Gonadotropin-releasing hormone (GnRH) inhibits ovulation induced with luteinizing hormone (LH) in proestrous hypophysectomized rats

In this paper we present evidence that a single low dose of the natural synthetic gonadotropin-releasing hormone (GnRH), inhibits ovulation induced by LH in proestrous-hypophysectomized rats. Rats hypophysectomized by the parapharyngeal route in the morning of proestrus received an intravenous injection of 100 or 300 ng GnRH at 1400 h immediately followed by 1.0 microgram LH per 100 g bw. In control groups, either one or both hormones were replaced with 0.9% NaCl. Ovulation was assessed the following morning by counting the ova present in oviductal flushings. All the rats treated with LH alone ovulated, and the addition of GnRH reduced significantly the number of ovulating rats and the number of ova per ovulating rat. In other groups of rats hypophysectomized in the morning of proestrus and treated in the same way, ovarian or adrenal secretory rates of estradiol and/or progesterone were measured after cannulation of the corresponding vein, in the afternoon of proestrus. In these animals, GnRH failed to inhibit either the ovarian progesterone surge observed 2 h after LH administration, or the adrenal progesterone secretion. All hypophysectomized rats showed lower ovarian secretory rate of estradiol than intact rats; this rate was not affected by treatment with LH or LH plus GnRH. The systemic estradiol levels in plasma of hypophysectomized rats were distributed within a range of 20 pg/ml to 50 pg/ml. The number of rats whose levels were above 21 pg/ml on estrus day was significantly higher in rats receiving 300 ng GnRH as compared to those receiving 100 ng GnRH, reaching values that surpassed the concentration found in intact, untreated animals at the same time of estrus. This effect did not depend on LH administration.     

Preovulatory secretion of progesterone, luteinizing hormone, and prolactin in 4-day and 5-day cycling rats

Timing of ovulation and changes in plasma progesterone, luteinizing hormone (LH), and prolactin (PRL) during periovulatory stages were determined in Holtzman rats exhibiting regular 4- or 5-day cycles under a daily artificial illumination from 0500 to 1900 h. The 5-day cycling rats ovulated between 0130 and 0930 h on estrus, whereas some of the 4-day cycling animals ovulated as early as about 0130 h and others as late as 1130 h on estrus. Onset time of preovulatory LH and progesterone surges was about 1500 h on proestrus in both the 4- and the 5-day cycling rats. Peak levels of plasma LH and progesterone were measured at 1700 to 1900 h on proestrus, while the first rises and peak values of plasma PRL were evident a few hours earlier than those of plasma LH in the rats with two cycle lengths. Plasma LH levels at 1900 h on proestrus as well as plasma progesterone levels at 1600 and 2300 h on proestrus and at 0130 and 0330 h on estrus were significantly lower in the 5-day cycling rats than in the 4-day cycling animals (p less than 0.05). In contrast, PRL levels from 1500 through 2300 h on proestrus remained consistently higher in 5-day cycling rats than in 4-day cycling rats, and significant differences in PRL levels between these rats were apparent at 1500, 1600, and 2100 h (p less than 0.05-0.01). Thus, these results demonstrate that the 5-day cycling rats exhibit the attenuated magnitude of LH surge accompanied by the augmented preovulatory PRL release, and that plasma progesterone levels reflect the magnitude of LH surge. A tentative working hypothesis concerning the etiology of the 5-day cycle has been proposed.     

Advancement of first ovulation by the opioid antagonist naltrexone

The opioid antagonist naltrexone was administered to female rats during the late juvenile period, and its effects on sexual maturation were studied. Naltrexone treatment (2.5 or 20 mg/kg; four daily injections at 2-h intervals) at 28-32 days of age advanced first ovulation in about 55% of the rats. When naltrexone (20 mg/kg) was administered at 30-34 days of age, 75% of the rats responded. In these rats, first ovulation was advanced by 3.4 days and their body weight was 15.1 g lower than in control rats at first ovulation (p less than 0.01). Similar naltrexone treatment at younger (starting on Day 24 or 26) or older (starting on Day 32 or 34) ages did not advance first ovulation. The numbers of ova released in advanced, nonadvanced, and control rats were similar. A significant increase in serum luteinizing hormone (LH) concentration was seen 15 min after naltrexone injection (20 mg/kg) at all ages studied; the increase was significantly higher (p less than 0.05) at 30 days of age than before or after that age. Relatively high response to naltrexone (2.5 mg/kg) was seen from 8 to 4 days before first ovulation. Taken together, these data suggest that during the late juvenile stage (8 - 4 days before first ovulation) endogenous peptides critically restrict LH secretion and may constitute a hypothalamic restraint on the onset of puberty. However, changes in pituitary responsiveness to luteinizing hormone-releasing hormone may be part of the mechanism behind the high LH response to naltrexone in rats during the late juvenile stage.     

