The central effect of beta-endorphin and naloxone on the expression of GnRH Gene and GnRH receptor (GnRH-R) gene in the hypothalamus, and on GnRH-R gene in the anterior pituitary gland in follicular phase ewes.

The effect of prolonged intermittent infusion of beta-endorphin or naloxone into the third cerebral ventricle in ewes during the follicular phase of the estrous cycle on the expression of GnRH gene and GnRH-R gene in the hypothalamus and GnRH-R gene in the anterior pituitary gland was examined by Real time-PCR. Activation of micro opioid receptors decreased GnRH mRNA levels in the hypothalamus and led to complex changes in GnRH-R mRNA: an increase of GnRH-R mRNA in the preoptic area, no change in the anterior hypothalamus and decrease in the ventromedial hypothalamus and stalk/median eminence. In beta-endorphin treated ewes the levels of GnRH-R mRNA in the anterior pituitary gland also decreased significantly. These complex changes in the levels of GnRH mRNA and GnRH-R mRNA were reflected in the decrease of LH secretion. Blockade of micro opioid receptors affected neither GnRH mRNA and GnRH-R mRNA nor LH levels secretion. These results indicate that beta-endorphin displays a suppressive effect on the expression of the GnRH gene in the hypothalamus and GnRH-R gene in the anterior pituitary gland, but affects GnRH-R gene expression in a specific manner in the various parts of hypothalamus; altogether these events lead to the decrease in GnRH/LH secretion.     

LH down-regulates gonadotropin-releasing hormone (GnRH) receptor, but not GnRH, mRNA levels in the rat testis.

The demonstration of an inhibitory effect of gonadotropin-releasing hormone (GnRH) agonists upon steroidogenesis in hypophysectomized rats and the presence of mRNA coding for GnRH and GnRH receptors (GnRH-R) in rat gonads suggests that GnRH can act locally in the gonads. To assess this hypothesis, we investigated the effects of GnRH analogs, gonadotropins and testosterone on the levels of both GnRH and GnRH-R mRNA in the rat testis. Using dot blot hybridization, we measured the mRNA levels 2 to 120 h after the administration of the GnRH agonist, triptorelin. We observed an acute reduction of both GnRH and GnRH-R mRNAs 24 h after the injection (about 38% of control). However, the kinetics for testis GnRH-R mRNA were different from those previously found for pituitary GnRH-R mRNA under the same conditions. Initially, the concentrations of serum LH and FSH peaked, then declined, probably due to the desensitization of the gonadotrope cells. In contrast, the GnRH antagonist, antarelix, after 8 h induced a 2.5-fold increase in GnRH-R mRNA, but not in GnRH mRNA, while gonadotropins levels were reduced. Human recombinant FSH had no significant effect on either GnRH or GnRH-R mRNA levels. Inversely, GnRH-R mRNA levels markedly decreased by 21% of that of control 24 h after hCG injection. Finally, 24 h after testosterone injection, a significant increase in GnRH-R mRNA levels (2.3 fold vs control) was found, but a reduction in the concentration of serum LH, probably by negative feedback on the pituitary, was observed. In contrast, GnRH mRNA levels were not significantly altered following testosterone treatment. Since LH receptors, GnRH-R and testosterone synthesis are colocalized in Leydig cells, our data suggest that LH could inhibit the GnRH-R gene expression or decrease the GnRH-R mRNA stability in the testis. However, this does not exclude the possibility that GnRH analogs could also affect the GnRH-R mRNA levels via direct binding to testicular GnRH-R. In contrast, the regulation of GnRH mRNA levels appeared to be independent of gonadotropins. Taken together, our results suggest a regulation of GnRH and GnRH-R mRNA specific for the testis.     

Implication of dopaminergic systems on GnRH and GnRHR genes expression in the hypothalamus and GnRH-R gene expression in the anterior pituitary gland of anestrous ewes.

We examined by Real-time PCR how prolonged inhibition of dopaminergic D-2 receptors (DA-2) in the hypothalamus of anestrous ewes by infusion of sulpiride into the third cerebral ventricle affected GnRH and GnRH-R gene expression in discrete parts of this structure and GnRH-R gene expression in the anterior pituitary. Blockaded DA-2 receptors significantly decreased GnRH mRNA levels in the ventromedial hypothalamus but did not evidently affect GnRH mRNA in the preoptic/ anteriorhypothalamicarea. Blockaded DA-2 receptors led to different responses in GnRH-R mRNA in various parts of the hypothalamus; increased GnRH-R mRNA levels in the preoptic/anterior hypothalamic area, and decreased GnRH-R mRNA amounts in the ventromedial hypothalamus stalk/median eminence. An infusion of sulpiride into the III-rd ventricle increased GnRH mRNA levels in the anterior pituitary gland and LH secretion. It is suggested that the increase of GnRH gene expression in the anterior pituitary gland and LH secretion in sulpiride-treated ewes are related with an increase of biosynthesis GnRH with concomitant decreased biosynthesis of GnRH-R protein in the ventromedial hypothalamus/stalk median eminence allowing to an increase of GnRH release.     

