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.     

Laparoscopic investigation of the bovine ovary in the periovulatory phase of the cycle

Laparoscopy, in combination with a rapid radioimmunoassay for plasma-LH determination, has been used to predict and observe ovulation in heifers. Experiments on three animals with typical progesterone levels, LH levels and apex formation are described. Ovulation was observed from 25 h to 29 h after the beginning of LH rise and from 17 h to 19 h after LH peak. The LH peak lasted for 9 h to 11 h. Cow ovulation was observed and photographed. The preovulatory follicle, apex formation, ovulation and freshly ruptured follicles are illustrated. The results presented here demonstrate that laparoscopy could offer valuable diagnostic assistance in clinical veterinary medicine.     

Temporal relationship of hormonal peaks to ovulation and sex skin deturgescence in the baboon

The purpose of this study was to determine the temporal relationship of peak levels of oestradiol (E₂), LH and progesterone to ovulation and sex skin deturgescence in the baboon. A total of 55 baboons were used in these studies. Hormonal levels were measured in 47 cycles and ovulation was documented by laparoscopic examination in 26 of these cycles. A temporal relationship of ovulation to sex skin deturgescence was established in 57 cycles. The mean interval from E₂ peak to ovulation was 41.4±2.3 hr, the interval from E₂ peak to LH peak was 17.3±2.0 hr and that from LH peak to ovulation was 18.4±2.0 hr. Eleven baboons showed an LH peak on the day of the E₂ peak. The number of days to the first sign of sex skin deturgescence after ovulation was 2.07±0.14 days (range 0–5 days). Nineteen cycles (33.3%) showed sex skin deturgescence 1 day after ovulation, another 19 cycles (33.3%) showed sex skin deturgescence 2 days after ovulation, and only 13 cycles (22.8%) showed sex skin deturgescence 3 days after ovulation. Sex skin deturgescence was observed on day 0, 4 or 5 postovulation in only two baboons.     

Suppression of luteinizing hormone secretion is removed at late lactation in ovariectomized lactating rats

The effect of the suckling stimulus on pulsatile luteinizing hormone (LH) secretion in mid- and late lactation (days 10 and 20 of lactation) in rats was examined. Pulsatile LH secretion was strongly suppressed on either day 10 or 20 of lactation in intact rats in which the baselines of LH secretion were kept very low. In ovariectomized rats the baseline was kept as low as was observed in intact rats on day 10 of lactation, and pulsatile LH secretion was observed in 3 out of 6 rats. On day 20 the baseline secretion increased and pulsatile LH secretion was observed in 5 out of 6 rats, and the baseline for each rat showed various levels. These results clearly indicate that the pulsatile LH secretion was strongly suppressed until ovulation occurred on day 18-23 of lactation in intact rats and suggest that suppression of pulsatile LH secretion by the suckling stimulus at the hypothalamo-pituitary level is removed in late lactation and the time of the removal varies from animal to animal.     

Ovarian secretion of pregnane compounds at first ovulation in rats treated with pregnant mare's serum gonadotropin

Progesterone, 5 alpha-pregnane-3,20-dione (5 alpha-DHP), 3 alpha-hydroxy-5 alpha-pregnan-20-one (3 alpha-OH), 20 alpha-hydroxy-4-pregnen-3-one (20 alpha-DHP), 20 alpha-hydroxy-5 alpha-pregnan-3-one (20 alpha, 5 alpha), and 5 alpha-pregnane-3 alpha, 20 alpha-diol (DIOL) in ovarian venous plasma at first ovulation in female rats treated on day 30 with 10 IU of pregnant mare's serum gonadotropin (PMSG) were assayed using gas chromatography. Progesterone peaked at late proestrus before ovulation (day 32) and at early diestrus after ovulation (day 34). With the first peak, 5 alpha-DHP and 3 alpha-OH increased. The 20 alpha-DHP level peaked at early diestrus after ovulation (day 34) and remained high thereafter. The 20 alpha, 5 alpha and DIOL peaked at estrus after ovulation (day 33) and then fell slowly. Injection of 2 micrograms of luteinizing hormone (LH) before sample collection increased secretion of 20-keto-pregnane compounds, except when they were at peak levels. The secretion of 20 alpha-hydroxy-pregnane compounds was unaffected by LH at all times tested. These results suggest that rat ovaries without corpora lutea secrete 20-keto-pregnane compounds in response to LH, but that 20 alpha-hydroxy-pregnane compounds are secreted only from ovaries with corpora lutea.     

Effect of estrogen on postovulatory LH surge in baboons.

