Differential responses of the hypothalamo-pituitary-adrenocortical axis to acute restraint stress in Hatano high- and low-avoidance rats

The high- and low-avoidance animal (HAA and LAA respectively) strains of Hatano rats were originally selected and bred from Sprague-Dawley rats for their performance in the shuttle-box task. The present study focused on the activity of the hypothalamo-pituitary-adrenocortical (HPA) axis of HAA and LAA rats in response to restraint stress. The restraint stress induced an elevation in plasma concentrations of ACTH, prolactin, corticosterone and progesterone. Peak levels of plasma ACTH during stress conditions were significantly higher in HAA rats than in LAA rats, while peak levels of prolactin were significantly lower in HAA rats than in LAA rats. Under stress conditions, ACTH and prolactin synthesis in the anterior pituitary glands was significantly higher in HAA rats compared with LAA rats. The peak plasma concentrations of corticosterone, during restraint stress, were significantly higher in LAA rats compared with HAA rats. These results indicate that the response of the hypothalamo-pituitary axis to acute restraint stress is greater in HAA rats than in LAA rats, whereas the ACTH-induced adrenal response of corticosterone release is higher in LAA rats than in HAA rats. On the other hand, prolactin secretory activity is higher in LAA rats compared with HAA rats. These differences in endocrine responses to stress may be involved in the regulation of the avoidance responses in the shuttle-box task.     

Effect of oestrogen treatment on gonadotroph function in adult male rats

The effect of oestradiol-17 beta on the hypothalamo-pituitary axis of intact adult male rats was studied. A single injection of oestradiol did not change the serum LH response to gonadotrophin-releasing hormone (GnRH) 48 h or 7 days after the injection, while administration of oestrogen over 66 days suppressed basal serum LH to less than 3.1 micrograms/l and did not enhance the LH response to GnRH at any time. Treatment of ovariectomized rats with oestradiol capsules, however, enhanced the LH response to GnRH on days 3 and 14 of the treatment as compared with the control group (P less than 0.02 and P less than 0.05 respectively). Long-term treatment with oestradiol suppressed intrapituitary LH and FSH contents as well as pituitary GnRH receptors (P less than 0.0004, P less than 0.005 and P less than 0.001 respectively), whereas serum and intrapituitary prolactin levels were increased. To exclude the possible lactin levels were increased. To exclude the possible inhibitory effect of hyperprolactinaemia on LH were treated with bromocriptine. This prevented the rise in serum prolactin, but failed to enhance the LH response to GnRH. Neither short- nor long-term treatment with oestradiol given under conditions shown to be effective in female animals stimulated the hypothalamo-pituitary-gonadotrophin axis in adult male rats.     

Role of the adrenal cortex in chronic stress-induced inhibition of prolactin secretion in male rats

The response of prolactin to chronic stress in intact, adrenalectomized and adrenomedullectomized male rats was studied. Immobilization stress in intact animals induced a significant increase in plasma concentrations of prolactin after 20 and 45 min and a significant decrease when the rats were submitted to chronic restraint (6 h daily for 4 days). Five weeks after adrenomedullectomy, plasma prolactin and corticosterone responses to chronic stress were not modified. In contrast, the inhibitory effect of chronic stress on prolactin secretion was totally suppressed by adrenalectomy. When treated with dexamethasone during the 4 days of restraint, adrenalectomized stressed rats showed similar plasma concentrations of prolactin to the intact stressed rats. These data indicate that the adrenal cortex is able to play an inhibitory role on prolactin secretion during stress only through a prolonged release of glucocorticoids.     

