Increased bioactivity of serum follicle-stimulating hormone, but not luteinizing hormone, following hemicastration in ram lambs

This study evaluated the short-term effects of hemicastration on levels of bioactive (bio-) and immunoactive (immuno-) FSH and LH in 3.5-mo-old ram lambs. Biological activities of FSH and LH were determined using in vitro rat granulosa cell aromatase and mouse Leydig cell testosterone assays, respectively. Four rams each were either hemicastrated (HC) or left intact (INT) and blood samples were collected over a 2-wk period. In HC rams, serum bio- and immuno-FSH concentrations increased several fold within 5-8 h after surgery and remained elevated over INT controls for 7 and 14 days, respectively. The increase in bio-FSH was greater than that for immuno-FSH, resulting in an increase in the ratio of biological to immunological activity (B/I ratio) through Day 7. Neither immuno-FSH, bio-FSH, nor the B/I ratios varied throughout the 2-wk study in INT rams. In contrast to FSH, serum concentrations of immuno- and bio-LH and the B/I ratios were similar between HC and INT rams. For both gonadotropins, biological activity was positively correlated to immunological activity. These results demonstrate that (1) immuno- and bio-FSH concentrations are elevated after hemicastration; (2) the FSH biopotency (B/I ratio) also is increased, at least temporarily; and (3), despite these changes in FSH production, neither immuno- nor bio-LH secretion is altered by hemicastration.     

Changes in serum immunoreactive inhibin and follicle-stimulating hormone during gonadal development in male and female rats.

We have measured serum and ovarian immunoreactive inhibin alpha (irI alpha) and serum FSH in fetal and neonatal rats from 20 days of gestation until 40 days of age. For animals aged 10 days or older, serum measurements were made on intact and gonadectomized animals. Serum irI alpha was detectable in intact male and female rats at all ages studied. In females, irI alpha levels were low until Day 5 and then increased steadily to peak at Day 25. Thereafter they declined until Day 35 to reach levels typical of adult females. There was a significant decrease in irI alpha levels 24 h after ovariectomy at all ages. Serum FSH levels in females were low until Day 7, then increased rapidly to plateau from Days 10-15. The levels then declined until Day 25 and were generally unchanged after that time. There was a significant increase in FSH 24 h after ovariectomy in rats aged 20 days and older, and in younger rats by 48 h after ovariectomy. In male rats, serum irI alpha levels were significantly higher than females until Day 7. The levels increased at Day 7 and then remained relatively constant until Day 20, after which they declined to reach typical adult male levels. Serum irI alpha levels were significantly lower in males than females from Days 25-40. There was a significant decrease in serum irI alpha 24 h after castration at all ages studied. Serum FSH levels in males were low until Day 20, increased at Day 25, and thereafter remained relatively unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes in gonadotrope responsivity to gonadotropin releasing hormone during development of the rhesus monkey

To assess the changing responsiveness of pituitary gonadotropes to gonadotropin releasing hormone (GnRH) during development, 5 male and 5 female rhesus monkeys were studied. Three monkeys of each sex were tested periodically with a subcutaneous injection of 500 micrograms of GnRH dissolved in 50% polyvinylpyrrolidone (PVP) beginning at 2 to 4 weeks of age and continuing into young adulthood. The remaining 4 monkeys received injections of the vehicle (PVP) alone and served as controls. Serum concentrations of bioactive luteinizing hormone (LH) were determined by an interstitial cell testosterone bioassay, and follicle-stimulating hormone (FSH) levels were measured by radioimmunoassay. Baseline FSH levels in the 5 female neonatal monkeys were higher than those of the 5 male neonatal monkeys during the first 2 months of life. In both sexes, FSH concentrations decreased with age, and FSH was barely detectable by 6 months. Baseline LH values in the 5 female monkeys declined during the first 6 months of the study and were undetectable (less than 0.5 micrograms/ml) at 6 months of age. Baseline LH levels in 4 of the 5 neonatal males also declined to undetectable concentrations by 6 months of age. During the first 3 months of life, there was a striking increase in the serum concentrations of both LH and FSH following GnRH. Although the LH responses to GnRH (delta LH) were similar in males and females of comparable ages, the FSH responses (delta FSH) were considerably greater in the female monkeys. In the males, the delta LH exceeded the delta FSH, whereas in the females, the delta FSH were greater than the delta FSH. In both sexes, the delta LH and delta FSH generally were greatest in the youngest monkeys and decreased gradually with increasing age. By 6 months, the gonadotropin responses to GnRH either were undetectable (males) or very small (females). After 6 months there was no longer an increase in serum gonadotropins after GnRH in either sex until 1.5-4 years (females) or 3 years (males) of age. The delta LH in response to GnRH in the male monkeys 3-5 years of age were comparable to the responses during the first month after birth. Serum concentrations of FSH in the adult males, however, did not increase after GnRH. In the female monkeys, serum levels of LH and FSH increased after GnRH at 1.5 years (1 monkey) and 4 years (2 monkeys) of age. The delta LH were similar to those of the 1- to 2-month-old female monkeys. The delta FSH, however, were variable and were approximately 20% of the neonatal response. In these young adult female monkeys the delta LH exceeded the delta FSH.(ABSTRACT TRUNCATED AT 400 WORDS)     