In normally cycling female baboons, an LH surge appeared prior to ovulation, in addition, another LH surge (postovulatory LH surge) was observed within two days after ovulation. An attempt was then made to determine the effect of postovulatory LH on the luteinization of corpus luteum in baboons. Injections of 300 micrograms estradiol benzoate were given at 09.00 and 16.00 hr daily for 5 days following ovulation; the plasma level of LH was increased, but plasma progestin was suppressed. These results infer that the injected estrogen (estradiol benzoate) may inhibit the luteotrophic effect of postovulatory LH on the corpus luteum, therefore, plasma progestin remains lower even though postovulatory LH is elevated.     

Differential changes in the mechanisms controlling luteinizing hormone and prolactin secretion in middle-aged female rats

Serum luteinizing hormone (LH) and prolactin (PRL) concentrations were measured in young (3-4 month old) and middle-aged (10-12 month old) intact female rats on proestrus, in ovariectomized rats after two estrogen injections (estradiol benzoate; EB, 10 micrograms/100 g body weight, s.c.) or after preoptic stimulation in EB-primed ovariectomized rats. Only animals showing regular 4-day estrous cycles were selected for the experiment. The magnitude of proestrous LH surge was significantly smaller in middle-aged than in young rats. Two BE injections, at noon on Days 0 and 3, in ovariectomized middle-aged rats failed to induce surges in LH secretion on Day 4 whereas the same treatment produced LH surges in ovariectomized young rats. The preoptic electrochemical stimulation (50 microA for 60 sec) produced a prompt rise in serum LH levels in ovariectomized EB-primed young but not in middle aged rats. The preoptic stimulation with a larger current (200 microA) induced LH secretin in middle-aged rats. In none of these situations serum PRL concentrations were different between young and middle-age rats. These results suggest differential aging rates in the preoptic mechanisms governing LH and PRL secretion in the rat. The function of the preoptic ovulatory center in responding to the estrogen positive feedback action and inducing LH secretion may become impaired and independent of the PRL control mechanism, even before the regular estrous cycle terminates.     

Developmental patterns of FSH and LH in female rats deprived of light before puberty.

Plasma FSH and LH levels were examined in female rats reared in the dark at different ages from birth until sexual maturation to investigate whether, and to what extent, external factors such as light, influence gonadotropin levels during development. Control animals were raised in diurnal lighting consisting of 12 hours of light and 12 hours of dark. Light deprivation did not eliminate the characteristic peak of gonadotropins seen in early postnatal development but significantly increased levels of FSH and slightly decreased levels of LH (except for a transient rise at day 12). Constant darkness tended to lower whole body, ovarian and pituitary weights but to increase pineal weight. Whereas the time of eye-opening was the same in control and light-deprived animals, puberty (as judged by vaginal opening and first ovulation) was delayed in animals raised in the dark. The data suggest that environmental light has a mediating action on patterns of gonadotropin release, particularly on FSH, during prepuberal development.     

The modes of the anterior hypothalamic area as the regulatory center for the gonadotropin release

The effects of the anterior hypothalamic area (AHA) implants of gonadal steroid estrogen and progesterone as well as the effects of electrical stimulation and electrolytic lesion confined in this area on the gonadotropin secretion were investigated in ovariectomized estradiol (20 microgram sc)-primed adult Wistar rats housed in light and temperature controlled room. Progesterone implants evoked the rise of serum LH by 6 hr whereas estradiol implants suppressed serum FSH by 24 hr after implantation. Electrical stimulation effectively depleted both gonadotropins with a latency not shorter than 6 hr. The lesion significantly prevented FSH elevation investigated at 72 hr post ovariectomy and potentiated FSH secretion in response to estradiol treatment at 3 week post ovariectomy. The result revealed the involvment of the AHA in LH release mechanism which required progesterone activation while its involvement in FSH regulatory mechanism depended upon estrogen. The area was elucidated as the inhibitory as well as the stimulatory loci for the feedback action of estrogen on FSH release.     

Effect of phenoxybenzamine on luteinizing hormone release in the female rat

To clarify the mode of action of phenoxybenzamine, an alpha adrenergic blocking agent, its effects upon plasma LH levels in ovariectomized rats and upon the ovulatory LH surge expected between 1400 and 1600, the critical period, on the day of proestrus in normal rats were studied. A single injection of phenoxybenzamine, 20 mg/kg, given at 1300 on the day of proestrus bokced ovulation (1 out of 7 ovulating), while plasma LH did not differ from controls between 1500 and 1600. An additional injection of 20 iu HCG at 1500 prevented the ovulation block (83% ovulating). A single phenoxybenzamine injection at 1700 failed to prevent ovulation (5 out of 7 ovulating). The beta adrenergic blocking agents, propanolol and MJ 1999, did not affect ovulation. Treatment with phenoxybenzamine for 2 days, 20mg/kg/day, for 8 days, 10mg/kg/day, were did not prevent the rise causing a reduction in blood flow through the ovary rather than acting as a neurogenic stimulus in the hypothalamus.     