Pituitary gonadal function in adult male rats subjected to crowding

The effect of crowding on the pituitary-gonadal axis was studied in adult male rats. Crowding reduced body weight gain, did not alter relative adrenal weight and increased relative testis weight. Neither basal levels of corticosterone nor its response to acute stress were altered by crowding. Likewise, LH secretion was similar in control and crowded rats. Prolactin levels tended to be lower in crowded than control rats, but they did not reach statistical significance. In contrast, impaired testosterone secretion was observed in crowded rats, at least in part due to reduced Leydig cell responsiveness to gonadotropin release. In addition, some mechanisms other than pituitary-adrenal hyperactivity might be responsible for reduced testosterone secretion during crowding.     

Pituitary receptors for LH-releasing hormone (LHRH) and responsiveness to LHRH in adult female rats after neonatal monosodium L-glutamate treatment

The effects of neonatal monosodium L-glutamate (MSG) treatment on pituitary responsiveness to LH-releasing hormone (LHRH) and on pituitary LHRH receptors have been investigated in the intact adult female rat. Three- to four-month-old rats treated with MSG (4 mg/g body wt) on days 2, 4, 6, 8 and 10 after birth had significantly reduced ovarian and pituitary weights, showed an absence or disruption of ovarian cyclicity after puberty, and had significantly higher concentrations of serum prolactin despite normal levels of LH. In-vitro pituitary LH responses to LHRH were in the normal range for one group of treated animals whilst in a second group the LH responses were markedly enhanced. In contrast, the total number of pituitary LHRH receptors were significantly reduced in all MSG-treated animals showing that the increased pituitary responsiveness of MSG-treated animals is not attributable to an increase in pituitary LHRH receptors.     

Effect of adrenomedullectomy and propranolol treatment on the response of gonadotrophins to chronic stress in male rats

In order to study the involvement of the adrenal medulla in stress-induced inhibition of gonadotrophin secretion, we measured plasma concentrations of LH, FSH and corticosterone in adult male rats subjected to chronic restraint after surgical ablation of the adrenal medulla. In intact animals, chronic restraint (6 h daily over 4 days) induced a significant (P less than 0.05) decrease in plasma concentrations of LH, whereas plasma concentrations of corticosterone showed the expected significant (P less than 0.01) increase. Adrenomedullectomy did not significantly modify basal plasma concentrations of LH or corticosterone. In these rats, there was no significant decrease of LH after stress, while the increase in corticosterone was as significant as in sham-operated animals (P less than 0.01). In order to confirm the role of adrenomedullary catecholamines in stress-induced gonadotrophin inhibition another group of rats was treated s.c. with the beta-adrenergic blocker propranolol (2 mg/kg twice daily). These rats showed an attenuated inhibition of LH during stress similar to that observed in adrenomedullectomized rats. Levels of FSH were significantly reduced after stress in the saline-treated group, while there were no differences between stressed or unstressed rats in the propranolol-treated group. These results may be considered as evidence that medullary catecholamines, acting through beta-receptors, are factors involved in gonadotrophin inhibition during chronic stress.     

Influence of pinealectomy on the suppression of gonadotropin secretion induced by hyperprolactinaemia in the adult male rat

To investigate the role of the pineal gland in the long-term suppression of gonadotrophin secretion induced by prolactin, the effects of pinealectomy were studied in adult male rats with hyperprolactinaemia produced by the transplantation of two pituitary glands under the kidney capsule. Pinealectomy had no effect on basal levels of LH, FSH or prolactin. The presence of pituitary transplants induced a significant twofold increase in prolactin levels and a prolonged suppression in both LH and FSH. These changes were not affected by pinealectomy. Castration resulted in a similar rise in plasma levels of LH and FSH in rats with and without pituitary transplants. In control rats this rise in LH and FSH was reduced by testosterone-containing silicone elastomer implants (s.c) of 10 mm in length and delayed by implants of 30 mm. These rises in LH and FSH were significantly delayed (10-mm implant) or abolished (30-mm implant) in rats with pituitary transplants indicating an increase in sensitivity of the hypothalamic-pituitary axis to the negative feedback effects of testosterone in these animals compared to controls. These responses were not affected by pinealectomy. These results suggest that the pineal gland is not involved in the mechanism whereby pituitary grafts, possibly through their secretion of prolactin, cause long-term suppression of gonadotrophin secretion.     

