Effects of glucocorticoids on responsiveness of luteinizing hormone and follicle-stimulating hormone to gonadotropin-releasing hormone by male rat pituitary cells in vitro

To determine if the inhibitory effects of glucocorticoids on GnRH-stimulated secretion of LH observed in male rats in vivo are exerted directly on the pituitary, dispersed pituitary cells from adult male rats were treated with 60 or 600 ng/ml cortisol (F) or corticosterone (B) during one or two 48-h incubations. Control cells received no glucocorticoids. During the second 48 h, some cells from each group were treated with GnRH (2.4 X 10(-11)-6.2 X 10(-8) M). Concentrations of LH and FSH in media and cells were measured by RIA. Treatment with steroids had no effect on basal secretion or maximal GnRH-stimulated secretion of LH, or on maximal secretion of FSH. Treatment with 600 ng/ml B for 96 h increased basal secretion of FSH relative to controls. All treatments with glucocorticoids increased the slopes of the GnRH dose-response curves for both LH and FSH, cell content of LH, total (cells + medium) LH, and total FSH. Incubation with 6 micrograms/ml F or B or 60 ng/ml dexamethasone gave similar results. Decreasing the time period of the second incubation to 6 h results in no significant differences between control cells and cells treated with B or F. These results show that glucocorticoids have different effects in vivo and in vitro, suggesting that inhibitory effects of glucocorticoids on secretion of LH in vivo may not be exerted directly on the pituitary but are exerted elsewhere, perhaps by altered hypothalamic secretion of GnRH. Also, these results show that male and female pituitaries in vitro respond differently to glucocorticoids.     

Differential effects of in vitro glucocorticoids on luteinizing hormone and follicle-stimulating hormone secretion: dependence on sex of pituitary donor

We have used a dynamic perifusion system to determine whether glucocorticoids exert a direct effect on the secretion of LH and FSH from rat anterior pituitaries. Anterior pituitary fragments from male, proestrous female, or metestrous female rats were perifused for 8 h in either the absence (basal secretion rate) or presence of pulsatile GnRH administration (50 ng/ml peak concentration). Perifusions used medium containing 0.05% ethanol (vehicle), 600 ng/ml corticosterone, or 600 ng/ml cortisol. GnRH-stimulated secretion of FSH was enhanced in pituitaries from both male and female rats after in vitro incubation with either corticosterone or cortisol. The basal secretion rate of FSH was also elevated in proestrous females after glucocorticoid treatment. The GnRH-stimulated secretion rate for LH was significantly decreased in pituitaries from male rats treated with either glucocorticoid. In contrast, pituitaries from proestrous rats responded to either cortisol or corticosterone with an increase in LH secretion. Metestrous pituitaries showed divergent effects of the glucocorticoids on LH secretion; corticosterone enhanced secretion rates, and cortisol effected a decrease. Our data demonstrate that 1) glucocorticoids exert a direct effect on the secretion of LH and FSH from male and female rat pituitaries; 2) glucocorticoids elicit different effects on the secretion of LH and FSH, suggesting that they act at separate sites to regulate LH and FSH secretion; and 3) the effect of in vitro glucocorticoid treatment on gonadotropin secretion is dependent on sex and cycle stage of the pituitary donor and may be linked to prior in vivo concentrations of estrogen.     

Inhibition of pituitary gonadotropin secretion by the gonadotropin-releasing hormone antagonist antide. I. In vitro studies on mechanism of action

The GnRH antagonist antide is among the most promising "third generation" compounds available for clinical evaluation. In primates, antide manifests prolonged (several weeks) and reversible inhibition of pituitary gonadotropin secretion after a single high dose injection. In the present study, we have examined the effects of antide on pituitary gonadotropin secretion in vitro. Dispersed anterior pituitary cells from adult female rats were plated (48 h; 5 x 10(5) cells/well), washed, and exposed to increasing concentrations of antide for up to 48 h. Media were removed, and cells were washed twice and then incubated with GnRH (1 x 10(-8) M) plus antide for 4 h. Media and cell lysates were assayed for LH/FSH by RIA. Antide had no effect on basal LH/FSH secretion at any dose tested (10(-6)-10(-12) M). In contrast, GnRH-stimulated LH/FSH secretion was inhibited by this GnRH antagonist in a dose- and time-dependent manner. When incubated simultaneously, antide blocked GnRH-stimulated gonadotropin secretion, with a maximal effect at 10(-6) M (ED50, 10(-7) M). Preincubation of pituitary cells with antide for 6-48 h before GnRH exposure shifted the dose-response curve to the left; the maximally effective dose was 10(-8) M; the ED50 was 10(-10) M antide after 48-h preincubation. Intracellular LH/FSH levels increased concomitant with the decrease in secreted gonadotropins. Total LH/FSH levels (secreted plus cell content) remained unchanged. The inhibition of LH secretion by antide was specific for GnRH-stimulated gonadotropin secretion; antide had no effect on K(+)-stimulated LH secretion. Moreover, antide had little or no residual effect on LH secretion; full recovery of GnRH responsiveness in vitro occurred within 4 h after removal of antide. Lineweaver-Burke analysis of antide inhibition of GnRH-stimulated LH secretion indicated that antide is a direct competitor of GnRH at the level of the pituitary GnRH receptor. In summary, antide is a pure antagonist of GnRH stimulation of gonadotropin secretion; no agonistic actions of antide were manifest in vitro. Moreover, antide has no apparent noxious or toxic effect on pituitary cells in culture; the actions of antide are immediately reversible upon removal of antide from pituitary gonadotropes. We conclude that the long term inhibition of gonadotropin secretion by antide in vivo is not due to deleterious effects of this compound at the level of the pituitary gonadotrope.     

