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.     

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.     

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)     

Secretion of 17 alpha-hydroxyprogesterone, androstenedione, and estrogens by porcine granulosa and theca interna cells in culture

The steroid secreting activities of dispersed granulosa and theca interna cells from preovulatory follicles of prepubertal gilts 72 h after pregnant mare's serum gonadotropin treatment (750 IU) were compared. The cells were cultured for 24 h with or without steroid substrate (10(-8) to 10(-5) M progesterone, 17 alpha-hydroxyprogesterone, or androstenedione), FSH (100 ng/mL), LH (100 ng/mL), and cyanoketone (0.25 microM, an inhibitor of 3 beta-hydroxysteroid dehydrogenase). Granulosa cells cultured alone secreted mainly progesterone. Theca interna cells secreted mainly 17 alpha-hydroxyprogesterone and androstenedione, with secretion being markedly enhanced by LH. In the presence of cyanoketone, which inhibited endogenous progesterone production, theca interna but not granulosa cells were able to convert exogenous progesterone to 17 alpha-hydroxyprogesterone and androstenedione, and exogenous 17 alpha-hydroxyprogesterone to androstenedione and estradiol-17 beta in high yield. The secretion of the latter steroids from exogenous substrates was unaffected by LH. Theca interna cells secreted more estradiol-17 beta than did granulosa cells in the absence of aromatizable substrate, but estradiol-17 beta secretion by the latter was markedly increased after the addition of androstenedione. These apparent differences in steroid secreting activity between the cell types suggest that the enzymes responsible for conversion of C21 to C19 steroids, i.e., 17 alpha-hydroxylase and C17,20-lyase, reside principally in the theca interna cells. However, aromatase activity appears to be much higher in granulosa cells.     

Metabolism of androstenedione by human ovarian tissues in vitro with particular reference to reductase and aromatase activity

The ability of granulosa and theca cells of the human ovarian follicle at different stages of development, as well as stromal and luteal tissues from human ovaries to metabolize androstenedione (delta 4) to testosterone (T), dihydrotestosterone (DHT), estrone (E1) and estradiol (E2) with or without exposure to additional amounts of folicle-stimulating hormone was investigated by in vitro experiments. The results show that all the aforementioned ovarian tissues metabolized delta 4 to DHT. Indeed, with the exception of estrogen-secreting granulosa cells from large antral follicle (greater than 10 mm diameter) and possibly also luteal tissue from mid-luteal phase ovaries, the various ovarian tissues preferentially metabolized delta 4 to DHT instead of E (E1 + E2). Although thecal tissue is a major source of delta 4 in human ovaries it is concluded that the granulosa cells do not interact with the theca for the synthesis of E as the follicle enlarges from 1 to 10 mm in diameter. Indeed, excessive thecal delta 4 during this growth phase probably inhibits normal follicular development. However, as the follicle enlarges beyond 10 mm in diameter, and as the granulosa cells begin to preferentially metabolize delta 4 to E, the two cell-types of the follicle may increasingly interact to enhance the follicular output of E.     

Steroidogenesis by bovine theca interna in an in vitro perifusion system

The aims of these studies were: to examine the steroidogenic responses of perifused bovine theca interna to varying flow rates of media and varying amounts of luteinizing hormone (LH), and to compare the steroidogenic outputs of theca interna from follicles of differing size and health with those of other ovarian tissues. The results showed that the outputs of androstenedione by thecae interna from healthy but not atretic follicles, with or without stimulation by LH, were amplified by the flow rate of media. Steroidogenesis by perifused theca interna was also influenced by the mass and concentration of LH as well as by the duration of exposure to LH. When expressed on a per unit mass basis, the outputs of androstenedione from LH-primed thecae interna from small (2-5.5 mm diameter), medium (6-9.5 mm diameter) and large (greater than or equal to 10 mm diameter) healthy follicles were comparable. But when the above data were expressed per total mass of theca interna, the androstenedione output increased significantly with increasing follicular diameter (P less than 0.01). Under the experimental conditions employed, the fraction of androstenedione produced by thecal tissue as a percentage of the total output of progesterone, androstenedione, testosterone and estradiol was 82%, whereas the progesterone, testosterone and estradiol fractions were 1%, 15% and 2%, respectively. By contrast, the granulosa cell output of progesterone, androstenedione, testosterone and estradiol were 79%, 0%, 0% and 21%, respectively. When this cell type was supplied with saturating amounts of androstenedione, it contributed greater than or equal to 90% of the total quantity of estradiol by the two cell types in isolation.     

