Acute facilitory action of progesterone on gonadotropin secretion of perifused rat pituitary cells

The purpose of this study was to investigate the kinetics and estrogen dependence of the facilitory progesterone action on LH and FSH secretion from pituitary cells under dynamic culture conditions. Anterior pituitary cells obtained from ovariectomized or intact adult Wistar rats were cultivated on Cytodex 1 microcarrier beads. The perifusion experiments were performed with four separate perfusion chambers. The cells of chambers I + II had been pretreated with medium containing vehicle (0.1% ethanol), those of chambers III + IV with medium containing 1 nmol/l estradiol for 48 h. After perfusion was started, each of the chambers was challenged with an initial 2-min GnRH (1 nmol/l) pulse. Chamber I was further perifused with medium containing vehicle, chamber II with medium containing vehicle + 100 nmol/l progesterone, chamber III with medium containing 1 nmol/l estradiol, and chamber IV with medium containing 1 nmol/l estradiol + 100 nmol/l progesterone. Three further GnRH pulses were administered at 50-min intervals to each of the chambers. In estradiol-primed cells from intact rats, progesterone induced a positive effect on LH and FSH secretion after 50 min of exposure to progesterone. After 100 min of progesterone treatment, LH and FSH release were enhanced to 420 and 500 per cent, respectively. When such cells were not primed with estradiol, a slight though insignificant positive action of progesterone on LH release was present after 50 and 100 min of treatment, whereas FSH secretion was not influenced. The facilitory effect of progesterone occurred only after 100 min when estradiol-primed cells from ovariectomized rats were used.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interactions of insulin-like growth factor-I, insulin and estradiol with GnRH-stimulated luteinizing hormone release from female rat gonadotrophs

BACKGROUND: It is well established that ovarian steroids modulate gonadotropin secretion from anterior pituitary cells. It has been speculated that insulin and IGF-I might influence gonadotropin secretion. OBJECTIVE: To investigate the effects of IGF-I and estradiol alone, or combinations of IGF-I with insulin and estradiol on GnRH-stimulated LH release from female rat pituitary cells in serum-supplemented and serum-free culture conditions. METHODS: Pituitary cells were incubated for 24 h or 48 h with a series of increasing concentrations of IGF-I or estradiol and stimulated with 1 nmol/l GnRH for 3 h. To determine the interaction of IGF-I and estradiol on GnRH-stimulated LH secretion, cells were exposed to increasing concentrations of IGF-I and 100 pmol/l estradiol for 24 h. We also investigated the effects of combined treatment with IGF-I and insulin on GnRH-stimulated LH secretion. RESULTS: Our findings indicate that long-term IGF-I treatment (24 h) alone has a significant augmenting effect on GnRH-stimulated LH release in serum-free medium only, with a maximum at low concentrations (10 and 100 pmol/l). Estradiol significantly increased GnRH-induced LH release in a dose-dependent manner. The extent of GnRH-stimulated LH secretion by long-term estradiol treatment (24 h) was significantly greater in serum-supplemented (+42%) medium than in serum-free medium. Estradiol facilitated IGF-I-primed LH responses to GnRH in serum-free medium. In contrast, in serum-supplemented medium, the facilitating potential of estradiol was lower. We also found that, in GnRH-stimulated cells, LH release was augmented by insulin treatment, in contrast to quiescent cells that had been pretreated with 100 pmol/l IGF-I alone and 1 nmol/l insulin alone. CONCLUSIONS: IGF-I and to a lesser extent insulin stimulate GnRH-induced LH secretion from pituitary gonadotrophs. This action is enhanced by estradiol treatment of the cells. However, the well known stimulatory action of estradiol on LH secretion is dependent on the presence of growth factors.     

