Michael Knecht

Gonadotropin-Releasing Hormone as a Modulator of Ovarian Function

GnRH and its agonist analogs exert direct inhibitory and stimulatory effects on the ovaries of animals from several species. In the immature follicle, GnRH inhibits the actions of FSH on an integrated array of biochemical responses that lead to follicular development and corpus luteum formation. GnRH also suppresses gonadotropin action in mature follicles, and stimulates certain ovarian processes such as steroidogenesis and oocyte maturation. The inhibitory and stimulatory effects of GnRH are mediated through the binding of the peptide to high-affinity receptors in granulosa and thecal cells. Recent studies have shown that GnRH action in the ovary is dependent upon calcium mobilization and probably operates through stimulation of phospholipid turnover and activation of protein kinase C.

Transforming growth factor-beta regulates the expression of luteinizing hormone receptors in ovarian granulosa cells

In cultured granulosa cells, addition of 1 to 50 ng follicle-stimulating hormone induced a 350-fold rise in luteinizing hormone receptors, while larger amounts of gonadotropin up to 200 ng reduced these receptors to approximately 50% of peak levels. Transforming growth factor-beta (16 pM) enhanced the stimulatory actions of low levels of gonadotropin (2.5-10 ng) by 2 to 3-fold, and inhibited the induction of luteinizing hormone receptors by higher levels of follicle-stimulating hormone (greater than or equal to 50 ng) by 30-50%. The actions of the growth factor were concentration-dependent over the range from 0.8 to 16 pM and included a similar biphasic effect upon gonadotropin-induced cAMP production. Modulation of cAMP formation and luteinizing hormone receptor expression by transforming growth factor-beta could influence the ability of the granulosa cell to respond to luteinizing hormone during ovarian follicular maturation and ovulation.

Activation of protein kinase C potentiates cyclic AMP production and stimulates steroidogenesis in differentiated ovarian granulosa cells

Gonadotropin-stimulated steroidogenesis in the differentiating ovarian granulosa cell is mediated through the activation of cAMP-dependent protein kinase, and is also modulated by calcium-dependent mechanisms. Granulosa cells contain calcium-activated, phospholipid-dependent protein kinase (C kinase), and show an increase in phosphatidylinositol turnover in response to GnRH agonist analogs. To evaluate the role of C kinase in ovarian steroidogenesis, the potent phorbol ester, TPA, and the permeant diacylglycerol, OAG, were used to activate C kinase in granulosa cells from PMSG-treated immature rats. Both TPA and OAG caused dose-dependent stimulation of progesterone production without affecting intra- or extracellular cAMP levels. However, the maximum steroid responses to these compounds were less than those stimulated by cAMP. The ED50 for TPA-stimulated progesterone production was 3 nM, which is close to the known Km for activation of C kinase. Stimulation of steroidogenesis was only observed with biologically-active phorbol esters and permeant diacylglycerols such as OAG and DOG. Exposure of granulosa cells to phospholipase C also increased progesterone production in a dose-dependent manner without changing the cAMP content. Although TPA and OAG did not increase basal cAMP production, both agents enhanced the cAMP responses stimulated by hCG and forskolin; likewise, phospholipase C alone did not change cAMP production but caused a dose-dependent increase in the cAMP responses to hCG and forskolin. These results demonstrate that activation of C kinase promotes steroidogenesis in ovarian granulosa cells, and potentiates the activation of adenylate cyclase by hCG and forskolin. Such findings support the possibility that the calcium, phospholipid-dependent enzyme could be involved in the regulation of progesterone production by hormonal ligands such as gonadotropins and GnRH.

Differential actions of phorbol ester and diacylglycerol on inhibition of granulosa cell maturation.

Hormonal induction of granulosa cell maturation is inhibited by phorbol esters and permeant synthetic diacylglycerols, but these activators of protein kinase C differ in their effects on cAMP production and actions. Both agents prevented the induction of luteinizing hormone receptors and progesterone biosynthesis by follicle-stimulating hormone, choleragen, and forskolin, but only diacylglycerol abolished the cAMP responses to these stimuli. Granulosa cell aggregation and aromatase activity were inhibited by phorbol ester but not completely by diacylglycerol. In intact granulosa cells, cytosolic C kinase activity was rapidly decreased by phorbol ester but unaffected by diacylglycerol. Although diacylglycerol has a marked inhibitory action on cAMP production, the more prominent suppression of granulosa cell differentiation by phorbol ester may be related to its rapid and prolonged action on kinase C.