Changes in serum FSH concentrations in the pig during development

Serum FSH concentrations were measured in fetal and prepubertal pigs between 40 days postcoitum and 25 weeks after birth. In addition, serum FSH was estimated in prepubertal, unilaterally cryptorchid, freemartin and castrated pigs. The average serum FSH concentrations in male and female fetuses was low (less than 2 ng/ml) until 80 days p.c. During the remaining fetal period, concentrations in females were elevated (7.9 +/- 0.4 ng/ml) and remained fairly constant after birth (16.3 +/- 0.8 ng/ml). In the male, serum FSH concentrations gradually rose to 22.5 +/- 5.5 ng/ml during the first 3 weeks after birth and declined thereafter. The changes in FSH concentrations in male pigs are reflected in gonadal-development. In contrast, in fetal and prepubertal females, ovarian development seems not to be influenced by changes in serum FSH concentrations. Unilateral cryptorchidism did not affect serum FSH concentrations. After castration, however, concentrations rose significantly. In freemartin pigs concentrations were similar to those in female pigs.     

Effects of ovariectomy on clock-timed daily gonadotropin rhythms in prepubertal golden hamsters

Daily rhythms of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) are measurable in the serum of prepubertal female golden hamsters by 17 days after birth. These rhythms, which are characterized by peak levels at 1700 h, persist until they are replaced by a 4-day rhythm as ovulatory cycles begin, approximately 3 wk later. We have tested the proposition that the ovaries are required for the onset and maintenance of clock-timed gonadotropin release by removing the ovaries and measuring the levels of LH and FSH in prepubertal hamsters. Ovariectomy was performed both before and after the onset of the rhythm and the effect of removal was determined by subsequent collection of blood samples during the mid- to late-prepubertal period. Ovariectomy on 7, 10 or 13 days after birth results in tonic levels of LH and FSH in blood samples collected at 1400, 1700 and 2000 h on Days 17 through 29. Sham-operated or intact controls had significantly elevated levels of these hormones at 1700 h. Ovariectomy on Day 21 and killing on Day 25 at the same times of day abolished the rhythm of serum LH measured in sham-ovariectomized controls. Ovariectomy on Day 21 and killing on Days 26, 28 or 30 at hourly intervals resulted in variable but nonrhythmic patterns of circulating LH. Thus, ovariectomy before the initiation of clock-timed gonadotropin release prevented its initiation; ovariectomy after its initiation abolished the rhythm. These results show that the ovary provides an essential "message" to the brain-pituitary axis for the initiation and maintenance of clock-timed gonadotropin release in prepubertal females.     

Effect of vascular cannulation on serum concentrations of LH, FSH, prolactin and cortisol in prepubertal gilts