Estradiol differentially modulates the exocytotic proteins SNAP-25 and munc-18 in pituitary gonadotrophs

Long-term treatment with estradiol increases LH secretion from female gonadotrophs. The mechanisms are not fully clarified yet. Our previous data indicated that sexual steroids might affect late steps in GnRH signal transduction such as exocytosis. The secretion of hormones from neuroendocrine cells requires the merger of secretory vesicles with the plasma membrane. This regulated exocytosis is mediated by specific proteins, which are present in the pituitary gland. Here, we examined whether two of these crucial exocytotic proteins, SNAP-25 and munc-18, are affected by estradiol in female gonadotrophs. Female rat anterior pituitary cells and alphaT3-1 cells, derived from a murine immortalized gonadotroph cell line, were treated with 100 pM estradiol for 48 h. LH secretion of anterior pituitary cells, additionally stimulated with eight consecutive pulses of 1 nM GnRH for 15 min at an interval of 1 h, was determined by RIA. Gene expression was measured by quantitative RT-PCR and protein expression by immunoblotting. Additionally, quantitative RT-PCR was performed in single rat gonadotrophs to ascribe effects exclusively to intact gonadotrophs. Pulsatile GnRH enhanced the mRNA expression of SNAP-25 and munc-18 in accordance with the LH secretory response with the greatest increase at the third pulse of GnRH. Estradiol treatment further increased GnRH-induced LH secretion at all GnRH pulses. SNAP-25 gene expression was significantly decreased at the fifth GnRH pulse and unaffected at basal after 48 h of estradiol treatment. In contrast, munc-18 mRNA levels were not significantly affected by estradiol at different GnRH-pulses in mixed anterior pituitary cells, whereas munc-18 gene expression was significantly increased at basal. In alphaT3-1 cells and single gonadotrophs, long-term estradiol treatment significantly reduced SNAP-25 protein and gene expression. In contrast, the protein and gene expression of munc-18 was significantly enhanced in both alphaT3-1 cells and single gonadotrophs. In conclusion, munc-18 and SNAP-25 were oppositionally influenced by estradiol. The results suggest that estradiol modulates the expression of exocytotic proteins in gonadotrophs and thus affects LH secretion.     

Modulation of cytoplasmic calcium signaling in rat pituitary gonadotrophs by estradiol and progesterone.

The stimulatory action of GnRH on gonadotropin secretion from cultured rat pituitary cells is modulated by estradiol (E) and progesterone (P). Since secretory responses to GnRH are initiated by phosphoinositide hydrolysis and Ca2+ mobilization, the effects of gonadal steroids on the pattern of Ca2+ signaling were analyzed in single pituitary gonadotrophs. Increasing concentrations of GnRH elicited a spectrum of [Ca2+]i signals in single gonadotrophs, ranging from subthreshold to threshold-oscillatory and biphasic (spike & plateau) responses. In E-treated gonadotrophs, short-term P treatment shifted subthreshold [Ca2+]i responses to oscillatory and oscillatory to biphasic responses, whereas long-term P treatment shifted oscillatory to subthreshold [Ca2+]i response profiles. These changes parallel the effects of P on GnRH-induced LH release, and indicate that the modulatory effects of ovarian steroids on gonadotropin secretion include a significant action on the Ca2+ signaling pathway.     

Acute effects of oestradiol and progesterone on melittin- and gonadotrophin-releasing hormone-induced LH secretion.

It is well established that oestradiol and progesterone modulate gonadotrophin-releasing hormone (GnRH)-induced LH secretion from cultured rat pituitary cells. Short-term oestradiol and long-term progesterone treatment exert inhibition, while short-term progesterone and long-term oestradiol treatment lead to enhancement of GnRH-stimulated LH secretion. There are several lines of evidence to suggest that the steroid effects might be mediated via a mechanism involving modulation of the GnRH signal-transduction system. To evaluate the role of arachidonic acid, which serves as an intracellular signal transducer by itself or its lipoxygenase metabolites, in the mediation of oestradiol and progesterone actions, we examined their effects on melittin (activator of phospholipase (A2)-stimulated LH secretion. When pituitary cells from adult female rats were treated for 48 h with 1 nmol oestradiol/l or 1 nmol oestradiol/l plus 100 nmol progesterone/l, GnRH (1 nmol/l)-induced LH secretion was stimulated or inhibited respectively. However, melittin (10-300 nmol/l)-stimulated LH secretion remained unaffected after such treatment. Short-term treatment with oestradiol inhibited GnRH-induced LH secretion while progesterone treatment of oestradiol-primed cells led to a stimulatory effect. Interestingly, melittin-stimulated LH secretion was influenced in the same way after the short treatment paradigm. Perifusion studies were performed to assess the kinetics of these acute steroid actions further. Four separate perifusion chambers were continuously perifused with medium and stimulated for 2 min with 1 nmol GnRH/l or 1 mumol melittin/l every 50 min in a pulsatile fashion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Modulation of the estradiol-induced luteinizing hormone surge by progesterone or antiestrogens: effects on pituitary gonadotropin-releasing hormone receptors

