Binding kinetics of the long-acting gonadotropin-releasing hormone (GnRH) antagonist antide to rat pituitary GnRH receptors.

The GnRH antagonist Antide has been shown to produce prolonged inhibition of gonadotropin secretion in ovariectomized monkeys and other animal models. The reasons for such a long duration of action have not yet been clarified. To understand the mode of action of this new antagonist, we have performed association and dissociation binding kinetics using either crude rat pituitary homogenates as source of GnRH receptors or dispersed pituitary cells in culture. The binding characteristics of the radioiodinated Antide analog 125I-labeled[D-Tyr0] Antide to GnRH receptors in rat pituitary homogenates were comparable to those of the first generation GnRH antagonist 125I-labeled [Ac(3)Pro1,pFD-Phe2,D-Trp3,6]GnRH or the GnRH agonist 125I-labeled [D-Trp6,(N-Et)Pro9,Des,Gly10]GnRH, with an affinity constant (Ka) in the 10(10) M-1 range. The maximum binding capacity was consistently higher with the antagonist tracers than with the [125I]GnRH agonist. Both antagonists dissociated at a slower rate at 4 C (approximately 4 times) than the [125I]GnRH agonist. Incubation at 23 C of 125I-labeled [D-Tyr0] Antide previously bound at 4 C resulted in complete dissociation within 8 h after the addition of an excess amount of any of the GnRH analogs; in addition, simple dilution of the incubation medium produced spontaneous dissociation at this temperature. Using rat pituitary cells, Antide was found to inhibit the LH response to native GnRH (10(-8) M) in a dose-related manner. To test whether the binding of Antide is normally reversible at 37 C, Antide (10(-7) M) was added to the culture medium 3 days after cell plating, and the initial preincubation was resumed for 24 h. Cells were then washed twice, and dissociation was allowed to take place. Bound Antide was shown to dissociate rapidly at 37 C, as cells previously treated with Antide produced a full LH response within 24 h if challenged with native GnRH. In conclusion, the binding kinetics of 125I-labeled [D-Tyr0]Antide to GnRH receptors, which should reflect those of Antide, did not present abnormal features. Although this antagonist, similar to other GnRH antagonists, dissociated from pituitary receptors at a slower rate than GnRH analogs, rapid and spontaneous dissociation was achieved at 23 C with simple dilution, and dissociation of unmodified Antide occurred at 37 C. Taken together, our results support the concept that the long duration of action of Antide is not due to any toxic effect of Antide at the receptor site and could derive only marginally from the slow dissociation rate of this antagonist.

Evidence that neuropeptide Y could represent a neuroendocrine inhibitor of sexual maturation in unfavorable metabolic conditions in the rat.

Neuropeptide Y (NPY) is known to be involved in the central regulation of appetite, sexual behavior and reproductive function. Whereas central administration of NPY strongly stimulates feeding, diet restriction produces overexpression of NPY in the arcuate and paraventricular nuclei that might reflect behavioral adaptations to shortage of food. The role of NPY for the regulation of sexual function is still controversial. Whereas NPY is stimulatory during proestrus in the rat, acute administration of NPY is inhibitory in castrated animals and we have shown that chronic administration of NPY inhibits both the gonadotropic and somatotropic axis in adult female rats. In order to further analyse the role of NPY during sexual maturation, a model of delayed sexual maturation imposed by food restriction and return to ad-libitum feeding was used. Young female rats were restricted to 7-8 g food daily starting at 24 days of life (d). This restriction completely prevented sexual maturation. At 50 d, ICV cannulas were placed and at 60 d, Alzet minipumps either delivering NPY (18 micrograms/day) or vehicle into the ICV cannula were implanted dorsally. At 61 d, rats were switched to ad-libitum feeding, a change that produced vaginal opening within 4 days in all vehicle-treated rats. In the rats receiving NPY, significantly increased food intake and weight gain were observed but only one out of the 9 rats studied experienced vaginal opening at 66 d, the other 8 animals remaining sexually immature at 67 d at sacrifice. Sexual immaturity of NPY-treated rats was further confirmed by decreased ovarian weight and reduced number of pituitary GnRH receptors. Plasma IGF-I levels were markedly reduced in NPY-treated rats. Since food restriction has been shown both to increase hypothalamic NPY and to reduce or inhibit sexual function, these data bring evidence for the first time that NPY could be involved in the inhibition of sexual maturation imposed by food restriction, since maintenance of elevated NPY levels in the hypothalamus did prolong this state of sexual immaturity despite restoration of normal food intake.