Serotonin neuroleptics change patterns of preovulatory secretion of luteinizing hormone in rats

Serotonin receptor agonists or antagonists were used in this study to determine the timing and influence of serotonergic neurotransmission on phasic secretion of luteinizing hormone (LH). Daily injections of cyproheptadine (CP) or methysergide (MS), serotonin antagonists, initiated at 1600h on the day of vaginal proestrus, blocked the LH surge and ovulation. Vaginal smears remained cornified for 2–3 days. The drugs were ineffective when given at 0800h, though they terminated the LH surge prematurely when administered at 1730h. When quipazine, a serotonin receptor agonist was injected at 1400h or 2000h on proestrus, serum LH levels rose. This effect caused the LH surge to begin prematurely or to be sustained unusually long. Quipazine injected on diestrus 2 did not cause LH levels to rise, suggesting that its effect is estrogen dependent. Serotonin turnover in the hypothalamus was greater during onset of the LH surge than during its termination. When the LH surge was prolonged by exposing rats to light on proestrous evening, serotonin turnover remained high. The results of this study indicate that phasic secretion of LH on proestrus is accompanied by and may be dependent upon a period of serotonin neural activity.     

Opiate antagonist treatment reinstates estrous cycles in middle-aged persistent-estrous rats

Middle-aged female rats display luteinizing hormone (LH) surge deficits and cycle irregularity followed by the onset of persistent estrus (PE). The central nervous system has been identified as a primary locus of failure in PE rats, but the particular neural elements involved have not been determined. The goal of the present study was to identify a role for endogenous opioid peptides (EOP) in age-related acyclicity by evaluating the effect of opiate antagonist treatment on vaginal cytology in PE rats. PE rats were administered, s.c., saline (SAL), naloxone (NAL) or naltrexone (NTX) once daily for 20 days, or repetitively on Day 1 and on successive proestrus days if cyclicity was resumed. Single NTX (50 mg/kg), but not NAL (2 mg/kg), treatment interrupted the PE state in almost half of treated animals. Daily or repetitive proestrus NTX (10 mg/kg) treatment interrupted PE more frequently, and many animals displayed repeated estrous cycles and ovulation. Afternoon LH surges were observed after initial NTX treatment in animals displaying PE interruption. This demonstration that LH surges and ovulatory cycles can be reinitiated in PE rats with NTX suggests that dysfunction in the 'brake' on EOP secretion during proestrus may be one of the neuroendocrine impairments mediating acyclicity in aging female rats.     

Effect of adrenergic blocking drugs on secretion of luteinizing hormone in the ovariectomized ewe.

The effects of the adrenergic blocking drugs phenoxybenzamine, phentolamine, and pimozide on basal luteinizing hormone (LH) levels and on estrogen-induced LH release were tested in ovariectomized ewes. Phentolamine was given at a dose of 10 mg/kg; phenoxybenzamine was given at a dose of 8 mg/kg; and pimozide was given at a dose of 800 mcg/kg. Estradiol benzoate (EB) was given at a dose of 50 mcg/animal. Sera were assayed for LH levels by double-antibody radioimmunoassay. Phenoxybenzamine given as a single dose significantly reduced basal LH levels. Given at extremenly high doses, phenoxybenzamine was unable to consistently block estrogen-induced LH release. Pimozide significantly reduced basal LH levels in the ewes and blocked or greatly reduced estrogen-induced LH release in 9 of 10 treated animals. Reduced basal LH levels were seen with phentolamine injection but were of short duration of action. It is concluded that normal function of noradrenergic neurons is required for maintenance of normal basal LH release but unnecessary for estrogen-induced LH release. Dopaminergic neurons appear to facilitate basal and estrogen-induced LH release.     

