Estrogen dependence of luteinizing hormone receptor expression in cultured rat granulosa cells. Inhibition of granulosa cell development by the antiestrogens tamoxifen and keoxifene

In rat ovarian granulosa cells cultured for 48 h, addition of 10(-8) M estradiol (E2) enhanced choleragen-induced cAMP formation and LH receptor content by 2-fold and 6-fold, respectively. Two potent antiestrogens, tamoxifen and keoxifene, inhibited these effects of E2 in a concentration-dependent manner and significantly reduced cAMP production and LH receptors below the levels induced by choleragen. Both antiestrogens (greater than or equal to 1 microM) also reduced the effects of choleragen on cAMP levels and LH receptor content in the absence of exogenous E2. In addition, the antiestrogens (1 microM) inhibited the stimulatory effects of FSH and forskolin on granulosa cell maturation, as well as the enhancement of their actions by exogenous E2. FSH caused a concentration-dependent rise in endogenous E2 accumulation during the 48-h culture period, suggesting that antiestrogens may prevent FSH-stimulated increases in LH receptors by inhibiting the actions of newly formed E2. Tamoxifen prevented the induction of LH receptors by 8-bromo-cAMP, indicating that its effects were on both cAMP production and cAMP action, whereas keoxifene predominantly altered granulosa cell development by its inhibition of estrogen effects on cAMP production. Although both exogenous E2 and the antiestrogens modified cAMP accumulation and LH receptor expression largely during the second 24 h of culture, their actions commenced during the first day. The antiestrogens had no effect alone and did not reduce the DNA content of granulosa cells. Also, they could be washed from the cells after 48 h of culture with complete recovery of forskolin-stimulated cAMP responsiveness by 72-96 h of culture. At a lower concentration (0.4 microM), tamoxifen, but not keoxifene, acted as a partial estrogen agonist since it enhanced choleragen action. These results indicate that the cAMP-mediated induction of LH receptors in cultured granulosa cells is dependent upon the continued actions of estrogen throughout the maturation process.     

Granulosa cell differentiation in vitro: induction and maintenance of follicle-stimulating hormone receptors by adenosine 3',5'-monophosphate

Granulosa cell differentiation is stimulated in vitro by FSH and other agents that increase cAMP production. To determine if alterations in FSH receptors are associated with cAMP-mediated granulosa cell maturation, FSH-binding sites were measured during culture of undifferentiated granulosa cells from hypophysectomized diethylstilbestrol-implanted rats. FSH receptors decreased rapidly in the absence of stimulatory ligands, with loss of 75% and 90% of the FSH-binding activity from freshly prepared cells after 24 and 48 h, respectively. The decline in FSH receptors during culture was accompanied by a corresponding decrease in cAMP responses to added FSH. In cells cultured with FSH, the available FSH receptor content fell to 15% after 8 h, then rose to 25% of the initial receptor levels from 24-48 h of culture. Cells treated with 8-bromo-cAMP or choleragen for 48 h retained about 40% and 90%, respectively, of their initial FSH-binding activity. Although choleragen did not prevent the 60-70% fall in FSH binding during the first 6 h of culture, it increased receptors 2.5-fold from 12-48 h. Also, the addition of choleragen after 3, 6, or 12 h of culture elevated FSH receptors at 48 h in proportion to the amount of cAMP produced. The FSH receptors induced by choleragent treatment were functionally active, as shown by their ability to mediate FSH-stimulated cAMP production. A GnRH agonist prevented the choleragen-induced rise in FSH receptors and cAMP accumulation from 24-48 h of culture. Scatchard analysis revealed a single population of FSH receptors after all treatments, with association constant of 5 X 10(9) M-1. Freshly prepared cells contained approximately 1600 FSH binding sites/cell, while treatment with choleragen or FSH for 48 h restored receptor levels to 1150 and 500 sites/cell, respectively. These results indicate that the expression of functional FSH receptors during granulosa cell maturation is mediated by cAMP.     

Estrogen augmentation of gonadotropin-stimulated progestin biosynthesis in cultured rat granulosa cells