Interaction between cortisol and arachidonic acid on the secretion of LH from ovine pituitary tissue.

In several species, glucocorticoids act directly on the pituitary gonadotroph to suppress the gonadotrophin-releasing hormone (GnRH)-induced secretion of the gonadotrophins, especially LH. A mechanism for this action of these adrenal steroids has not been established, but it appears that the glucocorticoids influence LH release by acting on one or more post-receptor sites. This study investigated whether glucocorticoids disrupt GnRH-induced LH release by altering the liberation of arachidonic acid from plasma membrane phospholipids, a component of GnRH-induced LH release. Using perifused ovine pituitary tissue, it was established that exposure of gonadotrophs to 1-1000 nmol cortisol/l for 4 h or longer significantly reduced GnRH-stimulated LH release with the maximal inhibitory effect being observed after 6 h of exposure to cortisol. This suppressive effect of cortisol could be reversed by administration of arachidonic acid, which in its own right could stimulate LH release from ovine pituitary tissue. Furthermore, the inhibitory effect of cortisol on GnRH-stimulated LH release could be directly correlated with decreased pituitary responsiveness to GnRH-stimulated arachidonic acid liberation, consistent with our hypothesis that glucocorticoids can suppress GnRH-induced secretion of LH by reducing the amount of arachidonic acid available for the exocytotic response of GnRH.     

Increase in luteinizing hormone content occurs in cultured human fetal pituitary cells exposed to gonadotropin-releasing hormone

To investigate the mechanisms by which GnRH regulates LH production during intrauterine life, dispersed pituitary cells from second trimester human fetuses were cultured on extracellular matrix-coated plates for 48 h. Exposure of cells to 3 x 10(-10) mol/L GnRH for 1-48 h significantly increased cumulative LH secretion compared to that in respective controls (P less than 0.01). The rate of GnRH-stimulated LH release was accelerated during the first 6 h, after which it declined to a level similar to that of basal release. This phenomenon was associated with a decrease in the GnRH concentration of the medium. Exposure of cells to GnRH (3 x 10(-10) to 10(-6) mol/L) for 48 h induced a dose-dependent elevation of total LH which correlated with an increase in releasable, but not cellular, LH. Desensitization to GnRH (10(-7) mol/L) occurred when cells were cultured with pharmacological amounts of GnRH for 48 h. These results indicate that GnRH induces the increase in total and releasable LH in human fetal pituitary cells. These cells also appear to inactivate GnRH. Thus, GnRH may increase LH production in the human fetal pituitary and the pituitary receptor mechanism may be involved in GnRH action on LH release during intrauterine life.     

Cortisol regulates secretion and pituitary content of the two gonadotropins differentially in female rats: effects of gonadotropin-releasing hormone antagonist.