Growth hormone (GH) deprivation induced by passive immunization against rat GH-releasing factor does not disturb the course of sexual maturation and fertility in the female rat.

The importance of normal GH secretion for the onset of sexual maturation is a subject of controversy. Also, the need to achieve a minimal body size or body fat content has been postulated to be of importance for determining the timing of the onset of puberty. To evaluate the importance of GH secretion on the onset of sexual maturation in the female rat, GH deprivation has been induced by treating prepubertal rats with antirat GRF serum to passively immunize these animals against GRF. Chronic administration of anti-GRF serum produced in all series an impressive reduction in growth rate (from 5 to 2 g/day), resulting in a body weight averaging 50-60% the normal value at 50 days of life. Despite this deficit in growth, sexual maturation, as established by vaginal opening and first estrous cycles, occurred at the normal age in three of four series of rats; in one series, however, sexual maturation was delayed by 4 days, but thereafter, all parameters indicated that the gonadotropic axis was normally activated. In one series, fertility was tested at 59 days of age in females with a body weight corresponding to 51% of the control weight; these females conceived and delivered a reduced number of pups (9.4 +/- 0.7 instead of 14.2 +/- 0.8 in control dams), but the pups were of normal size. In a second experimental approach, the effect of GH deprivation was evaluated in a model of late sexual maturation obtained by severe food restriction followed by a switch to ad libitum feeding. Severe food restriction initiated at approximately 28 days, when the body weight was 75 g, drastically reduced the growth rate and completely prevented sexual maturation. A switch to ad libitum feeding at 50 days provoked an important compensatory growth and the occurrence of sexual maturation 4 days later. Passive immunization against GRF during this recovery phase did reduce the growth rate, but did not delay sexual maturation. Plasma insulin-like growth factor-I (IGF-I) secretion was very low in food-restricted rats and in each situation with induced GH deprivation. During food restriction, plasma IGF-binding protein-3 (IGFBP-3) and to a lesser extent IGFBP-1 were decreased, and IGFBP-2 was increased; after switching to ad libitum feeding, plasma levels of IGFBP-2 normalized, but levels of IGFBP-1 and IGFBP-3 remained low in the face of normalized plasma IGF-I levels.(ABSTRACT TRUNCATED AT 400 WORDS)

Metabolic control of sexual function and growth: role of neuropeptide Y and leptin.

The discovery of leptin has generated an extraordinary interest in the field of obesity but also in the understanding of the relationship between metabolic status and the neuroendocrine system. Following the initial demonstration that leptin administration to fasting mice can 'protect' neuroendocrine secretions and prevent the changes that are associated with fasting, the concept has emerged that a normal leptin secretion is a prerequisite for normal neuroendocrine secretions. Several unfavorable metabolic situations are associated with low plasma leptin, increased secretion of hypothalmic neuropeptide Y (NPY), and hypogonadism, and a causal relationship has been evoked. Severe dietary restriction in juvenile female rats is associated with low plasma leptin and sexual immaturity. Cessation of food restriction leads to immediate increase in plasma leptin followed 4 days later by vaginal opening. If food restriction is maintained, central leptin infusion can induce sexual maturation, thus demonstrating that leptin can act as a signal for the onset of puberty. In untreated type-I diabetic rats, hypogonadism is associated with very low plasma leptin and increased hypothalmic NYP synthesis and oestrous cyclicity. Fasting rapidly inhibits growth hormone (GH) secretion in association with low plasma leptin and elevated hypothalmic NPY. Central infusion of leptin to fasting rats was able to completely prevent the collapse of GH secretion and to maintain a normal low NPY synthesis. In summary, normally elevated plasma levels appear to be a prerequisite for normal GH and gonadotropin secretion in the rat. Degradation of metabolic conditions results in a rapid reduction of circulating leptin that could represent the signal for several alterations of neuroendocrine secretions. At the level of the hypothalamus, leptin could act on NPY neurons to transduce part or all of this 'metabolic' message. The possibility that changing plasma levels for leptin also affect peripheral endocrine targets, such as pituitary, ovary, adrenal or pancreas, is likely since these endocrine organs express functional long-term leptin receptors.