Blockade of spontaneous and LH-induced ovulation in rats by indomethacin,an inhibitor of prostaglandin biosynthesis

Indomethacin, an inhibitor of prostaglandin synthesis, blocks ovulation in immature rats pre-treated with pregnant mare serum gonadotropin (PMS), when given either at 0800, 1200 or 1600 hours on the second day after PMS treatment (the equivalent of proestrus in normally cycling adult rats). The drug also blocked ovulation in response to exogenous luteinizing hormone, whether the latter was administered 30 minutes before or 30 minutes after the inhibitor. Luteinization of follicles, and signs of pre-ovulatory progesterone secretion (loss of uterine lumen fluid) were not prevented when the inhibitor was given at 1600 hours, or when exogenous LH was administered in addition to the inhibitor, indicating that the luteinizing and steroidogenesis actions of LH upon the ovary were not completely blocked. When the drug was administered before the “critical period” for LH secretion, follicular luteinization and signs of progesterone secretion were also prevented, suggesting an additional action of indomethacin at the level of the hypothalamic-pituitary axis, inhibiting LH secretion.     

Does corpus luteum function autonomously during estrous cycle in the rat? A possible involvement of LH and prolactin

This study examined the of LH and prolactin in the control of corpus luteum function during 4-day cycles in the rat. Bromocriptine (BRC) treatment was performed on proestrus or/and estrus morning that means before or after the preovulatory release of LH. This caused complete blood prolactin depression from the time of injection until diestrus 1 afternoon. This decrease in blood prolactin concentration was associated with a rise in the tonic level of LH secretion in those females which received BRC as soon as on proestrus. We first observed that injection on the morning of proestrus of doses of BRC capable of blunting prolactin secretion on proestrus afternoon did not significantly impair the preovulatory release of LH and did not prevent ovulation occurring during the following night. The life span of the corpora lutea edified from ovarian follicles rupturing before or under BRC administration did not exceed that of those formed under physiological circumstances since 4-day cycles culminating in ovulation constantly took place in all the treated animals whatever the time of BRC injection. To determine the pattern of luteal activity in the absence of prolactin secretion, we measured blood progesterone concentration from estrus until late diestrus in female rats injected with BRC on proestrus and/or estrus at 1100 h. The initiation of the function of corpus luteum on estrus and the achievement of its full activity on diestrus 1 did not appear to be affected by BRC. By contrast the level of blood progesterone declined more rapidly on the morning of diestrus 2 in BRC-treated than in control females. The capacity for autonomous progesterone secretion by corpus luteum of the cycle was discussed in the light of previous and present observations.     

Ovarian responses to perphenazine-induced prolactin secretion in the rats: Effect of ovulation, stress, and steroids.

A single injection of 2.5 mg perphenazine (PH)/kg body wt to rats on the day of estrus (day 0) did not result in increased serum progesterone 24 hr later. Continued daily injections, however, resulted in a 2.5-fold increase in serum progesterone between days 1 and 3 and a 1.6-fold increase between days 3 and 5 to a final concentration of 58 plus or minus 4 ng/ml on day 5 in serially anesthetized and bled rats. Neither daily administration of 5.0 nor 10.0 mg PH/kg body wt to rats subjected to the stressful conditions of this regimen resulted in further increases in serum progesterone, but the 5.0 mg dose of PH in unstressed rats bled only on day 5 resulted in a highly significant increase in serum progesterone to 110 plus or minus 7 ng/ml. In unstressed rats the increase in serum progesterone over control values after five daily injections of 2.5 mg PH/kg body wt could be attributed to decreased 20alpha-reduction of progesterone, but when the dose of PH was increased to 5.0 mg/kg, a highly significant increase in both progesterone and total progestins occurred indicating that prolactin can increase steroidogenesis as well as reduce 20alpha-hydroxysteroid dehydrogenase activity. After inhibition of ovulation, the 5.0 mg daily dose of PH resulted in serum progesterone of only 25 plus or minus 8 ng/ml on day 5 in unstressed rats. Thus, serum progesterone in ovulating rats treated with PH originated primarily in the corpora lutea. Perphenazine, 5.0 mg/kg, administered only on estrus and the first day of diestrus was sufficient to induce pseudopregnancy of 14.5 plus or minus 1.6 days. No evidence for gonadotropin stimulation of the ovaries of any rats was observed. The effect of stress on the progesterone response was not mimicked by administration of cortisol acetate and is assumed to be medicated by suppression of prolactin secretion.     