The influence of estrogens on gonadotropin-stimulated production of progesterone and 20 alpha-hydroxypregn-4-en-3-one (20 alpha-OH-P) was examined in primary cultures of rat granulosa cells. Granulosa cells were cultured for 3 days with increasing concentrations of FSH in the presence or absence of either diethylstilbestrol (DES) or estradiol. FSH treatment increased progestin production in a dose-dependent manner, whereas treatment with estrogens alone were ineffective. In contrast, concomitant addition of either DES or estradiol augmented FSH-stimulated production of progesterone and 20 alpha-OH-P. Increasing concentrations of estradiol (10(-10) - 10(-7) M) augmented the stimulatory effect of FSH (30 ng/ml) on progesterone production in a dose-dependent manner with ED50 values of approximately 3 X 10(-9) M. The facilitatory action of estradiol was time-related, becoming significant after 36 h of treatment. Granulosa cells were also cultured for 2 days with FSH to induce functional LH receptors. The FSH-primed cells were treated for an additional 3 days with increasing concentrations of LH (0.3-30 ng/ml) in the absence or presence of DES (10(-7) M). LH stimulated progesterone and 20 alpha-OH-P production in a dose-dependent manner, whereas concomitant addition of DES further enhanced LH-induced progestin biosynthesis. (Bu)2cAMP also increased progesterone and 20 alpha-OH-P production by the granulosa cells; however, concurrent addition of DES did not augment the actions of (Bu)2cAMP. The effect of estrogens on gonadotropin-stimulated cAMP accumulation was also examined. FSH treatment dose-dependently increased cAMP accumulation, whereas concomitant treatment with estradiol further increased the FSH action. Similarly, LH treatment also stimulated cAMP accumulation in FSH-primed cells, whereas concurrent addition of DES further augmented LH action. Thus, the stimulatory effect of estrogens upon gonadotropin-stimulated progestin production may be related to the augmentation of cAMP biosynthesis. The present observations suggest that intraovarian estrogens may act locally to enhance the sensitivity of granulosa cells to FSH and LH, thereby increasing the biosynthesis of progestins and cAMP by the granulosa cells.     

Enhanced follicle-stimulating hormone activity of deglycosylated human chorionic gonadotropin in ovarian granulosa cells

The receptor binding properties and biological actions of chemically deglycosylated asialo human CG (AHF-hCG) were studied in ovarian granulosa cells from diethylstilbestrol (DES)-treated immature rats. In ovarian homogenates from DES- and FSH-treated rats, the relative binding affinity of AHF-hCG was 2-fold higher than that of native hCG and 14-fold higher than that of ovine LH. When assayed for LH-like activity in granulosa cells from DES plus FSH-treated animals, the deglycosylated hormone behaved as a partial agonist in terms of cAMP formation, but fully stimulated progesterone production to the same extent as that elicited by LH. When added with LH to FSH-treated cells, AHF-hCG inhibited LH-stimulated cAMP formation by 70% but did not alter the elevated level of progesterone production. These findings are consistent with the presence of excess or spare LH receptors in the maturing granulosa cell. When added to freshly prepared granulosa cells which have minimal LH receptors, AHF-hCG decreased FSH-stimulated cAMP production by 20% and reduced progesterone production by 50% and increased cGMP formation by 100% during 48 h of culture. The ability of AHF-hCG to decrease the progesterone response to FSH suggests that no spare FSH receptors are present during granulosa cell differentiation. In contrast, native hCG did not alter FSH-induced cAMP or progesterone production but reduced the cGMP responses to FSH and choleragen. Whereas native hCG displayed negligible binding potency when compared with that of ovine FSH in competition with [125I]iodo-human FSH for ovarian receptors, AHF-hCG bound to FSH receptors with about 5% of the binding affinity of ovine FSH. In choleragen-treated granulosa cells, the increases in cAMP and progesterone synthesis were enhanced by addition of both hCG and AHF-hCG, and cGMP production was increased by AHF-hCG but slightly decreased by hCG. These results indicate that the enhanced LH receptor affinity caused by removal of the sugar moieties from hCG is accompanied by a relatively greater increase in FSH receptor affinity, and that deglycosylated hCG acts as a partial agonist with the ability to modify granulosa cell responses to both LH and FSH.     

Bifunctional role of transforming growth factor-beta during granulosa cell development

Regulatory actions of transforming growth factor-beta (TGF beta) on granulosa cell function were analyzed in cells cultured from the ovaries of diethylstilbestrol-implanted rats. In the presence of a suboptimal concentration of FSH (5 ng/ml) that increased LH receptors by 100-fold during a 72-h culture, TGF beta augmented this response in a dose-dependent manner with a maximal effect at 16 pM. In contrast, the growth factor inhibited the LH receptor response to an optimal dose of FSH (50 ng) by up to 50% and was inactive in the absence of gonadotropin. TGF beta also enhanced the formation of cAMP by 5 ng FSH and partially inhibited the effects of higher FSH concentrations. However, the actions of TGF beta were more prominent on LH receptor induction than on cAMP production with either low or high amounts of FSH. In addition, TGF beta had little effect on cAMP production stimulated by cholera toxin or forskolin, but amplified the actions of these ligands as well as that of 8-bromo-cAMP on LH receptor expression. TGF beta also modulated the steroidogenic activity of the granulosa cells, with increased production of progesterone in response to 5-100 ng FSH. The bifunctional actions of TGF beta on FSH-induced LH receptor formation were observed throughout a 96-h culture period. However, the presence of the growth factor was not required for the first 24 h of culture, indicating that TGF beta alters the later events involved in LH receptor formation. TGF beta augmented the stimulatory actions of 5 ng FSH on LH receptors in the absence or presence of insulin, but its inhibitory effect on these receptors was only observed in cells treated with insulin. These results indicate that TGF beta modifies FSH action during granulosa cell development in a biphasic manner. TGF beta can exert stimulatory or inhibitory effects depending upon the concentration of FSH and the presence of insulin, and these are due to alterations in cAMP action as well as cAMP production. Autocrine and/or endocrine actions of TGF beta during granulosa cell differentiation may be involved in the processes of follicle selection and development.     

