An acute increase in serum prolactin does not modify gonadotropin release in female rats

Attempts were made to find out whether hyperprolactinemia has an effect on the hypothalamo-pituitary response to estrogen feedback and LHRH stimulation. Adult female rats of Wistar strain were ovariectomized and received subcutaneous injection of 20 micrograms estradiol benzoate (EB) 3-4 weeks later (day-0). A second injection of 20 micrograms EB, when administered at noon on day-3, induced a highly significant increase in serum LH (p less than 0.001 vs. basal values), but not FSH, estimated at 1800 h on the same day. This EB-promoted LH release was not altered by pretreatment with rat PRL (5 micrograms/day), which was administered subcutaneously daily in the morning (1100 h) between day-1 and day-3. No statistical difference in the serum LH concentration was found when compared with the values for the control animals pretreated with 0.9% saline alone. Serum gonadotropins 15 min after LHRH administration (100 ng/100 g BW) in 32-day-old female rats were not statistically different between the animals pretreated with 5 micrograms PRL, which was given subcutaneously daily (at 0800 h) for 3 days, and the controls pretreated with 0.9% saline. These results suggest that an acute increase in serum PRL may not exert a negative effect on the gonadotropin release induced by estrogen feedback and LHRH stimulation.     

Prenatal melatonin exposure influences the maturation of gonadotropin and prolactin estradiol-benzoate feedback system.

Gonadotropin and prolactin response to estrogen feedback in female rat offspring of control and melatonin treated (150 microg/100 g BW) mother rats during pregnancy (MEL-offspring) were studied at these periods: infantile, prepubertal and pubertal. In controls negative or absent LH feedback developed after estradiol benzoate (EB) injection up to 30 days of age indicating that the onset of puberty had not occurred. The positive feedback was established from day 33 on. However, in MEL-offspring the first activation of gonadotropin secretion during afternoon, 31 h after EB, was observed at 25 days of age, representing the first neuroendocrine sign of the onset of puberty. This positive response disappeared on day 30 in MEL-offspring. At 33 days of age, the LH positive response to EB was found in both groups, indicating a more advanced sexual development. In controls, this response increased at 35 days of age while in MEL-offspring it was highly depressed. FSH secretion in response to EB showed a negative feedback effect from infantile to the end of prepubertal period in both groups. The positive feedback was observed earlier in MEL-offspring (at 33 days of age) than in controls (at 35 days of age), but at this age it was absent in MEL-offspring. A positive prolactin response to EB at all ages in controls was observed. The typical pulsatility with higher values in the afternoon appeared by the first time at 30 days of age. However, in MEL-offspring no pulsatile response was observed throughout any age. These data suggest that prenatal melatonin administration altered gonadotropin and prolactin response to EB inducing precocious sensitivity during prepubertal period but depressed response during the pubertal period.     

Effects of castration of immature rats on serum FSH and LH, and of various steroid treatments after castration

The intricate relationship between the gonads and pituitary gonadotropin secretion has been studied in the immature, 26-day-old rat. In male rats or chidectomized at this age, serum LH and FSH rose to significantly higher levels at 8 hours postcastration. A much later response was seen in ovariectomized females: at 24 hours and 48 hours for FSH and LH respectively. When groups of rats castrated at 26 days of age were treated with pharmacologic dosages of various steroids for 6 and 15 days postoperative, it was found that testosterone, 5alpha-dihydrotestosterone, and estradiol prevented the rise of both FSH and LH, in both sexes. A steroid-derived drug, 17alpha-ethinyl-testosterone-2, 3-isoxazol, was also effective, while progesterone alone was unable to suppress gonadotropins in either sex. Results reaffirm that the gonadal-hypophyseal relationhsip is sensitive before puberty. The marked sex difference in the response to castration is undoubtedly due to different gonadal hormones (androgen or estrogen) present at the time of castration, and their contributions to this feedback process. However it appears that hormones of either type can suppress both gonadotropins in both sexes. Results with 17alpha-ethinyl-testosterone-2, 3-isoxazol were particularly encouraging with respect to its clinical usefulness as a gonadotropin inhibitor with little or no biologic activity as a sex steroid.     