The present study examined the question of whether modulation of estradiol-induced LH surges by progesterone or antiestrogens in the immature rat might be related to changes in the concentration of pituitary GnRH receptors (GnRH-R). Rats (28 days old) that received estradiol implants at 0900 h had LH surges approximately 32 h later. Administration of progesterone or nafoxidine (U-11,100 A; 1-(2-[P-(3,4-dihydro-6-methoxy-2-phenyl-1-naphthyl)phenoxy]pyrrolidine hydrochloride) concomitantly with estradiol led to blockade of these LH surges (progesterone or nafoxidine inhibition), while progesterone treatment 24 h after estradiol brought about premature and enhanced LH release (progesterone facilitation). GnRH-R-binding capacity was determined by saturation analysis in homogenates of single pituitaries from immature rats treated with estradiol and progesterone or nafoxidine and controls treated only with estradiol using [125I]iodo-(D-Ala6,Des-Gly10)GnRh ethylamide. The affinity of GnRH-R for this analog ranged from 8.2-15.1 X 10(9) M-1 and was not affected by in vivo steroid or antiestrogen treatment. The number of GnRH-R in gonadotrophs from untreated 28-day-old rats (57.2 +/- 2.6 fmol/pituitary or 177 +/- 11 fmol/mg protein) was comparable to values previously reported for 30 day-old females. GnRH-R levels were first measured 1, 8, 24, 32, and 48 h after estradiol treatment. The pituitary content of GnRH-R paralleled changes in total pituitary protein (nadir at 24 h, rebound at 32 h, continued increase at 48 h), while their concentration (femtomoles per mg protein) was highest at 8 h. Next, GnRH-R levels were examined at 1200 h and at hourly intervals (1400-1800 h) on the afternoon of the LH surge. While GnRH-R concentrations were significantly lower at 1400 and 1700 h than at 1200 or 1800 h in animals treated with estradiol in the progesterone facilitation model, they did not change over time in the other two paradigms. There was no significant difference in pituitary content or concentration of GnRH-R at any time between immature rats treated with estradiol and progesterone or nafoxidine and their respective estradiol-treated controls. These results suggest that changes in GnRH-R levels in pituitary gonadotrophs do not play a major role in enhancement of LH surges by progesterone or in their suppression by progesterone or nafoxidine in the immature rat; therefore, these compounds may affect the pituitary at a site distal to the GnRH receptor.     

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.     

Androgen receptors in gonadotrophs in pituitary cultures from adult male monkeys and rats