Induction of granulosa cell differentiation by forskolin: stimulation of adenosine 3',5'-monophosphate production, progesterone synthesis, and luteinizing hormone receptor expression

The effects of forskolin on the acquisition of differentiated functions in cultured ovarian granulosa cells were compared with the actions of FSH and prostaglandin E2 (PGE2). In 48-h granulosa cell cultures from immature diethylstilbestrol-treated rats, 100 microM forskolin caused a 45-fold increase in cAMP accumulation and stimulated progesterone production from undetectable levels (less than 0.2 ng/ml) to 80 ng/ml. The forskolin-induced increase in cAMP was similar to the maximum response to FSH, and progesterone production was about 50% of that elicited by FSH. PGE2 also enhanced cAMP and progesterone production in a concentration-dependent manner, with a maximum 8-fold increase in cAMP accumulation and an increase in progesterone to 5.6 ng/ml when the PGE2 concentration was 10 micrograms/ml. The time course of forskolin-stimulated cAMP production was notable for its rapid rise to the maximum level during the first 24 h of culture, followed by a plateau for up to 72 h. This contrasted with FSH-stimulated cAMP production, which increased progressively for up to 72 h when measured at 24-h intervals. LH receptor levels were low in untreated cells and after exposure to the various stimuli for 24 h, but increased 9- to 11-fold after culture with FSH or forskolin for 48-72 h. PGE2-induced LH receptor formation was about 20% of that seen after FSH stimulation. Forskolin enhanced cAMP and progesterone production in response to FSH and choleragen, but impaired the effects of these ligands on LH receptor formation. Exposure of the cultured cells to a potent GnRH agonist inhibited forskolin-induced progesterone and LH receptor synthesis, but did not influence forskolin-stimulated cAMP production. These results demonstrate the ability of forskolin to serve as a nonhormonal stimulator of granulosa cell differentiation and indicate the importance of cAMP in this process, as well as the ability of GnRH agonists to exert inhibitory effects on post-cAMP steps in cellular maturation.     

Ovarian follicular development in the rat: hormone receptor regulation by estradiol, follicle stimulating hormone and luteinizing hormone.

The effects of estradiol, FSH and LH on ovarian follicular development and granulosa cell differentiation were examined in the immature rat hypophysectomized on day 24 of age. Administration of estradiol to hypophysectomized rats for 4 days stimulated the growth of large preantral follicles with a concomitant 1.5-fold increase in FSH receptor content and a 4-fold decrease in LH receptor content in the granulosa cells. When highly purified hFSH was administered alone, receptor content for FSH increased progressively for 4 days while receptor for LH remained essentially unchanged. However, when rats were pretreated with estradiol, the response of follicles to FSH was markedly enhanced as indicated by the appearance of large, antral follicles and elevated receptor content for both FSH and LH. Receptor content for FSH increased markedly in response to hFSH following only one day of estradiol pretreatment, while receptor content for LH increased most rapidly in response to hFSH after 3 days of estradiol pretreatment. LH administered to rats possessing large preovulatory follicles caused luteinization of granulosa cells and a marked decline in receptor content for both gonadotropins within 24 h. Receptor content remained low even 48 h after LH administration when granulosa cells were fully luteinized. These results indicated that follicular development and granulosa cell differentiation are dependent on steroid-protein hormone regulation of hormone specific receptors.     

Gonadotropin-induced expression of receptors for growth hormone releasing factor in cultured granulosa cells.

The hypothalamic neuropeptide, GRF, is formed in the ovary and acts via specific receptors in granulosa cells to enhance cAMP production and steroidogenic responses to the pituitary gonadotropin, FSH. Granulosa cells cultured without hormonal treatment displayed low levels of binding sites for GRF and the related neuropeptide, vasoactive intestinal peptide. However, treatment with increasing concentrations (50-500 ng/ml) of FSH caused dose-dependent increases in cAMP production and expression of binding sites measured with radioiodinated [His1, Nle27]human GRF(1-32)NH2, with no change in binding affinity. The maximum increase in GRF binding sites (2.2-fold) was elicited by 250 ng/ml FSH after 72 h incubation. GRF binding sites were also increased by agents that elevate intracellular cAMP, including choleragen, vasoactive intestinal peptide, dibutyryl cAMP, and forskolin. Low doses of forskolin that did not alone increase [125I] [His1, Nle27] human GRF(1-32)NH2 binding potentiated the action of FSH on GRF binding sites, but the effects of maximal stimulatory doses of both agents were not additive. These findings demonstrate that FSH promotes the expression of GRF receptors in maturing granulosa cells through cAMP-dependent mechanisms. Since GRF enhances the actions of FSH on cAMP production and granulosa cell differentiation, and GRF receptors are increased by the cAMP-mediated actions of FSH, locally produced GRF could exert a positive autoregulatory action to accelerate follicular maturation by amplifying the granulosa cell response to FSH.     