Dexamethasone suppresses gonadotropin-releasing hormone (GnRH) secretion and has direct pituitary effects in male rats: differential regulation of GnRH receptor and gonadotropin responses to GnRH

Endogenous or exogenous glucocorticoid excess leads to the development of hypogonadotropic hypogonadism, but the site(s) and mechanisms of glucocorticoid action are uncertain. We studied the effects of various doses of dexamethasone (Dex) on the hypothalamic-pituitary-gonadal axis in intact and castrate testosterone-replaced (cast + T) male rats and attempted to determine possible sites of Dex effects. A dose-dependent suppression of basal gonadotropin secretion was induced by 5 days of Dex treatment (20, 100, 500, or 2,500 micrograms/kg.day), and the highest dose completely abolished the postcastration rise in pituitary GnRH receptor number (GnRH-R) and serum gonadotropin levels. Administration of exogenous GnRH (0.02-200 micrograms/day over 2 days) resulted in a dose-dependent induction in GnRH-R in both intact and cast + T rats, but the effect was significantly (P less than 0.01) augmented in Dex-treated animals. In contrast, acute LH and FSH responses to GnRH (10, 25, 50, 100, or 250 ng, iv) were significantly blunted in Dex-treated rats. The data suggest that 1) Dex suppresses hypothalamic GnRH secretion, thereby preventing the postcastration rises in GnRH-R and gonadotropins; 2) at the pituitary level, Dex dissociates GnRH-R and gonadotropin responses to GnRH, augmenting GnRH-R induction by GnRH and suppressing gonadotropin responses to GnRH at a postreceptor site; and 3) the model of Dex-treated rats may be useful to study differential GnRH regulation of GnRH-R and gonadotropin secretion.     

Seasonal changes in expression of genes encoding five types of gonadotropin-releasing hormone receptors and responses to GnRH analog in the pituitary of masu salmon

Five types of gonadotropin-releasing hormone receptor (GnRH-R) genes, designated as msGnRH-R1, R2, R3, R4, and R5, are expressed in the brain and pituitary of masu salmon (Oncorhynchus masou). In the present study, seasonal changes in the expression of these five genes were examined in the pituitary to elucidate their roles in GnRH action during growth and sexual maturation. In addition, the seasonal variation of these genes in response to GnRH was examined in a GnRH analog (GnRHa) implantation experiment. Pituitary samples were collected 1 week after the implantation every month from immaturity through spawning. The absolute amount of GnRH-R mRNA in single pituitaries was determined by real-time PCR assays. Among the five genes, R4 was predominantly expressed in the pituitaries. In the immature fish, the amount of GnRH-R mRNA varied with seasons and subtypes. In the pre-spawning period, R1 and R4 mRNAs in both sexes and R2 and R3 mRNAs in the females increased 4- to 20-fold and then decreased in the spawning season. The effects of GnRHa treatment were significantly different in both sexes. In the females, GnRHa tended to elevate the expression of all the subtypes of GnRH-R genes in various stages during the experimental period, whereas it had almost no apparent effects in the males. These results indicate that the expression of the five GnRH-R genes is seasonally variable and may be related to the responses of the pituitary hormone genes to GnRH, and the regulation of GnRH-R genes by GnRH is different in both sexes.     

Expression of alpha-subunit and luteinizing hormone (LH) beta messenger ribonucleic acid in the rat during lactation and after pup removal: relationship to pituitary gonadotropin-releasing hormone receptors and pulsatile LH secretion