Neuroendocrine control of luteinizing hormone secretion and reproductive function in spontaneously persistent-estrous aging rats

Middle-aged female rats cease to display estrous cycles and exhibit a state of persistent estrus (PE). Under PE and chronic anovulatory conditions, there is a lack of spontaneous luteinizing hormone (LH) surges, but ovulations often occur after the females are caged with males. This study examined the effects of caging and mating with male rats on LH release in PE females, and assessed their reproductive capacity. Young cyclic rats received intra-atrial cannulae, and subsequently were sampled every 90 min during 1400-2130 h on proestrus for plasma LH measurement. PE females were similarly cannulated and sampled. Two days later, these PE rats received an s.c. injection of estradiol benzoate (EB) and were sampled on the following day. While young females exhibited the proestrous LH surge, PE rats maintained low plasma LH levels persistently and were unable to increase LH release after EB administration. On the other hand, when cannulated PE females were caged with fertile males, 92% displayed lordotic responses, and 75% of those sexually receptive PE females exhibited LH surges followed by ovulation. The initiations of the lordotic response and the LH surge both were more rapid in PE females caged with males beginning at 1500 h than at 1400 h. In contrast, when individual PE rats were placed in clean boxes without males, only one of 13 females showed an increase in LH release followed by ovulation. Separate groups of PE rats were mated with fertile males, and subsequently used for counting the number of blastocysts in the uteri on Day 5 of pregnancy and the number of pups delivered at term.(ABSTRACT TRUNCATED AT 250 WORDS)     

Blockade of first ovulation in pubertal rats by delta-9-tetrahydrocannabinol: requirement for advanced treatment due to early initiation of the critical period

Successful blockade of ovulation in pubertal rats by delta-9-tetrahydrocannabinol (THC) required earlier treatment during proestrus than was required in adults under the same conditions. Only 1 of 8 adult rats ovulated after treatment with THC (10 mg/kg body weight, i.p.) at 1400 h proestrus, whereas 77% of pubertal rats released full sets of ova following similar treatment during proestrus of the first or second vaginal cycle. When treatment of pubertal rats was advanced to 1300 h, only 2 of 10 THC-treated rats exhibited full ovulation, an incidence significantly lower than the 80% ovulation rate observed in vehicle-treated animals (p less than 0.05). To determine whether the requirement for earlier THC treatment in pubertal rats was related specifically to THC or reflected possible age-associated differences in timing of the critical period, the ovulation-blocking efficacy of atropine sulfate (ATR) was tested in pubertal rats for comparison with that of THC. The serum concentrations of luteinizing hormone (LH) during the first proestrus (1200-1900 h) were determined in pubertal rats that remained untreated. The incidence of ovulation in rats treated with ATR (350 mg/kg, s.c.) at 1400 h proestrus was not significantly reduced from that in vehicle-treated rats; however, after ATR treatment at 1300 h, only 2 of 11 animals released full sets of ova whereas all vehicle-treated rats ovulated (p less than 0.025). The mean serum LH concentration in untreated pubertal rats was not significantly increased over baseline at 1300 h proestrus, but was markedly elevated by 1400 h (1009 +/- 375 ng/ml; p less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)     

Periovulatory changes in serum concentration and ovarian content of 5 alpha-androstane-3 alpha, 17 beta-diol in the adult rat

