Effect of steroid hormones and antihormones on hypothalamic beta-endorphin concentrations in intact and castrated female rats

The aim of the present study was to evaluate the effects of estrogens and androgens on hypothalamic beta-endorphin (beta-EP) concentrations. Intact or castrated female rats were chronically (2 weeks) treated with estrogen (estradiol benzoate) and/or antiestrogens (clomiphene, cyclophenil or epimestrol), and with androgens (dihydrotestosterone or dehydroepiandrosterone sulphate) and/or antiandrogen (cyproterone acetate). A group of rats treated with vehicle were studied as comparison. The beta-EP concentrations were measured by radioimmunoassay on acidic extracts of rat hypothalami. The administration of clomiphene and cyclophenil significantly reduced hypothalamic beta-EP concentrations in intact rats, while both drugs or estradiol benzoate increased the peptide concentration in castrated rats. Both intact and castrated rats treated with epimestrol showed hypothalamic beta-EP concentrations higher than vehicle treated rats. The estradiol-induced increase of beta-EP was not changed by the concomitant administration of antiestrogens. The administration of dihydrotestosterone significantly decreased beta-EP concentrations in both intact and castrated female rats, while the treatment with dehydroepiandrosterone sulphate only slightly decreased beta-EP levels in intact female rats. The cyproterone acetate-chronically treated rats showed higher beta-EP concentrations than vehicle-treated rats and these changes were reversed by the concomitant addition of dihydrotestosterone or dehydroepiandrosterone sulphate. These results showed that estrogens play a positive role while androgens negatively influence the hypothalamic beta-EP concentrations in female rats, supporting the view that central beta-EP might be a target of gonadal steroid feedback signals.     

Sexual differentiation of positive feedback: effect of hour of castration at birth on estradiol-induced luteinizing hormone secretion in immature male rats

In the male rat, a dramatic increase in hypothalamic testosterone and estradiol concentrations occurs during the first few hours of postnatal life. These experiments sought to determine whether such increases participate in the defeminization of positive estrogen feedback effects on LH secretion. Newborn male rats were castrated either in utero (0 h males), or 10 or 24 h after birth. Some males were castrated at 0 h in utero and injected at the time of surgery with 1,2.5, or 5 micrograms testosterone propionate. A group of females was ovariectomized at 0 h in utero (0 h females). The control group consisted of male and female rats sham gonadectomized at 0 h in utero which were either gonadectomized at 21 days of age or left intact. The experimental groups were challenged before puberty to determine if estrogen induced a release of LH using two different types of estrogen treatment. The first treatment consisted of an injection of 0.2 microgram estradiol benzoate (EB) on day 28 followed by a second 10 micrograms injection of EB on day 29. This treatment resulted on the afternoon of day 30 in a surge of LH in intact females. Normal males, 0 h males, or females castrated at 21 days did not have a significant LH surge. The second test consisted of the daily injection of 0.05 microgram EB on days 23-27; on day 28 the rats were injected with 2.5 micrograms EB. Zero hour male and female rats showed a large LH surge on the afternoon of day 29; sham castrated males never responded to this treatment. No sex difference was observed in the mean size of the LH surge providing the males were castrated at 0 h in utero. The effect of the hour of castration on the day of birth also was studied. Males castrated at 10 or 24 h after birth showed either no LH surge or the magnitude of the surge was greatly reduced compared to that obtained in the 0 h males (P less than 0.001). The fact that 0 h males injected with 1 microgram testosterone propionate never showed an LH surge after prepuberal treatment with estrogen suggests that 0 h is a time during which the newborn is sensitive to the defeminizing effect of androgens. These results are consistent with the idea that the testicular hyperactivity which occurs at the time of birth could influence the defeminization of the LH surge mechanisms.     