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.     

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.     

Development of preovulatory follicles expected to form short-lived corpora lutea in beef cows

Oestrus, expected to be followed by a short luteal phase, was induced in post-partum cows by weaning their calves at 35 days after parturition. Ovaries containing the first preovulatory follicles (Type F) formed after parturition were collected 3 h after the onset of oestrus. For comparison, preovulatory follicles (Type C) were collected 3 h after the onset of oestrus in normally cycling cows. The number of granulosa cells was determined and the concentrations of receptors for follicle-stimulating hormone (FSH) and luteinizing hormone (LH) in granulosa cells and for LH in theca cells were measured. Concentrations of oestradiol-17 beta, testosterone, androstenedione and progesterone in follicular fluid were also measured. Type F follicles contained about twice the number of granulosa cells (based on DNA) as did Type C follicles (45.8 +/- 11.3 and 24.5 +/- 3.9 micrograms DNA/follicle, respectively; P less than 0.05) but these cells had fewer receptors for LH (0.13 +/- 0.02 vs 0.29 +/- 0.03 fmol/micrograms DNA; P less than 0.01) and FSH (0.61 +/- 0.08 vs 1.3 +/- 0.29 fmol/micrograms DNA; P less than 0.08) than did those from Type C follicles. Additionally, there were fewer receptors for LH in theca tissue from Type F than from Type C follicles (28.3 +/- 5.2 vs 51.3 +/- 6.1 fmol/follicle; P less than 0.01). Concentrations of oestradiol-17 beta (475.8 +/- 85.6 vs 112.9 +/- 40.0 ng/ml; P less than 0.01) and androstenedione (214.1 +/- 48.7 vs 24.7 +/- 7.7 ng/ml; P less than 0.01) in follicular fluid were higher in Type C than in Type F follicles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of resistin on granulosa and theca cell function in cattle

Resistin is an adipokine that has not been extensively studied in cattle but is produced by adipocytes in greater amounts in lactating versus non-lactating cattle. Seven experiments were conducted to determine the effect of resistin on proliferation, steroidogenesis, and gene expression of theca and granulosa cells from small (1-5mm) and/or large (8-22 mm) cattle follicles. Resistin had no effect on IGF-I-induced proliferation of large-follicle theca cells or small-follicle granulosa cells, but decreased IGF-I-induced proliferation of large-follicle granulosa cells. Resistin weakly stimulated FSH plus IGF-I-induced estradiol production by large-follicle granulosa cells, but had no effect on IGF-I- or insulin-induced progesterone and androstenedione production by theca cells or progesterone production by granulosa cells of large follicles. In small-follicle granulosa cells, resistin attenuated the stimulatory effect of IGF-I on progesterone and estradiol production of small-follicle granulosa cells. RT-PCR measuring abundance of side-chain cleavage enzyme (CYP11A1), aromatase (CYP19A1), FSH receptor (FSHR) and LH receptor (LHCGR) mRNA in large- and small-follicle granulosa cells indicated that resistin reduced the stimulatory effect of IGF-I on CPY11A1 mRNA abundance in large-follicle granulosa cells but had no effect on CYP19A1, FSHR or LHCGR mRNA abundance in large- or small-follicle granulosa cells. Resistin had no effect on CYP11A1, CYP17A1 or LHCGR mRNA abundance in theca cells. These results indicate that resistin preferentially inhibits steroidogenesis of undifferentiated (small follicle) granulosa cells and inhibits proliferation of differentiated (large follicle) granulosa cells, indicating that the ovarian response to resistin is altered during follicular development.     

