Influence of prenatal steroid exposure on neonatal gonadotropin imprinting. Effect of single and combined hormone treatments on the chicken ovary

Chicken embryos treated with DES or AE at the 9th day of incubation showed postnatally an increase in ovarian mass, parenchymal zone thickness, follicle diameter and granulosa cell count. Perinatal gonadotropin treatment had a similar effect on these parameters in the control birds not receiving pretreatment, but had no influence on them in the birds pretreated with steroid. The tested ovarian parameters of the DES- and AE-pretreated birds still differed from the control at 6 weeks of age. Neonatal gonadotropin exposure induced imprinting in the birds not pretreated with steroid, to judge from an increased response (indicated by changed values of the tested parameters) to gonadotropin reexposure in adulthood. Similar, but considerably slighter changes were also shown by the steroid pretreated birds. It follows that in the birds prenatally exposed to AE or DES, supervening perinatal exposure to gonadotropin did not elicit greater changes than the prenatal exposure itself.     

Effects of neonatal treatment with diethylstilbestrol and 17 alpha-hydroxyprogesterone caproate on in vitro pituitary prolactin secretion

The effects of neonatal hormone treatment with diethylstilbestrol (DES) and 17 alpha-hydroxyprogesterone caproate (HPC) on days 1-5 of life on serum prolactin (PRL) levels and 3H-PRL synthesis and release were studied in C3H/MTV+ mice at 2, 4, 6, 8 and 10 weeks of age. Neonatal treatment of mice with 2.5 micrograms/day DES was the only treatment that affected the developmental pattern of serum PRL levels. Serum PRL levels were significantly decreased at 6 wks of age with this dose of DES. Neonatal treatment with 2.5 micrograms/day DES and 150 micrograms/day HPC affected the developmental pattern of H-PRL synthesis by the pituitary. At 10 wks of age 3H-PRL synthesis was significantly decreased by these doses of DES and HPC. The percent of 3H-PRL released did not differ between neonatally hormone treated and control animals, suggesting that neonatal treatment affected mechanisms that regulate PRL synthesis but not those that regulate release.     

Effect of tamoxifen treatment at adolescent age on the sexual behaviour and steroid hormone receptor binding of adult female rats

Hormonal imprinting takes place perinatally, at the first encounter between the target hormone and its developing receptor. However, there is a secondary critical period of imprinting at puberty. In these periods molecules similar to the hormones (members of the same hormone family, antagonists, certain environmental pollutants, etc.) can cause faulty imprinting with lifelong consequences. In the present experiments 5+2 days of tamoxifen treatment (120 microg/day) at adolescent age dramatically (from approx. 40% to 10%) reduced the sexual activity (Meyerson index and lordosis quotient) of female rats, soon after the finishment of the treatment and between four to six weeks after treatment. Similar results were observed in animals neonatally treated with allylestrenol and tamoxifen treated at puberty. Thymic glucocorticoid receptor and uterine estrogen receptor binding capacity were not influenced.     

Hormonal imprinting by steroids: a single neonatal treatment with diethylstilbestrol or allylestrenol gives rise to a lasting decrease in the number of rat uterine receptors

Binding of hormone by the uterine receptors of 6 week old rats treated with diethylstilbestrol (DES) or allylestrenol (AE) in neonatal age differed considerably from the controls. Both pretreatments accounted for a decrease in the number of Type II binding sites for estradiol without altering receptor affinity. It follows that steroids, too, are able to induce a hormonal imprinting during the critical stage of receptor maturation.     

Life-long effect of a single neonatal treatment with estradiol or progesterone on rat uterine estrogen receptor binding capacity.

Rats treated with a single dose of 17 beta-estradiol or progesterone within 24 h of birth were subjected to ovariectomy at 8 weeks of age and were nine days later examined for the binding capacity of the uterine estradiol receptors by saturation and competition tests (with diethylstilbestrol used as competitor). The Bmax value of the neonatally estradiol-treated rats (6.78 x 10(-10) M) was significantly decreased relative to the control (1.99 x 10(-9) M). The competition analysis affirmed these results. Neonatal progesterone treatment also accounted for a significant decrease (1.25 x 10(-9) M) in receptor concentration relative to the control (1.66 x 10(-9) M). Considering the competition analysis the decrease was less than in the case of estradiol and not even significant by saturation analysis. The uterine mass did not differ between the experimental and control rats, but part of those treated with estradiol developed ovarian cysts. It follows that not only synthetic steroids (DES, allylestrenol), but also an excessive presence of the physiological steroid hormone during the critical period of receptor maturation can account for a decrease in uterine receptor concentration in adulthood.     