Chronic administration of leptin into the lateral ventricle induces sexual maturation in severely food-restricted female rats.

In many species, delayed sexual maturation occurs when metabolic conditions are not satisfactory. Recently, leptin was shown to be involved in the regulation of food intake and body mass. Furthermore, leptin administration was shown to advance sexual maturation in mice and to rescue sexual function in adverse metabolic conditions. We examined plasma leptin levels in female rats during development and evaluated the role of leptin on sexual maturation in rats subjected to food restriction. In normal rats, plasma leptin levels were low at day 24 of life, then steadily increased during the juvenile period, reaching 740+/-56 pg/ml at 40 days at time of vaginal opening (VO) and further increasing by day 60 (957+/-73 pg/ml). Food restriction initiated at day 25 strongly impaired this increase, in proportion to the severity of the restriction. With a daily food intake reduced to 7-8 g/day, that permanently prevented VO, plasma leptin levels were very low at day 53 (169+/-67 pg/ml). Following switch to ad libitum feeding, plasma leptin reached high levels within 2 days (1577+/-123 pg/ml), and VO occurred 4 days later. If the severe food restriction was maintained and a central infusion of leptin (10 microg/day) was initiated, a significant decrease in body weight compared with vehicle-infused controls was observed. In these conditions, VO occurred in eight out of the nine leptin-treated rats, representing induction of the process of sexual maturation confirmed by increases in ovarian and uterine weights. This induction of sexual maturation exclusively results from a central effect of leptin because no leak of the i.c.v. administered leptin to the general circulation was observed. These data suggest that the rising plasma levels of leptin in the prepubertal period represent a signal to the brain indicating that the young animal is metabolically ready to go through the process of sexual maturation.

Chronic administration of neuropeptide Y into the lateral ventricle starting at 30 days of life delays sexual maturation in the female rat.

The role of neuropeptide Y (NPY) in the regulation of sexual function is still controversial. Whereas central NPY administration is stimulatory during proestrus in the rat and other species, such administration is inhibitory in castrated animals and we have shown that chronic, central infusion of NPY inhibits both the gonadotropic and somatotropic axis in adult rats. Previous studies have suggested that NPY could be involved in the triggering of the first ovulatory LH surge and a recent report indicated that a single central NPY injection given at 30 days of life could advance sexual maturation. We therefore evaluated the effect of chronic NPY administration on the timing of sexual maturation in the female rat and compared the effects obtained with those induced by a single NPY injection. Constant infusion of NPY (18 micrograms/day) into the lateral ventricle delayed sexual maturation as seen by the absence of vaginal opening, delayed ovarian growth and reduced number of pituitary GnRH receptors. This inhibitory effect was seen as long as NPY was infused. In contrast, a single NPY injection either at 30 days of life or earlier, or repeated single injections between 28 and 31 days of life, did not modify the pace of sexual maturation. Unlike what is observed in adult animals, overall food intake was only minimally increased between 30 and 37 days of life in chronically NPY-infused rats, but this increase became more important thereafter.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of constant infusion with insulin-like growth factor-I (IGF-I) to immature female rats on body weight gain, tissue growth and sexual function. Evidence that such treatment does not affect sexual maturation of fertility.