Hormonal control of epidermal growth factor receptors by gonadotropins during granulosa cell differentiation

The hormonal induction of epidermal growth factor (EGF) receptor formation was analyzed during the maturation of granulosa cells obtained from diethylstilbestrol-implanted immature rats. In the absence of FSH, EGF receptors (as measured by the binding of [125I]iodo-EGF to the intact cells) rose by 50% at 6 h of culture, but then declined to about 25-40% of their initial levels at 24-96 h of culture. Scatchard analyses demonstrated the presence of high affinity EGF-binding sites in both freshly prepared cells and after FSH treatment. FSH stimulated a dose-dependent increase in the EGF receptor content of granulosa cells during a 96-h culture period. Concentrations of FSH as low as 2.5-5 ng/ml elevated EGF receptor levels 2- to 3-fold compared to those in untreated control cells, and 30 ng/ml FSH caused a maximal 15-fold rise. FSH increased EGF receptor levels approximately 2-fold in the first 6 h of culture and by up to 7-fold at 96 h compared to levels in freshly prepared cells. FSH treatment did not change the binding affinity (Kd = 5-6 X 10(-11) M) of the EGF receptor, but increased the total number of EGF-binding sites. The stimulatory effects of FSH on EGF receptor expression were mimicked by other cAMP-inducing ligands, including 8-bromo-cAMP, forskolin, and choleragen. Ligands known to inhibit granulosa cell function, including GnRH agonists and the phorbol ester 12-O-tetradecanoyl-phorbol 13-acetate, reduced the stimulation of EGF receptors by FSH. However, only 12-O-tetradecanoyl-phorbol 13-acetate suppressed the induction of EGF receptors by 8-bromo-cAMP. In granulosa cells cultured for 48 h with FSH, subsequent treatment with hCG for 24 h reduced EGF receptor content by 25%. Autoradiographic studies with [125I]iodo-EGF in ovarian thin sections demonstrated that EGF-binding sites were uniformly dispersed throughout the ovaries of diethylstilbestrol-implanted rats. Treatment with PMSG markedly increased EGF receptors in the outer walls of the growing follicles, while hCG treatment after PMSG caused a general decline in ovarian labeling. These results indicate that FSH maintains and increases the number of EGF receptors during granulosa cell differentiation, while LH/hCG reduces EGF-binding sites. Such changes in EGF receptors in the presence of endogenous growth factors may influence the number and selection of follicles destined for ovulation.     

Aromatase inhibitors prevent granulosa cell differentiation: an obligatory role for estrogens in luteinizing hormone receptor expression

To determine the role of newly synthesized estrogens in LH receptor expression, granulosa cells from diethylstilbestrol-implanted immature rats were cultured with FSH plus aromatase inhibitors. When present throughout the 48-h culture period, 4-hydroxy-4-androstene-3,17-dione (4-OHA; greater than or equal to 100 microM) and 1,4,6-androstatriene-3,17-dione (greater than or equal to 5 microM) inhibited FSH-induced LH receptor formation by 40% and 90%, respectively. Both aromatase inhibitors caused relatively greater inhibition of LH receptor formation when added from 20-48 h of culture, the period during which FSH-stimulated estrogen synthesis occurs (85% maximal inhibition with 4-OHA and 95% with 1,4,6-androstatriene-3,17-dione). Addition of estradiol, but not androstenedione, reversed the reduction of LH receptor formation by 4-OHA, indicating that the effects of the aromatase inhibitors were specifically related to their blockade of estradiol synthesis. The stimulation of estrogen production by FSH alone (8-fold) or with androstenedione (80-fold) during the 48-h culture period was prevented by 4-OHA. FSH-stimulated cAMP production was initially enhanced by 4-OHA from 0-20 h of culture, but was reduced from 20-48 h. Lower concentrations of 4-OHA (less than or equal to 50 microM) amplified FSH-stimulated cAMP production and LH receptor formation. However, these responses were blocked by the antiestrogen keoxifene or the antiandrogen flutamide, indicating that 4-OHA or a metabolite may have partial estrogenic or androgenic properties. The inhibitory effects of higher concentrations of 4-OHA on LH receptor expression were potentiated by keoxifene or flutamide. These results indicate that estrogen production and action are necessary for LH receptor expression in the granulosa cell.     