Pituitary GnRH receptor (GnRH-R) levels and LH secretion are suppressed in the lactating rat. To determine if LH synthesis is also inhibited, we have measured LH subunit mRNA levels in the pituitary of lactating rats. We have also examined the temporal relationship among restoration of GnRH-R, LH secretion, and LH synthesis after withdrawing the sensory stimulus of suckling. Pituitary alpha-subunit and LH beta mRNA levels were sharply reduced on day 10 of lactation in both intact and ovariectomized (OVX) animals compared with those in cycling diestrous rats or OVX controls. Removal of the suckling stimulus from OVX animals led to significant increases in alpha-subunit and LH beta mRNA levels by 24 h. Upon removal of the suckling stimulus from intact rats, alpha-subunit mRNA levels were restored by 48 h, but LH beta mRNA levels did not return to diestrous levels until 72 h. Pituitary GnRH-R levels were clearly up-regulated within 1 day after pup removal. Some LH pulses were observed by 48 h, but consistent plasma LH pulses were not detected until 72 h. When pulsatile GnRH was administered during the 24 h after pup removal from intact rats, the regimen of pulsatile GnRH was successful in inducing LH secretion; however, the restoration of pulsatile LH was not accompanied by increases in alpha-subunit and LH beta mRNA levels. The present studies provide further evidence to support the hypothesis that during lactation, the suppression of pituitary gonadotroph function is mainly due to the loss of hypothalamic GnRH secretion. Our data also show that 1) the restoration of GnRH-R alone is not sufficient to activate LH subunit mRNA and LH secretion; 2) the normal restoration of pulsatile LH secretion and increases in LH subunit mRNA are temporally correlated, as increases in LH secretion appear to precede increases in LH subunit mRNA; and 3) the restoration of pituitary LH subunit mRNA levels and pulsatile LH secretion took longer in the intact rat than in the OVX rat, suggesting that ovarian steroids may play a role in the inhibitory effect of lactation.     

Dose response effects of pulsatile GnRH administration on restoration of pituitary GnRH receptors and pulsatile LH secretion during lactation

Ovariectomized (OVX) rats suckling 8 pups have a complete suppression of pulsatile LH secretion and a decrease in pituitary GnRH receptor (GnRH-R) content. Removing the suckling stimulus for 24 h results in a sharp increase in GnRH-R and a restoration of pulsatile LH secretion. These findings suggest that the suckling stimulus induces a suppression of GnRH secretion, and removal of the suckling stimulus permits the restoration of GnRH secretion. Indeed, if GnRH antiserum is injected at the time of pup removal, the restoration of pituitary GnRH-R and LH secretion is prevented. The present studies were designed to test our hypothesis that the deficits in pituitary gonadotroph function observed during lactation are due to suckling-induced suppression of GnRH. Exogenous GnRH was administered in a pulsatile regimen to OVX lactating rats on days 10 and 11 postpartum, and the effects on pituitary GnRH-R levels, pituitary sensitivity to GnRH, and pulsatile LH secretion were assessed. GnRH doses of 0, 0.5, 2.0 or 5.0 ng/pulse were administered every 50 min for 24 h beginning on day 10. Administration of 0.5 ng GnRH/pulse for 24 h increased GnRH-R from 35 +/- 3 to 63 +/- 8 fmol/pituitary. There was a clear GnRH dose-related upregulation of GnRH-R to approach nonsuckling levels (140-160 fmol/pituitary) with the 5 ng GnRH dose. At the beginning of GnRH administration, the pituitary was very unresponsive to GnRH. Consistent LH pulses were only observed with 5 ng GnRH/pulse.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pituitary gonadotropin-releasing hormone (GnRH) receptor responses to GnRH in hypothalamus-lesioned rats: inhibition of responses by hyperprolactinemia and evidence that testosterone and estradiol modulate gonadotropin secretion at postreceptor sites

Increased hypothalamic GnRH secretion appears to influence positively the number of pituitary GnRH receptors (GnRH-R). GnRH-R increase after castration in male rats, and this rise can be prevented by testosterone (T), anti-GnRH sera, or hypothalamic lesions. GnRH also increases serum LH and GnRH-R in hypothalamus-lesioned rats, and these animals injected with exogenous GnRH are, therefore, a good model in which to study the site of steroid feedback at the pituitary level. Adult male and female rats were gonadectomized, and radiofrequency lesions were placed in the hypothalamus. Males received T implants, and females received estradiol implants at the time of surgery. Empty capsules were placed in the control animals. Beginning 3-5 days later, animals in each group were injected every 8 h with vehicle (BSA) or GnRH (0.002-200 micrograms/day) for 2 days. After these GnRH injections, all rats received 6.6 micrograms GnRH, sc, 1 h before decapitation to determine acute LH and FSH responses. GnRH-R were determined by saturation analysis using 125I-D-Ala6-GnRH ethylamide as ligand. In males, GnRH injections increased GnRH-R. T inhibited acute LH and FSH responses to GnRH in all groups, but had little effect on GnRH-R, indicating that T inhibits gonadotropin secretion at a post-GnRH receptor site. In females, the GnRH-R response to GnRH was less marked, and only the 200 micrograms/day dose of GnRH increased GnRH-R, indicating that the positive feedback effects of estradiol at the pituitary level are also exerted at a site distal to the GnRH receptor. There was no positive correlation between the number of GnRH-R and GnRH-stimulated gonadotropin release in males or females. Female rats with hypothalamic lesions had markedly elevated serum PRL levels (greater than 300 ng/ml). Suppression of PRL secretion by bromocryptine resulted in augmented GnRH-R responses to GnRH, and GnRH-R concentrations rose to the same values induced in males. This suggests that hyperprolactinemia inhibits GnRH-R responses to GnRH in females by a direct action on the pituitary gonadotroph.     