Changes in the concentration of LH, FSH and estrogen in the immature female rat during precocious sexual maturation induced by electrochemical stimulation of the brain.

Electrochemical stimulation of the hypothalamus of 23-day-old female rats induced precocious puberty as judged by occurrence of vaginal opening, the degree of uterine hypertrophy, changes in ovarian steroid content and incidence of first ovulation. Three types of responses were observed: (I) pubertal ovulation within 96 h; (II) pubertal ovulation within 120 h, and (III) vaginal opening at 120 h not followed by ovulation. All treated animals showed a sustained increase in the LH/FSH ratio in both pituitary and plasma. Plasma estrogen was also increased 1 h after stimulation. A preovulatory rise in plasma estrogen and gonadotropins was noted in type I and type II animals. These data lend further support to the suggestion that brain stimulation causes a release of gonadotrophins which induced ovarian steroidogenesis leading to an ovulatory gonadotropin surge via a positive feedback effect.     

Exposure to endotoxin during estrus alters the timing of ovulation and hormonal concentrations in cows

The effect of intramammary (IMM) or intravenous (IV) administration of E. coli endotoxin (LPS), at the onset of estrus, at the time of ovulation was examined. Steroid and gonadotropin concentrations around ovulation were also determined. Lactating Holstein cows (n=33) were assigned to saline-controls (n=12) and treated with LPS-IV (0.5mug/kg; n=13) or LPS-IMM (10mug; n=8). Synchronized cows were observed continuously for estrus. LPS (or saline) was injected within 30min from the onset of standing estrus, at peak estradiol concentrations. The typical rise of body temperature, somatic cell count, cortisol, and NAGase activity was noted. One-third of both LPS-IV- and LPS-IMM-treated cows were manifested by an extended estrus to ovulation (E-O) interval of around 75h or did not ovulate, compared with about 30h in the other 2/3 of LPS cows and all controls. Estradiol concentrations 24h before and after LPS did not differ between groups. However, LPS-IV cows with extended intervals exhibited another estrus and an additional rise of estradiol followed by delayed ovulation. LPS-treated cows with a delayed E-O interval had low or delayed LH surge; two LPS-treated cows did not exhibit LH surge and did not ovulate. All control cows exhibited normal hormone levels. Delayed ovulation was associated with a delayed rise of luteal progesterone. The results indicated that exposing cows to endotoxin during estrus induced a decreased and delayed LH surge in one-third of the cows. This was associated with delayed ovulation, which reduces the chances of successful fertilization.     

Pituitary regulation of preovulatory estrogen secretion in the rat

The factors stimulating estrogen secretion in the preovulatory phase and an attempt to explain the mechanism of termination of estrogen secretion are discussed. Female Wistar rats, hypophysectomized at 1 p.m. in proestrus, were injected with rat pituitary extracts. Ovarian venous blood was collected and the estrogen activity of the plasma was measured. The estrogen secretion was minimized within 3 hours after hypophysectomy. The rat pituitary extract caused an 11-fold increase of estrogen concentration in the ovarian venous blood within 1 hour. Either LH or FSH alone was able to restore the estrogen secretion: LH took 1 hour to reach maximal response, FSH 2 hours. In the 1-hour test, the minimal effective dose for LH appeared to be less than .25 mcg per rat, for FSH, 2.5 mcg per rat. The total ability of the two preparations to produce estrogen appeared to be the same. 10 I.U. of prolactin slightly stimulated estrogen secretion, but 20 mU of ACTH was quite negative. These results demonstrate the pituitary gonadotropin dependency of estrogen secretion from the ovary having ripened follicles. It also showed that the ovary, after completion of ovulatory surge of LH, abolished its reactivity to the pituitary extract containing sufficient amount of substances in promoting estrogen secretion. Either LH or FSH was able to terminate estrogen secretion even at minute doses as small as 10 mcg. This shows that both FSH and LH provide a dual effect on ovarian estrogen secretion at the preovulatory stage, promotion and suppression. Promotion is an acute and direct action of hormones on steroidogenesis and suppression probably a delayed and indirect action of ovulation-inducing hormone, the release of which initiates the differentiation of estrogen-forming cells towards ovulation unfavorable to estrogen synthesis.     