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.     

Androgen synthesis during follicular development: evidence that rat granulosa cell 17-ketosteroid reductase is independent of hormonal regulation

Although androgens have been implicated in follicular atresia, ovarian follicular androgen synthesis is required for preovulatory follicular growth. To localize the site(s) of androgen biosynthesis and to obtain a better understanding of the regulation of the androgenic pathway(s) in rat ovarian follicles we examined the relative abilities of developing follicles to accumulate specific androgens [testosterone (T) and dihydrotestosterone (DHT)] using both radioimmunoassay (RIA) and 3H-substrate metabolism techniques. Small antral and preovulatory follicles were obtained from control or human chorionic gonadotropin (hCG)-primed immature rats, respectively (Richards and Bogovich, 1982). Small antral follicles, theca and granulosa cells produced little immunoassayable androgen (T + DHT) when incubated with or without 8-bromo-cAMP. In contrast, preovulatory follicles and theca produced more androgen than small antral tissues and in a manner acutely stimulable by cAMP. Granulosa cells produced little androgen under these conditions. Inclusion of [3H] androstenedione in the incubates yielded increased accumulation of [3H] T and [3H] DHT for all small antral and preovulatory tissues. Indeed, granulosa cells from both small antral and preovulatory follicles possessed a remarkable ability to accumulate [3H] T. This ability was not altered by hypophysectomy or subsequent treatment with estradiol and/or follicle-stimulating hormone (FSH). These results suggest that 17-ketosteroid reductase may be a constitutive enzyme in granulosa cells.     

Ovarian steroidogenesis during follicular maturation in the domestic fowl (Gallus domesticus)

The steroidogenic potential of various physiological compartments within the ovary of the hen were examined using in vitro systems. Three-hour incubations of individual whole small follicles (less than 1 mm-1 cm) or 100,000 collagenase-dispersed theca cells of the five largest ovarian follicles (F1-F5) were conducted in 1 ml of Medium 199 at 37 degrees C in the presence and absence of luteinizing hormone (LH) (0.39, 0.78, 1.56, 3.13 and 6.25 ng), progesterone (5 ng), and dehydroepiandrosterone (DHEA, 5 ng). Steroid output was measured by radioimmunoassay of incubation media. Progesterone was not produced by small follicles although they are a major source of DHEA and estradiol and a significant source of androstenedione. Output of DHEA, androstenedione and estradiol was highly stimulated by LH. The substrate for androstenedione and estradiol in small follicles is probably DHEA. Output of DHEA and androstenedione in theca cells of F2-F5 was stimulated by LH in a dose-related manner. A dose-response relationship between estradiol output and the concentration of LH in media was not apparent in theca cells from F2-F5. Steroidogenesis in theca tissue of large follicles occurs predominantly via the delta 4 pathway. The ability of these theca cells to metabolize progesterone to androstenedione is lost between 36 and 12 h before ovulation. Their ability to metabolize DHEA to androstenedione is still present 12 h before ovulation. Aromatase activity is significantly reduced between 36 and 12 h before ovulation. These data indicate that both large and small follicles can be stimulated by LH. The small follicles are the major source of estrogen. As the large yolky follicles mature, steroidogenesis shifts from the delta 5 to the delta 4 pathway. By 12 h before ovulation, the F1 follicle has lost the ability to convert progesterone to androstenedione. The inability of the largest ovarian follicle to convert progesterone to androstenedione contributes at least in part to the preovulatory increase in the plasma concentration of progesterone that generates the preovulatory LH surge by positive feedback.     

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.     

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.     