Differential gonadotropin-releasing hormone (GnRH) and GnRH receptor messenger ribonucleic acid expression patterns in different tissues of the female rat across the estrous cycle

GnRH, the main regulator of reproduction, is produced in a variety of tissues outside of the hypothalamus, its main site of synthesis and release. We aimed to determine whether GnRH produced in the female rat pituitary and ovaries is involved in the processes leading to ovulation. We studied the expression patterns of GnRH and GnRH receptor (GnRH-R) in the same animals throughout the estrous cycle using real-time PCR. Hypothalamic levels of GnRH mRNA were highest at 1700 h on proestrus, preceding the preovulatory LH surge. No significant changes in the level of hypothalamic GnRH-R mRNA were detected, although fluctuations during the day of proestrus are evident. High pituitary GnRH mRNA was detected during the day of estrus, in the morning of diestrus 1, and at noon on proestrus. Pituitary GnRH-R displayed a similar pattern of expression, except on estrus, when its mRNA levels declined. Ovarian GnRH mRNA levels increased in the morning of diestrus 1 and early afternoon of proestrus. Here, too, GnRH-R displayed a somewhat similar pattern of expression to that of its ligand. To the best of our knowledge, this is the first demonstration of a GnRH expression pattern in the pituitary and ovary of any species. The different timings of the GnRH peaks in the three tissues imply differential tissue-specific regulation. We believe that the GnRH produced in the anterior pituitary and ovary could play a physiological role in the preparation of these organs for the midcycle gonadotropin surge and ovulation, respectively, possibly via local GnRH-gonadotropin axes.     

Daily GnRH and GnRH-receptor mRNA expression in the ovariectomized and intact rat

We recently described patterns of GnRH and GnRH receptor (GnRH-R) expression in the hypothalamus, pituitary and ovary throughout the rat estrus cycle. Here, we wished to distinguish between regulatory effects of ovarian factors and underlying circadian rhythmicity. We quantified GnRH and GnRH-R mRNA in the pituitary and hypothalamus of long-term ovariectomized (OVX) rats, at different times of day, using real-time PCR. Furthermore, we expanded our previous study of hypothalamic and pituitary GnRH and GnRH-R expression in intact rats by including more time points throughout the estrus cycle. We found different daily patterns of GnRH and GnRH-R expression in intact versus OVX rats, in both tissues. In the hypothalamus of OVX rats, GnRH mRNA peaked at 12, 16 and 20 h, whereas in the hypothalamus of intact rats we observed somewhat higher GnRH mRNA concentrations at 19 h on every day of the estrus cycle except proestrus, when the peak occurred at 17 h. In this tissue, GnRH-R fluctuated less significantly and peaked at 16 h in OVX rats. During the estrus cycle, we observed higher levels in the afternoon of each day except on estrus. In OVX rats, pituitary GnRH mRNA rose sharply at 9 h, with low levels thereafter. In these animals, pituitary GnRH-R also peaked at 9h followed by a second rise at 22 h. In intact rats pituitary GnRH was high at noon of diestrus-II and on estrus, whereas GnRH-R mRNA was highest in the evening of diestrus-II. This is the first demonstration of daily GnRH and GnRH-R mRNA expression patterns in castrated animals. The observed daily fluctuations hint at underlying tissue-specific circadian rhythms. Ovarian factors probably modulate these rhythms, yielding the observed estrus cycle patterns.     

Hyperprolactinemia inhibits gonadotropin-releasing hormone (GnRH) stimulation of the number of pituitary GnRH receptors