The high amounts of 5 alpha-androstane-3 alpha, 17 beta-diol (3 alpha-diol) present in immature female rats decline towards first ovulation, but on the day of first proestrus a peak is seen. This raises the possibility that during adulthood similar proestrous peaks may occur. Therefore, serum concentrations and ovarian content of 3 alpha-diol were estimated every two hours between 0900 and 2100 h in adult cyclic rats on the day of proestrus. In the same rats, serum concentrations of estradiol (E2), progesterone (P) and luteinizing hormone (LH) were measured, as were ovarian contents of E2 and P. A significant elevation in ovarian 3 alpha-diol was found between 0900 and 1700 h proestrus, whereas serum concentrations of 3 alpha-diol were elevated from 1300 to 2100 h. The high morning values of ovarian 3 alpha-diol correlated with those for ovarian E2 (p less than 0.005); the elevated serum concentrations of 3 alpha-diol during the afternoon correlated with serum P (p less than 0.005) and with serum LH concentrations (p less than 0.005). Serum and ovarian values were positively correlated for P and E2, but not for 3 alpha-diol. The rise in serum 3 alpha-diol could be prevented by blocking the LH surge with sodium pentobarbitone (Nembutal; 35 mg/kg b.w.) administered at 1300 h. In Nembutal-treated rats, the concentration of 3 alpha-diol at 1700 h (886 pg/ml) was significantly lower than in saline-treated control rats (1135 pg/ml; p less than 0.005).(ABSTRACT TRUNCATED AT 250 WORDS)     

Unilateral ovariectomy, flutamide treatment and HCG reverse the anovulatory action of antiprogesterone RU486 in rat.

Administration of antiprogesterone RU486 (4 mg/day) from estrus through proestrus to cyclic rats blocked ovulation. Moreover, RU486 increased basal serum concentrations of LH, PRL, testosterone and estradiol, while it decreased basal serum concentration of FSH. Both unilateral ovariectomy and antiandrogen flutamide treatment, as well as an ovulatory injection of HCG in the proestrus afternoon partially reversed, the ovulatory blockade of RU486. These results indicate that both the decreased FSH concentration and the increased testosterone concentration, as well as the reduced ovulatory LH release are responsible for the anovulatory effects of RU486.     

Bimodal effects of luteinizing hormone and role of androgens in modifying superovulatory responses of rats to infusion with purified porcine follicle-stimulating hormone

Prepubertal (28-30 days old) female rats were infused s.c. over a 60-h period with a purified porcine pituitary follicle-stimulating hormone (FSH) preparation having FSH specific activity 8.4 times that of NIH-FSH-S1 and luteinizing hormone (LH) specific activity less than 0.005 times that of NIH-LH-S1, based on radioreceptor assays. When the FSH infusion rate of this preparation was increased over the range of 0.5-2 units/day (mg NIH-FSH-S1 equivalent), an all-or-none response was observed, with the threshold dose for superovulation being between 1 and 2 units/day. Eleven of twelve rats receiving the 2 units/day dose ovulated a mean +/- SEM of 67 +/- 8 oocytes on the morning of the third day after the beginning of FSH infusion. Addition of human chorionic gonadotrophin (hCG), as a source of LH activity, to a subthreshold (1 U/day) FSH infusion rate resulted in 20% of rats ovulating at an hCG dosage of 50 mIU/day; increasing the hCG infusion to 200 mIU/day concomitant with the subthreshold FSH infusion rate increased ovulation rate to a mean of 69 +/- 8/rat, with 100% of rats ovulating. To determine the effect of varying both FSH infusion rates and LH:FSH ratios, FSH was infused at several rates, with hCG added to give varying hCG:FSH ratios for each FSH infusion rate. Administration of hCG alone was ineffective in causing ovulation except at the highest infusion rates. Adding hCG to FSH to reach a ratio of 0.2 IU hCG/U FSH significantly increased the superovulatory response to an intermediate, 1 U/day FSH dose, but not to the low, 0.5 U/day dose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of nembutal on LH release in baboons.

Regularly cycling female baboons were selected and maintained under a diurnal light schedule from 0500 to 1900 hr (CST). Beginning three days prior to the expected LH peak, blood was collected daily at 0800 and 1600 hr for 6 days in 5 baboons under light sedation for radioimmunoassay of plasma LH and estrogen. The plasma level of LH increased linearly and reached a peak in the afternoon of the second day. The peak in plasma estrogen appeared prior to the LH peak. In order to examine the critical period of LH surge in baboons, nembutal was injected daily at 1300 hr beginning a few days prior to expected LH relase. Initial dose of nembutal was 35 mg/kg body weight, but a supplementary dose was later required for a full 5 hours of anesthesia. Blood was collected at 1600 hr from 4 baboons during nembutal injections and after cessation of nembutal injections for radioimmunoassay of plasma LH and estrogen. It was found that nembutal injections suppressed LH release in 2 baboons, and caused a delay of LH release in 2 baboons. However, the plasma level of estrogen declined immediately after initiation of nembutal injection and remained lower. The evidence illustrates the nature of the neural components of LH release which became effective in the afternoon during the ovulatory phase. In addition, a linear increase in plasma level of LH, which is due to accumulation of circulating LH, is necessary for induction of ovulation in baboons.     