To determine if LH and FSH respond to cortisol exposure the same way in females as they do in males, metestrous females were implanted with cholesterol or cortisol (F) subcutaneously, and either ovariectomized or left intact 4 days later. Tail vein injections of 1000 ng of GnRH in saline, or saline alone, were given 4.5, 23.5, or 47.5 h after the time of ovariectomy. Animals were killed 30 min after the injections at 5, 24, and 48 h after surgery. F attenuated the postovariectomy increase in serum LH at 48 h. F also suppressed GnRH-stimulated LH release 24 and 48 h after surgery in ovariectomized animals and in intact animals at 48 h. Pituitary content of LH was increased moderately by F at 5 h. These effects of F are similar to those seen in males. In contrast to LH, F increased serum FSH in intact females and suppressed levels in ovariectomized animals at 24 and 48 h, while inducing a remarkable increase in pituitary FSH content at all three times. These divergent effects of F on serum FSH (suppression in gonadectomized and stimulation in intact groups) were not seen in males, and the increase in pituitary FSH as a result of exposure to F was much more profound and reliable in females than in males. To determine if the F-induced increase in pituitary FSH was dependent on endogenous secretion of GnRH, intact metestrous females were implanted with either cholesterol or F pellets. Each implant group received sc injections of 100 micrograms GnRH antagonist or control injections every 48 h beginning at the time of steroid implantation. Animals were killed 5 days after implantation. The antagonist suppressed both serum and pituitary LH. F also suppressed serum LH levels, but had no effect on pituitary content of LH. Neither the antagonist nor F affected serum FSH. F greatly increased pituitary content of FSH in the presence or absence of GnRH antagonist. These data suggest that 1) LH responds to F treatment in a similar way in females and males; 2) pituitary FSH content is more sensitive to the enhancing effect of F in females than in males; 3) the ability of F to increase pituitary FSH in females is not dependent on GnRH.     

Inhibin increases and progesterone decreases receptors for gonadotropin-releasing hormone in ovine pituitary culture

Treatments (48 h) with highly purified bovine or porcine inhibins (10 ng/ml) induced ovine pituitary cells to increase their binding for des-Gly10-[D-Ala6]LHRH-ethylamide by 3.6- and 5-fold, respectively. Studies with less pure inhibin from porcine follicles showed that increased binding could reach 7-fold within 48 h and was due to higher numbers of receptors for GnRH. The 48-h increase in GnRH receptors was linear with time and was rapidly reversible, since removal of inhibin at 24 h decreased GnRH binding below control levels at 48 h. Inhibin (bovine or porcine) also increased GnRH-stimulated secretion of LH by 2-fold. The ED50 for both inhibin actions noted above was in the range of 0.5-2.0 ng/ml (in terms of highly purified bovine inhibin). Progesterone (P) totally counteracted inhibin induction of GnRH binding and GnRH-stimulated LH secretion at 48 h. In the absence of inhibin, P decreased GnRH binding below control levels by as much as 80% within 48 h, but did not affect GnRH-stimulated LH secretion at 48 h. The ED50 for P action was near 1 nM, which is within the physiological range for P during the luteal phase of the sheep estrous cycle. The data suggest that P may act during the luteal phase to decrease receptors for GnRH. The rapid decrease in P during the 48 h before the preovulatory LH surge should permit GnRH receptors to rise under the influence of inhibin (and estradiol) to boost gonadotroph responsiveness to GnRH so the LH surge may occur to its fullest.     

Effects of inhibin from primate Sertoli cells on follicle-stimulating hormone and luteinizing hormone release by perifused rat pituitary cells

We used a pituitary cell perifusion system to investigate the time course and selectivity of the inhibin effect on pulsatile GnRH-stimulated LH and FSH release. Dispersed pituitary cells from 7- to 8-week-old male rats were perifused on a Cytodex bead matrix and stimulated with 10 nM GnRH for 2 min every hour for 8-11 h. The addition of a preparation of inhibin partially purified from primate Sertoli cells reduced pulsatile FSH release within 2 h. After removal of inhibin from the perifusion medium, the effect was reversed within 3 h. GnRH-stimulated LH release was also influenced by inhibin, although the decline in LH was less than that in FSH (80 +/- 3% vs. 68 +/- 4% of control; P less than 0.025). Smaller doses of inhibin suppressed GnRH-induced FSH secretion, but had no effect on LH release. Further, prolonged incubation of pituitary cells with inhibin at the higher dose reduced its FSH inhibitory effect and eliminated the effect on LH. These results indicate that inhibin can reduce both LH and FSH secretion in vitro, although the specificity and magnitude of the effect are a function of both the dose and duration of inhibin treatment. Further, the actions of inhibin and GnRH on the pituitary may be interrelated.     

Luteinizing hormone synthesis in cultured fetal human pituitary cells exposed to gonadotropin-releasing hormone.