Influence of estrogens on pituitary responsiveness to LHRH and TRH in human (author's transl)]

Estrogens are supposed to be responsible for the increased sensitivity of the pituitary to LHRH and TRH observed in female in comparison to male adults. The influence of physiological and pharmacological variations of estrogens was studied throughout female life. Adolescents girls showed enhanced responses to both LHRH and TRH, as compared to cycling adult women. The adolescent pituitary seems to be particularly sensitive to the increasing estradiol secretion. Adult cycling women disclosed higher LH and FSH responses to LHRH during the periovulatory and luteal phases than during the follicular phase; prolactin response to TRH was enhanced only during the periovulatory phase while TSH response remained constant throughout the menstrual cycle. In adult women, sequential oral contraceptives increased LH, FSH and prolactin responses to LHRH and TRH while TSH response was unchanged. Combined contraceptives displayed an important inhibition of the LH, FSH and TSH responses but not of that of prolactin. The inhibitory effects on gonadotrophins and TSH may be due to the association of gestagens to estrogens. Postmenopausal women presented a TSH response to TRH similar to that found in male adults while prolactin response remained unchanged in spite of decreased basal values. The potentiatory effects of estrogens on the pituitary responsiveness to LHRH and TSH may be attributed either to an increased number or to an enhanced binding activity of the pituitary receptors to LHRH and TRH, as suggested by several experimental data.     

Diurnal variation in neuroendocrine response to stress in rats: plasma ACTH, beta-endorphin, beta-LPH, corticosterone, prolactin and pituitary cyclic AMP responses

The effects of restraint stress applied at different times of the day on levels of five stress-responsive plasma hormones (ACTH, beta-endorphin, beta-LPH, corticosterone and prolactin) and pituitary cyclic AMP levels were assessed. Different groups of rats were subjected to 15 min of restraint stress at 2-hour intervals over a 24-hour period. Rats were sacrificed immediately upon removal from their home cage (controls) or immediately following restraint (stressed). The time of day of stress exposure markedly affected the stress responses measured. Generally, responses to stress applied at the beginning of the dark cycle (18:00) were less than those seen following stress applied at the beginning of the light cycle (06:00). Stress at 06:00 increased levels of pituitary cyclic AMP 10-fold, while stress applied at 18:00 did not significantly increase pituitary cyclic AMP levels. In stressed rats, high correlations were seen among levels of hormones derived from the common precursor, proopiomelanocortin (ACTH, beta-endorphin, beta-LPH) and between these hormones and levels of pituitary cyclic AMP. These findings support the hypothesis that pituitary cyclic AMP is involved in the stress-induced release or synthesis of the pituitary hormones ACTH, beta-endorphin, and beta-LPH.     

Role of LHRH in the gonadotrophin response to restraint stress in intact male rats

A hypothalamic site of action has been hypothesized for the inhibitory effect of chronic stress on gonadotrophin secretion. The aim of the present study was to examine the temporal changes in hypothalamic LHRH content and gonadotrophin secretion during restraint stress, and the pituitary responsiveness to LHRH stimulation in chronically stressed rats. Adult male rats were killed after being restrained for 0, 20, 45, 90, 180 and 360 min or for 6 h daily over 2, 3 and 4 days. After 20-45 min of stress there was an increase in plasma concentrations of LH (P less than 0.01) and a decrease in hypothalamic LHRH content (P less than 0.01), suggesting a negative correlation between plasma LH and hypothalamic LHRH concentrations. Plasma concentrations of FSH were also increased by restraint, but the FSH response was slower and less than the plasma LH response, being significant after 90 min of restraint. Plasma LH and FSH and hypothalamic LHRH concentrations were decreased in chronically stressed rats. In rats restrained for 6 h daily over 4 days, the response of plasma gonadotrophins to administration of 500 ng LHRH was enhanced 45 min after the injection. On the basis of these observations we concluded that in the intact rat, stress may acutely stimulate LHRH and gonadotrophin secretion, and the inhibitory effect of chronic stress on plasma LH and FSH seems not to be due to a reduction in pituitary responsiveness to LHRH, but rather to a decrease in LHRH secretion.     