There is substantial evidence demonstrating that the principal feedback action of androgens to decrease LH secretion in male primates, including man, is to slow the GnRH pulse generator, whereas in male rats androgens not only decrease GnRH but also suppress LH synthesis and secretion through a direct pituitary effect. Previous experiments in our laboratory revealed that testosterone (T) suppresses LH secretion and decreases alpha-subunit mRNA levels in male rat pituitary cell cultures perifused with pulses of GnRH but not in pituitary cells from adult male monkeys. In the present study, we sought to determine whether the lack of responsiveness of gonadotrophs to androgens in the primate is androgen receptor (AR) related. Primary cultures were prepared from the anterior pituitary glands of adult male monkeys and rats. Cells were identified as gonadotrophs if they were immunoreactive for LH-beta or FSH-beta. Of these cells in the monkey, 80% contained both gonadotropins, 17% contained only LH-beta, and 3% contained only FSH-beta. AR immunoreactivity (IR) was nuclear in 22% and 15%, respectively, of monkey and rat FSH-beta-positive cells in the absence of T. Following T treatment, nuclear AR IR was identified in 79% of monkey and 81% of rat gonadotrophs. T treatment similarly intensified AR IR in mouse gonadotroph alphaT3-1 and LbetaT2 cells and in monkey and rat fibroblasts. Single-cell RT-PCR confirmed coexpression of LH-beta and AR mRNA as well as LH-beta and GH mRNA in monkey gonadotrophs. Our data reveal that most monkey, as well as rat, gonadotrophs are AR-positive with nuclear localization in the presence of T. GH expression is not required for AR expression in gonadotrophs. We conclude that the failure of T to inhibit LH secretion and decrease alpha-subunit mRNA expression in the male primate is not due a disturbance in AR nuclear shuttling.     

Estrogen receptor alpha-induced cholecystokinin type A receptor expression in the female mouse pituitary

Estrogen plays a critical role in inducing LH surge. In the pituitary, estrogen receptor alpha (ERalpha) mediates the action of estrogen, while the downstream pathway of ERalpha activation is yet to be elucidated. Here, we report the finding that cholecystokinin type A receptor (CCK-AR) is an ERalpha downstream gene in the mouse anterior pituitary. In the cycling mouse pituitary, the expression of CCK-AR mRNA is markedly higher in the afternoon of proestrus compared with metestrus. Both ovariectomy (OVX) and null mutation of the ERalpha gene completely abolish CCK-AR mRNA expression. Injection of 17beta-estradiol to OVX wild-type mice induces recovery of CCK-AR mRNA expression to levels observed at proestrus, but no such recovery is induced in OVX ERalpha knockout mice. The same pattern of estrogen dependency in inducing CCK-AR mRNA expression was seen in cultured primary anterior pituitary cells, indicating that estrogen directly acts on pituitary cells to induce CCK-AR expression. Immunohistological analysis revealed that more than 80% of gonadotrophs express CCK-AR in the afternoon of proestrus. To test whether CCK-AR mediated the sensitizing effect of estrogen in GnRH-induced LH secretion, primary pituitary cells were primed with estrogen followed by treatment with GnRH in the presence or absence of lorglumide, a CCK-AR antagonist. While both groups secreted LH upon GnRH treatment, lorglumide treatment significantly decreased LH secretion. Taken together, this study finds CCK-AR to be an ERalpha downstream gene in the pituitary and suggests that CCK-AR may play a role in the estrogen sensitization of the pituitary response to GnRH.     

Targeted pituitary overexpression of pituitary adenylate-cyclase activating polypeptide alters postnatal sexual maturation in male mice

The neuropeptide pituitary adenylate cyclase activating polypeptide (PACAP) is present in high concentrations within the hypothalamus, suggesting that it may be a hypophysiotropic factor, whereas pituitary expression suggests a paracrine function. PACAP stimulates gonadotropin secretion and enhances GnRH responsiveness. PACAP increases gonadotropin α-subunit (αGSU), lengthens LHβ, but reduces FSHβ mRNA levels in adult pituitary cell cultures in part by increasing follistatin. PACAP stimulates LH secretion in rats; however, acceptance of PACAP as a regulator of reproduction has been limited by a paucity of in vivo studies. We created a transgenic mouse model of pituitary PACAP overexpression using the αGSU subunit promoter. Real-time PCR was used to evaluate PACAP, follistatin, GnRH receptor, and the gonadotropin subunit mRNA in male transgenic and wild-type mice of various ages. Transgenic mice had greater than 1000-fold higher levels of pituitary PACAP mRNA; and immunocytochemistry, Western blot, and ELISA analyses confirmed high peptide levels. FSH, LH, and testosterone levels were significantly suppressed, and the timing of puberty was substantially delayed in PACAP transgenic mice in which gonadotropin subunit and GnRH receptor mRNA levels were reduced and pituitary follistatin expression was increased. Microarray analyses revealed 1229 of 45102 probes were significantly (P < 0.01) different in pituitaries from PACAP transgenic mice, of which 83 genes were at least 2-fold different. Genes involved in small molecule biochemistry, cancer, and reproductive system diseases were the top associated networks. The GnRH signaling pathway was the top canonical pathway affected by pituitary PACAP excess. These experiments provide the first evidence that PACAP affects gonadotropin expression and sexual maturation in vivo.     