Alterations in the onset of ovulatory failure and gonadotropin secretion following steroid administration to lightly androgenized female rats

The present studies were designed to characterize the gonadotropin response to exogenous steroids in neonatally androgenized female rats in various states of reproductive decline. Female rats were androgenized by the administration of a single injection of testosterone propionate (TP) (10 or 100 micrograms) at 5 days of age. Control rats received sesame oil. Treatment with 100 micrograms TP resulted in persistent vaginal estrus (PVE) from the onset of vaginal introitus. Treatment with 10 micrograms TP resulted in a period of regular estrous cyclicity followed by PVE. In the first experiment, all animals were ovariectomized between the ages of 60-85 days and the gonadotropin response to exogenously administered estradiol benzoate (EB) (10 micrograms/100 g BW) and progesterone (P) (2 mg/animal) was determined. When testing began 3 days following ovariectomy, control females exhibited significant (P less than 0.01) afternoon elevations of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) following EB, which were further amplified following P. When ovariectomy occurred prior to the onset of PVE (PRE PVE), lightly androgenized females (10 micrograms TP) showed no significant afternoon gonadotropin increase following EB. Following P, phasic LH secretion was present but significantly (P less than 0.01) decreased in amplitude and delayed in onset versus that of control females. When ovariectomy occurred 3 to 4 wk following the onset of PVE, lightly androgenized females (PVE group) as well as fully androgenized females (FAS) (100 micrograms TP) showed no gonadotropin response to steroid priming.(ABSTRACT TRUNCATED AT 250 WORDS)     

Gonadotropin secretion during prolonged hyperprolactinemia: basal secretion and the stimulatory feedback effect of estrogen

Inoculation of cyclic female rats with the prolactin (Prl)/growth hormone-secreting pituitary tumor, MtT.W15, resulted in a cessation of estrous cyclicity within 5--10 days. Associated with this acyclicity was a persistently low serum concentration of estradiol and marked increases in both circulating Prl and progesterone. At Day 26 of acyclicity, basal serum luteinizing hormone (LH) values measured in samples taken every 20 min from 0900--1100 h were significantly reduced when compared to cyclic, nontumor animals on diestrus Day 2. There was no difference in basal follicle-stimulating hormone (FSH) concentrations. In a separate group of acyclic, tumor-bearing females 42--56 days after transplantation, a single s.c. injection of 20 micrograms estradiol benzoate (EB) at 1030 h elicited significant increases in both serum LH and FSH values between 1700 and 1830 h on the next day. The magnitude of the LH surge was reduced and that of FSH was increased in tumor-bearing animals when compared to cyclic, nontumor females given a similar EB injection on diestrus Day 1. These results demonstrate that chronic hyperprolactinemia is associated with inhibition of basal LH secretion and ovarian estrogen production and an increase in circulating progesterone concentrations. Nevertheless, the stimulatory feedback effects of estrogen on LH and FSH release are still present and functioning in acyclic female rats under chronically hyperprolactinemic conditions. These data suggest that the cessation of regular ovulatory cycles associated with hyperprolactinemia may be due to a deficiency of LH and/or estrogen secretion, but not to a lack of central nervous system response to the stimulatory feedback action of estrogen.     

Regulation of pulsatile gonadotropin secretion by estrogen, inhibin, and follistatin (activin-binding protein) in ovariectomized rats.

The following study was conducted to examine the effects of estrogen and polypeptides, given either alone or in combination, on pulsatile gonadotropin secretion. One week after ovariectomy, rats received s.c. injections of oil or various doses (0.5, 5, 20 micrograms) of estradiol benzoate (EB) followed 1 day later by i.v. administration of 60 micrograms purified porcine follistatin, 10 micrograms recombinant inhibin, or the appropriate vehicle. Four hours after injection of the nonsteroids, blood was collected at 10-min intervals for 2 h, and the effects on pulsatile hormone release were assessed. Administration of EB alone dose-dependently suppressed mean and trough (lowest point between two pulses) FSH levels and all parameters of pulsatile LH release. Both follistatin and inhibin at the doses employed suppressed mean FSH levels to an equivalent extent (40%). Follistatin, but not inhibin, suppressed FSH pulse amplitude, while neither polypeptide alone influenced FSH pulse frequency or any parameter of pulsatile LH release. The effects of follistatin and EB on mean FSH levels were additive at all EB doses, whereas the effects of inhibin and EB were additive only at the middle EB dose. Follistatin in combination with the lowest EB dose significantly suppressed mean LH levels. These studies are the first to demonstrate that combined treatment with estrogen and the nonsteroids follistatin and inhibin is more efficacious in suppressing FSH release than treatment with either agent alone, thereby indicating that both steroids and nonsteroids are probably important in the physiological regulation of FSH secretion in rats. The additive effects of these compounds on FSH secretion could form the basis for exploring novel contraceptive interventions.     