Neonatal glucocorticoid administration: effect on the diurnal rhythm of serum concentrations of corticosterone, progesterone and LH, and the response to pregnant mare serum gonadotrophin in immature female rats

The effects of neonatal cortisol acetate administration on diurnal changes in serum corticosterone, progesterone and LH and on the response to pregnant mare serum gonadotrophin (PMSG) were examined in immature female rats. Neonatal cortisol treatment (250 micrograms/rat) abolished the diurnal rhythm of serum progesterone in rats at 27-29 days of age, and lowered overall the serum progesterone response to PMSG. Neonatal cortisol also reduced the number of animals ovulating on day 28 after PMSG injection 48 h earlier. This dosage of cortisol did not alter the diurnal rhythm of serum corticosterone in these animals. Serum LH concentrations in control rats at 27-29 days of age did not differ between 09.00 and 18.00 h, and prior treatment with cortisol acetate did not significantly influence serum concentrations of this hormone. Our data suggest that ovarian production of progesterone contributes significantly to diurnal fluctuations of this steroid in the circulation of immature rats. Perinatal exposure to cortisol acetate abolishes the diurnal rhythm of serum progesterone and impairs the ovarian response of the immature female rat to PMSG. The mechanism(s) by which cortisol acetate alters these processes remains to be determined.     

Orexin A and B levels in the hypothalamus of female rats: the effects of the estrous cycle and age

OBJECTIVE: Orexins have been implicated in the regulation of several physiological functions including reproduction, energy balance and vigilance state. For successful reproduction, the precisely timed hormonal secretions of the estrous cycle must be combined with appropriate nutritional and vigilance states. The steroid- and nutritional state-dependent modulation of LH release by orexins, as well as an increase of vigilance, suggest that orexins may co-ordinate these functions in the course of the estrous cycle. DESIGN: We studied the brain tissue levels of orexins in the course of the estrous cycle in young and middle-aged rats. Young cycling rats (3 months old) and irregularly/non-cycling (7-9 months old) female rats were inspected for vaginal smears and serum hormone levels. METHODS: Tissue concentrations of orexin A and B were measured in the hypothalamus and lateral hypothalamus on different days of the estrous cycle. RESULTS: Orexin A concentration in the hypothalamus of young cycling rats was higher on the day of proestrus 5-6 h after the lights were switched on than on the other days of the estrous cycle at the same circadian time. Orexin B concentration was higher on both the day of proestrus and the day of estrus as compared with the days of diestrus. The hypothalamic concentrations of both orexin A and B in the non-cycling middle-aged rats were lower than those in cycling rats on the days of proestrus and estrus. CONCLUSIONS: We have concluded that the high hypothalamic concentration of orexins on the day of proestrus may contribute to the LH and prolactin surges. High orexin A levels may also contribute to the decreased amount of sleep on the day of proestrus.     

Hypothalamic luteinizing hormone releasing factor and corticotrophin releasing activity in relation to pituitary and plasma hormone levels in male and female rats.

Hypothalamic corticotrophin releasing (CR) activity and LH-releasing factor (RF) content, and pituitary and plasma LH, FSH and ACTH were measured in adult male and female Wistar rats maintained under 14 h light per day. Hypothalamic LH-RF and pituitary and plasma hormones were estimated by radioimmunoassay while CR-activity was assessed by the amount of ACTH released from hemipituitaries in vitro. Two experiments were carried out on male animals. In the first, some of the animals were kept in a room, distant from the animal house, in which the lighting was reversed with respect to the external environment. In animals exposed to the reversed lighting regime, hypothalamic LH-RF content and pituitary gonadotrophin concentrations were significantly lower than the values in male rats kept in the animal house where they were in close proximity to female rats. In the second experiment, which was carried out on animals which had all been kept in the animal house, there was no significant differences between the LH-RF contents measured at 3-4 h intervals throughout the day. Pituitary LH and FSH contents, but not concentrations, were significantly increased at 12.00 h. There was little differences between the experiments in CR-activity, plasma ACTH concentrations and profiles of pituitary ACTH content and concentration. As expected there was a diurnal rhythm in plasma corticosterone concentrations (determined by competitive protein-binding assay) with the peak occurring between 15.00 and 18.00 h. The profiles of plasma and pituitary ACTH were similar to that of plasma corticosterone. Corticotrophin releasing activity dropped significantly between 12.00 and 16.00 h, but remained steady at the other times. In female rats there were no significant differences between hypothalamic LH-RF content throughout the 4-day cycle. During pro-oestrus the mean LH-RF content rose to teach a high level at 18.00 h at which time plasma LH concentration had risen sharply to a level consistent with the peak of the preovulatory surge. Plasma FSH concentration also rose significantly between 15.00 and 18.00 h of pro-oestrus. At metoestrus and dioestrus, plasma FSH levels were lower in the morning than in the evening. These results suggest that (1) there is no diurnal rhythm in hypothalamic LH-RF, (2) there may be a diurnal rhythm in pituitary gonadotrophin content in the male and in plasma FSH concentration on the days of metoestrus and dioestrus in the female, (3) if a surge of LH-RF does occur on the afternoon of pro-oestrus, the rate of LH-RF synthesis exceeds its release, and (4) the mechanism which regulates gonadotrophin secretion in the male may be affected by factors in the environment other than daylength. The results provide further evidence for the view that the diurnal rhythm of corticosterone secretion is under hypothalamo-hypophysial control.     