Intragonadal regulation of follicular maturation

Although there are interspecies of variations in the process of follicular development, a generalized summary is presented that encompasses theories of follicular maturation from laboratory and domestic animals, nonhuman primates, and women. As there are many new substances whose actions within the follicle are unknown, it is difficult to ascribe definitive roles to these proteins in follicular development and ovulation. However, where possible, these substances are included in the summary. During early follicular development, FSH binds to granulosa cells of primary follicles to stimulate production of estradiol by the induction or enhancement of aromatase synthetase (37, 336, 337). Estradiol, in turn, induces proliferation of granulosa cells (338-344) and increases the sensitivity of the follicle to further gonadotropin stimulation (12, 339, 345-349). Estradiol can synergize with gonadotropins to increase ovarian weight, enhance proliferation of granulosa cells, and promote growth of preantral follicles and antrum formation (345, 347, 350-352). In addition, estradiol enhanced the responsiveness of granulosa cells to FSH and LH by increasing synthesis of progesterone (353, 354). The generalized enhancement of gonadotropin action by estradiol is partially mediated by FSH-induced accumulation of cAMP. However, as synthesis of estradiol increases, this steroid directly stimulated follicular growth, since estrogens have long been known to stimulate growth of ovarian cells and exert a direct antiatretic effect (355, 356). However, the exact mechanism involved in follicular growth achieving preovulatory status rather than undergoing atresia remains uncertain. Estradiol not only enhances gonadotropin stimulation of LH and FSH receptors in granulosa cells (357, 348) but is required for FSH induction of FSH receptors (359, 360). Estradiol alone can increase numbers of its own receptor in granulosa cells (350) as well as increase its own production by stimulating aromatase activity (361). Estradiol secreted by the dominant follicle has a positive feedback effect on the hypothalamus and pituitary, enhancing gonadotropin secretion and ensuring the preovulatory gonadotropin surges (362). The increased gonadotropins can further increase the production of estradiol which, in turn, enhances its own production. Therefore, estradiol is included in two positive feedback loops (one at the pituitary and one at the ovary) to maintain the dominant follicle and ensure ovulation. Progesterone and androgens also have intrafollicular effects on follicular growth and steroidogenesis.(ABSTRACT TRUNCATED AT 400 WORDS)     

Control of FSH receptor mRNA expression in rat granulosa cells by 3',5'-cyclic adenosine monophosphate, activin, and follistatin.

FSH is required to maintain FSH and LH/hCG receptors at elevated steady-state levels after receptor induction. Although this function of FSH is mediated by cAMP, how cAMP level is related to the maintenance of gonadotropin receptors is unknown. To investigate cAMP's effect on changes in the levels of FSH receptor mRNAs in rat granulosa cells, total RNA from cells was prepared and analyzed by Northern blots. Incubation with 8-Br-cAMP for 24 h produced a dose-related increase in FSH receptor mRNA in granulosa cells of DES-primed immature rats. On the other hand, 8-Br-cAMP, washed at 24 h, exerted inverse dose-related effects on FSH receptor mRNA levels at 96 h. The addition of 1 mM cAMP resulted in higher levels of FSH receptor mRNA than that induced by 0.2 mM cAMP at 24 h, while 0.2 mM cAMP is as effective as 1-2 mM cAMP for the induction of FSH receptor mRNA at 96 h. To further analyze cAMP's role in the production of activin in granulosa cells, we measured activin levels in the culture medium after the addition of 8-Br-cAMP. The levels of activin A were suppressed by the addition of 8-Br-cAMP in a dose-dependent manner. In addition, the procedure by which 8-Br-cAMP was removed after 24 h incubation showed that the level of activin in the medium increased after medium change. With regard to the actions of activin A on gonadotropin receptors, our laboratory has demonstrated that activin A increases the levels of FSH receptor mRNAs. Therefore, cAMP has a negative effect on FSH receptor expression by suppressing the activin level. Since follistatin production is up-regulated by cAMP in this system, we examined the effect of follistatin on FSH receptor mRNA level, which is induced by activin and FSH. Cotreatment with follistatin (0-100 ng/ml) and activin (50 ng/ml) in the presence of FSH (30 ng/ml) caused a significant reduction in FSH receptor mRNA levels induced by activin. Based on these observations, it is possible that cAMP has both stimulatory and inhibitory effects on the expression of gonadotropin receptors, and the overall influence of cAMP on their expression might be determined by the integration of such opposing effects.     

Growth hormone enhances follicle-stimulating hormone-induced differentiation of cultured rat granulosa cells