Progesterone administration prolongs the inhibitory effects of hyperprolactinemia on luteinizing hormone secretion in acutely ovariectomized rats

Several studies have shown that hyperprolactinemia in rats inhibits the post-gonadectomy rise in plasma luteinizing hormone (LH) for a limited period only. In intact rats the suppression of plasma LH during hyperprolactinemia is more prolonged. In the present study we have examined the possibility that the elevated levels of progesterone brought about by the raised plasma prolactin levels in intact rats are involved in the maintenance of LH inhibition. We have observed the effect of exogenous progesterone administration during the early post-ovariectomy period on plasma LH levels in female rats made hyperprolactinemic by administration of the dopamine antagonist, domperidone. Following ovariectomy of virgin, female rats, plasma LH was determined on each day from Day 3 to Day 10 after ovariectomy. In control rats plasma LH had increased by approximately 5-fold during the period of the experiment. In control rats treated with progesterone the rise in plasma LH was inhibited temporarily but LH had increased to similar levels to the controls by Day 10. In hyperprolactinemic rats LH was suppressed until Day 7, after which significant rises were observed. However, in hyperprolactinemic rats treated with progesterone, LH did not rise in a similar fashion, and remained low throughout the experiment. We conclude that a combination of hyperprolactinemia and raised plasma progesterone concentrations is necessary for the continued inhibition of LH release after ovariectomy.     

Luteinizing hormone requirements for ovulation in the rat.

Luteinizing hormone requirements for ovulation induction were studied in proestrous rats through detailed observation of the preovulatory surge, through various forms of LH injection under sodium pentobarbital blockade, and through estimation of LH uptake by the ovary. Blood LH levels in individual proestrous rats were obtained every 30 min and grouped according to their peak time (designated 0 h); mean LH levels higher than 7 and 5 ng/ml continued for 30 min and 2.5 h, respectively, the pituitary LH contents at 1400 and 2000 h on the day of proestrus were 2.1 and 0.7 micrograms, respectively, indicating that the amount of LH secreted during the surge was at least 1.4 micrograms. Single intravenous injections of 2 micrograms and 1 micrograms of pure rat LH (NIDDK-rLH-I-7; FSH and prolactin contaminations: 0.02% and less than 0.01%, respectively) to sodium pentobarbital-blocked rats induced ovulation in 4 out of 4 rats and 4 out of 6 rats, respectively, while 500 ng failed to induce ovulation in any (out of 7) rats. Two injections of 300 ng each with an interval of 20 min induced ovulation in 3 out of 8 rats, but if the interval was prolonged to between 30 and 120 min, 100% ovulation was obtained. Blood LH levels in these experiments indicated that a lower long-lasting LH level (about 5 ng/ml blood) is more important than a short, high level for ovulation induction. It was also shown that this level of LH could be given in separate doses if the interval was 30-120 min.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ultrastructure of canine oocytes during in vivo maturation

The aim of the present study was to describe the canine oocyte ultrastructural modifications during in vivo maturation, with precise reference to the timing of the LH surge and of ovulation. Twenty-five bitches were ovariectomized at specific stages between the onset of proestrus and the fifth day post-ovulation: 65 oocytes were observed by transmission electron microscopy (TEM), either before the LH surge (n = 10), between the LH surge and ovulation (n = 12) or after ovulation (n = 43). Prior to the LH surge, the oocyte nucleus had already begun its displacement to the vicinity of the oolemma and reticulated nucleoli were infrequent. The cytoplasm showed signs of immaturity (few organelles preferentially located in the cortical zone, "mitochondrial cloud", scarce cortical granules). The LH surge was immediately followed by cumulus expansion but the ovulation occurred 2 days later. Retraction of the transzonal projections and the meiotic resumption occurred after another 3 days (5 days after the LH peak). The ovulation was then followed by gradual cytoplasmic modifications. Nucleoli re-assumed a reticulated aspect around 24 hr post-ovulation. From 48 hr post-ovulation mitochondria and SER were very numerous and evenly distributed. In conclusion canine oocyte maturation began prior to the LH surge and no cytoplasmic or nuclear modifications followed immediately the LH surge and ovulation. This study suggests that two distinct signals are needed for the final in vivo maturation: one prior to the LH surge (to induce maturation) and another one, around 3 days post-ovulation (to induce meiotic resumption).     

