled hCG (P less than 0.05) to granulosa cells. Overall there was also more (P less than 0.05) hCG binding to granulosa and theca cells from progesterone-pretreated animals. Non-ovulatory follicles recovered from progesterone-primed ewes had more (P less than 0.05) binding of 125I-labelled hCG to theca and a higher testosterone concentration in follicular fluid (P less than 0.05) than did those from non-primed ewes. These results suggest that inadequate luteal function after repeated injections of GnRH may be due to a poor response to the LH surge indicative of a deficiency in the final maturational stages of the follicle.     

Prostaglandin production by the largest preovulatory follicles in the domestic hen (Gallus domesticus)

An injection of 5 micrograms of gonadotropin-releasing hormone (GnRH) into hens 8 h prior to oviposition advanced the expected time of oviposition by approximately 1 h. The plasma concentration of progesterone increased approximately 1 h earlier in GnRH-injected hens in comparison to saline-injected hens. The plasma concentration of 13,14-dihydro-15-keto-prostaglandin F2 alpha (PGFM) increased significantly (p less than 0.05) at the time of oviposition in both the GnRH- and saline-injected hens. Significantly (p less than 0.05) greater concentrations of prostaglandin F2 alpha (PGF2 alpha) were assayed in media containing the largest preovulatory follicles collected at oviposition than in media containing the second and fifth largest preovulatory follicles collected at the same time. No prostaglandin was detected in media containing small, nonhierarchial follicles. The concentration of PGF2 alpha in media containing granulosa cells from the largest preovulatory follicle was significantly greater (p less than 0.05) than in media containing 4 times as many theca cells. Ovine luteinizing hormone (oLH) alone or in combination with arachidonic acid had no effect on PGF2 alpha output from granulosa cells collected 6 h before oviposition, whereas A23187 caused a small stimulation of PGF2 alpha output. However, treating cells first with oLH and then with A23187 stimulated a 15- to 20-fold increase in PGF2 alpha. None of these stimuli enhanced the already high output of PGF2 alpha when added to incubations of granulosa cells collected within 5 min after oviposition. These data suggest that the granulosa cells of the largest preovulatory follicle are the major intraovarian source of prostaglandin and that production of PGF2 alpha is associated with the preovulatory surges of gonadotropins and steroid hormones preceding oviposition.     

Influence of follicular maturation on luteinizing hormone-, cyclic 3',5'-adenosine monophosphate-, forskolin- and cholesterol-stimulated progesterone production in hen granulosa cells

The influence of follicular maturation on progesterone production by collagenase-dispersed hen granulosa cells was measured in short-term incubations. Granulosa cells of the largest follicle (F1) produced up to ten times more progesterone than cells from smaller follicles (F3-F5), not only in response to luteinizing hormone (LH), but also when stimulated by exogenous cyclic AMP or forskolin, both of which raise intracellular cyclic AMP levels by nonreceptor-mediated mechanisms. Moreover, when granulosa cell progesterone synthesis was stimulated by incorporating 25-hydroxy-cholesterol into the incubation medium, an identical pattern was obtained. This could be attributed to a corresponding increase in the specific activity of the mitochondrial cholesterol side-chain cleavage enzyme (20,22 desmolase). An increase in the apparent Vmax was observed without a change in the apparent Km values. Pregnenolone substrate at concentrations which raised progesterone production to levels similar to those observed in response to LH stimulation was utilized equally by granulosa cells of mature and developing follicles. However, at high pregnenolone concentrations, granulosa cells of mature follicles converted significantly more of the precursor to progesterone. Assay of 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD) showed that the enzyme has two Kms: a low Km present in cells of both mature and developing follicles, and a high Km found only in granulosa cells of more mature follicles. It is concluded that LH-promoted progesterone synthesis in granulosa cells of developing chicken follicles is restricted not so much by the availability of receptors and the competence of the adenylate cyclase/cyclic AMP system, but by the activity of key enzymes, principally the cholesterol-20,22 desmolase.     

Local roles of TGF-beta superfamily members in the control of ovarian follicle development

Members of the transforming growth factor-beta (TGF-beta) superfamily have wide-ranging influences on many tissue and organ systems including the ovary. Two recently discovered TGF-beta superfamily members, growth/differentiation factor-9 (GDF-9) and bone morphogenetic protein-15 (BMP-15; also designated as GDF-9B) are expressed in an oocyte-specific manner from a very early stage and play a key role in promoting follicle growth beyond the primary stage. Follicle growth to the small antral stage does not require gonadotrophins but appears to be driven by local autocrine/paracrine signals from both somatic cell types (granulosa and theca) and from the oocyte. TGF-beta superfamily members expressed by follicular cells and implicated in this phase of follicle development include TGF-beta, activin, GDF-9/9B and several BMPs. Acquisition of follicle-stimulating hormone (FSH) responsiveness is a pre-requisite for growth beyond the small antral stage and evidence indicates an autocrine role for granulosa-derived activin in promoting granulosa cell proliferation, FSH receptor expression and aromatase activity. Indeed, some of the effects of FSH on granulosa cells may be mediated by endogenous activin. At the same time, activin may act on theca cells to attenuate luteinizing hormone (LH)-dependent androgen production in small to medium-size antral follicles. Dominant follicle selection appears to depend on differential FSH sensitivity amongst a growing cohort of small antral follicles. Activin may contribute to this selection process by sensitizing those follicles with the highest "activin tone" to FSH. Production of inhibin, like oestradiol, increases in selected dominant follicles, in an FSH- and insulin-like growth factor-dependent manner and may exert a paracrine action on theca cells to upregulate LH-induced secretion of androgen, an essential requirement for further oestradiol secretion by the pre-ovulatory follicle. Like activin, BMP-4 and -7 (mostly from theca), and BMP-6 (mostly from oocyte), can enhance oestradiol and inhibin secretion by bovine granulosa cells while suppressing progesterone secretion; this suggests a functional role in delaying follicle luteinization and/or atresia. Follistatin, on the other hand, may favor luteinization and/or atresia by bio-neutralizing intrafollicular activin and BMPs. Activin receptors are expressed by the oocyte and activin may have a further intrafollicular role in the terminal stages of follicle differentiation to promote oocyte maturation and developmental competence. In a reciprocal manner, oocyte-derived GDF-9/9B may act on the surrounding cumulus granulosa cells to attenuate oestradiol output and promote progesterone and hyaluronic acid production, mucification and cumulus expansion.     

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.