The hypothalamic-pituitary axis of streptozotocin-induced diabetic female rats is not normalized by estradiol replacement

Studies in diabetic rats have found abnormalities at the hypothalamic, pituitary, and/or ovarian level but have not controlled for changes in estrogen levels induced by diabetes. The purpose of this investigation was to study the effect of diabetes on the hypothalamic-pituitary axis in ovariectomized rats treated with estradiol (E2). Ovariectomized 60 day old female rats were assigned to control (C, n = 42), diabetic (D, n = 47) or insulin-treated diabetic (DI, n = 16) groups. Diabetes was induced with an injection of streptozotocin in the D and DI groups. In the C, D, and DI groups, estrogen was replaced by implanting blank, 5 micrograms or 20 micrograms E2 pellets sc. Pituitary LH responsiveness to GnRH was assessed in C and D animals. Anterior hypothalamic and midhypothalamic concentrations of proGnRH and GnRH, pituitary LH and FSH and serum levels of LH, and E2 were measured by RIA. Anterior hypothalamic proGnRH concentrations were decreased in diabetic rats treated with 5 micrograms E2 compared to 5 micrograms E2 control animals (P less than 0.05). Midhypothalamic GnRH concentrations were also reduced in D vs. C animals despite comparable estrogen therapy (P less than 0.004). GnRH-stimulated LH levels were greater in E2-treated diabetic females than in similarly treated control rats (P less than 0.001). D and DI animals were more sensitive than controls to the inhibitory effect of estrogen on basal LH levels. Pituitary LH and FSH content was lower in 20 micrograms E2-replaced animals but was not influenced by the diabetic state. These data demonstrate a diabetes-induced decrease in hypothalamic proGnRH and GnRH concentration which is not corrected with E2 replacement. The hyper-responsiveness of the diabetic rat pituitary to GnRH also suggests a chronic lack of GnRH stimulation from the hypothalamus but a continued ability of the pituitary to respond to GnRH.     

Inhibition of estrous behavior by progesterone in rats: role of neural estrogen and progestin receptors

Sexual receptivity can be induced in ovariectomized rats with sequential injections of 17 beta-estradiol-3-benzoate (EB; 2 micrograms sc) and progesterone given 24 h apart. If a high dose of progesterone is used, estrous behavior is followed by a period during which sexual receptivity cannot be reinduced with a second progesterone injection (sequential inhibition). We have examined the effects of a hormone treatment which causes a sequential inhibition on levels of estrogen and progestin receptors in the hypothalamus-preoptic area-septum of ovariectomized rats. In a preliminary experiment, a single injection of 2 micrograms EB caused a significant increase in the concentration of brain cell nuclear estrogen receptors, Peak levels were seen at 12-24 h and remained significantly elevated as long as 72 h after EB. In a second experiment, we found that 48 h after EB, brain cytoplasmic estrogen receptors were significantly depressed and nuclear estrogen receptors were significantly elevated. However, a single progesterone injection (5 mg, sc) 24 h after EB had no significant effect on either cytoplasmic or nuclear estrogen receptor levels. Forty-eight hours after EB, brain cytoplasmic progestin receptors were significantly elevated compared with oil-injected controls. In a third experiment, progesterone (5 mg, sc) given 24 h after EB reduced neural cytoplasmic progestin receptors to levels significantly below those of oil-injected controls at 48 h. These results are consistent with the suggestion that progesterone does not interact with neural estrogen receptors to inhibit lordosis in rats. Rather, we suggest that progesterone may induce a behavioral refractoriness to subsequent progesterone treatments, at least in part, by reducing the concentration of neural cytoplasmic progestin receptors.     