Rapid recovery of estrogen-induced pituitary gonadotropin surges after luteectomy in rhesus monkeys

In the presence of a functional corpus luteum, positive estrogen feedback on the surge modes of gonadotropin secretion is blocked in rhesus monkeys. We investigated the effects of luteectomy (Lx) on the time required for recovery of pituitary responsiveness (LH/FSH surges) to positive estrogen feedback. Estradiol-17 beta-3- benzoate (EB, 50 microgram/kg sc) was given: 1) 24th prior to, 2) the day of, or 3) 24 h after luteal ablation. Daily measurements of serum follicle stimulating hormone (FSH), luteinizing hormone (LH), estradiol-17 beta (e2) and progesterone (P) were made on each monkey for 5 days. Serum P fell to undetectable levels within 24 h after Lx, whereas E2 levels in circulation peaked within 24h after injection of EB. Among early follicular phase monkeys, this EB treatment results in typical midcycle type LH/FSH surges within 48h. Lx alone was not soon followed by significant changes in pituitary gonadotropin secretion. When circulating P levels were undetectable the pituitary responded fully to EB; that is, typical midcycle type FSH/LH surges occurred. When serum P was in the midst of declining after Lx, gonadotropin surges were present, but attenuated. However, when P levels remained elevated for more than 24 h after EB injection, the surge modes of FSH/LH secretion remained fully blocked. These results demonstrate that the suppressive influence of luteal secretions (principally progesterone) on positive estrogen feedback regulation of the surge modes of pituitary gonadotropin secretion is quite transient in these primates.     

Improved model for the induction of proestrus-like gonadotropin surges in long-term ovariectomized rats

In long-term (greater than 4 wk) ovariectomized rats the positive response of the gonadotropin release apparatus to a priming dose of estradiol is moderate as compared with that of proestrous rats exposed to endogenous estradiol. In the present study, high sensitivity to estrogen was restored in long-term ovariectomized rats by pretreatment with estradiol benzoate (EB, 20 micrograms, day 0) and progesterone (P, 2.5 mg, day 3). Estradiol benzoate (20 micrograms) given on day 5 induced proestrus-like surges of LH and FSH in the afternoon on day 6. Additional administration of P (2.5 mg at noon on day 6) had a facilitatory effect. Stimulation of LH release could be evoked in rats by the described regimen 1, 6 or 50 wk after ovariectomy. The long-term ovariectomized rat injected with EB and P as described might provide a useful model for neuroendocrinological investigations on the gonadotropin surge mechanism.     

Androgen- and estrogen-induced copulatory behavior and inhibition of luteinizing hormone (LH) secretion in the male rat

The purpose of the present investigation was to determine if estrogen, aromatizable androgen or nonaromatizable androgen is capable of (1) inducing copulatory behavior and (2) inhibiting the postcastration rise in plasma LH. Castrate male rats were injected daily with either 1 mg testosterone (T), androstenedione (A), dihydrotestosterone (DHT), or 25 μg estradiol benzoate (EB) or oil and tested weekly for masculine behavior and for lordosis behavior after 38 days of steroid treatment. On day 40 blood was collected for radioimmunoassay of plasma LH. At least 89% of the males treated with T, A, or EB and 55% of those treated with DHT displayed ejaculatory behavior whereas none of the oil-treated males showed male copulatory behavior. Only estrogen-treated males displayed lordosis behavior. T and to a lesser extent A treatment reduced high levels of plasma LH; however, DHT and EB further reduced plasma LH to undectable levels. The relative potency of the steroid effect in stimulating accessory sex tissues followed the order: DHT > T > A > EB = oil. Significant dissociation was observed between the effects of these steroids on peripheral morphology, negative feedback, and mating behavior. These results indicate that masculine behavior is facilitated to the greatest extent, although not exclusively, by centrally acting aromatizable androgen or estrogen, whereas under the present conditions only estrogen stimulates feminine behavior.     