Gonadotropin secretion is diminished in the presence of hyperprolactinemia, and previous studies have shown that PRL can reduce GnRH secretion and impair LH responses to GnRH. To investigate the mechanisms of the inhibitory effects of PRL on the pituitary, we administered intraarterial pulse injections of GnRH (25 ng/pulse every 30 min) to castrate testosterone-implanted male rats placed in restraint cages. Serum PRL, GnRH receptor (GnRH-R), and LH responses to GnRH were measured at intervals over 72 h. In control animals which received saline pulses, serum PRL was transiently elevated to the range of 100-150 ng/ml during the first 24 h, GnRH-R remained stable (approximately 300 fmol/mg protein) and serum LH was low (less than 10 ng/ml) throughout the 72 h. GnRH pulses in castrate testosterone-implanted animals increased GnRH-R to values (approximately 600 fmol/mg) similar to those in castrate controls (no testosterone implant, saline pulses) through 48 h, but GnRH-R declined to baseline values by 72 h in both groups. Serum LH responses to GnRH pulses were only present at 24 h. Administration of bromocriptine throughout the 72 h to immobilized castrate rats or to castrate testosterone-replaced animals treated with GnRH pulses suppressed serum PRL, and GnRH-R concentrations remained elevated through 72 h. Serum LH responses to GnRH pulses were 5- to 20-fold higher in bromocriptine-treated rats, and responses were present throughout the 72 h of the experiment. Delaying the start of bromocriptine treatment until 36 h (after the spontaneous PRL peak) resulted in reduced GnRH-R and LH responses at 72 h. Similarly, administration of ovine PRL (during the first 48 h) to bromocriptine-treated rats produced low GnRH-R concentrations at 72 h. Thus, the transient elevation of PRL seen in immobilized rats can inhibit the GnRH-stimulated increase in GnRH-R and is associated with reduced LH responses to GnRH. These results indicate that PRL has a direct inhibitory effect on the gonadotrope and suggest that impaired GnRH-R responses to GnRH are one of the mechanisms involved in the diminished gonadotropin secretion seen in hyperprolactinemia.     

Effects of gonadotropin-releasing hormone on pituitary-ovarian axis of one-year old pre-pubertal red seabream

To identify the pubertal development of the brain-pituitary-gonad (BPG) axis in female red seabream (Pagrus major), we investigated the effects of gonadotropin-releasing hormone agonist (GnRHa) on seabream (sb) GnRH mRNA levels in the brain, gonadotropin subunit mRNA levels in the pituitary, and serum concentrations of luteinizing hormone (LH), testosterone (T) and estradiol-17beta (E2) in pre-pubertal fish. Sexually immature 12-month-old fish were implanted with a cholesterol pellet containing GnRHa and maintained for 10-20 days. In the brain, GnRHa had no effect on sbGnRH mRNA levels. In the pituitary, although no marked changes were observed in follicle-stimulating hormone (FSH) beta subunit mRNA levels, the expression of glycoprotein (GP) alpha, and LHbeta subunit genes in the pituitary was drastically up-regulated (approximately 4- and 5-fold, respectively) and serum LH levels were also increased (approximately 3-fold) by GnRHa implantation. However, ovaries of GnRHa treated fish contained only oocytes at the peri-nucleolus stage, and oocyte development such as vitellogenesis and oocyte maturation did not occur throughout the experimental period. In these fish, even though LH was released, only slight increases in serum concentrations of T and E2 were observed. These results indicate that the pituitary gonadotropin cells of pre-pubertal 12-month-old fish were already receptive to GnRH stimulus, and acquired the ability to synthesize and release of LH as in the case of adult fish. Deficient factors for the onset of puberty by GnRHa treatment will be discussed.     

Annexin 5 messenger ribonucleic acid expression in pituitary gonadotropes is induced by gonadotropin-releasing hormone (GnRH) and modulates GnRH stimulation of gonadotropin release.

Our previous studies on annexin 5, a member of the annexin family of proteins, have shown its expression in the anterior pituitary gland, its preferential distribution in gonadotropes, and its increase after ovariectomy. In the present study, we examined (1) whether annexin 5 is synthesized in gonadotropes, (2) whether its expression is under the control of gonadotropin-releasing hormone (GnRH), and (3) the effect of annexin 5 on gonadotropin release. Large cells, also called castration cells, appeared in anterior pituitary tissue 3 weeks after ovariectomy. These cells have been confirmed to be hyperfunctioning gonadotropes and are easily discriminated from other pituitary cells without immunostaining. Using in situ hybridization with a digoxigenin-labeled ribonucleic acid probe, enhanced expression of annexin 5 messenger ribonucleic acid (mRNA) in these gonadotropes was clearly demonstrated. Northern blot analysis showed an increase in the level of annexin 5 mRNA expression 3 weeks after ovariectomy. It was lessened 3 h after the injection of Cetrorelix (GnRH antagonist, 10 microg i.v.). Administration of a GnRH analog [GnRHa; Des-Gly 10 (Pro9) GnRH ethylamide, 0.2 ml of 2.5 microg/ml saline ten times intraperitoneally at 30-min intervals] significantly increased pituitary annexin 5 mRNA. In primary cultures of anterior pituitary cells, recombinant rat annexin 5 stimulated luteinizing hormone (LH) and follicle-stimulating hormone (FSH) release in a dose-dependent manner. Concomitant administration of annexin 5 (1 microg/ml) and GnRHa augmented the LH and FSH release induced by GnRHa. After a 1-hour incubation, cycloheximide (10 microg/ml) apparently inhibited the LH response to GnRHa, while annexin 5 (2 microg/ml) moderated this inhibition. Further, the antisense oligodeoxynucleotide to annexin 5 mRNA blunted the LH response to GnRHa. It is thus concluded that annexin 5 is synthesized in the gonadotropes under the effect of GnRH, and it is suggested that annexin 5 synthesis mediates at least partly GnRH receptor signaling to stimulate gonadotropin secretion.     