The role of the ventrolateral part of the medulla oblongata in the control of gonadotropin secretion. II. The effect of ovarian steroid implantation into the ventrolateral part of the medulla oblongata on LH secretion in the female rat

To investigate whether neurons in the ventrolateral part of the medulla oblongata (VLMO) are sensitive to ovarian steroid, estradiol benzoate (EB) or progesterone (Prog.) was implanted through a stainless steel double cannula into the VLMO of ovariectomized, EB-primed rats and serum LH was measured. Two weeks after ovariectomy, rats were primed with 20 micrograms EB at 1200h and this day was arbitrarily defined as day 0. At 1200h on day 3, powdery steroid, EB or Prog., was unilaterally implanted into the VLMO. Implantation of EB into the VLMO was effective in increasing serum LH at 1600, 1800 and 2000h on days 3 and 4, but the serum LH concentration at 1600, 1800 and 2000h was much more increased on day 4 than on day 3. Implantation of Prog. into the VLMO failed to induce a significant increase in serum LH on days 3 and 4. To further investigate the effects of anterolateral hypothalamic (ALH) transection and complete spinal transection at T4-T7 levels on EB implantation into the VLMO was examined. It has been shown that both ALH transection and spinal transection at high thoracic levels (T4-T7) significantly blocked proestrous gonadotropin surges and ovulation. In rats with ALH transection, EB implantation into the VLMO was not effective in increasing serum LH at 1600, 1800 and 2000h on days 3 and 4, but in rats with complete spinal transection, EB implantation into the VLMO was effective in increasing serum LH at 1800 and 2000h on days 3 and 4. These results suggest that EB exerts its stimulatory feedback action on the VLMO and the anterolateral hypothalamic area is involved in the mechanism of this stimulatory feedback action of EB.     

Effects of red dim illumination and surgery on prolactin secretion during the estrous cycle and early pseudopregnancy in the rat: different regulatory mechanisms for prolactin secretion

The effects of surgery and red light on prolactin (Prl) secretion were investigated in cycling and in pseudopregnant (PSP) rats. Secretion patterns of Prl were determined at hourly intervals from 07.00 to 22.00 h. Different regulatory mechanisms for Prl secretion were hypothesized for three time periods: a nocturnal (07.00-11.00 h), a prediurnal (14.00-17.00 h), and a diurnal (19.00-22.00 h) period. The results demonstrate that red light can affect significantly Prl secretion, in particular nocturnal and prediurnal Prl secretion in estrous, diestrous day 1 and PSP rats. The effect of surgery varied with the time of the day and was dependent upon whether the animals, during the dark period, were maintained under full darkness or constant red dim illumination. In PSP rats the regulation of Prl secretion was different for the three time periods. In PSP day 0 rats there was a prediurnal surge of Prl secretion, comparable in timing and regulation to a prediurnal surge in estrous rats. This prediurnal surge was not evident on the other days of PSP. The regulation of nocturnal as well as diurnal Prl secretion was similar in PSP rats, but differed from cycling rats. The afternoon surge of Prl secretion on proestrus lasted the full afternoon and was basically one surge, distinct from all other surges. In diestrous rats Prl levels were low but showed a circadian variation. In summary, the effects of red light and surgery on Prl secretion varied with the physiological state and with the time of the day, indicating that the regulation of Prl secretion is complex and multimodal in nature.     

Steroid regulation of the synthesis and secretion of retinol-binding protein by the uterus of the pig.