Two experiments were conducted to determine whether cannulation of the jugular vein in gilts alters serum concentrations of LH, FSH, prolactin (PRL) or cortisol (C). In Experiment 1, 12 crossbred prepubertal gilts weighing 95 +/- 1.3 kg were immobilized by snaring, and tygon tubing was threaded into the anterior vena cava through a 12-gauge needle inserted into the jugular vein. Five hours later, blood samples were drawn at 20-min intervals for 4 h (Day 0). Samples were also drawn at 20-min intervals for 4-h periods 24 h (Day 1) and 48 h (Day 2) after cannulation. Serum concentrations of LH were similar (P=0.26) among Day 0 (0.40 ng/ml), Day 1 (0.39 ng/ml) and Day 2 (0.34 ng/ml). Serum PRL was similar (P=0.07) among Day 0 (4.10 ng/ml), Day 1 (3.87 ng/ml) and Day 2 (3.43 ng/ml). Serum concentrations of C were greater (P < 0.001) on Day 0 (8.32 ng/ml) than Day 1 (4.48 ng/ml) or Day 2 (3.54 ng/ml). In Experiment 2, cannulas were placed in 29 prepubertal gilts. Two days after initial cannulation, six blood samples were drawn at 20-min intervals. Gilts were then immobilized by snaring, and a second cannulae was inserted into the contralateral vein. Five blood samples were taken at 2-min intervals during the second cannulation and then six samples were drawn at 20-min intervals. Serum LH and FSH were not altered by cannulation or elevated during the subsequent 2-h sampling period (P>0.05). In contrast, serum concentrations of PRL rose slowly (P<0.05) during cannulation and remained elevated for 60 min before returning to baseline. Serum concentrations of C rose within 6 min of cannulation, remained elevated for 30 min, and then declined over the next 90 min. From these two experiments, it appears that secretory patterns of LH and FSH can be accurately assessed immediately after cannulation in prepubertal gilts. Measurements of serum PRL and C that reflect nonstressed conditions, however, cannot be obtained until at least 2 h or 1 d after cannulation, respectively.     

Blood concentrations of gonadotrophins, prolactin and gonadal steroids in males and in non-pregnant and pregnant female African elephants (Loxodonta africana)

No seasonal variation in any of the hormones measured was apparent in males or females. Testosterone levels in males increased around puberty (10-11 years) and remained significantly higher in adult than prepubertal males. This was not accompanied by any significant change in levels of LH, FSH or prolactin. In non-pregnant females there was no apparent difference in levels of LH, FSH or prolactin with age. There was a significant increase in progesterone around puberty (12 years) but there was considerable overlap in values between prepubertal and adult females. During pregnancy, progesterone levels were significantly higher than in non-pregnant females with maximum levels occurring at mid-pregnancy (9-12 months). However, there was considerable overlap in values between non-pregnancy and pregnancy. Concentrations of LH and FSH decreased significantly during mid-pregnancy while prolactin levels increased dramatically during pregnancy; after 7 months of gestation until term levels were always at least 8 ng/ml greater than in any non-pregnant female. It is suggested that this consistent increase in plasma/serum levels of prolactin can be used to diagnose pregnancy in the elephant.     

Negative feedback regulation of gonadotropin secretion by androgens in fetal rhesus macaques

Previously we described sex differences in circulating gonadotropin concentrations (greater in females) in fetal rhesus macaques, and demonstrated that these sex differences relate, at least in part, to the negative feedback actions of testicular secretions. A fully functional gonadal-hypothalamic-pituitary feedback relationship is present as early as Day 100 of gestation in fetal males because castration at this time results in a dramatic increase (greater than 10-fold) in fetal luteinizing hormone (LH) concentrations. Although short-term (6-h) treatment of fetuses with testosterone (T) 3 wk after gonadectomy (GX) does not lower LH levels in males, it is completely effective in females. These data suggest that either T is not the primary testicular factor responsible for feedback suppression of LH in fetal males, or the hypothalamic-pituitary axis becomes insensitive to T after GX. To determine if immediate treatment with T after GX is effective in maintaining LH levels, we gonadectomized five fetal rhesus males on Days 98-104 of gestation and immediately implanted crystalline-T-containing intraabdominal Silastic capsules. An additional five fetuses were treated with the nonaromatizable androgen dihydrotestosterone (DHT). Umbilical arterial samples for hormone analysis were obtained prior to GX and again approximately 3 wk later. Serum from control males (n = 11) castrated in utero on Day 100 of gestation contained significantly greater concentrations of LH and follicle-stimulating hormone (FSH) 3 wk after the operation than before GX. Five sham-operated male fetuses did not have elevated levels of either LH or FSH in their serum on Day 120 of gestation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of a gonadotrophin-releasing hormone antagonist on gonadotrophin secretion and gonadal development in neonatal pigs