Simultaneous effect of gonadotropin-releasing hormone (GnRH) on the expression of two gonadotropin beta genes by passive immunization to GnRH

In order to reveal the action of gonadotropin-releasing hormone (GnRH) on the synthesis of gonadotropins in the pituitary gland of castrated rats, passive immunization to GnRH designed to block the activity of GnRH was performed. The levels of prolactin mRNA in castrated and rabbit anti-GnRH serum (RAGnRH)-treated rats decreased, whereas TSH beta mRNA showed no statistically significant change. In contrast, mRNAs encoding common alpha, LH beta and FSH beta were increased 2.7-, 1.7- and 1.5-fold, respectively, by castration. These elevated mRNA levels of gonadotropin subunits in castrated rats well explain the increased hormone levels in serum and in the pituitary. Two days later, a single administration of RAGnRH to the castrated rats significantly suppressed the mRNA levels to 2.0-fold for alpha, 1.2-fold for LH beta and 1.1-fold for FSH beta relative to the respective control values. These results showed that the two gonadotropin beta genes respond more rapidly to GnRH action that the common alpha gene.     

Pituitary gonadotropin-releasing hormone receptor regulation in the hypogonadotrophic hypogonadal (hpg) mouse

Recent evidence indicates that endogenous GnRH is required for maintenance of its own pituitary receptors (GnRH-R). We have measured GnRH-R in pituitaries of hypogonadotrophic hypogonadal (hpg) mice, in whom hypothalamic GnRH is deficient or absent. The GnRH-R concentration in hpg male mouse pituitaries was 10.6 +/- 1 fmol/pituitary vs. 30.9 +/- 1 fmol/pituitary in normal male littermate pituitaries. Similarly, GnRH-R in female hpg mice (15.2 +/- 1.7 fmol/pituitary) were 30% those of normal random cycling females (51.4 +/- 3.5 fmol/pituitary). There was no difference in receptor affinity (Ka = 1.5-3 C 10(9) M-1) of hpg mouse pituitaries. The pituitary LH content in hpg male and female mice was very similar (range 3.4-4.8 micrograms/pituitary) representing 5% and 19% of normal male (95 +/- 7.2 micrograms/pituitary) and female (18.1 +/- 1.5 micrograms/pituitary) values, respectively. The administration of 50 ng GnRH sc 10 times daily to male hpg mice, increased GnRH-R to 80% of normal values within 3 days. Serum FSH and pituitary FSH content rose to normal male values after 7 days of GnRH injections. However, serum LH remained undetectable and pituitary LH reached only 20% of normal male levels, even after 15 days of GnRH administration. Treatment of hpg male mice with 60 ng GnRH either once daily for 6 days, or 12 times daily for 5 days, increased GnRH-R to 50% of normal male values. Twelve daily injections of GnRH elevated serum FSH to above the normal male range, whereas daily GnRH only doubled untreated hpg levels. Pituitary FSH was stimulated to 50% of normal with 12 daily injections, whereas once daily administration elevated pituitary FSH to 30% of normal values. Both pulsatile regimes depleted pituitary LH. These data demonstrate that: 1) despite absence of bioactive GnRH, GnRH-R values are only reduced to 30% of normal in hpg mouse pituitaries, suggesting that little, if any, endogenous GnRH is required for expression of GnRH receptors. 2) Pituitary GnRH-R number rapidly increase when GnRH is administered to hpg male mice indicating that, as in the rat, GnRH positively regulates its own receptor concentration. 3) The pituitary FSH and LH responses to GnRH treatment in hpg mice depends to a different extent on the frequency and duration of GnRH administration. 4) The hpg mouse provides an ideal animal model for investigating the interaction of defined regiments of exogenous GnRH and gonadal steroids on pituitary GnRH receptor and gonadotroph function.     