Influence of adrenocorticotropin and adrenalectomy on gonadotropin secretion in immature rats

We examined the effects and mechanisms of action of ACTH and ACTH fragments on gonadotropin secretion in immature rats. ACTH administered by daily injection or continuous infusion (osmotic minipumps) attenuated the postcastration rise in serum LH. Pituitary LH concentration was either unchanged or increased in ACTH-treated rats and pituitary sensitivity to gonadotropin-releasing hormone (GnRH) was reduced by ACTH treatment. A fragment of ACTH (ACTH 4-10), which is less steroidogenic, did not alter levels of serum LH, and ACTH did not reduce LH secretion in adrenalectomized castrates. Serum and pituitary concentrations of prolactin were normal in ACTH-treated animals. These studies demonstrate that the suppression of gonadotropin secretion by ACTH is mediated by the adrenal gland. This mechanism causes a decreased pituitary sensitivity to GnRH, but LH synthesis does not appear to be affected. Prolactin does not play a role in this mechanism.     

Dopamine agonist- and antagonist-induced modulation of pituitary gonadotrophin releasing hormone receptors are independent of changes in serum prolactin

The effect of drug-induced hypo- and hyperprolactinaemia on pituitary gonadotrophin releasing hormone receptors (GnRH-R), serum and pituitary gonadotrophins (LH and FSH) and prolactin was investigated in intact adult male and female rats. Hypoprolactinaemia (serum prolactin less than 20% of control values) resulting from dopamine agonist (bromocriptine) infusion (4 mg/kg per day for 7 days) was accompanied by a 40-50% increase in GnRH-R in both male and female animals, though this was not accompanied by any major change in serum or pituitary LH and FSH. Hyperprolactinaemia (serum prolactin greater than ten times control values) induced by the dopamine receptor antagonist metoclopramide (65 mg/kg per day for 7 days) increased GnRH-R between 35 and 45% in both male and female rats without altering serum gonadotrophins. Domperidone (1 mg twice daily for 14 days) also increased GnRH-R by 50% but only in female rats. Both dopamine antagonists significantly increased pituitary prolactin content. Pituitary FSH increased in female rats treated with both metoclopramide and domperidone. The stimulatory effects of bromocriptine and metoclopramide on GnRH-R in male rats were prevented by concurrent treatment with a GnRH antiserum, suggesting that the drug effects were mediated through alteration in endogenous GnRH secretion. Induction of massive (serum prolactin greater than 2000 micrograms/l) hyperprolactinaemia in male and female rats with a transplantable prolactin-secreting pituitary tumour did not reduce GnRH-R concentration, although serum gonadotrophins were suppressed and pituitary gonadotrophin content was increased.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of an aproteic diet on gonadotropin release response to GnRH and estrogen-progesterone in rats

The fasting-induced gonadotropin function decrease is unspecific, because in this situation there is a lack of all nutrients. We report here the effect of specific protein lack in the diet during 21 days, on pituitary gonadotropin synthesis and response to exogenous GnRH in adult male rats. We also studied the effect of the aproteic diet (AP) on the positive feedback mechanism in adult female castrated rats. The AP diet decreased significantly, both LH and FSH pituitary concentration and also basal gonadotropin plasma levels in male rats. GnRH produced a significantly increment in LH secretion in both treated and control groups, reaching similar levels after stimulation. Nevertheless, the percentile increment from basal levels in the aproteic group was almost four times the controls, suggesting an increased sensitivity in pituitary response to GnRH in rats fed with AP diet. In female castrated rats, the aproteic diet imposed 3 weeks after the surgery was unable to reduce basal gonadotropin secretion, and so also prolactin secretion. Estradiol/progesterone (EP) administration produced the activation of positive feedback mechanism, increasing significantly LH and FSH secretion in both controls and AP groups. Nevertheless, both gonadotropin responses to EP were significantly greater in rats fed with AP diet. Basal prolactin levels and response to EP were not different between both groups. This results suggest that selective protein lack in a diet, reduced pituitary LH and FSH synthesis and secretion. This type of diet also increments pituitary sensitivity to GnRH administration in male rats, and gonadotropin response to positive feedback mechanism in female rats.     