The endometrium of the pig secretes retinol-binding protein (RBP) under the influence of progesterone (P4). The objective of this study was to determine how conceptus-derived estrogen might modulate this production of RBP around days 11-13 of pregnancy when conceptuses elongate from spheres to long thread-like forms. Concentrations of retinol and RBP were low (35 +/- 7 ng/ml) in uterine flushings obtained on days 10-12 of the estrous cycle or from pregnant gilts in which conceptuses had not elongated. Concentrations of retinol and RBP increased 7- to 8-fold (P less than 0.01) in flushings where filamentous conceptuses were present. Size exclusion and ion exchange chromatography demonstrated that virtually all retinol assayed in uterine flushings was associated with RBP. Northern blot analysis with a cDNA representing uterine RBP revealed a single endometrial mRNA 1.1 kilobases in length. Expression of RBP mRNA in uterine endometrium was measured in ovariectomized prepubertal gilts after the administration of steroids according to the following regimens: I, corn oil (days 0-16; n = 10); II, estradiol benzoate (EB; days 13-14; n = 11); III, EB (days 1-2; n = 12); IV, EB (days 1-2) plus P4 (days 3-16; n = 12); and V, EB (days 1-2) plus P4 (days 3-16) plus EB (days 13-14; n = 12). EB (200 micrograms) and P4 (100 mg) were administered twice daily. Treatment IV was designed to stimulate the estrous cycle, and treatment V simulated early pregnancy. All gilts were hysterectomized on day 16, and total uterine mRNA (3 micrograms) was analyzed by Northern blotting. No RBP mRNA was detected in groups I, II, or III. In group IV, 5 of 12 gilts had detectable RBP mRNA, as measured by densitometric scanning (OD = 0.35 +/- 0.14). RNA isolated from all gilts in group V (12 of 12) gave a strong hybridization signal (OD = 1.58 +/- 0.22) for RBP. Finally, RBP mRNA was examined in the uterine endometrium of mature gilts on day 13 of the estrous cycle (n = 4), day 13 of pseudopregnancy (2.5 mg EB given on days 11-12; n = 4), or day 13 of pregnancy after conceptuses had elongated (n = 4). RBP mRNA was present in all groups, but was enhanced approximately 12-fold (P less than 0.01) in pregnant and pseudopregnant gilts compared to that in control gilts.(ABSTRACT TRUNCATED AT 400 WORDS)     

Endocrine aspects of early pregnancy in pony mares: a comparison of uterine luminal and peripheral plasma levels of steroids during the estrous cycle and early pregnancy

Comparisons of estrone, 17 beta-estradiol, and plasma progestin concentrations were made in uterine fluid and peripheral blood of nonpregnant and pregnant pony mares. Concentrations of these steroids were also measured within yolk sac fluid from blastocysts on days 12, 14, 16, and 18 of pregnancy to obtain more complete analyses of the uterine environment (uterine fluid plus yolk sac fluid) of early pregnancy. Thirty mares were randomly assigned to six treatment groups (n = 5/group), and uterine fluid and peripheral blood samples were obtained on days 8, 12, 14, 16, 18, and 20 postovulation. After a recovery period of one estrous cycle, mares were bred at their next estrus. Animals were hysterectomized on the same treatment day to which they had previously been assigned in the nonpregnant phase of this study. Using this design, uterine fluid and peripheral blood samples were collected from each mare on equivalent days of the estrous cycle and pregnancy. Significant differences in day trends were found between nonpregnant and pregnant animals for estrogens and progestins in both uterine fluid and peripheral plasma. Furthermore, these data demonstrate that large increases in estrogens occur after day 12 of pregnancy in uterine and yolk sac fluids, with estrone becoming the predominant estrogen by days 18 and 20 in yolk sac and uterine fluids, respectively. These changes were not detected in peripheral plasma, which indicates that changes occurring within the uterine environment are not discernible in the systemic circulation during early pregnancy. These results indicate that the large amounts of estrogens appearing in uterine fluids during early pregnancy are of conceptus origin and may be an important factor in regulating the environment in which the conceptus develops.     

Abolition of prolactin surge induced by ovarian steroid hormones in the lactating rat.

There are data indicating that stress-induced prolactin (PRL) release is blunted in the lactating rat like the release of other stress-associated hormones. In this experiment, the PRL release evoked by administration of estrogen, which is another principal stimulus for PRL release, was examined in ovariectomized lactating rats 8-15 days after delivery. Estradiol benzoate (EB, 20 micrograms) injections into ovariectomized nonlactating rats induced a PRL surge starting between 13:00 and 15:00 h with a peak at 17:00 h 2 days after the treatment, whereas the EB-induced PRL surge was absent in ovariectomized lactating rats separated from their pups at 09:00 h on the day or in mothers without separation from their pups. Injection of either thyrotropin-releasing hormone (TRH; 10 micrograms/kg) or pimozide (0.5 mg/kg) elevated serum PRL concentrations similarly in lactating and nonlactating rats when examined just before the beginning of the expected estrogen-induced PRL surge. Thus, the main cause for the reduced PRL response to estrogen in lactating rats seems not to be in the pituitary gland but in the brain. Progesterone, which is known to induce a PRL surge in ovariectomized estrogen-primed rats by acting on the mediobasal hypothalamus, also failed to evoke a PRL surge in lactating rats. Recovery from the inhibitory influence of suckling on PRL response to EB followed a time course similar to that observed in response to immobilization stress or to morphine injection; estrogen-induced PRL surge started to recover at 6 days and was almost fully recovered 8 days after weaning.(ABSTRACT TRUNCATED AT 250 WORDS)     