Dexamethasone alters responses of pituitary gonadotropin-releasing hormone (GnRH) receptors, gonadotropin subunit messenger ribonucleic acids, and gonadotropins to pulsatile GnRH in male rats.

Dexamethasone (Dex), when administered in high doses, has been shown to suppress spontaneous and GnRH-induced gonadotropin secretion, but the level and the mechanism(s) of this effect are unknown. We administered Dex to castrate testosterone-replaced male rats to determine if gonadotropin gene expression is affected and whether Dex differentially influences GnRH-modulated parameters of gonadotrope function: induction of GnRH receptors (GnRH-R) and gonadotropin synthesis and secretion. GnRH was given iv at 25 ng/pulse at 8, 30, and 120 min intervals for 48 h. Rapid GnRH injection frequency preferentially increased alpha and LH-beta messenger RNA (mRNA) responses to GnRH as well as LH secretion. Slower GnRH injection frequencies were required to increase levels of GnRH-R, FSH-beta mRNA, and FSH secretion. Dex selectively inhibited the serum LH, alpha, and LH-beta mRNA responses to GnRH, but not the serum FSH or FSH-beta mRNA responses. Additionally, it augmented the GnRH-induced increase in GnRH-R. We conclude: 1) induction of GnRH-R, gonadotropin synthesis, and secretion require different modes of GnRH stimulation; 2) Dex acts directly on the gonadotrope to differentially modulate GnRH-induced increases in GnRH-R levels, gonadotropin gene expression, and gonadotropin secretion; and 3) GnRH effects upon induction of GnRH-R, LH, and FSH synthesis and secretion are likely to be mediated via different cellular pathways.     

Gonadotropin-releasing hormone desensitization preferentially inhibits expression of the luteinizing hormone beta-subunit gene in vivo

In this study we investigated changes in steady state cytoplasmic mRNA levels for LH subunits in pituitaries of male rats desensitized by continuous infusion of GnRH in vivo. Seven days of GnRH infusion (340 micrograms/day) reduced (P less than 0.01) LH beta mRNA levels in intact adult male rats and prevented the LH beta mRNA rise observed after castration. In contrast, common alpha mRNA doubled (P less than 0.05) in intact rats, and the elevated alpha mRNA after 7 days castration was unchanged. Serum and pituitary LH levels were suppressed below values of intact controls. Fourteen days of GnRH infusion (290 micrograms/day) further reduced LH beta mRNA levels in both intact and castrated male rat pituitaries. alpha mRNA levels in intact rat pituitaries were unchanged by 14 days of GnRH infusion, while in castrated rats there was a 23% (P less than 0.05) decrease, though values were still twice those of intact controls. As at 7 days, serum and pituitary LH were suppressed. Infusion of a superagonist analog (Buserelin) at a dose of 14 micrograms/day for 28 days reduced LH beta mRNA to 15% of intact control values in both castrated and intact rats. Common alpha mRNA was significantly (P less than 0.05) increased in intact rats and reduced by 13% (P less than 0.05) in castrates by superagonist infusion. These results were similar to those produced by 20- to 30-fold higher doses of native GnRH. GnRH and agonist analog effects were specific since no changes were observed in other mRNA species (GH, PRL, actin). These results indicate that in GnRH-desensitized gonadotropes LH beta gene expression is inhibited, and this may largely explain the reduced LH biosynthesis. However, there is a differential effect of continuous GnRH or agonist analog treatment on LH subunit gene expression, with a time-dependent stimulation of common alpha gene expression in intact rats. This may be caused by a stimulatory interaction between GnRH and progestagens at the level of the gonadotrope. Thus, common alpha gene expression is less tightly coupled than that of LH beta to GnRH action.     

Influence of steroids and GnRH on biosynthesis and secretion of secretogranin II and chromogranin A in relation to LH release in LbetaT2 gonadotroph cells