Delayed suppression of serum luteinizing hormone after naloxone treatment in neonatal female rats

In female neonatal rats, opiate receptor blockade markedly raises serum luteinizing hormone (LH) levels. The LH effect of acute treatment with opiate antagonists is apparently brief in older rats; however, age-related differences in antagonist pharmacokinetics may result in different LH response patterns. The duration of LH response to naloxone (NAL) and naltrexone (NTX) was examined in 5 day-old (d.o.) female rats and compared to the duration of analgesia blockade. The rise in serum LH following opiate receptor blockade in 5 d.o. rats was of similar duration to that previously observed in older animals and much briefer than blockade of analgesia. Furthermore, neonatal rats exhibited a delayed suppression of LH 6 hr following NAL, but not NTX, treatment. Stimulation and later suppression of LH were still observed after five repetitive NAL treatments at 6 hr intervals.     

Progesterone-synthesizing ability of preovulatory follicles of cows relative to the peak of LH

Preovulatory cow follicles (n = 34) were collected at different times after the onset of oestrus until shortly before ovulation. In-vitro conversion of tritiated pregnenolone in the presence of NAD+ by homogenates of the follicular wall was compared in phases relative to the LH peak. During phase 0 (before the LH surge) a moderate conversion into progesterone occurred, but it was subsidiary to that into 17 alpha-hydroxypregnenolone and other unidentified steroids. During phases 1 (0-6 h after the LH peak), 2A (6-14 h) and 2B (14-20 h) the production of progesterone and 17 alpha-hydroxypregnenolone remained constant; at phase 2B the percentage of remaining pregnenolone was higher than in the preceding phases. In phase 3 (20 h after the LH peak until ovulation) conversion into progesterone had increased about 4-fold to the highest levels observed (97% after 2 h incubation), and production of 17 alpha-hydroxypregnenolone and unidentified steroids was low. In an additional experiment, homogenates of the wall of 3 follicles at phase 3 were also incubated with tritated progesterone in the presence of NADPH. The percentage of remaining progesterone was high, and a moderate conversion into 17 alpha-hydroxyprogesterone occurred. In the main experiments, however, production of this steroid was not observed. The results indicate that steroid synthesis in the preovulatory follicle of the cow changes to the production of progesterone shortly before ovulation.     

Effect of coitus on serum levels of testosterone and LH in male and female rabbits.

Levels of testosterone (T) and LH in the peripheral serum of male and female rabbits were measured and compared following coitus. Blood was collected by heart puncture from restrained, unanesthetized animals of both sexes. In male rabbits, basal serum T levels were highly variable, ranging from 131 to 12,149 pg/ml, and if low preceding coitus they tended to rise; whereas, if high, they usually dropped as they did in nonmated males subjected to repeated heart punctures. In contrast, basal serum LH levels in males were quite constant (mean +/- SE, 1993 +/- 152 pg/ml) and were not significantly altered after coitus unless blood T levels had been drastically lowered by two priming doses of estradiol benzoate. In intact does, on the other hand, copulation which resulted in ovulation induced an approximately 20-fold increase in serum LH concentration which was sustained for about 4 hr. Postcoital elevations in serum LH also occurred in estrogen-primed intact and estrogen-primed ovariectomized does. Under the conditions of our experiments, the parallel elevations in serum LH and T observed postcoitally in the female rabbit could not be demonstrated in the male.     

Periovulatory time courses of plasma estradiol and progesterone in the Japanese monkey (Macaca fuscata)

Periovulatory time courses of plasma estradiol and progesterone were determined in 21 menstrual cycles of 20 Japanese monkeys. Both steroids were measured by radioimmunoassay. Ovulation was detected by serial laparoscopic observations of the ovaries. Three of the 21 cycles were anovulatory cycles. In the remaining 18 ovulatory cycles, a preovulatory estradiol peak occurred on day 12.2±1.4 (range 10–15) of the menstrual cycle. The estradiol concentration at the peak was 431±199 (range 210–930) pg/ml. The time interval between the estradiol peak and ovulation was within 48 hr; the shortest interval was 10–13 hr and the longest 32–48 hr. Although the progesterone levels began to increase slightly (0.6–1.4 ng/ml) before ovulation, they did not show a continuous increase but decreased once before ovulation. The increase in progesterone with development of the corpus luteum after ovulation was very gradual during the first 2 days after ovulation. Subsequently, in 13 of 18 ovulatory cycles the progesterone levels rose rapidly and reached a maximum, 4.0±1.2 (range 2.3–5.7) ng/ml, 4–8 days after ovulation. In 5 of the 18 cycles, the progesterone levels did not rise at all or did not exceed 2.0 ng/ml even if they showed more or less an increase. In the 5 cycles, the length of the luteal phase was 8.2±1.6 (range 6–10) days, which was significantly shorter than that of the former 13 cycles with 14.0±1.1 (range 13–16) days.