Growth differentiation factor 9 (GDF9) stimulates proliferation and inhibits steroidogenesis by bovine theca cells: influence of follicle size on responses to GDF9

Ovarian follicular development is controlled by numerous paracrine and endocrine regulators, including oocyte-derived growth differentiation factor 9 (GDF9), and a localized increase in bioavailable insulin-like growth factor 1 (IGF1). The effects of GDF9 on function of theca cells collected from small (3-6 mm) and large (8-22 mm) ovarian follicles were investigated. In small-follicle theca cells cultured in the presence of both LH and IGF1, GDF9 increased cell numbers and DNA synthesis, as measured by a (3)H-thymidine incorporation assay, and dose-dependently decreased both progesterone and androstenedione production. Theca cells from large follicles had little or no response to GDF9 in terms of cell proliferation or steroid production induced by IGF1. Small-follicle theca cell studies indicated that GDF9 decreased the abundance of LHR and CYP11A1 mRNA in theca cells, but had no effect on IGF1R, STAR, or CYP17A1 mRNA abundance or the percentage of cells staining for CYP17A1 proteins. GDF9 activated similar to mothers against decapentaplegics (SMAD) 2/3-induced CAGA promoter activity in transfected theca cells. Small-follicle theca cells had more ALK5 mRNA than large-follicle theca cells. Small-follicle granulosa cells appeared to have greater GDF9 mRNA abundance than large-follicle granulosa cells, but theca cells had no detectable GDF9 mRNA. We conclude that theca cells from small follicles are more responsive to GDF9 than those from large follicles and that GDF9 mRNA may be produced by granulosa cells in cattle. Because GDF9 increased theca cell proliferation and decreased theca cell steroidogenesis, oocyte- and granulosa cell-derived GDF9 may simultaneously promote theca cell proliferation and prevent premature differentiation of the theca interna during early follicle development.     

Exogenous progesterone reduces follicular prostaglandin E and 6-keto prostaglandin F-1 alpha in the cyclic hamster

In cyclic hamsters, exogenous progesterone (100 micrograms) administered s.c. at 09:00 h on the day of dioestrus II reduced prostaglandin (PG) E and 6-keto PGF-1 alpha but not PGF concentrations in preovulatory follicles measured at 09:00 h of pro-oestrus. The injection of 10 micrograms ovine LH (NIADDK-oLH-25) concurrently with 100 micrograms progesterone on dioestrus II prevented the decline in follicular PGE and 6-keto PGF-1 alpha values. Administration of LH alone did not significantly alter follicular PG concentrations. Inhibition of follicular PGE accumulation by progesterone was due to a decline in granulosa PGE concentration and not thecal PGE. Progesterone administration also reduced follicular oestradiol concentrations. Administration of oestradiol-17-cyclopentanepropionate (ECP) (10 micrograms) with progesterone did not prevent the decline in follicular PGE and 6-keto PGF-1 alpha but did increase follicular PGF concentrations. However, ECP given alone on dioestrus II reduced follicular PGE and increased PGF concentrations in preovulatory follicles on pro-oestrus. It is concluded that exogenous progesterone administered on dioestrus II inhibits granulosa PGE and 6-keto PGF-1 alpha accumulation in preovulatory follicles, probably by reducing serum LH concentrations, and that the granulosa cells, which are LH-dependent, are a major source of follicular PGE.     

In vitro effects of cycloheximide and luteinizing hormone on the estradiol-to-progesterone shift in follicular steroidogenesis