To investigate whether GnRH regulates LH synthesis during human development, pituitary cells from second trimester fetuses were incubated with [35S]methionine ([35S]met) and [3H]glucosamine ([3H]gln) for 48 h with 0, 10(-9), and 10(-7) mol/L GnRH. Immunoassayable (i) LH was measured in media and cellular lysates, and dual label scintillation analysis was used to quantitate incorporation of radiolabeled precursors into cells, trichloroacetic acid-precipitable proteins, and immunoprecipitated LH subjected to electrophoresis. Exposure of cells to GnRH did not affect cellular uptake or incorporation of precursors into proteins, but specifically increased total (secreted plus cellular) LH synthesis. Both GnRH concentrations significantly increased iLH release and enhanced secreted and cellular [3H]gln-LH. The secretion of [35S] met-LH was stimulated only by 10(-7) mol/L GnRH. The proportion of newly synthesized LH that was secreted and the 3H/35S ratio of secreted and cellular LH were uninfluenced by GnRH. Although basal LH synthesis was not sex dependent, total iLH content and GnRH-stimulated LH translation were greater in cells from females than in those from males. Therefore, GnRH regulates LH synthesis by second trimester fetal human gonadotrophs without influencing the proportion of total radiolabeled LH that is secreted. The existence of a sex difference in total iLH content and GnRH-stimulated LH translation is consistent with the sexual dimorphism in pituitary LH content occurring during human development.     

The dynamics of gonadotropin inhibition in women induced by an antagonistic analog of gonadotropin-releasing hormone

The inhibitory effect of a GnRH antagonist, [AC-delta 2-Pro1, p-F-D-Phe 2, D-Trp3,6]GnRH (4F-Antag), on gonadotropin secretion was determined by four sequential studies in five hypergonadotropic postmenopausal women. In response to an iv (80 micrograms/kg) dose of 4F-Antag, a progressive decline in basal gonadotropin levels with a marked attenuation of pulse amplitude was observed. Mean serum LH and FSH concentrations were maximally reduced by 46% and 26%, respectively, 4 and 9 h after the iv bolus. A similar pattern of suppression was found with sc and im routes of administration, with maximal effects occurring at 6.0 h for LH and 8.5 h for FSH. This was followed by the resumption of pulsatile release and a return to basal levels between 10 and 24 h for both gonadotropins. When 4F-Antag was superimposed during an iv infusion of GnRH (0.2 micrograms/min) at the time (2 h) of maximal LH release (231% above basal values), a 47.1% decrease in GnRH-stimulated LH levels and a 15.8% decrease in FSH values occurred at 1.75 h. A positive linear correlation was found between basal and exogenous GnRH-stimulated LH and FSH concentrations and the inhibitory effect of the 4F-antagonist. The dynamics of the antagonistic effect demonstrated by this analog provide an important reference for future investigations of endogenous GnRH control of gonadotropin secretion as well as for exploring contraceptive potential.     

Photoperiodic differences in in vitro pituitary gonadotropin basal secretion and gonadotropin-releasing hormone responsiveness in the golden hamster

In order to examine pituitary gonadotropin secretion and responsiveness to GnRH after photic-induced changes in reproductive condition, an in vitro pituitary perifusion system was established for male golden hamster tissue. Anterior pituitaries from adult males which had been maintained on 14 h light:10 h dark (long days) or 6 h light:18 h dark (short days) for 10 weeks were perifused using an Acusyst perifusion system. Perfusates from unstimulated tissue (basal secretion) and from tissue stimulated with hourly pulses of GnRH (25, 50, or 100 ng/ml) were assayed for LH and FSH by RIA. Tissue from short-day animals had lower basal LH secretion than tissue from long day animals, but there were no significant photoperiodic differences for GnRH-stimulated LH secretion. In contrast, there were no photoperiodic differences in basal FSH secretion, but tissue from short-day animals secreted more FSH than tissue from long-day animals when stimulated with GnRH. Bioactivity of a small number of perfusate samples was assessed using in vitro rat granulosa cell and mouse Leydig cell assays for FSH and LH, respectively, and did not show any photoperiodic differences in LH or FSH bioactivity for GnRH-stimulated tissue. These studies indicate that the pituitaries of gonadally regressed hamsters are capable in vitro of responding to GnRH with similar or greater levels of gonadotropin release compared to pituitaries from animals with functional gonads. Therefore, it appears that the lowered serum gonadotropin levels seen in vivo in gonadally regressed animals are not due to a reduction in intrinsic pituitary sensitivity to GnRH.     