In vitro effect of leptin on LH release by anterior pituitary glands from female rats at the time of spontaneous and steroid-induced LH surge.

OBJECTIVE: The purpose of this work was to study the direct effect of leptin on LH release by anterior pituitary glands from female rats at the time of spontaneous and steroid-induced LH surge. METHODS: LH responsiveness to leptin by pituitaries from rats killed in the afternoon (1500 h) at different stages of the 4-day estrous cycle (diestrus-1: D1; diestrus-2: D2; proestrus; estrus), ovariectomized (OVX; 15 days post-castration) and ovariectomized steroid-primed (OVX-E(2)/Pg; pretreated with 5 microg estradiol and 1 mg progesterone), was evaluated in vitro. Hemi-adenohypophyses were incubated in the presence of synthetic murine leptin for 3 h. RESULTS: Addition of increasing concentrations of leptin (0.1-100 nmol/l) to the incubation medium of proestrus pituitaries produced a dose-related stimulation of LH release; the maximal increase to 315% of control was obtained with 10 nmol/l leptin. Leptin (10 nmol/l) enhanced LH release at all days of the estrous cycle, the greatest response occurring in proestrus (318%) and the lowest at D1 (123%). In order to evaluate the role of nitric oxide (NO) in the action of leptin on LH release, glands from proestrus rats were incubated in the presence of 10 nmol/l leptin with or without 0.3 mmol/l N(G)-monomethyl-l-arginine (NMMA), a competitive inhibitor of NO synthase (NOS). NMMA completely suppressed the stimulation of LH release induced by leptin. Leptin also stimulated LH release by pituitaries from OVX rats, and treatment with steroid hormones led to a marked increase in the response (OVX: 162% compared with OVX-E(2)/Pg: 263%; P<0.05). For comparative analysis, a similar experimental procedure was carried out using GnRH (10 nmol/l). Leptin acts at the pituitary level in a similar manner as GnRH, although with significantly lower potency. CONCLUSIONS: These results confirm and extend previous reports regarding a direct action of leptin at the pituitary level, stimulating LH release by anterior pituitaries from female rats at the time of spontaneous and steroid-induced LH surge. In the female rat pituitary this leptin action is controlled by gonadal steroids and mediated by NO.     

Importance of pituitary and neural actions of estradiol in induction of the luteinizing hormone surge in the ewe

Two experiments were performed to test the importance of both pituitary and neural sites of action of estradiol in inducing the surge of luteinizing hormone (LH) in the ewe. Both experiments were conducted using an animal model in which pulsatile secretion of gonadotropin-releasing hormone (GnRH) and endogenous secretion of ovarian steroids were eliminated by ovariectomy during seasonal anestrus and treatment with Silastic implants which maintained a luteal-phase level of serum progesterone. The hormonal requirements for the surge were then evaluated by systematic application of GnRH and estradiol signals using pulsatile infusion pumps (for GnRH) and Silastic implants (for estradiol). In experiment 1, the circulating level of estradiol and frequency of GnRH pulses were increased either abruptly or progressively (i.e. mimicking the changes in the estrous cycle between luteolysis and just before the LH surge). Abrupt increments led to an LH surge in all ewes; progressive rises to the same absolute levels did not. However, sudden application of a further large increase in GnRH upon the progressive rise elicited an LH surge in every instance. In experiment 2, a GnRH pulse pattern known to be effective in inducing the LH surge was applied under conditions of differing estradiol concentration: no estradiol, basal estradiol, basal rising to peak estradiol. The GnRH signal elicited high-amplitude surges of LH only in the presence of a peak estradiol concentration. Our findings are consistent with the conclusion that two actions are required for a rise in estradiol to elicit a full-amplitude surge of LH in the ewe: an action on the brain to evoke a sudden increase in GnRH release and an action on the pituitary to maximize its response to GnRH.     