Effect of vagotomy on postcastration gonadotropin secretion in male rats

The postcastration increase in gonadotropins was studied in intact and vagotomized male rats. Rats underwent vagotomy or sham surgery immediately prior to castration. In the first experiment, rats were bled before castration and at 1, 2, 4, and 7 days after castration. Serum LH and FSH were significantly lower in vagotomized rats 1 day after castration. On days 2, 4, and 7 postcastration, serum gonadotropin levels were generally not different among experimental groups. In a second experiment, rats were decapitated at 12 or 24 hr after surgery and castration. Trunk blood was collected for assay of LH. Vagotomy had no effect on LH levels at 12 hr postcastration, but, at 24 hr postcastration, vagotomized rats had significantly lower serum LH than did sham-operated rats. These experiments indicate that vagotomy has a transient suppressive effect on gonadotropin release following castration. Such observations support the hypothesis that the vagus nerve may play a modulatory role in gonadotropin secretion.     

Seminiferous tubule fluid and interstitial fluid production. I. Effects of age and hormonal regulation in immature rats

Efferent duct ligation was used to assess seminiferous tubule fluid (TF) production and studies of the kinetics of TF production following this procedure were performed on 25-day-old rats. The rate of TF production was linear for 48 h, thereafter reached a plateau until 72 h and began decreasing at 96 h post-ligation. Using a 16-h ligation period, the onset of TF production was investigated in groups of immature rats from 15 days of age. TF secretion was not detected prior to 15 days but rose rapidly after Day 20 coincident with the prepubertal rise in serum FSH. The acute effect of hormone on TF production following unilateral efferent duct ligation (EDL) was evaluated in 25-day-old rats in which interstitial fluid production (IF) was also assessed in the unligated testis by the method of Sharpe (1977). Single subcutaneous injections of the following hormones were given to groups of rats at the time of EDL: a) NIH follicle-stimulating hormone (FSH) S13 (20 micrograms/rat); b) NIH luteinizing hormone (LH) S22 (200 micrograms/rat); c) testosterone propionate (2 mg/rat); d) human chorionic gonadotropin (hCG) (10 IU/rat); or e) NIH prolactin (Prl) 14 (200 micrograms/rat). A significant rise in TF production occurred following FSH treatment but no effect was noted in any of the other groups. In contrast, a marked stimulation of IF production occurred in rats treated with LH or hCG.     

Effects of hyperprolactinemia on the control of luteinizing hormone and follicle-stimulating hormone secretion in the male rat

Experiments were conducted to determine the effects of acute hyperprolactinemia (hyperPRL) on the control of luteinizing hormone and follicle-stimulating hormone secretion in male rats. Exposure to elevated levels of prolactin from the time of castration (1 mg ovine prolactin 2 X daily) greatly attenuated the post-castration rise in LH observed 3 days after castration. By 7 days after castration, LH concentrations in the prolactin-treated animals approached the levels observed in control animals. HyperPRL had no effect on the postcastration rise in FSH. Pituitary responsiveness to gonadotropin hormone-releasing hormone (GnRH), as assessed by LH responses to an i.v. bolus of 25 ng GnRH, was only minimally effected by hperPRL at 3 and 7 days postcastration. LH responses were similar at all time points after GnRH in control and prolactin-treated animals, except for the peak LH responses, which were significantly smaller in the prolactin-treated animals. The effects of hyperPRL were examined further by exposing hemipituitaries in vitro from male rats to 6-min pulses of GnRH (5 ng/ml) every 30 min for 4 h. HyperPRL had no effect on basal LH release in vitro, on GnRH-stimulated LH release, or on pituitary LH concentrations in hemipituitaries from animals that were intact, 3 days postcastration, or 7 days postcastration. However, net GnRH-stimulated release of FSH was significantly higher by pituitaries from hyperprolactinemic, castrated males. To assess indirectly the effects of hyperPRL on GnRH release, males were subjected to electrical stimulation of the arcuate nucleus/median eminence (ARC/ME) 3 days postcastration. The presence of elevated levels of prolactin not only suppressed basal LH secretion but reduced the LH responses to electrical stimulation by 50% when compared to the LH responses in control castrated males. These results suggest that acute hyperPRL suppresses LH secretion but not FSH secretion. Although pituitary responsiveness is somewhat attenuated in hyperprolactinemic males, as assessed in vivo, it is normal when pituitaries are exposed to adequate amounts of GnRH in vitro. Thus, the effects of hyperPRL on pituitary responsiveness appear to be minimal, especially if the pituitary is exposed to an adequate GnRH stimulus. The suppression of basal LH secretion in vivo most likely reflects inadequate endogenous GnRH secretion. The greatly reduced LH responses after electrical stimulation in hyperprolactinemic males exposed to prolactin suggest further that hyperPRL suppresses GnRH secretion.     