Effects of gonadal steroids on gonadotropin secretion in males: studies with perifused rat pituitary cells

The feedback effects of testosterone (T) and estradiol (E2) on FSH and LH secretion were compared in dispersed pituitary cells from adult male rats perifused with pulses of GnRH. Cells were stimulated with 10 nM GnRH for 2 min every 1 h. T (10 nM) pretreatment for 24 h reduced the amplitude of FSH and LH pulses to 77 +/- 4% (mean +/- SE) and 47 +/- 3% of control values, respectively (P less than 0.01), whereas 6-h T treatment was without effect. By contrast, interpulse secretion of FSH was increased after 24 h T to 184 +/- 7% of the control value (P less than 0.01), but interpulse LH release was unchanged (104 +/- 5%). E2 (0.075 nM) treatment of pituitary cells reduced GnRH-stimulated FSH and LH release within 2 h to 75 +/- 2% and 73 +/- 3% of control values, respectively (P less than 0.01). E2 pretreatment for 24 h stimulated (P less than 0.025) GnRH-induced FSH (136 +/- 10%) and LH (145 +/- 8%) release and also increased (P less than 0.01) interpulse FSH (127 +/- 5%) and LH (145 +/- 8%) secretion. These data indicate that the suppression of FSH and LH secretion by T in males is due in part to a direct effect on the pituitary. The findings that T suppresses GnRH-stimulated FSH less than LH, and that T stimulates interpulse FSH, but not LH, provide evidence for differential regulation of FSH and LH secretion by T. The dissimilar actions of T on GnRH-stimulated pulses and interpulse gonadotropin secretion suggest that interpulse secretion is unrelated to stimulation by GnRH, although its physiological significance is unknown. Since E2, in physiological levels for males, increased pituitary FSH and LH secretion, the suppression of gonadotropin secretion by E2 in vivo in males may result from an effect on the hypothalamic pulse generator; however, additional studies are needed before extending these conclusions to higher mammals and men.     

Action kinetics of inhibin in superfused pituitary cells depend on gonadotropin-releasing hormone treatment

We examined the effects of partly purified inhibin from porcine follicular fluid on FSH and LH release in superfused rat pituitary cell cultures exposed to different GnRH stimuli. Pituitary cells from immature male rats were cultured in chemically defined medium. After 4 days of static culture in the absence of inhibin preparation and GnRH, the cell monolayers were superfused for approximately 10 h at a constant speed (0.15 or 0.25 ml/min) with medium with or without inhibin preparation (1 micrograms/ml). During the superfusion, some cultures were stimulated with GnRH (10 nM) continuously or intermittently (1 min/0.5 h or 6 min/1 h). In the basal condition (no GnRH), inhibin suppressed FSH release after 5 h of exposure (P less than 0.01), whereas LH secretion was not affected. In cultures treated with GnRH pulses (of either frequency), the inhibitory effects on the GnRH-stimulated FSH and LH release were statistically significant (P less than 0.01) after 2 h of exposure, became more pronounced in the next several hours, then remained stable until the end of the experiment. In cultures exposed to GnRH continuously, the suppressing effects of inhibin preparation became significant (P less than 0.01) after 3 h of exposure and were maximal at 4 h (52% and 61% of control values for FSH and LH, respectively). Later, the suppressing effect became less pronounce due to the decreasing rate of gonadotropin secretion in control (no inhibin) cultures exposed continuously to GnRH. The magnitude of FSH and LH suppression after 9 h of exposure to the inhibin preparation was statistically different (P less than 0.05) for different GnRH treatments and was more pronounced with GnRH pulses (24-27% and 54-57% of control values for FSH and LH, respectively) than with cultures exposed to GnRH continuously (77% and 89% of control values for FSH and LH, respectively) or in the absence of GnRH (50% and 92% of control values for FSH and LH, respectively). We conclude that both the kinetics and magnitude of action of the inhibin preparation on FSH and LH release can differ significantly depending on the presence or absence of GnRH as well as on the mode of GnRH stimulation. Of particular importance is the observation that suppressive effects of inhibin preparation decline in cultures that have been desensitized to GnRH after prolonged continuous GnRH exposures. These differences stress the role of GnRH-inhibin interactions in the regulation of gonadotropin secretion and emphasize the importance of the mode of GnRH stimulation in studies concerning inhibin action on pituitary cells in vitro.     

Effect of gonadotropin-releasing hormone pulse frequency on gonadotropin secretion and subunit messenger ribonucleic acids in perifused pituitary cells.