Rapid augmentation by progesterone of agonist-stimulated luteinizing hormone secretion by cultured pituitary cells

Progesterone acts bimodally at the hypothalamus and at the pituitary gland, the sequelae in vivo being either stimulation or inhibition of gonadotropin secretion depending on a host of preconditions. Pituitary cells in culture were studied to characterize the acute action of progesterone on LH secretion. Preliminary studies established that anterior pituitary cells from adult female rats cultured for three days in 10% charcoal treated fetal bovine serum (c/t FBS) resulted in LH secretory responses to GnRH pulses which were half that for cells cultured in untreated FBS or c/t FBS + 0.2 nM 17 beta-estradiol (E2). Under standardized culture conditions (c/t FBS + E2), GnRH self-potentiation was evident. With this system, 90 min exposure to 200 nM progesterone resulted in a 3-fold augmentation of GnRH-stimulated LH secretion without affecting baseline LH. This action was manifested by 45 but not 15 min of progesterone exposure and was inhibited by simultaneous addition of cycloheximide. The augmentation of agonist-stimulated LH release could be elicited up to 4-5 h after progesterone addition. The estimated half-maximal effect was 10(-9) M, and this concentration of progesterone required E2-pretreatment of the cultured cells. In summary, addition of progesterone to cultured anterior pituitary cells pretreated with E2 leads to a concentration-, time-, and protein synthesis-dependent augmentation of pulsatile GnRH-stimulated LH secretion within 45 min of progesterone exposure. This rapid and unambiguous progesterone action in pituitary cells could function in vivo to define the final magnitude of the preovulatory LH surge.     

Direct pituitary effects of estrogen and progesterone on gonadotropin secretion in the ovariectomized ewe

The direct pituitary effects of estrogen and progesterone on the secretion of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) were studied in ovariectomized (OVX) ewes in which the pituitary had been disconnected surgically from the hypothalamus (hypothalamo-pituitary disconnection, HPD). Gonadotropin secretion was restored with hourly pulses of 500 ng gonadotropin-releasing hormone (GnRH) via intra-atrial cannulae. Intramuscular injections of 50 micrograms estradiol benzoate (EB) to 5 sheep initially caused reductions (approximately 50%) in plasma LH baseline, peak values and LH pulse amplitude. Thereafter all parameters of plasma LH concentration increased 2- to 3-fold above starting values. After these 5 sheep had received 2 subcutaneous progesterone implants (mean +/- SEM plasma levels 5.3 +/- 1.5 nmol/l), the biphasic LH response to EB was still apparent and increases in LH peak values (267 +/- 19%) and LH pulse amplitudes (262 +/- 23%) were greater (p less than 0.05) than those seen with EB alone (195 +/- 11 and 172 +/- 14%, respectively). The presence of 2 progesterone implants alone did not change plasma LH baseline, peak values or pulse amplitude, or plasma FSH values. In the second experiment, where 4 OVX-HPD ewes were given 4 progesterone implants (plasma progesterone 27.7 +/- 3.4 nmol/l), there were no effects on basal plasma LH or plasma FSH values. The LH responses to EB were more marked in 4 OVX-HPD ewes given 4 progesterone implants than in the animals given EB alone. Also, the estrogen-induced LH surge occurred earlier in the ewes given 4 progesterone implants than in those given estrogen alone.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibitory actions of keoxifene on luteinizing hormone secretion in pituitary gonadotrophs