Changes in gonadotropin secretion following complete or hemicastration in the adult rat.

The effect of sham castration, hemicastration or complete castration on gonadotropin and testosterone secretion was studied in adult male rats. Untreated control rats were autopsied 1, 10, 20, 30 and 40 days following assignment to treatment groups. Sham-castrated controls were autopsied 1, 2 and 3 days after surgery. Complete and hemicastrates were autopsied 1, 2, 3, 10, 20, 30 and 40 days after surgery. Serum levels of both FSH and LH were elevated by 24 h postcastration and the levels of both gonadotropins continued to rise throughout the course of the experiment. Serum levels of LH rose following hemicastration and remained above control values through day 30. Serum FSH levels were not significantly affected by hemicastration. Compensatory testicular hypertrophy was not observed in hemicastrated rats.     

Altered negative feedback response to ovariectomy and estrogen in prepubertal restricted-diet rats

Studies were conducted to explore the hypothesis that the delayed sexual maturation of female rats induced by reduced food intake (R) may result partially from an altered negative feedback response to estrogen. Animals were placed on 60% of normal food intake at 20 days of age. Controls (C) were fed ad libitum. Rats were used for three different experiments at 31-32 days of age. In Experiment I, rats were ovariectomized (OVX) and injected subcutaneously for 4 days with varying doses of estradiol benzoate (EB). They were killed the day after the last injection. In Experiment II, rats were ovariectomized and killed in groups at 4, 12, 24, 48, 72, and 120 h after OVX. In Experiment III, they were castrated and 1 wk later received a single injection of 0.5 microgram EB. Groups were killed at 1, 2, 4, 8, and 24 h after injection. Sera from all experiments were assayed for follicle-stimulating hormone (FSH), luteinizing hormone (LH), and prolactin. Results of Experiment I indicate that the efficacy of EB for suppressing LH, but not FSH, secretion is increased significantly in R rats. In Experiment II, OVX resulted in a delayed increase in serum LH, but not FSH, concentrations of R rats when compared to C animals. Results of Experiment III indicate a delayed, but more prolonged, suppression of LH secretion by EB in R rats when compared to C rats. Prolactin secretion, on the other hand, increased earlier in R rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kainic acid lesioning of the preoptic area alters positive feedback of estrogen in prepubertal female rats

Stereotaxic infusion of kainic acid (KA) was performed to induce intrinsic neural lesions of the preoptic area (POA) in 25-day-old female rats. After KA infusion, rats in Experiment 1 received 10 micrograms of estradiol benzoate (EB) administered subcutaneously to assess positive feedback of EB on release of luteinizing hormone (LH) from the pituitary gland. Rats were perfused for light microscopic (LM) or electron microscopic (EM) evaluation of the lesion site. Rats of Experiment 2 were allowed to develop until the appearance of vaginal opening (VO) after which time vaginal lavages were taken to monitor the cyclicity of the vaginal epithelium. At 50 days of age, the right ovary from each rat was removed, trimmed of fat, and weighed. At 60 days of age, the remaining ovary was removed to assess compensatory ovarian hypertrophy (COH). In Experiment 3, we investigated the effects of POA/KA-infusion on sexual behavior. Sex behavior tests were conducted at 48 h after EB during the dark phase of the light cycle. In Experiment 1, all the control and saline-infused rats exhibited the expected rise of plasma LH two days after estrogen injection while the POA/KA-infusion abolished the positive feedback effect of EB on LH release. Ultrastructural examination of the lesion site revealed that neurons were undergoing acute degeneration while axons and afferent terminals seen in the same fields of analysis were morphologically intact. Preoptic area/KA lesions caused a marked delay in the appearance of VO. Duration of this temporal delay in POA/KA-lesioned rats was approximately 4 days, or one vaginal cycle. The lesioned animals showed normal compensatory hypertrophy after unilateral ovariectomy.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of the intraventricular administration of 5,7-dihydroxytryptamine on FSH, LH and prolactin secretion in neonatally estrogenized male rats