Male (N = 8) and female (N = 8) pigs were assigned to receive saline or a potent GnRH antagonist ([Ac-D2Nal1,D4-Cl-Phe2,D-Trp3,D-Arg6, D-Ala10]- GnRH*HOAc; 1 mg/kg body weight) at 14 days of age. The GnRH antagonist caused LH to decline (P less than 0.01) from 1.7 ng/ml at 0 h to less than 0.5 ng/ml during 4-32 h in males and females. Concentrations of FSH in gilts declined slowly from 75 +/- 8 to 56 +/- 5 ng/ml (P less than 0.05) at 32 h. In males FSH was low (5.7 +/- 0.5 ng/ml) at 0 h and did not change significantly. To observe the effect of long-term treatment with GnRH antagonist, 10 male and 10 female pigs, 3 days of age, were treated with saline or 1 mg GnRH antagonist per kg body weight every 36 h for 21 days. Concentrations of LH were reduced (P less than 0.01) to 0.2-0.4 ng/ml throughout the experimental period in male and female piglets treated with GnRH antagonist. Plasma FSH increased in control females, but remained suppressed (P less than 0.001) in females treated with GnRH antagonist. Treatment with the GnRH antagonist suppressed FSH levels in males on Days 8 and 16 (P less than 0.05), but not on Day 24. Treatment of females with the GnRH antagonist did not influence (P greater than 0.10) oestradiol-17 beta concentrations. Administration of GnRH antagonist to males suppressed testosterone and oestradiol-17 beta values (P less than 0.01) and reduced testicular weight (P less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)     

Plasma luteinizing hormone levels in normal and prenatally stressed male and female rat fetuses and their mothers

Concentrations of luteinizing hormone (LH) were measured in plasma of fetal and neonatal rats obtained from control mothers and from mothers exposed to stress from Days 14 to 21 of gestation. The regimen of stress used is known to be associated with an abnormal ontogenetic pattern of testosterone secretion from the fetal testes. The overall ontogenetic pattern of immunoreactive LH levels in plasma was similar in male and female rats, and was unaffected by stress. In all groups, LH was low from Days 16 to 20 of gestation, and then rose progressively through birth, i.e. Day 23. However, stressing the mother significantly decreased the already low levels of LH between Days 16 and 20, as indicated by a larger percentage of samples from stressed fetuses of both sexes with LH levels below the limit of sensitivity of the assay. Sex differences in both the control and stressed group became evident only after Day 20 of gestation, with plasma concentrations of females exceeding those of males from Day 21 to 23 post-conception.     

Effect of gonadectomy and steroid treatment on the receptor-binding activity and immunoreactivity of serum and pituitary FSH in the adult rats of both sexes

The receptor binding activity (R) and immunoreactivity (I) of serum and pituitary FSH were measured in normal, gonadectomized, and gonadal steroid-treated rats of both sexes employing radioreceptor assay and radioimmunoassay, respectively, and R/I ratios were analyzed. At 11 weeks of age, R/I ratios of serum and pituitary FSH were significantly higher in normal females than in males. From 11 to 13 weeks of age, the ratios of both FSH further increased in females, while in males, the ratio of serum FSH decreased and that of pituitary FSH increased. Orchiectomy caused an increase in the ratio of serum FSH, while ovariectomy caused a decrease, so the ratios in the gonadectomized animals of both sexes became almost equal, suggesting the secretion of a gonadectomy type FSH in these animals. Both testosterone propionate (TP) and estradiol benzoate (EB) treatments decreased the ratios of serum FSH in gonadectomized rats. However, TP and EB had an effect opposite on the ratio of pituitary FSH in these rats, i.e. TP caused a decrease, while EB caused an increase. This effect was more obvious in females than in males. These observations indicated that the presence and absence of the gonads, and the gonadal steroids influence not only the quantity but also the quality of FSH. The changes in the quality of the hormone are discussed in relation to its multiplicity.     

A role for aromatizable androgens in female rat puberty

The function that aromatizable androgens may have in female puberty is unclear. The present experiments were undertaken to examine, using a quantitative approach, the role that physiological levels of these androgens may play in determining the timing of vaginal opening and first ovulation in female rats. Serum androstenedione (delta 4) levels increased markedly between Postnatal Days 4 and 8, remained elevated through Day 16, and declined thereafter to remain at about 100 pg/ml throughout juvenile development (Days 20-32). Serum testosterone (T) also increased, though less prominently after Postnatal Day 4. Maximal values were found at Day 12 (about 150 pg/ml); thereafter, T levels decreased to intermediate values (about 100 pg/ml), which were maintained during juvenile days. Serum dehydroepiandrosterone (DHA) remained undetectable throughout prepubertal development. At puberty, serum delta 4 increased 2.5-fold, but only at the time of the preovulatory luteinizing hormone (LH) surge. In contrast, T levels increased significantly 2-fold on the early proestrous-2 phase of puberty, 3.5-fold on the morning of first proestrus, and 9-fold at the time of the LH surge. Serum DHA remained undetectable. Implantation of Silastic capsules containing T at 2 or 6 mg/ml oil into juvenile 28-day-old rats resulted in serum T levels similar to those found on early proestrous 2 (about 150-180 pg/ml) and at 1300 h of first proestrus (ca. 300-400 pg/ml), respectively. Both treatments induced precocious vaginal opening, but failed to advance first ovulation. About 50% of the T-implanted rats had ambiguous estrous-type vaginal cytology preceding the day of first diestrus, and failed to show corpora lutea at this time.(ABSTRACT TRUNCATED AT 250 WORDS)     