The effect of keoxifene (LY 156 758) on GnRH-stimulated LH release and its ability to antagonize estrogen actions were investigated in rat anterior pituitary cells. Estrogens exert either stimulatory or inhibitory effects on GnRH-induced LH secretion in rat pituitary cells depending on the incubation time with the steroid. When pituitary cells were treated for 24 h with 10(-9) M estradiol, the LH response to GnRH was clearly enhanced, and this effect was completely inhibited by 300 nM keoxifene. Short term treatment (4 h) of pituitary cells with 10(-9) M estradiol inhibits GnRH-stimulated LH release, and this effect was also blocked by keoxifene in a dose-dependent manner. In the absence of exogenous estrogen the treatment of pituitary cells for 4 h with increasing concentrations of keoxifene reduced the LH response to 10(-9) M GnRH only at very high concentrations (10(-5) M) of the antiestrogen. After treatment for 24 h, the inhibitory effect of keoxifene was evident at concentrations greater than or equal to 10(-8) M, with a reduction of GnRH-induced LH release by up to 60%. The effects of the antiestrogen were also analyzed in a dynamic culture system, in which pituitary cells grown on microcarrier beads were continuously perifused with medium and stimulated with GnRH in a pulsatile fashion. The LH response to a 2 min pulse of 10(-9) M GnRH was reduced in magnitude after 40 min of perifusion with 10(-9) M estradiol. When keoxifene (300 nM) was present at the same time, the LH response was identical to that observed in vehicle-treated cells. At the concentration of 300 nM, keoxifene per se did not change the responsiveness of the pituitary cells to the GnRH stimulus. These findings show that keoxifene is a potent antagonist of both positive and negative estrogen actions in the pituitary gonadotroph. In addition, after short term treatment with high concentrations or after long term treatment, keoxifene itself exerts an inhibitory effect on GnRH-induced LH secretion.     

Effects of p-nonylphenol and 4-tert-octylphenol on the anterior pituitary functions in adult ovariectomized rats

p-Nonylphenol (NP) and 4-tert-octylphenol (OP) are known to mimic the action of estrogens as endocrine disruptors. However, their acute effects on the pituitary and the hypothalamus functions in vivo have been uncertain. We therefore determined their effects on the anterior pituitary, in particular, gonadotropin secretion. Two weeks after ovariectomy, the rats were given a subcutaneous injection of 10 mg NP, 10 mg OP, 10 mg bisphenol A, 1 microg 17beta-estradiol, or sesame oil alone as control. Twenty-four hours after the treatment, the expression of progesterone receptor mRNA in the anterior pituitary and the level of luteinizing hormone (LH), follicle-stimulating hormone, and prolactin were determined. The expression of progesterone receptor mRNA in the anterior pituitary was significantly increased by either NP, OP, bisphenol A, or estradiol, but bisphenol A was less effective. The level of LH was significantly decreased by either NP or OP, but not by bisphenol A and estradiol. Only estradiol significantly increased the level of prolactin. The level of follicle-stimulating hormone was unchanged by any of the treatments. To check the effects of NP and OP on pulsatile LH secretion, blood samplings were done at 6-min intervals for 3 h. Twenty-four hours after treatment in ovariectomized adult rats, we found that the injection of NP significantly decreased the amplitude of LH pulses and the mean LH concentrations, but not the frequency of LH pulses. The injection of OP significantly decreased the mean LH concentrations without affecting the frequency and amplitude of the LH pulses. Finally, the rats given an injection of NP or sesame oil were intravenously injected with 50 ng of gonadotropin-releasing hormone (GnRH) to check whether NP affected the LH secretory responsiveness of the anterior pituitary to GnRH. We found that the responsiveness to GnRH in NP-injected rats was significantly attenuated compared to the sesame oil-injected rats. The present study suggests that NP, even with a single injection, suppresses the pulsatile LH secretion in adult ovariectomized rats, probably by affecting the anterior pituitary level.     