Organizational effects of testosterone via aromatization on feminine reproductive behavior and neural progestin receptors in rat brain

The present studies were undertaken to determine whether estrogenic actions of testosterone during development govern the apparently irreversible suppression of feminine reproductive behavior in the male and lead to a suppression of the capacity of the ventromedial nucleus (VMN) of the hypothalamus to produce cytosol progestin receptors (CPRs) in response to estrogen priming. Timed-pregnant female rats received daily injections of the aromatase inhibitor 1,4,6-androstatriene-3,17-dione (ATD; 5 mg/0.2 ml) from the 14th day of pregnancy until parturition. Males exposed to ATD in utero received Silastic capsules containing ATD for the first 10 days of life. Some females from litters not exposed to ATD received injections of estradiol benzoate (EB; 10 micrograms) 6-12 h and 3 days after birth. The remaining pups not exposed to ATD served as controls. Pups were gonadectomized on days 60-70 and were tested for feminine reproductive behavior or killed for CPR measurements on days 85-90. To elicit behavior, animals received daily injections of EB (15 micrograms for 3 days) and one injection of progesterone (500 micrograms) 4 h before testing. To induce CPRs, animals received EB but not progesterone. Significantly less receptive and proceptive behavior was observed in males and females given perinatal EB than in normal females and males given perinatal ATD. The CPR content of the VMN in males was similar to that in females given perinatal EB and significantly less than that in normal females and males given perinatal ATD. Neonatal hormonal manipulation did not alter the CPR content of other hypothalamic or preoptic nuclei. These findings are consistent with the hypothesis that one event mediated by estradiol which underlies activation of feminine reproductive behavior is the induction of CPRs in the VMN. This capacity is apparently restricted by estrogen-mediated events in males during the perinatal period.     

Dissociation of prolactin secretion from tuberoinfundibular dopamine activity in late pregnant rats

This study investigated whether the PRL surge that precedes parturition is accompanied by a decrease in activity of hypothalamic tuberoinfundibular dopamine (TIDA) neurons, as occurs during the PRL surges of early pregnancy. Serial blood samples were collected at regular intervals during early and late pregnancy via chronic indwelling jugular cannulae, and concentrations of plasma PRL were determined by RIA. In addition, pregnant rats were killed at either 1200 and 0300 h on different days throughout pregnancy. Levels of TIDA neuronal activity were estimated using concentrations of 3,4-dihydroxyphenylacetic acid (DOPAC) in the median eminence as an index of dopamine metabolism. During early pregnancy, plasma PRL concentrations showed characteristic diurnal and nocturnal surges peaking at 1700 and 0300 h, respectively, whereas during late pregnancy, there was a broad nocturnal surge throughout the night preceding parturition. During early pregnancy, DOPAC was elevated at 1200 h, associated with suppressed plasma PRL, whereas at 0300 h, during the nocturnal PRL surge, DOPAC was significantly reduced (P < 0.05). On the last day of pregnancy DOPAC levels were significantly reduced at both 1200 and 0300 h compared with those at 1200 h in early pregnancy regardless of the PRL concentration. This experiment was repeated with additional groups to further characterize the timing of the fall in TIDA activity during late pregnancy. DOPAC concentrations were elevated throughout the second half of pregnancy, then fell significantly between 0300-1200 h on day 21, approximately 36 h before parturition. As in the previous experiment, the timing of changes in DOPAC concentrations in the median eminence was dissociated from the antepartum PRL surge. These data indicate that the regulation of PRL secretion during late pregnancy is different from that of early pregnancy. Despite the prolonged reduction in activity of TIDA neurons during late pregnancy, PRL secretion still occurs as a nocturnal surge, suggesting that dopamine is not the only regulator of PRL secretion at this time.     