Suppression of serum GH levels in immature rats is associated with delayed onset of puberty and decreased ovarian steroidogenic responsiveness to FSH. To investigate possible direct effects of GH on the differentiation of ovarian cells, granulosa cells from hypophysectomized estrogen-treated rats were cultured with FSH in the presence or absence of GH for 3 days. FSH stimulated granulosa cell LH receptor formation and steroid production in a dose-dependent manner. Concomitant treatment with GH increased LH receptor content by enhancing the action of low doses of FSH without substantial increases in the maximal response. This increase was due to an elevation in the receptor number rather than changes in their affinity for hCG. At 3 ng/ml FSH, concomitant treatment with ovine or bovine GH increased LH/hCG binding in a dose-dependent manner, with 300 ng/ml GH increasing the FSH action by about 3-fold. LH receptors in the GH-treated cells were functional, as indicated by the enhanced cAMP production of these cells in response to LH treatment. The cellular protein content in the FSH-treated cultures was slightly increased by GH (18%), but cell number and viability were unaffected. The change in cell protein content could not account for the increases in the amount of LH receptors. In addition to its effects on LH/hCG receptor content, GH also augmented FSH-stimulated progesterone and 20 alpha-hydroxy-4-pregnen-3-one production in a dose-dependent manner, with 100 ng/ml GH causing significant increases in FSH-induced progesterone production. In contrast, GH treatment did not significantly affect FSH-stimulated estrogen production. The augmentating effects of GH on LH receptor formation and progestin biosynthesis were associated with an enhancement of FSH-stimulated cAMP production. In addition, GH increased forskolin- and 8-bromo-cAMP-induced LH receptor formation and progestin production. Thus, GH-augmented LH receptor induction and progestin biosynthesis may be due to both increased cAMP production and enhanced action of cAMP. The present data have demonstrated that GH augments gonadotropin-stimulated differentiation of ovarian granulosa cells, suggesting an important regulatory role of GH in follicular growth and pubertal development.     

CI628 inhibits follicle-stimulating hormone (FSH)-induced increases in FSH receptors of the rat ovary: requirement of estradiol for FSH action

Although estradiol (E2) alone does not increase receptors for FSH in granulosa cells, E2 priming before administration of FSH increases numbers of FSH receptors significantly compared with FSH alone. We hypothesized that if E2 is required for FSH to increase its own receptor, blocking estrogen action should prevent FSH-induced increases in FSH receptors. Five groups of hypophysectomized rats were injected sc with: saline at 0 h; the antiestrogen CI628 (1 mg) at -6 h; human FSH (hFSH, 2 micrograms) at 0 h; CI628 at -6 h, then hFSH at 0 h; and CI628 plus E2 (2 mg) at -6 h, then FSH at 0 h. Animals were decapitated at 0, 6, 12, or 24 h, and granulosa membrane receptors for FSH, LH, and nuclear receptors for E2 were measured. LH receptor levels increased only after administration of E2 before hFSH. Treatment with hFSH for 6 h increased numbers of FSH receptors 3-fold (P less than 0.01) without any increase in numbers of E2 receptors. At 12 and 24 h, hFSH increased numbers of FSH and E2 receptors 6- and 7-fold (P less than 0.01) over controls. CI628 prevented the hFSH-induced increases in FSH receptors at 6, 12, and 24 h. Administration of E2 concomitant with CI628 before hFSH significantly reversed the inhibitory effects of CI628 on hFSH-induced increases in FSH receptors. There were no changes in affinity of FSH or E2 receptors from 0 to 24 h. To determine whether E2 was acting on the adenylate cyclase system, the ability of hFSH to increase the content of cAMP in granulosa cells in each treatment group was determined. After an iv injection of hFSH, cAMP levels were similar in CI628- and saline-treated rats but had increased 6-fold (P less than 0.01) in hFSH or CI628 plus hFSH-treated animals. Thus, blocking hFSH-induced increases in FSH and E2 receptor appeared to have no effect on FSH stimulation of cAMP. In conclusion E2 appears to be required for FSH action, perhaps by acting within granulosa cells distal to the cAMP-adenylate cyclase system.     

Deglycosylated luteinizing hormone (LH) prevents desensitization of cyclic adenosine monophosphate response by LH: dissociation between receptor uncoupling and down-regulation

Deglycosylated LH ( DGLH ) abolished the stimulatory effect of LH on cAMP production by mature granulosa cells. DGLH , however, had no such inhibitory effect on the stimulatory activity of FSH, prostaglandin E2, isoproterenol, or choleragen. We have examined whether DGLH could prevent the desensitization of the cAMP response induced by continuous exposure to LH, or if it would induce receptor down-regulation. Cells were cultured with DGLH and LH concomitantly for a period of 3 h or 20 h and afterwards washed in acidic medium to dissociate bound ligands from their receptors. The cells were then challenged with fresh LH or with labeled 125I-human CG. At 20 h of culture with LH the cAMP response to the LH challenge was only 10% of the control, whereas after a 20-h culture with DGLH there was a 55% response to challenge with LH. DGLH , however, prevented LH from inducing desensitization in a dose-dependent manner (0.2-1.0 microgram/ml). Both LH and DGLH (1.0 microgram/ml each) markedly reduced (85%) the extent of binding of 125I-human CG to membrane receptors. At 3 h of culture, the cAMP response to challenge with LH was 25% of the control, whereas after 3-h culture with DGLH there was a 65% response to challenge with LH. DGLH (1.0 micrograms/ml) again prevented LH-induced desensitization, although only a moderate reduction in receptor-binding capacity (33%) by LH or DGLH was noted. The results suggest that occupancy of LH receptors alone for a long period is essential, but not sufficient to induce hormone desensitization. DGLH on its own is as active as LH in inducing a loss of membrane receptors, but causes only a moderate desensitization. The data support previous evidence that desensitization may result from postreceptor events, such as uncoupling of the receptors from the adenylate cyclase moiety, rather than receptor disappearance.     