Age-related adaptation of pituitary-adrenocortical responses to stress

It has been reported that aged rats show impaired feedback regulatory control of pituitary adrenocorticotropic hormone release by adrenal glucocorticoids, yet, show no age-related deficit in eliciting an adrenocortical stress response when compared to younger animals. However, the effects of age on the capacity of the pituitary-adrenocortical system to adapt from an acute to a chronic stress situation have not been fully resolved. In the present study, groups of 6-month-old (young) and 22-month-old (old) F-344 rats were sacrificed at various times during the 1st (day 1) and 3rd (day 3) acute exposure to a two-way electric shock-escape stress procedure and subsequently during the 28th (day 28) and 56th (day 56) chronic exposure. Determinations of stress-induced corticosterone and adrenocorticotropic hormone responses indicated that: (1) adrenocortical responses were similar between young and old rats on the first stress exposure, whereas by the third stress session corticosterone responses were higher in young than in old rats; (2) attenuation of pituitary-adrenal responses to chronic stress was less in old compared to young rats, and (3) environmental factors may delay the development of age-related physiological alterations in the pituitary-adrenocortical system.     

Prolactin stimulation test with perphenazine: an evaluation of plasma prolactin levels and pituitary secretory activity in the rat.

Many investigations of the regulation of prolactin synthesis and release are based on single plasma prolactin determinations. The purpose of the present experiment was to ascertain whether groups of rats (i.e. young or adult, male or female animals, being either intact, gonadectomized or gonadectomized and treated with oestrone), differing in age and/or endocrine status, will react to a single dose of perphenazine by an acute release of pituitary prolactin in proportion to their initial plasma prolactin levels. No consistent relation existed between the classification of the twelve groups of rats into three categories of basal plasma prolactin levels (i.e. less than 20, 25-50, greater than 125 ng/ml) and their response to perphenazine. Even though all groups showed a highly significant increase of plasma prolactin levels the magnitude of the maximum prolactin response at 30 min varied greatly within the groups of one category and thus was not related to the initial prolactin levels. The effect of 14 days of oestrone treatment in increasing plasma prolactin levels in gonadectomized animals was greatest in young and adult male rats, less in young females and not significant in adult females. The results obtained after perphenazine treatment in the latter group made it clear that the effect of oestrogen treatment on prolactin release can be completely blocked by increasing synthesis and/or release of the prolactin-release inhibiting factor (PIF). Since perphenazine induces decrease of pituitary prolactin and a concomitant increase of plasma prolactin levels through lowered PIF-action, the positive effect of oestrogens on prolactin release (as observed in gonadectomized male and young female rats) apparently is caused by a different mode of action. The implications of these findings for the regulation of prolactin release, as affected by the endocrine status of the rat, is discussed. Moreover, comparison of prolactin lost from the pituitary and gained in the circulation of the experimental animals, with amounts of prolactin that were observed to disappear from plasma during the experiment, provided suggestive evidence that the capacity to synthesize and/or eliminate prolactin, after a sudden provoked release of the hormone, differed among the groups. The rates of synthesis by the pituitary, of release from the pituitary into the circulation as well as of elimination of the hormone from the circulation (equally involved in determing actual plasma levels) are thought, therefore, to be far more important for the elucidation of prolactin regulation than single plasma prolactin determinations.     