Estrogen exposure affects the post-ovariectomy increases in both LH and FSH release in female rats

In female rats ovariectomy (OVX) on the morning of diestrus day 2 resulted in a prompt (within 8 h) and gradual increase in LH release, whereas a similar operation on estrus did not raise serum LH until 24 h later. In proestrous females, OVX in the morning neither prevented the anticipated LH surge on that evening, nor increased LH release on the next morning. Since circulating concentrations of estradiol (E2) are progressively increased during diestrus day 2 and proestrus, this pattern of E2 secretion may affect the acute increase in LH secretion following OVX. To test such a hypothesis, we examined the effects of large, sustained or large, transient increases in circulating estrogen on the subsequent increase in gonadotropin secretion after OVX. On the morning of diestrus day 1 a subcutaneous injection of 20 micrograms estradiol benzoate (EB) produced prompt and large increases in both serum E2 and estrone (E1) for about 2 days, despite OVX of females at 24 h after the EB injection. An injection of 20 micrograms 17 beta-estradiol (E2) also promptly increased both serum E2 and E1. micrograms E2 injection were twice that observed after 20 micrograms EB, and both E2 and E1 returned to low baseline values within 24 h after the E2 injection. In contrast, administration of 1 microgram EB only produced small and transient rises in serum E2 and E1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ontogeny of nyctohemeral variations of thyrotropin-releasing hormone in rat hypothalamus

The ontogeny of nyctohemeral variations of hypothalamic TRH content was determined in male rats from 7-45 days after birth, exposed to a daily 12-h light, 12-h dark cycle (0600-1800 h light; 1800-0600 h dark) or maintained in complete darkness until 45 days. TRH was extracted from whole hypothalami with 90% methanol and assayed by specific RIA. Hypothalamic TRH extracted from rats at different ages showed immunological, chromatographic, and biological properties identical to those of synthetic TRH. No significant variations in hypothalamic TRH content during the day were observed in 7-, 10-, and 17-day-old rats; a significant change, with a maximal value at 1800 h, was observed in 23-day-old rats, while an adult pattern with a maximal value at 1200 h and a minimal value at 2400 h was found in rats of 31 days of age and became more evident in 45-day-old rats. In animals maintained in complete darkness for 45 days after birth, no significant changes in hypothalamic TRH content at 1200 and 2400 h were observed. These findings indicate that environmental cyclic light-dark exposure is required for the development of diurnal changes in hypothalamic TRH content. Furthermore, any study involving hypothalamic TRH determination should take into account the age of animals and the diurnal variations of TRH.     

Developmental changes in luteinizing hormone secretion in the female guinea pig. II. Positive feedback effects of ovarian steroids

Developmental changes in the positive feedback effects of ovarian steroids on LH release in female guinea pigs were studied. Administration of estradiol benzoate (EB; 10 micrograms) to intact females on day 30 of age (prepubertal) elicited a LH surge in only 1 of 14 instances. However, by day 46 of age (peripubertal), EB induced a sharp rise in serum LH concentrations in 9 of 12 females. The magnitude and timing of the LH surge in these peripubertal animals were similar to those in cycling adults given EB on day 13 of the estrous cycle. Progesterone (P; 1.0 mg) administration to intact females 30 h after a priming dose (1.5 microgram) of EB was also effective in eliciting a LH surge on day 46, but not on day 30, of age. The magnitude of the P-induced LH surge was significantly greater (P less than 0.001) than that of the EB-induced LH surge on day 46 of age. Pentobarbital anesthesia delayed, but did not prevent, the EB-induced LH surge in peripubertal females, while it completely abolished the P-induced LH surge. These results suggest that ovarian steroids can stimulate LH release in the immature female guinea pig, but not until an age approaching the normal time of the first ovulation. Those observations together with results presented in a preceding paper suggest that establishment of the positive feedback system between days 30 and 46 of age is associated with an increased capacity of the hypothalamic-pituitary axis to stimulate LH release; such developmental changes may represent the major events leading to the onset of puberty in the female guinea pig.     

Correlation of luteinizing hormone surges with estrogen nuclear and progestin cytosol receptors in the hypothalamus and pituitary gland. II. Temporal estradiol effects