The objectives of this study were to establish a completely in vitro system that would simulate the in vivo effects of cycloheximide (cyclo) on preovulatory serum levels of estradiol (E2) (prolonged) and progesterone (P4) (reduced). Graafian follicles were removed from proestrous hamsters at 0900 h and incubated for a basal hour (Hour 1) with various doses of cyclo before the medium was replaced; in Hour 2, 100 ng luteinizing hormone (LH) was added with cyclo added every hour for 5 or 6 h. The endpoints were steroid levels/follicle/h per ml medium of P4, 17 alpha-hydroxyprogesterone (170HP), androstenedione (A), and E2. The goal was best accomplished with hourly addition of 400 ng cyclo, which reduced follicular protein synthesis by 76%. Cyclo suppressed P4 and 170HP and prolonged the accumulation of A and E2, in Hour 5 and Hour 6, correlated with sustained thecal C-17,20-lyase/17 alpha-hydroxylase as determined by enzyme assays. Cyclo therefore prevented the early demise of the enzyme complex after LH stimulation and hence prolonged the ability of the theca to provide androgens for conversion to E2 by the granulosa cells. Our earlier work established that one of the major effects of LH is to recruit the granulosa compartment as a source of C-21 steroids, and cyclo interferes with the availability of cholesterol to mitochondrial side-chain cleavage (Greenwald and Limback, 1984). Thus, cyclo affects follicular steroidogenesis through different mechanisms in theca and granulosa.     

Effects of ovarian theca cells on granulosa cell differentiation during gonadotropin-independent follicular growth in cattle

We investigated the effects of theca cells or FSH on granulosa cell differentiation and steroid production during bovine early follicular growth, using a co-culture system in which granulosa and theca cells were cultured on opposite sides of a collagen membrane. Follicular cells were isolated from early antral follicles (2-4 mm) that were assumed to be in gonadotropin-independent phase and just before recruitment into a follicular wave. Granulosa cells were cultured under serum-free conditions with and without theca cells or recombinant human FSH to test their effects on granulosa cell differentiation. Messenger RNA levels for P450 aromatase (aromatase), P450 cholesterol side chain cleavage (P450scc), 3beta-hydroxysteroid dehydrogenase (3beta-HSD), LH receptor (LHr), and steroidogenic acute regulatory protein (StAR) in granulosa cells were measured by real-time quantitative RT-PCR analysis. FSH enhanced aromatase mRNA expression in granulosa cells, but did not alter estradiol production. FSH also enhanced mRNA expression for P450scc, LHr, and StAR in granulosa cells, resulting in an increase in progesterone production. In contrast, theca cells enhanced aromatase mRNA expression in granulosa cells resulting in an increase in estradiol production. Theca cells did not alter progesterone production and mRNA expression in granulosa cells for P450scc, 3beta-HSD, LHr, and StAR. The results of the present study indicate that theca cells are involved in both rate-limiting steps in estrogen production, i.e., androgen substrate production and aromatase regulation, and that theca cell-derived factors regulate estradiol and progesterone production in a way that reflects steroidogenesis during the follicular phase of the estrous cycle.     

Steroidogenesis in porcine atretic follicles: loss of aromatase activity in isolated granulosa and theca

To evaluate the mechanisms involved in the reduction of estrogen concentrations in porcine follicular fluid during atresia, nonatretic and atretic follicles ranging from 4 to 7 mm in diameter were selected. Follicular fluid estrogen concentrations were 7-16-fold less in the atretic follicles. Isolated granulosa cells from atretic follicles demonstrated a significant reduction in aromatase activity and in follicle-stimulating hormone (FSH)-induced progesterone production in vitro compared to granulosa cells from nonatretic follicles. Isolated theca from atretic follicles also demonstrated a reduction in estrogen production. However, androgen concentrations were equivalent in the follicular fluid of atretic and nonatretic follicles, and theca from atretic follicles maintained testosterone and androstenedione production in vitro. The loss of thecal aromatase activity with atresia is not secondary to a reduction in FSH responsiveness, since FSH did not increase thecal progesterone production in vitro. Cell degeneration also does not account for the reduction in thecal estrogen production, since both androgen output in vitro and follicular fluid androgen concentrations were maintained. These data thus demonstrate that a mechanism other than reduced FSH responsiveness must account for the selective loss of thecal aromatase activity in this stage of atresia.