GnRH agonist-induced inhibitory and stimulatory effects during ovarian follicular maturation

The in vivo regulation of ovarian gonadotropin and prolactin receptors and adenylate cyclase activity by FSH, and the potent GnRH agonist [D-Ala6]des-Gly10-GnRH N-ethylamide (GnRHa), was studied in immature hypophysectomized diethylstilbestrol-implanted rats. During FSH treatment over a 48 h period, FSH receptors increased 2-fold with the maximum response during the first 12 h, whereas LH and prolactin receptors increased by 10-fold and 6-fold with the maximum response from 12 to 48 h. Administration of GnRHa at any time during the 48 h period of FSH treatment inhibited the subsequent development of gonadotropin and PRL receptors. In contrast, administration of a single dose of 10 micrograms GnRHa after 48 h of FSH treatment stimulated follicular luteinization and caused increases in basal adenylate cyclase activity, ovarian weight and PRL receptor content, and concomitant decreases in gonadotropin receptors and adenylate cyclase responses. In the immature follicles of animals not primed with FSH, GnRHa caused progressive inhibition of FSH-sensitive adenylate cyclase activity, with a decrease in FSH receptors, but increased both basal and GMP-P(NH)P-stimulated adenylate cyclase activities. These results demonstrate that GnRHa causes marked inhibition of gonadotropin receptor expression in the basal and FSH-stimulated ovary. This decrease in gonadotropin receptors is an important component of the mechanism by which GnRH agonists inhibit ovarian gonadotropin-sensitive adenylate cyclase activity. In addition, these peptides exert stimulatory effects upon ovarian weight and basal adenylate cyclase activity, and cause an increase in PRL receptors and luteinization of mature ovarian follicles.(ABSTRACT TRUNCATED AT 250 WORDS)

GnRH receptors in cultured rat granulosa cells: Mediation of the inhibitory and stimulatory actions of GnRH☆

The regulatory actions of FSH and the GnRH agonist [D-Ala6]des-Gly10-GnRH N-ethylamide (GnRHa) upon ovarian GnRH receptors were studied in granulosa cells obtained from ovaries of hypophysectomized diethylstilbestrol-treated rats. When granulosa cells were cultured for 48 h in the presence of FSH (5-250 ng/ml) the binding of 125I-GnRHa to granulosa cell receptors was increased in a dose-dependent manner, to a maximum of 3-4 fold above the control value. Addition of FSH (100 ng) also caused a dose-dependent increase of more than 100-fold in the accumulation of cAMP and progesterone in the culture medium. In freshly prepared cells, Scatchard analysis of GnRHa binding data revealed an equilibrium constant (Ka) of 1.1 x 10(10) M-1 and GnRH receptor concentration fo 401 fmoles/mg protein. Granulosa-cell GnRH receptors decreased during culture without FSH, but were maintained in the presence of 100 ng FSH at 580 femoles/mg protein, with Ka of 0.8 x 10(10) M-1. This action of FSH on GnRH receptors was significantly reduced by 10(-8) M GnRHa. Also, GnRHa concentrations of 10(-10) and 10(-8) M caused inhibition of FSH-induced cAMP and progesterone accumulation. In cells cultured with GnRHa alone, there was a slight enhancement of GnRH receptors by GnRHa concentrations up to 10(-8) M, and a decrease below control levels with higher amounts. Also, GnRHa concentrations from 10(-8) to 10(-5) M caused a 3-4-fold increase in cAMP accumulation in the absence of FSH. These results demonstrate that FSH maintains GnRH receptors in cultured granulosa cells, and that GnRHa attenuates this effect, as well as the other actions of FSH on granulosa cell maturation. It is also evident that GnRHa itself can slightly stimulate cAMP production and partially maintain GnRH receptors, but at high concentrations causes loss of the homologous receptor sites. These findings also emphasize the ability of GnRH agonists to exert both positive and negative direct effects on rat granulosa cell function.

Plasminogen activator is associated with the extracellular matrix of ovarian granulosa cells

Follicle-stimulating hormone (FSH) increases the activity of a cell-associated, tissue-type plasminogen activator (tPA) during the initial hours of granulosa cell development. In order to determine the cellular localization of tPA, granulosa cells were labeled with [35S]methionine for 4 h and detergent-solubilized proteins were immunoprecipitated and analyzed by polyacrylamide gel electrophoresis. FSH stimulated the synthesis of a Mr 70,000 PA in granulosa cells that was specifically immunoprecipitated by tPA antibodies. Subcellular fractionation of granulosa cells indicated that the newly biosynthesized tPA was present in a 100,000 X g membrane fraction with minimal tPA in the cytosolic, nuclear, and secreted compartments. Isolation of the extracellular matrix (ECM) synthesized by granulosa cells revealed that the membrane-associated tPA induced by FSH was present in the basement membrane. Deposition of tPA into the ECM increased with time and the enzyme exhibited a low turnover rate of greater than 4 h at this site. The ECM-associated tPA was functionally active as determined by fibrin autography and approximately 95% of the PA activity observed in intact, plated cells was localized to the ECM. When the attachment of cells and deposition of ECM were reduced by maintaining granulosa cells in suspension culture, 40% of the newly synthesized tPA was released instead of being cell-associated. The addition of increasing quantities of anti-tPA IgG or unlabeled tPA minimally depleted the biosynthesized enzyme from the cells, indicating that tPA tightly interacted with the ECM. These results indicate that FSH regulates the biosynthesis of a tPA that is preferentially localized to the ECM region of granulosa cells.(ABSTRACT TRUNCATED AT 250 WORDS)