Evidence that changes in tonic luteinizing hormone secretion determine the growth of preovulatory follicles in the rat

Physiological concentrations of progesterone (20-100 ng/ml), maintained by the insertion of implants into 30-day-old rats, delayed first ovulation, and withdrawal of progesterone on day 47 of age synchronized first ovulation in rats. Inhibition of ovulation involved negative feedback regulation of tonic LH and FSH secretion, blockage of gonadotropin surges, and suppression of preovulatory, but not antral, follicular growth. Removal of implants resulted in a rapid decline in serum progestrone from 100 to 5 ng/ml within 0-12 h. Between 0-36 h there were progressive increases in serum concentrations of LH and FSH, enhanced accumulation of estradiol by individual follicles incubated in vitro with or without exogenous substrate, and marked progressive increases in the content of LH (but not FSH) receptors in both thecal and granulosa cells. These events were followed by gonadotropin surges at 48 h (1800 h on day 49), ovulation, and morphological and biochemical signs of luteinization, including decreases in follicular gonadotropin receptor content and estradiol accumulation, evident by 60 h. With the exception of changes in basal LH, this sequence of events is remarkably similar in time and pattern to that after the decline of progesterone on diestrous day 2 and ovulation on proestrus of a 5-day cycle. Although a direct effect of progesterone on ovarian follicular cell function cannot be excluded, the data suggest that subtle but sustained increases in LH (and possibly FSH) are required for the enhanced follicular accumulation of estradiol and LH-binding activity occurring between diestrus and proestrus of the rat estrous cycle. Thus, perhaps some of the mystery surrounding the endocrine events between diestrus and proestrus can be ascribed to changes in serum LH that have been too small and/or variable for current nonserial sampling methods and RIAs to detect reliably.     

Luteinizing hormone receptor induction in dispersed granulosa cells requires estrogen

Studies on granulosa cell responses in vitro have routinely utilized cell preparations in which intercellular gap-junctions are maintained. The present study was conducted to determine if disruption of these junctions, prior to culture, would affect subsequent follicle-stimulating hormone (FSH)-stimulated luteinizing hormone (LH) receptor induction on these cells. Granulosa cells were expressed from ovaries of diethylstilbestrol (DES)-primed immature rats after a short incubation of the excised ovaries in culture medium alone or medium containing 6.8 mM EGTA. The latter procedure disrupts gap-junctions between granulosa cells thus providing a predominantly mono-dispersed cell suspension. The two cell preparations were cultured, separately, for 72 h in sterile polypropylene tubes in media containing either FSH or FSH plus various steroids (estradiol, testosterone, or 5 alpha-dihydrotestosterone (DHT)). LH receptor content of cells was determined at 72 h of culture. Both the cell yield and the proportion of viable cells obtained were enhanced by the EGTA pretreatment. LH receptors were induced in all FSH-containing cultures of non-dispersed granulosa cells. In the dispersed cell cultures, FSH alone failed to induce LH receptors. The inclusion of either estradiol or testosterone but not DHT with FSH, however, restored LH receptor induction to levels comparable to non-dispersed cultures. LH receptors were not induced in cultures of either cell preparation with steroids alone. Aromatase activity, however, was stimulated in both cell preparations by FSH alone. These results suggest that cell-cell communication may be necessary for LH receptor induction in granulosa cells and that estradiol (or an aromatizable androgen) can promote intercellular interactions if this communication has been disrupted.     

Effect of pregnant mare serum gonadotropin on the induction and degradation of FSH and LH receptors in the granulosa cell of the immature rat

The relative induction of FSH and LH receptors in the granulosa cells of immature rat ovary by pregnant mare serum gonadotropin (PMSG) has been studied. A single injection of PMSG (15 IU) brought about a 3- and 12-fold increase in FSH and LH receptor concentration, respectively, in the granulosa cells. Maximal concentration was reached by 72 h but the receptor levels showed a sharp decline during the next 24-48 h. The kinetic properties of the newly formed FSH receptors were indistinguishable from the pre-existing ones. The induced FSH receptors were functional as demonstrated by an increase in the in vitro responsiveness of the cells to exogenous FSH in terms of progesterone production. Treatment of immature rats with cyanoketone, an inhibitor of delta 5,3 beta-hydroxysteroid dehydrogenase, prior to PMSG injection effectively reduced the PMSG-stimulated increase in the serum estradiol, uterine weight and LH receptors but had no effect on the FSH receptor induction. The ability of PMSG to induce gonadotropin receptors can be arrested at any given time by injecting its antibody, thereby suggesting a continuous need for the hormonal inducer. Estrogen in the absence of the primary inducer was unable to maintain the induced LH and FSH receptor concentration. Inhibition of prostaglandin synthesis using indomethacin aslo had no effect on either the induction or degradation of gonadotropin receptors. Administration of PMSG antiserum, 48 h after PMSG injection, brought about a rapid decline in the induced receptors over the next 24 h, with a rate constant and t 1/2 of 0.078 h-1 and 8.9 h for FSH receptors and 0.086 h-1 and 8.0 h for the LH receptors, respectively.     