The granin proteins secretogranin II (SgII) and chromogranin A (CgA) are commonly found associated with LH and/or FSH within specialised secretory granules in gonadotroph cells, and it is possible that they play an important role in the differential secretion of the gonadotrophins. In this study we have examined the regulation of the biosynthesis and secretion of SgII and CgA, in relation to LH secretion, in the LbetaT2 mouse pituitary gonadotroph cell line. Three experiments were carried out to investigate the effects of oestradiol (E2) and dexamethasone (Dex) in the presence and absence of GnRH (experiment 1), differing GnRH concentrations (experiment 2) and alterations in GnRH pulse frequency (experiment 3). In experiment 1, exposure to E2, Dex or E2+Dex, either with or without GnRH treatment, resulted in increased LH secretion. Steroids alone had no effect on LHbeta mRNA levels, but in the presence of GnRH LHbeta mRNA levels were increased in Dex- and E2+Dex-treated cells. GnRH receptor (GnRH-R) mRNA levels were up-regulated by Dex and E2+Dex, but were unaffected by GnRH. There were no steroid-induced changes in SgII or CgA mRNA, but increased levels of CgA mRNA were observed after GnRH treatment in cells cultured in the presence of Dex. In experiment 2, increasing concentrations of GnRH resulted in increases in LH secretion that were inversely dose-dependent. No changes in LHbeta, GnRH-R or SgII mRNA levels were observed, but there were dose-dependent increases in CgA mRNA levels. In experiment 3, GnRH was given as either 1 pulse/day or 4 pulses/day for 3 days. Both pulse regimes resulted in increased LH, SgII and CgA secretion compared with controls during the first 15 min pulse on day 3. Exposure to GnRH at 4 pulses/day increased LH and SgII secretion compared with controls during all 4 pulses, but secretion of both proteins was reduced during pulses 2-4 compared with pulse 1. CgA secretion also increased due to GnRH in pulse 1, but was decreased by GnRH treatment during pulse 2, and unchanged by GnRH during pulses 3 and 4. Total daily secretion of LH and SgII from cells given 1 pulse/day of GnRH increased compared with controls on all three treatment days, while total CgA secretion increased in response to GnRH on days 2 and 3 only. Intracellular levels of SgII, but not LH, decreased after GnRH treatment. In contrast, intracellular CgA was increased, but only after 4 pulses/day of GnRH. Levels of LHbeta, but not SgII, mRNA were increased by both pulse regimes, while CgA mRNA levels increased after 1 pulse/day of GnRH. These results indicate that there is a close correlation between the GnRH-stimulated release of LH and SgII from LbetaT2 cells, suggesting that SgII may have an influential role in the regulated secretion of LH, possibly by inducing LH aggregation to facilitate trafficking into secretory granules. CgA secretion does not appear to be closely associated with that of LH, but CgA expression does appear to be regulated by GnRH, which may indicate involvement in the control of LH secretion, possibly by influencing the proportion of LH in the different types of secretory granules.     

The interaction of gonadotropin-releasing hormone and estradiol on luteinizing hormone and prolactin gene expression in female hypogonadal (hpg) mice

We have investigated the interaction of estrogen with GnRH on the regulation of LH subunit mRNA in female hypogonadal (hpg) mice receiving constant frequency and amplitude pulsatile GnRH treatment for up to 18 days. The level of cytosolic common alpha mRNA in female hpg mouse pituitaries was 45 +/- 6% of normal female littermate values, and treatment with pulsatile GnRH increased alpha mRNA to 40% above the normal value at 24 h and 2-4 times normal at 7 and 12 days (P less than 0.001); by 18 days levels had returned to those of untreated hpg controls. Concurrent treatment with estradiol (E2) did not affect those changes. However, in ovariectomized hpg mice the 2- to 4-fold rise in alpha mRNA was sustained for 18 days with GnRH treatment. E2 treatment alone for 7 and 12 days doubled alpha mRNA. LH beta mRNA levels in untreated female hpg mice were between 5-10% of normal values. Levels increased significantly (77 +/- 6.4%) 24 h after GnRH treatment and were normal at 7, 12, and 18 days. E2 together with GnRH did not affect the LH beta mRNA increase at 12 days, but reduced it to 45% of normal at 18 days. Ovariectomy did not alter the LH beta mRNA response to GnRH treatment, and E2 treatment alone did not increase LH beta mRNA. Serum LH concentrations were normalized by GnRH treatment at all times and did not increase in ovariectomized animals. LH release was prevented when E2 was combined with GnRH. Pituitary LH content in hpg mice was 20% of normal and increased gradually with GnRH treatment. Neither concurrent treatment with E2 nor ovariectomy affected the GnRH-induced synthesis of LH. PRL mRNA levels were 30-40% of normal littermate values in untreated female hpg mice, and pulsatile GnRH increased these to 70-80% of normal. E2 alone raised PRL mRNA slightly above normal values, although together with GnRH this rise was attenuated by about 40%. Pulsatile GnRH treatment of ovariectomized hpg mice did not increase PRL mRNA. E2 increased pituitary PRL content, and GnRH did not attenuate this aspect of E2 action. Serum PRL levels rose with E2 treatment at 7 and 12 days, and concurrent GnRH treatment prevented the rise at 12 days. We conclude the following: 1) The stimulatory action of pulsatile GnRH on the expression of both common alpha and LH beta mRNA is rapid (less than 24 h).(ABSTRACT TRUNCATED AT 400 WORDS)