Development of the sex difference in glandular kallikrein and prolactin levels in the anterior pituitary of the rat

Glandular kallikrein is a major estrogen-induced and dopamine-repressed protein of the rat anterior pituitary that appears to originate from lactotrophs. This study examined the development of glandular kallikrein levels in the anterior pituitary in both female and male rats and compared it to anterior pituitary prolactin. In addition, the development of glandular kallikrein levels in the neurointermediate lobe of the pituitary and the kidney were also examined. During puberty, a dramatic surge in glandular kallikrein occurred in female anterior pituitaries (16- to 20-fold increase) and levels remained elevated thereafter. The dynamics of the increase were biphasic--glandular kallikrein increased between Day 30 and 45, plateaued between Days 45 and 55, and then increased again between Days 55 and 65. Female anterior pituitary prolactin increased 7- to 8-fold during puberty. The rise during puberty was biphasic and was generally synchronized with increases in glandular kallikrein. However, the initial rise was proportionately less than that of glandular kallikrein, and the secondary surge was more dramatic. In contrast to females, anterior pituitary glandular kallikrein remained at low levels in male rats; prolactin levels also remained unchanged through puberty and increased moderately thereafter. Glandular kallikrein in the female neurointermediate lobe remained unchanged through Day 55, almost doubled on Day 60, and returned to prepubertal levels by Day 65; males did not exhibit the transient surge in neurointermediate lobe levels. Starting at age 60 days, renal glandular kallikrein was found to be slightly higher (15-20%) in females than in males.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cocaine inhibits mating-induced, but not human chorionic gonadotropin-stimulated, ovulation in the rabbit.

The effects of cocaine on ovulation and corpus luteum function were investigated in New Zealand White rabbits. Forty females were randomly assigned to control and cocaine-treated groups. Controls were given vehicle s.c. daily for 5 days and cocaine-treated rabbits received 40 mg/kg cocaine hydrochloride s.c. daily for 5 days. One hour after the last cocaine dose, half the control and half of the cocaine-treated groups were mated with fertile males and the other half of each group received hCG i.v. Serial blood samples were obtained over 4 h on the day of mating or hCG treatment (Day 0), and then at intervals from Days 1-18. No mated, cocaine-treated rabbits ovulated, vs. 6 of 10 controls (chi-square: p = 0.01). In contrast, all animals given hCG had comparable numbers of corpora lutea (control: 7.1 +/- 0.8; cocaine: 5.7 +/- 0.8). Peak levels of benzoylecgonine (the major cocaine metabolite) occurred between 180 and 240 min after cocaine administration. In cocaine-treated animals that were mated, Day 0 serum LH (repeated measures MANOVA, p less than 0.01) and FSH (p less than 0.03) concentrations were lower than those in pregnant controls. Serum LH and FSH levels for all hCG recipients (cocaine-treated and control) did not differ. Serum prolactin concentrations in mated, pregnant rabbits were higher than in all other groups; cocaine treatment did not affect this hormone.(ABSTRACT TRUNCATED AT 250 WORDS)     

Acute suppression of FSH secretion by oestradiol in the ovariectomized rhesus monkey