Effects of adrenergic blockade on plasma catecholamine levels during adrenaline infusion.

Alpha and beta adrenergic blocking drugs were administered, either singly or in combination, prior to a 3hr adrenaline infusion (2 microgram kg body wt-1 min-1)), Animals were premediated with either phenoxybenzamine (1 mg kg body wt-1 min-1). Phenoxybenzamine did not affect circulating adrenaline levels, but propranolol, either alone or in combination with phenoxybenzamine, resulted in a significant reduction in plasma adrenaline levels when compared with the control unblocked situation of adrenaline infusion without premedication. The results provide a possible explanation for the protective effect of combined adrenergic blockade in shock situations.     

A possible dual mechanism of the anovulatory action of antiprogesterone RU486 in the rat

The purpose of these experiments was to investigate the mechanism of the anovulatory action of antiprogesterone RU486 (RU486) in rats by studying its effects on follicular growth, secretion of gonadotropins and ovarian steroids, and ovulation. Rats with 4-day estrous cycles received injections (s.c.) of either 0.2 ml oil or 0.1, 1, or 5 mg of RU486 at 0800 and 1600 h on metestrus, diestrus, and proestrus. At the same times, they were bled by jugular venipuncture to determine serum concentrations of luteinizing hormone (LH), follicle-stimulating hormone (FSH), 17 beta-estradiol (E), and progesterone (P). On the morning of the day after proestrus, ovulation and histological features of the ovary were recorded. Rats from each group were killed on each day of ovarian cycle to assess follicular development. Rats treated similarly were decapitated at the time of the ovulatory LH surge and blood was collected to measure LH. The serum levels of LH increased and those of FSH decreased during diestrus in rats treated with RU486. Neither E nor P levels differed among the groups. Treatment with RU486 caused both a blockade of the ovulation and an increase in ovarian weight in a dose-dependent manner. At the time of the autopsy (the expected day of ovulation), rats treated with 1 mg RU486 had ovaries presenting both normal and post-ovulatory follicles and unruptured luteinized follicles. Rats treated with 5 mg RU486 presented post-ovulatory follicles without signs of luteinization. The number of follicles undergoing atresia increased in rats treated with RU486. Rats treated with 5 mg RU486 exhibited a significant decrease in ovulatory LH release. The mechanism by which RU486 produces the ovulatory impairment in rats seems to be dual: first, by inducing inadequate follicular development at the time of the LH surge and second, by reducing the amount of ovulatory LH released. The physiological events-decreased basal FSH secretion and follicular atresia-that result from use of RU486 cannot be elucidated from these experiments and should be investigated further.     

Antiovulatory effect of a single injection of pure antiestrogen ZK 191703 at early stage of rat estrus cycle

The effects of ZK 191703 (ZK), a pure antiestrogen, on ovulation, follicle development and peripheral hormone levels were investigated in rats with 4-day estrus cycle and gonadotropin-primed immature rats in comparison to tamoxifen (TAM)-treatment. In adult rats, a single s.c. injection of ZK (5 mg/kg) or TAM (5 mg/kg) at an early stage of the estrus cycle (diestrus 9:00) inhibited ovulation, and was associated with suppression of the surge of preovulatory LH, FSH and progesterone. In rats treated with ZK or TAM at a late stage of the estrus cycle (proestrus 9:00), no inhibitory effects on ovulation, the gonadotropin and progesterone surge were detected. ZK treatment at diestrus 9:00, in contrast to TAM, increased the baseline LH level. When immature rats were treated with antiestrogens in the earlier stage of follicular development, 6 and 30 h but not 48 h or later after injection of gonadotropin (PMSG), ovulation was attenuated, associated with a lowered progesterone level. Unruptured preovulatory follicles were found in most of the ovaries from anovulatory animals treated with ZK or TAM. Antiestrogens, ZK and TAM administered at an early phase of the estrus cycle delay the follicular development functionally and inhibit ovulation in rats and suppression of the preovulatory progesterone surge.     