Slow frequency GnRH pulses have been proposed to preferentially increase circulating FSH levels by increasing FSH synthesis and pulsatile release. Examination of this proposal using various in vivo models, however, has produced conflicting results. To examine directly the effects of GnRH pulse frequency on the pituitary, we compared the effects of 2.5-nM GnRH pulses administered every 1 h or every 4 h vs. no GnRH, using perifused rat pituitary cells. FSH secretion (total area under the response curve) was 2-fold greater (P less than 0.01) with every hour than with every 4 h GnRH pulses. This difference resulted from the increased number of GnRH pulses and increased (P less than 0.05) interpulse FSH secretion, whereas FSH pulse amplitude was unchanged. FSH beta mRNA levels at the completion of the 11-h perifusion were increased 4.5-fold by GnRH every h (P less than 0.01) and 3.3-fold by GnRH every 4 h (P less than 0.05) above levels in untreated cells. FSH beta mRNA levels were greater (P less than 0.05) at the faster GnRH pulse frequency. Because more frequent stimulation delivered more GnRH during the study, cells were next stimulated with 2.5 nM GnRH every 1 h for nine pulses, 7.5 nM GnRH every 4 h for three pulses to equalize the GnRH dose, or 2.5 nM GnRH every 4 h for three pulses. Interpulse FSH secretion and FSH beta mRNA levels were again greater (P less than 0.05) with every hour than every 4 h GnRH pulses. Interpulse LH secretion, FSH and LH pulse amplitude, and LH beta and alpha-subunit mRNA levels were not different between the groups. GnRH doses of 0.1-10 nM every hour increased FSH and LH pulsatile secretion dose-dependently, but FSH beta, LH beta, and alpha-subunit mRNA levels were similar. In conclusion, our data reveal that reducing the frequency of GnRH pulses from every hour to every 4 h reduces both FSH beta mRNA levels and FSH interpulse secretion, but does not change GnRH-stimulated FSH pulsatile release. We suggest that the finding by others that slow frequency GnRH pulses increase circulating FSH levels under certain experimental conditions in vivo may instead be explained by complex hormonal interactions or changes in FSH clearance.     

Effects of testosterone on gonadotropin subunit messenger ribonucleic acids in the presence or absence of gonadotropin-releasing hormone.

There is accumulating evidence that the negative feedback actions of testosterone on the pituitary may contribute to the differential regulation of FSH and LH secretion in males. In the present study we measured steady state levels of the mRNAs encoding the gonadotropin subunits in pituitary cell cultures treated with 10 nM testosterone (T) as well as in T-treated pituitary cells perifused with pulses of GnRH to explore further the direct actions of T on the pituitary. T treatment of pituitary cells in monolayer culture for 72 h increased FSH beta mRNA 1.5-fold (P less than 0.05), decreased alpha-subunit mRNA to 45% of the control level (P less than 0.05), and decreased LH beta mRNA to 75% of the control level (P less than 0.05). FSH and uncombined alpha-subunit secretion were increased and decreased by T, respectively, whereas basal LH secretion was unchanged. Treatment with 0.1 nM estradiol, a physiological concentration for males, did not change gonadotropin secretion or subunit mRNA concentrations. Between days 2 and 5 in culture in the absence of steroid treatment, steady state levels of LH beta and alpha-subunit mRNA declined (P less than 0.01) 52% and 61%, respectively, but FSH beta mRNA levels were unchanged. Pulsatile stimulation with 2.5 nM GnRH every 1 h for 10 h increased FSH beta mRNA 2.8-fold (P less than 0.05) and increased (P less than 0.05) alpha-subunit mRNA to 117% of the control level. When cell cultures were pretreated with T for 48 h and then perifused with pulses of GnRH, FSH beta, LH beta, and alpha-subunit mRNA levels were 66%, 74%, and 70% of the value during GnRH alone (P less than 0.05). T treatment also reduced (P less than 0.01) the amplitudes of FSH, LH, and alpha-subunit secretory pulses by 18%, 26%, and 41%, respectively. These data indicate that a portion of the negative feedback action of T is at the pituitary to regulate gonadotropin subunit gene expression. Our data reveal two opposing effects of T on FSH beta mRNA: a stimulatory action, which is GnRH independent, and an inhibitory effect, which is related to the actions of GnRH. These divergent actions of T represent one mechanism through which FSH and LH are differentially regulated.     

Chronic inhibitory effect of follicle-stimulating hormone (FSH)-suppressing protein (FSP) or follistatin on activin- and gonadotropin-releasing hormone-stimulated FSH synthesis and secretion in cultured rat anterior pituitary cells