Homologous regulation of hormone receptors: luteinizing hormone increases its own receptors in cultured rat granulosa cells

LH receptors in granulosa cells are essential for ovulation and luteinization of ovarian follicles. We have studied the possible role of LH to regulate its own receptors in vitro. Granulosa cells obtained from immature hypophysectomized estrogen-treated rats were primed with FSH for 2 days to induce LH receptors. The cells were then challenged with or without increasing doses of LH or hCG for an additional 2 days, and the concentration of LH receptors was measured by [125I]iodo-hCG binding. FSH-induced LH receptors in granulosa cells decreased to negligible levels in cultures without gonadotropins, while LH receptor numbers were further increased by LH or hCG in a biphasic manner. Maximal stimulation of LH receptor content was obtained with gonadotropin doses of 6, 10, and 2.5 ng/ml for rat LH, ovine LH, and hCG, respectively. In contrast, higher doses of the gonadotropins were less effective. LH stimulation of [125I]iodo-hCG-binding sites was associated with increases in the number of LH receptors, without changes in the Kd value (control, 1.22 +/- 0.22 X 10(-10) M; LH-treated, 2.55 +/- 0.55 X 10(-10) M). Also, the changes in LH receptor numbers were correlated with the responsiveness of granulosa cells to LH stimulation of cAMP production. LH and hCG did not affect overall granulosa cell protein content. However, treatment with cycloheximide, a protein synthesis inhibitor, decreased LH-induced receptors by 46%, suggesting the involvement of new protein synthesis. Thus, these studies have demonstrated that LH, like FSH, is capable of stimulating granulosa cell differentiation by inducing its own receptors. This serves as an interesting model for studies on the positive autoregulation of hormone receptors and explains the important role of LH during advanced stages of follicular maturation.     

Direct actions of 17 beta-estradiol on progesterone production by highly differentiated porcine granulosa cells in vitro. II. Regulatory interactions of estradiol with luteinizing hormone and cyclic nucleotides

We investigated direct actions of 17 beta-estradiol and LH in the coordinate control of progesterone production by highly differentiated porcine granulosa cells maintained in monolayer culture. The administration of estradiol acutely suppressed both basal and LH-stimulated progesterone synthesis in vitro, i.e within the first 24-36 h of estrogen treatment. In contrast, continuation of estradiol administration alone beyond 48 h significantly augmented progesterone production per 10(5) granulosa cells. Among 12 independent experiments, the absolute stimulatory effects of estradiol were highly correlated (r = 0.991) with basal progesterone production by granulosa cells at the outset of culture, i.e. when steroid synthesis presumably reflected the degree of prior cytodifferentiation attained in vivo. Notably, estrogens also facilitated the dose-dependent actions of LH in a synergistic fashion. Synergism occurred during periods of both maximal and spontaneously declining steroidogenesis in vitro, and could be impeded by specific inhibitors of steroid biosynthesis (10 microM cyanoketone and 50 microM trilostane). In experiments designed to assess granulosa cell responsivity to delayed hormone rechallenge, there was a critical bihormonal requirement for both estradiol and LH in order to sustain maximal long term progesterone secretion. Further investigation of the biochemical mechanisms subserving synergistic effects demonstrated that estradiol was capable of augmenting the stimulatory actions of either exogenously supplied or endogenously generated cAMP. In particular, estradiol markedly enhanced the effects of potent phosphodiesterase resistant analogs of cAMP, 8-bromo-cAMP (0.1 mM), dibutyryl cAMP (2 mM) or 8-thio-cAMP (1 mM). Estradiol also significantly facilitated the stimulatory effects of agents that putatively increase or sustain intracellular pools of cAMP by various well defined mechanisms, i.e. choleratoxin (10 microgram/ml), guanyl-5'-imido-diphosphate (1.0 mM) or 3-isobutyl-1-methylxanthine (0.25 mM). Thus, the current in vitro studies delineate directly major interactions between estradiol and LH in the control of progesterone synthesis by highly differentiated granulosa cells. The present data further indicate that the synergistic stimulation of progesterone production by LH and estradiol is mediated in part by intracellular mechanisms operating distal to LH-stimulated cAMP production. These in vitro observations using physiological concentrations of hormones suggest a critically bihormonal role for estradiol and LH in the facilitation of progesterone secretion in vivo during late follicular phase differentiation of granulosa cells.