Opioidergic, dopaminergic and adrenergic regulation of LH secretion in prepubertal heifers

Studies have shown inhibitory effects of endogenous opioids on LH secretion in early post-natal heifers. However, it is not clear whether these effects change during the rest of the prepubertal period or whether the inhibitory influences on the GnRH neurones are direct or by way of other neuronal systems. Two experiments were performed in heifer calves to study the developmental patterns of opioidergic, dopaminergic and adrenergic regulation of LH and the possible interactions between opioids and dopaminergic and adrenergic neuronal systems, in the regulation of LH secretion. In Expt 1 four groups each of five heifer calves were used. Blood samples were taken every 15 min for 10 h and each calf received one of the following treatments as a single injection at 4, 14, 24, 36 and 48 weeks of age: (i) naloxone (opioid antagonist, 1 mg kg(-1), i. v.); (ii) sulpiride (dopamine D2 antagonist, 0.59 mg kg(-1), s.c.); (iii) naloxone and sulpiride combined; or (iv) vehicle (control group). Treatments began after the first blood sample was taken. The design of Expt 2 was similar; a separate group of heifer calves was assigned to receive one of the following treatments as a single injection at 4, 14, 24, 36 and 48 weeks of age: (i) naloxone; (ii) phenoxybenzamine (an alpha-adrenoreceptor blocker, 0.8 mg kg(-1), i. v.); (iii) naloxone and phenoxybenzamine; (iv) or vehicle. Results from Expt 1 showed that the maximum concentration of LH and the number of calves responding to treatments with an LH pulse was higher in the first hour after treatments at 36 and 48 weeks of age in the naloxone group compared with the control or sulpiride groups (P < 0.05). These values in the naloxone group also increased over time and were greatest at 48 weeks of age (P < 0.05). In heifers given naloxone + sulpiride treatment at 36 and 48 weeks of age, maximum concentrations of LH in the first hour after treatment did not differ from the naloxone and control groups. In Expt 2, at 36 and 48 weeks of age, treatment with naloxone with or without phenoxybenzamine resulted in higher concentrations of LH than in the controls (P < 0.05). No pulses were seen over the first hour of treatment at 36 and 48 weeks of age in heifers treated with phenoxybenzamine. The 10 h periods of blood sampling at 48 weeks of age revealed that phenoxybenzamine alone suppressed LH pulse frequency and mean serum concentrations of LH compared with the control group (P < 0.05). It was concluded that a strong or more acute inhibition of LH secretion by endogenous opioids developed in mid- to late prepubertal heifers, or alternatively, that removal of opioidergic inhibition at the GnRH neurone unmasked stimulatory inputs that were greater in heifers close to first ovulation. Since sulpiride appeared to negate in part the effects of naloxone on LH release, the suppressive effects of opioids could be exerted in part through the inhibition or blocking of a stimulatory dopaminergic system. alpha-Adrenergic neuronal systems have stimulatory effects on LH release, especially during the late prepubertal period, but do not appear to mediate opioidergic inhibition of LH secretion in prepubertal heifer calves.     

Effect of pinealectomy and of bilateral cervical ganglionectomy on serum LH levels in constant estrous-anovulatory rats.

The effects of pinealectomy or bilateral superior cervical ganglionectomy on serum luteinizing hormone (LH) levels and ovulation were studied in constant estrous-anovulatory rats bearing a frontal hypothalamic deafferentation (FHD). Ovulation returned in 65% of the animals undergoing pinealectomy or bilateral superior cervical ganglionectomy. Almost 50% of these ovulating animals showed elevated serum levels of LH on the day of vaginal proestrus, while the remainder ovulated without appreciable changes in serum LH concentrations. It is suggested that the absence of an LH peak in the latter cases was due to an insufficient sampling size. The results suggest that pinealectomy and cervical sympathectomy may result in LH release by interference with the hypothalamic and brain stem serotonergic system involved in the inhibition of LH release.