The effects of bovine FSH-suppressing protein (FSP) or follistatin on activin- and GnRH-stimulated FSH synthesis and secretion have been studied using cultured pituitary cells from adult male Sprague-Dawley rats. Exposure to FSP (0.001-10 nM) for 3 days dose-dependently suppressed basal FSH secretion (IC50 = 146 +/- 21 pM., mean +/- SE), cellular content (IC50 = 269 +/- 8 pM) and total FSH (IC50 = 181 +/- 25 pM), with no effect on LH. Activin (0.3 nM) increased FSH secretion 2.1-fold, cellular content 1.3-fold, and total FSH 1.9-fold during a 3-day incubation, but these increases were dose-dependently inhibited by concomitant treatment with 35-kDa bovine FSP (0.1-3 nM), with complete inhibition occurring at concentrations between 1 and 3 nM. The 31- and 39-kDa forms of bovine FSP also antagonized the actions of activin. GnRH (1 nM) increased FSH secretion 1.8-fold and total FSH 1.6-fold during a 3-day incubation, effects that were dose-dependently inhibited by concomitant treatment with 35-kDa bovine FSP. The highest tested concentration of FSP (3 nM) suppressed GnRH-stimulated FSH secretion and total FSH to 59 and 57%, respectively, of the levels found in untreated cultures. All three forms of bovine FSP produced a significant inhibition of FSH secretion and total FSH stimulated by GnRH. FSP also suppressed FSH secretion and total FSH in response to activators of protein kinase C including 100 nM phorbol 12-myristate 13-acetate (43 and 59%, respectively) and 100 nM mezerein (40 and 60%, respectively). Finally, treatment of cultured pituitary cells with 35-kDa FSP at 1 and 3 nM for 3 days resulted in 21 and 24% decreases in GnRH binding sites, respectively. It is concluded that (i) FSP inhibits not only the secretion but also the synthesis of FSH induced by activin and GnRH in long-term culture, and (ii) FSP may cause its inhibitory effects on GnRH by suppression of the protein kinase C system, and possibly by reduction of GnRH binding sites.     

Interactions of ovarian steroids with pituitary adenylate cyclase-activating polypeptide and GnRH in anterior pituitary cells

Pituitary adenylate cyclase-activating polypeptide (PACAP) releases LH and FSH from anterior pituitary cells. Although this effect is relatively weak, it has a strong sensitizing action on GnRH-induced gonadotropin secretion. Here we investigated the possibility that ovarian steroids, which are well-known modulators of LH secretion, interact with PACAP and GnRH in pituitary gonadotrophs. Rat pituitary cells were treated for 48 h with vehicle, 1 nmol/l estradiol, 1 nmol/l estradiol + 100 nmol/l progesterone or 48 h with 1 nmol/l estradiol and 4 h with 100 nmol/l progesterone. The cells were stimulated for 3 h with 1 nmol/l GnRH or 100 nmol/l PACAP. Estradiol treatment alone enhanced basal as well as GnRH- or PACAP-stimulated LH secretion. LH release was facilitated by additional short-term progesterone treatment. Long-term treatment with estradiol and progesterone led to reduced LH responses to GnRH and PACAP. Neither treatment paradigms affected cAMP production. However, estradiol treatment led to enhanced cAMP accumulation in quiescent or GnRH-stimulated cells. PACAP-induced increases of cAMP production were inhibited by estradiol treatment. After 7-h preincubation with 10 nmol/l PACAP, cells responded with enhanced LH secretion to GnRH stimulation. When steroid pretreatment was performed the responsiveness of gonadotrophs to low concentrations of GnRH was still increased. In contrast, at high concentrations of GnRH the sensitizing action of PACAP on agonist-induced LH secretion was lost in steroid-treated cells. There were no significant differences between the steroid treatment paradigms. It is concluded that estradiol but not progesterone acts as a modulator of adenylyl cyclase in gonadotrophs. The stimulatory effect of estradiol is thought to be involved in its sensitizing action on agonist-induced LH secretion. The inhibitory effect of estradiol on PACAP-stimulated adenylyl cyclase activities seems to be responsible for the loss of its action to sensitize LH secretory responses to GnRH.     

Pituitary-testicular interrelationships during germinal involution in the vitamin A deficient rat

Pituitary-testicular relationships in mature male rats were investigated during the period of germinal involution after the induction of vitamin A deficiency (VAD). Vitamin A deficiency caused a decrease in testicular weight, a gradual increase in the incidence of delayed spermiation, increased phagocytosis of spermatids and pyknosis of germ cell nuclei in rats aged 80 to 110 days. Both basal and gonadotrophin releasing hormone (GnRH)-stimulated serum FSH concentrations were increased by 100 days of age. During the same period, the per cent increment in GnRH-stimulated FSH secretion, pituitary FSH concentration and LH secretion remained unchanged. These results suggest that the increased serum FSH may mark specifically an alteration in the germinal epithelium. By 140 days of age, spermatogenic activity in the rats with VAD was limited to the spermatogonial proliferations so that only Sertoli cells, spermatogonia and preleptotene spermatocytes remained. At this time hypersecretion of FSH persisted while the per cent increment of GnRH-stimulated FSH secretion decreased. Concomitantly, basal and GnRH-stimulated LH concentrations were also increased in the presence of normal serum testosterone. These results indicate that a complete cessation of spermatogenesis beyond preleptotene spermatocytes is associated with a change in the secretion of both FSH and LH. The relationship between serum LH and testosterone was normal until at least 110 days of age. By 140 days the ratio between basal LH and basal testosterone, and between total LH and total testosterone, after GnRH administration, increased in the rats with VAD.(ABSTRACT TRUNCATED AT 250 WORDS)     