Plasma levels for insulin-like growth factor-I (IGF-I) steadily increase in female rats between 20 and 40 d of life, and this increase is intimately related to the wellknown growth spurt occurring at this age. Since specific actions of IGF-I related to sexual function have been described at the ovarian and hypothalamic levels, an endocrine role of rising circulating IGF-I levels during sexual maturation cannot be excluded. Therefore, the impact of adult-type plasma IGF-I levels during the juvenile age, on body weight (BW) gain, growth of several organs, sexual development, and fertility has been evaluated. Female Sprague-Dawley rats were infused with rhIGF-I (2 and 4 micrograms/g BW/d, using Alzet minipumps), between 20 and 41 d of life. When infusing 2 micrograms/g BW/d, plasma levels for IGF-I were increased 1.5- to 2-fold over controls at all ages studied. They were further increased with the higher dosage, but only after 35 d of age. Plasma levels for insulin-like growth factor binding protein (IGFBP)-1 to -3 were clearly increased. BW gain was significantly increased, but only with the higher dosage. Tail length was never modified. In contrast, a growth acceleration for spleen, kidneys, adrenals, and ovaries was observed with both dosages. The ovarian weight of treated animals represented approx 140% of control animals with the 4 micrograms/g BW/d dosage. Histology of the enlarged ovaries did not reveal any abnormalities. No meaningful modification of the timing of vaginal opening was observed, and fertility was not comprised by previous rhIGF-I infusion during 20-41 d age period. In summary, early exposure to increased (adult-like) plasma IGF-I levels did not modify BW gain or tail length, but affected the development of spleen, kidneys, adrenals, and ovaries. Exposure to supraphysiological plasma IGF-I levels (> 1200 ng/mL), accelerated BW gain and increased the weight of all organs studied. No signs of precocious sexual maturation were seen and fertility was normal. In conclusion, prematurely increased plasma IGF-I levels affected somatotropic parameters, but not the onset of sexual function.

Effects of constant infusion with insulin-like growth factor-I (IGF-I) to immature female rats on body weight gain, tissue growth, and sexual function : Evidence that such treatment does not affect sexual maturation or fertility.

Plasma levels for insulin-like growth factor-I (IGF-I) steadily increase in female rats between 20 and 40 d of life, and this increase is intimately related to the wellknown growth spurt occurring at this age. Since specific actions of IGF-I related to sexual function have been described at the ovarian and hypothalamic levels, an endocrine role of rising circulating IGF-I levels during sexual maturation cannot be excluded. Therefore, the impact of adult-type plasma IGF-I levels during the juvenile age, on body weight (BW) gain, growth of several organs, sexual development, and fertility has been evaluated. Female Sprague-Dawley rats were infused with rhIGF-I (2 and 4 µg/g BW/d, using Alzet minipumps), between 20 and 41 d of life. When infusing 2 µg/g BW/d, plasma levels for IGF-I were increased 1.5- to 2-fold over controls at all ages studied. They were further increased with the higher dosage, but only after 35 d of age. Plasma levels for insulin-like growth factor binding protein (IGFBP)-1 to-3 were clearly increased. BW gain was significantly increased, but only with the higher dosage. Tail length was never modified. In contrast, a growth acceleration for spleen, kidneys, adrenals, and ovaries was observed with both dosages. The ovarian weight of treated animals represented approx 140% of control animals with the 4 µg/g BW/d dosage. Histology of the enlarged ovaries did not reveal any abnormalities. No meaningful modification of the timing of vaginal opening was observed, and fertility was not compromised by previous rhIGF-I infusion during the 20-41 d age period. In summary, early exposure to increased (adult-like) plasma IGF-I levels did not modify BW gain or tail length, but affected the development of spleen, kidneys, adrenals, and ovaries. Exposure to supraphysiological plasma IGF-I levels (>1200 ng/mL), accelerated BW gain and increased the weight of all organs studied. No signs of precocious sexual maturation were seen and fertility was normal. In conclusion, prematurely increased plasma IGF-I levels affected somatotropic parameters, but not the onset of sexual function.