Using long-term ovariectomized rhesus monkeys, we examined the ability of oestradiol to decrease circulating FSH concentrations in the absence of other ovarian factors. Daily blood samples were obtained from untreated monkeys for 8 days, followed by insertion of oestradiol capsules after the Day-8 sample was taken. Samples were then taken on Days 9-15, the capsules were removed after the Day-15 sample, and samples were obtained on Days 16-19. Serum was assayed for concentration of oestradiol, FSH and LH by RIA. The concentration of FSH (ng/ml) in serum did not change during the first 8 days before oestradiol treatment (overall mean = 356 +/- 55) but decreased from the Day-8 value of 320 +/- 8 to 190 +/- 42 on Day 9 and by Day 15, after 7 days of oestradiol treatment, had reached a nadir of 20 +/- 5. By Day 17, i.e. 2 days after removal of the oestradiol capsules, serum FSH had increased (P less than 0.05) to 92 +/- 23 with a further increase (P less than 0.05) on Day 19 (171 +/- 16). This study demonstrates that, unlike in rats, mice, and sheep, administration of oestradiol alone to ovariectomized rhesus monkeys reduces immunoreactive serum FSH to concentrations measured in intact animals.     

Administration of a gonadotropin-releasing hormone antagonist to mares at different times during the luteal phase of the estrous cycle

The GnRH antagonist cetrorelix was given during the early (Days 1-5), mid (Days 6-10 or 5-12) or for the entire (Days 1-16) luteal phase of mares to inhibit the secretion of FSH and LH (Day 0=ovulation). Frequent blood sampling from Day 6 to Day 14 was used to determine the precise time-course of the suppression (cetrorelix given Days 6-10). Cetrorelix treatment caused a decrease in FSH and LH concentrations by 8 and 16 h, respectively, and an obliteration of the response to exogenous GnRH given 24h after treatment onset. Treatment never suppressed gonadotropin concentrations to undetectable levels; e.g. frequent sampling showed that the nadirs reached in FSH and LH were 46.2±6% and 33.1±11%, respectively, of pre-treatment concentrations. Daily FSH concentrations were decreased in all treatment groups but daily LH concentrations were lower only when treatment commenced at the beginning of the luteal phase; progesterone concentrations depended on the time of cetrorelix administration, but the changes suggested a role for LH in corpus luteum function. The inter-ovulatory interval was longer than controls when cetrorelix was given in the mid- or for the entire luteal phase, but was unaffected by treatment in the early phase. Nevertheless, in all groups, FSH concentrations were higher (P<0.05 when compared to Day 0, subsequent ovulation) approximately 6-10 days before this next ovulation. This consistent relationship suggests a stringent requirement for a GnRH-induced elevation of FSH above a threshold at, but only at, this time; i.e. approximately 6-10 days before ovulation.     

FSH and LH concentrations in periparturient mares.

The influence of the ovaries and presence of a foal on periparturient concentrations of FSH and LH were studied in 19 Pony mares. In intact and ovariectomized mares, mean concentrations of FSH fluctuated between 1.1and 9.9 ng/ml on Days -14 to-1 before parturition (Day 0). A surge of FSH occurred in all mares in association with parturition. From Days 1 to 10, the high levels of FSH gradually decreased in the intact group to the minimal concentrations that occur during oestrus, but remained elevated in the ovariectomized mares. There were no significant pre-partum changes in LH in either type of mare. Post-partum changes in LH concentrations increased at a similar rate in ovariectomized and intact mares. The presence of a foal significantly lengthened the interval to first oestrus, depressed LH levels on Days 6--10 and decreased the FSH concentrations as averaged over the 10 days before the first ovulation after parturition.     

Effect of FSH deprivation at specific times on follicular maturation in the bonnet monkey (Macaca radiata)

Cyclic monkeys were deprived of FSH for specific periods on different days of the follicular phase by injecting them with minimal doses of an FSH antiserum characterized for specificity and bioneutralizing ability. The effect of the antiserum on follicular maturation was assessed by determining (a) serum oestrogen concentrations through the midcycle period, (b) serum progesterone concentrations as an index of ovulation and luteal function, (c) laparoscopic examination of the surface of the ovary when necessary, and (d) overall cycle length. While antiserum injection on Day 5 of the cycle caused delay in the oestrogen surge from Days 9 to 11, injection on Day 6 led to the occurrence of two oestrogen surges, on Days 9 and 14. Laparoscopic examination showed that the earlier follicle had disappeared and a new follicle had appeared by Day 14. Antiserum injection on Day 7 of the cycle arrested further growth of the maturing follicle, but a new follicle appeared 9 days later, as indicated by a surge of oestrogen on Day 16. Injection of antiserum beyond Day 7 had no effect on follicular development, ovulation and luteal function. These observations suggest that the mature follicle becomes relatively independent of FSH support about 48 h before ovulation and this event could be a marker for follicular dominance.