Naltrexone does not reverse the inhibitory effect of chronic restraint on gonadotropin secretion in the intact male rat.

There is considerable evidence suggesting that endogenous opioids may play an important role in acute stress-induced decreases in luteinizing hormone (LH) release. Studies were undertaken to analyze the role of endogenous opioids in chronic stress-induced decrease in circulating LH and follicle-stimulating hormone (FSH). Chronic restraint (6 h daily over 4 days) evoked a decrease in circulating LH and FSH. Naltrexone treatment, (2 mg/kg three times daily) during the 4 days of restraint, caused an increase in plasma concentrations of LH and FSH, and antagonized the LH suppressory effect of morphine (10 mg/kg) administration. Despite this, naltrexone treatment was ineffective in preventing the inhibitory effect of chronic restraint stress on circulating LH and FSH. Chronic restraint also induced a decrease in hypothalamic LH-releasing hormone (LHRH) content in saline-treated rats. On the contrary, in naltrexone-treated rats, chronic restraint evoked an increase in hypothalamic LHRH content. Thus endogenous opioids and chronic stress seem to act by different mechanisms on the hypothalamic LHRH neuron. In unstressed orchidectomized rats, naltrexone administration did not modify circulating LH, but increased plasma concentrations of LH in acutely restrained rats. These data suggest that endogenous opioids may mediate gonadotropin secretion during acute stress, but not during chronic stress.     

Possible role of dopamine in changes in LH and prolactin concentrations after experimentally induced hyperprolactinaemia in rats

Nine-month-old female rats bearing an ectopic pituitary gland (from a litter-mate) under the right kidney capsule since day 30 of life and their sham-operated controls, were treated with a dopamine agonist (lysuride) or antagonist (metoclopramide). Plasma prolactin and LH levels were measured by double-antibody radioimmunoassays. Vaginal smears were taken before and during the treatment periods. Eight months after the operation, a significant (P less than 0.01) increase in basal prolactin levels together with a significant (P less than 0.05) reduction in LH values and permanent dioestrus occurred in the grafted animals when compared with controls. Lysuride treatment resulted in a marked reduction in plasma prolactin levels both in control and grafted rats over the whole 12 days of treatment, together with a partial restoration of plasma LH levels on day 1. From day 7 onwards a depression in LH values was again observed. Oestrous cycles were partially restored at the beginning of the treatment, but after 7 days dioestrus returned. Metoclopramide administration induced a significant (P less than 0.001) increase in basal prolactin levels in both grafted and control rats. Basal plasma LH values were unaffected in controls when compared with vehicle-treated animals. An increase could be seen in hyperprolactinaemic rats after 7 or 12 days of treatment however. The LH response to the administration of LH releasing hormone (LHRH) was greater in the experimental and control metoclopramide-treated rats when compared with vehicle-treated rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Paradoxical LH and prolactin responses to naloxone after chronic treatment with morphine

A series of experiments was conducted in adult male rats to study the development of tolerance to and dependence on morphine in the neural processes controlling LH and prolactin secretion. The central mechanisms controlling both these hormones became tolerant following chronic application of the opiate agonist; this was seen in the form of diminished responsiveness to the agonist with time. There was an apparently greater degree of tolerance in the mechanisms regulating LH secretion than in those regulating prolactin secretion. In parallel experiments, the opiate antagonist naloxone was used to test for the development of dependence in rats chronically treated with morphine. While behavioural signs of physical dependence (withdrawal) were evident, the LH and prolactin responses proved to be the same as those observed in response to acute administration of opiate agonists (i.e. naloxone respectively decreased and increased serum LH and prolactin concentrations in animals chronically treated with morphine). This paper may represent the first report of such paradoxical responses to naloxone. It also demonstrates that opioid tolerance and dependence may exist as two separate phenomena in vivo.     