Corticotropin-releasing hormone inhibition of gonadotropin release and the effect of opioid blockade

We studied the inhibitory effect of exogenous CRH on pulsatile gonadotropin secretion and the role of endogenous opioid peptides in this phenomenon in normal women. To do so, we infused human CRH (100 micrograms/h for 3 h) into 15 normal women during the midluteal phase of their menstrual cycle and studied its effect on both basal (10 women) and GnRH-stimulated (5 women) plasma gonadotropin levels. CRH infusion induced a significant decrease in plasma LH and FSH levels in all women. The decline in plasma LH (62%) was greater than that in FSH (36%). Plasma LH and FSH concentrations returned to basal levels within 30 min after the end of the CRH infusion. CRH infusion did not alter the gonadotropin response to GnRH. We also infused naloxone plus CRH in the 10 women who had received CRH alone during the midluteal phase of a different cycle. Addition of naloxone to CRH (5 women) reversed the LH and FSH inhibition when naloxone was started 1 h after the start of the CRH infusion. When naloxone was started 1 h before CRH infusion (5 women), plasma LH and FSH concentrations did not change. Plasma cortisol increased similarly during both the CRH and CRH plus naloxone infusions; the mean cortisol levels at the end of the CRH and CRH plus naloxone infusions were 497 +/- 40 (+/- SE) and 484 +/- 41 nmol/L, respectively, compared to 240 +/- 14 nmol/L after saline infusion (P less than 0.001). These results demonstrate that in normal women during the midluteal phase of the menstrual cycle, CRH inhibits the secretion of both LH and FSH. The CRH-induced inhibition of gonadotropin secretion is primarily mediated by endogenous opioid peptides, and this effect is not dependent on glucocorticoid levels. We suggest that the disruptive effect of stress on reproductive function in the women could be, at least in part, dependent on decreased gonadotropin secretion induced by elevated endogenous CRH levels.     

The effect of gonadotrophin surge-inhibiting factor on the self-priming action of gonadotrophin-releasing hormone in female rats in vitro.

The present study was designed to explore further the functional antagonism between gonadotrophin-releasing hormone (GnRH) and the ovarian factor, gonadotrophin surge-inhibiting factor (GnSIF). In all experiments, pituitary tissue was exposed to various amounts of GnSIF, after which the self-priming action of GnRH was studied. GnSIF was increased in vivo by FSH treatment and increased in vitro by adding various amounts of follicular fluid (FF) to cultured pituitary cells. Treatment with 3 or 10 IU FSH suppressed the initial LH response and delayed the maximally primed LH response to GnRH. Treatment with FSH was only effective in intact rats on days 1 and 2 of dioestrus. There was no difference in the rate of maximal LH release irrespective of treatment with either FSH or saline. Since FSH treatment was ineffective in long-term ovariectomized rats, it was concluded that the initial suppressive effect of FSH on LH release was mediated by GnSIF. Cycloheximide prevented the self-priming action of GnRH by inhibiting GnRH-induced protein synthesis. The initial protein synthesis-independent GnRH-stimulated LH release, which was already suppressed by FSH treatment, remained suppressed in the presence of cycloheximide. Pretreatment with GnRH in vivo increased the protein synthesis-independent GnRH-induced LH release during subsequent incubation of the glands. This increase did not occur after FSH treatment. Pituitary cells, cultured for 20 h in medium only, failed to elicit the self-priming effect of GnRH. Preincubation with FF maintained the self-priming effect. This was independent of the concomitant presence of various amounts of oestradiol. Preincubation with bovine FF suppressed the initial GnRH-stimulated LH release dose-dependently. Porcine FF, human FF and testicular extract suppressed the release of LH in a similar way. It was concluded that GnSIF suppresses the initial LH response to continuous GnRH stimulation. Increased levels of GnSIF caused by FSH treatment also delayed the primed LH release. The mechanism of functional antagonism between GnSIF and GnRH could give rise to the occurrence of the phenomenon of GnRH self-priming.