In these studies we examined the temporal parameters of estradiol (E2) priming required before progesterone (P4) amplifies the surge release of luteinizing hormone (LH) in short-term ovariectomized (OVX) rats. Thereafter, we correlated the time of appearance and concentrations of estrogen nuclear (E2Rn) and progestin cytosol (PRc) receptors in brain regions known to be involved in the surge release of LHRH. Steroid receptor concentrations were also measured in the pituitary gland. 1 week after OVX (day 0), Silastic capsules containing E2 (150 micrograms/ml in oil s.c.) were placed at 09.00 h. The serum E2 concentrations produced by these capsules peaked (41 +/- 2.1 pg/ml) at 10.00 h on day 0 and declined thereafter to values which ranged between 19 and 10 pg/ml on days 1 through 4. Some of these E2-treated rats also received 2 P4-containing Silastic capsules (50 mg/ml s.c. in oil) at 09.00 h on either days 0, 1, 2, 3 or 4. Serum P4 concentrations produced by such capsules were 9.3 +/- 0.5 ng/ml. Blood was collected sequentially at 09.00 h and at hourly intervals from 12.00-18.00 h on the day that the animals received the P4 capsules and 10.00 and 15.00 h samples also were taken from each group the next day. LH surges occurred in these E2-treated rats in the afternoons of days 2-4, but not on days 0 and 1. P4 treatment on day 1 elicited an LH surge and on days 2-4 it amplified plasma LH surge concentrations and advanced by 1 h the time of release of this gonadotropin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oestrous cycle-related LH responsiveness to naloxone: effect of high oestrogen levels on the activity of opioid receptors

Endogenous opioid peptides have a tonic inhibitory control on LH secretion, participating in the functional changes of the hypothalamic-pituitary-ovarian axis. To evaluate the activity of the endogenous opioid systems during the oestrous cycle, we measured plasma LH levels after naloxone administration (5 mg/kg, s.c.) at 09.00 and 16.00 h on all days of the cycle (two further measurements were taken at 14.00 and 18.00 h on the day of pro-oestrus) and after one dose or one week's treatment with oestradiol benzoate (OB; 0.2 micrograms/rat). Concentrations of LH were measured in the same experimental models after injection of LH-releasing hormone (LHRH; 1 microgram/kg, i.p.) or saline. Naloxone induced a significant rise in LH levels on the day of oestrus, dioestrus day-1 and dioestrus day-2; this response was blunted on the morning of pro-oestrus and absent in the afternoon and after acute and chronic OB treatment. Conversely LHRH was most effective in increasing LH levels on the day of pro-oestrus and in OB-treated rats. These results indicate that opioid mechanisms, independently of the time of day and the pituitary responsiveness, exhibit a reduced activity when preovulatory changes occur, probably as a result of increased oestrogen levels.     

Effect of estrogen on the growth hormone (GH) secretory response to GH-releasing factor in the castrate adult female rat in vivo

Five groups (n = 11) of 250-g female rats were oophorectomized and immediately thereafter received daily sc injections of estradiol benzoate (EB; 0.05, 0.5, 5.0, and 50.0 micrograms) or vehicle for 28 days. A sixth group underwent sham operation and received injections of vehicle. Somatomedin-C (SmC) concentrations were determined before EB administration. After 4 weeks of EB treatment, the GH response to human GH-releasing factor (1-44) (GRF; 5 micrograms/kg, iv) was determined under pentobarbital anesthesia in seven animals from each group. Serum PRL, LH, and estradiol and plasma SmC concentrations were also measured. The GH secretory response to GRF (delta GH) was greatest in castrated animals receiving vehicle (P less than 0.05) and was significantly blunted in animals receiving 5.0 and 50.0 micrograms EB (P less than 0.05) compared to that in sham-operated animals. A significant negative correlation was observed between delta GH and serum PRL concentrations (r = -0.53; P less than 0.0001). SmC concentrations after treatment were significantly lower in animals receiving 5.0 and 50.0 micrograms EB (P less than 0.01), than in sham-operated animals and were elevated compared to those in sham-operated controls in the group receiving the lowest dose of EB (0.05 microgram; P less than 0.01). Posttreatment SmC levels correlated positively with delta GH (r = 0.58; P less than 0.001) and negatively with serum estradiol concentrations (r = -0.47; P less than 0.01). Pituitary glands from the remaining animals in each group (n = 4) were weighed and assayed for GH, PRL, and LH content. Pituitary PRL content increased with increasing doses of EB replacement and correlated strongly (r = 0.82; P less than 0.0001) with pituitary weight. In the castrated adult female rat, high doses of estrogen inhibited the GH secretory response to GRF in vivo and decreased SmC concentrations. Low dose estrogen increased SmC concentrations, although the GH secretary response to GRF in this group was similar to that in sham-operated rats. The latter observation suggests that the rise in SmC levels associated with low dose estrogen may not be mediated through a change in GH secretion.