Restraint stress modulates brain, pituitary and adrenal expression of angiotensin II AT(1A), AT(1B) and AT(2) receptors

Angiotensin II (Ang II) AT(1) receptors are involved in the regulation of the stress response. In adult male rats, acute restraint increased AT(1A) mRNA in paraventricular nucleus. Repeated restraint increased AT(1A) mRNA and AT(1) binding in paraventricular nucleus and AT(1) binding in subfornical organ and median eminence. AT(1B) and AT(2) receptors were not expressed in brain areas involved in the stress response. Acute restraint increased anterior pituitary AT(1A) mRNA and AT(1) binding and decreased AT(1B) mRNA. During repeated restraint, the increase in AT(1A) mRNA in the anterior pituitary was maintained, but AT(1B) mRNA and AT(1) binding returned to normal levels. In adrenal zona glomerulosa, AT(1B) mRNA, AT(1) binding, AT(2) mRNA and AT(2) binding decreased during acute restraint. Receptor mRNA and binding returned to normal after repeated stress, with the exception of rebound increase in adrenal zona glomerulosa AT(2) mRNA. In adrenal medulla, AT(1A) mRNA increased and AT(2) mRNA decreased during acute restraint. AT(1A) mRNA remained increased during repeated restraint, while alterations in AT(2) mRNA were no longer present. Expression of AT(1A), AT(1B) and AT(2) receptors in the hypothalamic-pituitary-adrenal axis is tissue specific and is different in acute and repeated stress. Increased brain, pituitary and adrenomedullary AT(1A) receptor expression correlates with hypothalamic-pituitary-adrenal axis stimulation, supporting the hypothesis of Ang II, through selective AT(1A) receptor stimulation, as an important determinant of the acute and repeated stress response. Decreased adrenal zona glomerulosa and anterior pituitary AT(1B) receptors during acute stress can be interpreted as compensatory to increased stimulation by Ang II. There may be additional roles for adrenal AT(2) receptors during acute stress, possibly related to interaction or cross-talk with AT(1) receptors.     

Regulation of pituitary gonadotropin-releasing hormone (GnRH) receptors by pulsatile GnRH in female rats: effects of estradiol and prolactin

GnRH has been shown to modulate the concentration of its own pituitary receptors (GnRH-R), and changes in GnRH-R during the rat estrous cycle may reflect changes in GnRH secretion. To examine the relationship between GnRH and GnRH-R in female rats, we measured GnRH-R and serum gonadotropin responses to pulsatile GnRH in restrained ovariectomized (OVX) and ovariectomized estradiol-implanted (OVX-E2) rats. In addition, we examined the effects of suppression of serum PRL. Pulsatile injections of GnRH (10-250 ng/pulse) given every 30 min for 24 or 48 h did not increase GnRH-R in OVX or OVX-E2 rats compared to that in saline controls (246 +/- 27 fmol/mg). Bromocriptine treatment (2 mg/day) had no effect on GnRH-R in OVX animals. In contrast, OVX-E2 rats treated with bromocriptine showed significantly increased GnRH-R (500 +/- 43 fmol/mg) in response to GnRH injections. When ovine PRL was administered to bromocriptine-treated OVX-E2 rats, the GnRH induced rise in GnRH-R was abolished. Gonadotropin responses to GnRH were not correlated with changes in GnRH-R. In OVX animals, LH was only elevated in response to 250-ng pulses of GnRH. In OVX-E2 animals, basal LH was increased by all doses of GnRH, and acute responses to 50- and 250-ng pulses were observed. Bromocriptine treatment resulted in increased LH sensitivity to GnRH in OVX rats, but did not further enhance the responses in OVX-E2 animals. We conclude that in female rats, the presence of both E2 and a low serum PRL level is necessary for GnRH to increase GnRH-R, and the interaction of these factors may be involved in the regulation of GnRH-R during the estrous cycle.