The role of the serotoninergic system in the control of LH, FSH and prolactin secretion was analyzed in control and neonatally estrogenized male rats. Animals injected s.c. with 500 micrograms of estradiol benzoate (EB) on day 1 of life, or their corresponding sham-treated controls, were divided on day 75 into the following groups: (1) orchidectomized; (2) injected intraventricularly with 5,7-dihydroxytryptamine (5,7-DHT); (3) orchidectomized and treated with 5,7-DHT, and (4) sham operated. 15 days later, the animals were decapitated and their FHS, LH and prolactin plasma values measured by specific RIA systems. After the treatment with 5,7-DHT, control animals showed a decline in basal prolactin levels but no modification in basal LH and FSH values. After castration, 5,7-DHT-treated animals showed a reduced LH increase and a more marked prolactin decrease. In neonatal estrogen-treated animals, the 5,7-DHT injection did not change FSH, LH or prolactin levels but did partially or completely abolish the post-castration rise in FSH and LH levels, respectively. These data seem to indicate that neonatal estrogenization induced a modification of the serotoninergic role in the control of LH, FSH and prolactin.     

Selective failure of androgens to regulate follicle stimulating hormone beta messenger ribonucleic acid levels in the male rat

FSH beta, as well as LH beta, and alpha-subunit mRNA levels were examined in the pituitary glands of male rats after sex steroid replacement at various times (7, 28, or 90 days) after orchiectomy. Testosterone propionate, dihydrotestosterone propionate, or 17 beta-estradiol benzoate (E) were administered daily for 7 days before killing, to assess the role of different gonadal steroids on gonadotropin subunit mRNA levels. Subunit mRNAs were determined by blot hybridization using rat FSH beta genomic DNA, and alpha and LH beta cDNAs. At all time points, alpha and LH beta mRNAs increased after gonadectomy and fell toward normal levels with either androgen or estrogen replacement. FSH beta mRNA levels increased variably postcastration: 4-fold at 7 days, 2-fold at 28 days, and 4- to 5-fold at 90 days. Although E replacement uniformly suppressed FSH beta mRNAs, neither testosterone propionate nor dihydrotestosterone propionate administration suppressed FSH beta mRNA levels at any time point after orchiectomy. These data demonstrate that there is a relative lack of negative regulation of FSH beta mRNA levels by androgens in a paradigm in which E administration results in marked negative regulation of FSH beta mRNA levels. Thus, in the male rat, estrogens negatively regulate all three gonadotropin subunit mRNA levels while androgens negative regulate LH beta and alpha-subunit but fail to suppress FSH beta mRNAs.     

Postcastration rise in plasma gonadotropins is blocked by a luteinizing hormone-releasing hormone antagonist

The dependence of the acute increases in plasma gonadotropins following castration on luteinizing hormone-releasing hormone (LHRH) was assessed with the use of a potent LHRH antagonist [ALHRH; (Nac-L-Ala1,p-Cl-D-Phe2,D-Trp3,6) LHRH]. Blood samples were collected from male and female rats at the time of castration and 2, 4, 8, 12, 24 and 48 h following and plasma gonadotropin levels were determined. Immediately following castration (diestrus I for females) animals received one of the following treatments: females-vehicle, 100 micrograms ALHRH, 50 micrograms estrogen benzoate (EB), or 100 micrograms ALHRH + 50 micrograms EB; males-vehicle, 100 micrograms ALHRH, 500 micrograms testosterone propionate (TP), or 100 micrograms ALHRH + 500 micrograms TP. ALHRH blocked the selective increase in plasma follicle-stimulating hormone (FSH) observed in female rats as well as the parallel increases in both gonadotropins seen in male rats following castration. Administration of EB or ALHRH + EB to females significantly suppressed both gonadotropins compared with control levels. However, EB alone did not completely block the rise in plasma FSH in females. In males, all three treatments significantly suppressed the increases in both gonadotropins when compared with control levels. These data demonstrate that hypothalamic LHRH plays an essential role in the acute elevations of plasma gonadotropins following castration in rats. In addition, these data suggest that the selective rise of FSH in females is dependent on LHRH stimulation of pituitary gonadotropes.     