Effects of leptin on gonadotropin secretion in juvenile female rat pituitary cells

OBJECTIVE: Leptin is an adipocyte-derived hormone, which is the product of the obese gene and it is thought to play important roles in pubertal development and maintenance of reproductive function in the female. In a study using adult male or female rats, it was found that leptin stimulated the secretion of gonadotropin directly from the pituitary in a dose-related manner. However, there is no study in juvenile female rats before puberty. METHODS: In this study, we cultured pituitary cells from 4-, 6- and 8-week-old female Wistar rats with leptin (0-10(-7)mol/l) and gonadotropin-releasing hormone (GnRH) (0 or 10(-8) mol/l). Basal or GnRH-stimulated secretion of luteinizing hormone (LH) and follicle-stimulating hormone (FSH), and their synthesis within cells were determined by radioimmunoassay (RIA). RESULTS: Leptin induced bell-shaped dose--response curves of basal LH and FSH secretion from cultured cells of every age-group of rats studied. The most effective concentration of leptin on the basal secretion of LH and FSH from 6- and 8-week-old cultured pituitary cells was 10(-10) mol/l. This leptin concentration was consistent with circulating physiological serum leptin levels at each age. As for juvenile 4-week-old pituitary cells, the most effective concentration was 10(-11) mol/l which was lower than that of 6- and 8-week-old rats. It was consistent with the circulating serum leptin levels of 4-week-old rats. Also, the synthesis and the GnRH-stimulated secretion of LH and FSH were effectively controlled by leptin at concentrations similar to the serum leptin levels of given ages. CONCLUSIONS: Leptin induced pituitary cells to synthesize and secrete both LH and FSH regardless of the presence or absence of GnRH. The concentration of leptin that induced the greatest synthesis and secretion of gonadotropins from pituitary cells changed around the pubertal period. The most effective leptin concentrations in each experiment were similar to the physiological serum leptin level at each animal age. These results indicate that leptin stimulates gonadotrophs not only in the pubertal and the mature period but also in the juvenile period before puberty. It is also conceivable that leptin may modulate the sensitivity of gonadotrophs until the appearance of GnRH stimulation, and may be the factor that brings about puberty onset.     

Effects of progesterone on pulsatile luteinizing hormone (LH) secretion and LH subunit messenger ribonucleic acid during lactation in the rat

In ovarian-intact lactating rats, removal of the suckling stimulus leads to restoration of pituitary LH beta mRNA levels and pulsatile LH secretion after 72 h, which correlates with a sharp decrease in plasma progesterone concentrations to basal levels. In contrast, in ovariectomized lactating rats, the increase in pituitary LH function is observed by 24 h after pup removal. To determine if progesterone secretion from the ovary participates in the delayed recovery of LH secretion, we treated lactating rats with the progesterone antagonist RU 486 and determined the effects on the time course of recovery of pulsatile LH secretion and LH subunit mRNA after pup removal and on pituitary responsiveness to GnRH. In ovarian-intact lactating rats treated with RU 486, pulsatile LH secretion was observed in about 40% of the rats within 24 h after pup removal (LH interpulse interval, 43.7 +/- 8.3 min) and in about 90% of the rats within 48 h after pup removal (LH interpulse interval, 46.1 +/- 3.6 min). The mean plasma LH level in the RU 486-treated rats was 10.1 +/- 2.2 ng/ml 24 h after removal of pups (control, less than 5 ng/ml) and had increased to 35.1 +/- 6.4 ng/ml 48 h after pup removal (control, 9.1 +/- 2.5 ng/ml). However, RU 486 treatment had no significant effect on LH mRNA subunit levels. To determine whether progesterone acts at the pituitary to block GnRH stimulation of LH secretion, we tested the effects of RU 486 on LH secretion in response to 2- and 5-ng pulses of GnRH. Pituitary responsiveness was tested 24 h after pup removal. We found that both doses of GnRH were effective in stimulating pulsatile LH secretion, and treatment with RU 486 had no significant effect on this response. We conclude from these studies that progesterone secretion from the ovary contributes to the inhibition of LH secretion that occurs after pup removal, since antagonizing progesterone's action resulted in an earlier restoration of pulsatile LH secretion. The increase in LH secretion occurred in the absence of any significant changes in responsiveness of the pituitary to GnRH stimulation or in LH subunit mRNA levels. Therefore, the primary site of action of progesterone would appear to be at the hypothalamus to suppress pulsatile GnRH secretion.