A role for inhibin in the control of follicle-stimulating hormone secretion in male rats

We examined the relationship of testosterone (T) and porcine follicular fluid (pFF) in the negative feedback control of FSH and LH secretion in adult male rats. Either at the time of castration (acute) or at least 30 days after castration (chronic), we implanted T-filled Silastic capsules, which were 2 mm, 10 mm, or 30 mm long; empty capsules (30 mm) served as controls. Seven days later, we injected either 0.15 ml of pFF or saline (i.v.), decapitated the rats 6 hours later, and collected trunk blood for subsequent serum analysis of FSH, LH, and T by RIA. In the acute groups, T implants suppressed the postcastration rises in plasma FSH and LH levels in a dose-dependent manner, with only the largest implant, 30 mm, able to return them to intact levels. PFF injection significantly suppressed FSH levels in intact and acute rats but had no effect on serum LH. In chronic rats, T therapy for 7 days suppressed plasma LH levels in a dose-dependent relationship, yet did not do so to plasma FSH levels. FSH levels were significantly higher in rats with the 30 mm T implants than in intact rats, but were significantly suppressed as compared to chronic controls. PFF significantly suppressed serum FSH levels in all chronic groups with the chronic controls showing the greatest amount of suppression. We conclude that the role for inhibin in the normal control of FSH secretion is that of a secondary modulator which is superimposed on, yet independent of, the steroid feedback mechanism. At any given moment this modulation is dependent upon the secretory activity of the FSH gonadotrope.     

Effect of gonadotropin-releasing hormone,stage of sexual maturation and 6-methoxybenzoxazolinone on plasma gonadotropins,ovarian development and uterine weight in prepuberal gilts

Two experiments were conducted with prepuberal gilts at 60, 120 and 160 days of age to a) determine the effect of 6-methoxybenzoxazolinone 6-MBOA) on reproductive plasma hormone concentrations and organ development, and b) determine how plasma follicle-stimulating hormone (FSH) and luteinizing hormone (LH) concentrations before and after injection of gonadotropin-releasing hormone (GnRH) or 6-MBOA varied in relation to ovarian development. In Exp. 1, 12 gilts were used in a 4×4 Latin square design. Four gilts/age group were injected once with: 1) vehicle, 2.5% propylene glycol in 50% ethanol, 2) 2 μg of GnRH/kg body weight (BW), 3) 0.2 mg of 6-MBOA/kg BW, and 4) 2 mg of 6-MBOA/kg BW on four successive days in random order. Blood was collected via indwelling vena cava catheters. Injection of GnRH into gilts increased plasma FSH and LH at each age compared with vehicle (P<0.05). Hormone profiles for FSH and LH differed among age groups (P<0.01), but area under curves did not differ significantly among age groups. Injection of 6-MBOA did not significantly affect plasma FSH and LH. Plasma FSH and LH before the GnRH injection or on days when GnRH was not injected were greater at 60 than at 120 and 160 days (FSH, 128 vs 54 and 42 ng/ml; LH, 0.38 vs 0.16 and 0.13 ng/ml for 60, 120 and 160 days, respectively (P<0.05). In Exp. 2, vehicle, 0.2 or 2 mg of 6-MBOA/kg BW were injected once daily for 7 days in 19 gilts. Injections of 6-MBOA had no detectable effects on gonadotropin secretion, ovarian development or uterine weight. Between 60 and 120 days of age, vesicular follicles developed, ovarian weight increased 20-fold, and uterine weight increased 10-fold (P<0.05); basal concentrations of plasma FSH and LH decreased three- and twofold, respectively.