Effect of gonadotropin (FSH + LH) and thyrotropin (TSH) administered with or without endotoxin at the age of three weeks on the response capacity of the thyroid gland in adult rats

At the age of three weeks the experimental animals received either thyrotropin (TSH), or gonadotropin (FSH + LH), or endotoxin (LPS) alone or in combination. The effectivity of the treatments was evaluated at the age of two months (with or without further hormone treatment). Contrastingly to neonatal TSH treatment, TSH treatment at the age of three weeks did not give rise to imprinting. In female animals, however, TSH treatment increased the sensitivity to the related gonadotropin hormone. At the age of three weeks gonadotropin treatment--on its own--did not cause damages to the TSH receptors of the thyroid gland. While in previous experiments neonatal endotoxin treatment damaged considerably the thyroxin production of the adult thyroid gland, after treatments at the age of three weeks no similar effect could be observed. The treatment, however, decreased the sensitivity of the receptors to TSH. In female animals simultaneous administration of endotoxin and TSH led, even without further hormone treatment, to constant increase in T4 level (the increase could also be detected in the adult animal). Imprinting, however, did not develop. In male animals simultaneous administration of endotoxin and gonadotroph hormone decreased considerably the T4 baseline level, and further TSH or gonadotropin treatment was unable to enhance T4 production.     

Interaction of thyrotropin (TSH) and gonadotropins in the function of genital organs. Effect of TSH and gonadotropin pretreatment (hormonal imprinting) of newborn rats on hormonal overlap in adult animals

At the age of 25 days the TSH-gonadotropin overlap is minimal in rats and extremely high doses of TSH are required to produce gonadotropin-like responses. Although the effect may be due also to some occasional contamination, nevertheless a single treatment of newborn animals (hormonal imprinting) with either hormone augmented the response to a second treatment with either hormone performed at 25 days of age. Newborn rats pretreated with either TSH or gonadotropin were exposed to a second TSH challenge at the age of 25 days exhibited responses which were not commeasurable to those observed after gonadotropin treatment alone. However, the amplifying action of TSH pretreatment with regard to the second response to gonadotropin was comparable or even more apparent than that of gonadotropin pretreatment.     

Influence of hormone concentration and time factor on TSH-FSH imprinting and overlap in CHO cells

Exposure of Chinese hamster ovarian cell cultures (cell line CHO) to TSH of FSH gave rise to hormonal imprinting. In earlier studies re-exposure after 48 h displayed a considerable increase in hormone binding. In the present experiments similar increase was demonstrated with an interval of five days. After 14 days, the increment was of lesser degree or even a decrease was noted in hormone-binding capacity. Although the CHO line originates from the target cells of gonadotropin, long-term positive imprinting was greater for TSH than for FSH, imprinting for FSH being negative rather than positive. The experimental results suggest that even very low concentrations (10(-13) mol) of hormone induce imprinting after an exposure as short as 60 min.     

Influence of neonatal steroid (diethylstilbestrol, allylestrenol) treatment on the sexual behaviour of the adult rat

A single neonatal treatment with diethylstilbestrol (DES) or allylestrenol (AE) considerably depressed the sexual activity of male rats in adulthood. DES had a stronger depressive effect than AE. Though the adult sexual activity of intact female rats was also reduced by DES it was not influenced by AE. Ovariectomized females that had been hormone-treated before experimental mating showed reduced sexual activity under the influence of neonatal DES-treatment but increased sexual activity when treated neonatally with AE.     

Investigation of gonadotropin-thyrotropin overlapping and hormonal imprinting in the rat testis

In the neonatal period both gonadotropin and thyrotropin increase the weight of the testis, influence considerably the diameter of the contorted tubules increase the occurrence of Sertoli cells and decrease the number of spermatogonia. These phenomena can still be observed at the age of seven days but they disappear by the age of six weeks; at that time the hormones decrease the weight of the testis. One single TSH treatment administered in the neonatal period considerably increased the weight of the testis and the diameter of the channels when investigated at the age of six weeks. Gonadotropin had none of these effects. The phenomenon of imprinting could be proved as in the animals pretreated with TSH, gonadotropin given at the age of six weeks decreased the weight of the testis and both hormones decreased the diameter of the seminiferous cords.     

Influence of hormonal imprinting on hormone level. Permanent receptor damaging effect of pituitary hormones administered to newly-hatched cockerels

The overlapping effect of TSH and FSH on the gonad and on the thyroid gland can be demonstrated in cockerels even at the age of five weeks. These hormones influence the secretion of testosterone in a similar way and to a similar extent, while on the thyroxine level the influence of the specific hormone is more pronounced. Neonatal FSH and TSH treatment considerably decreased the basal testosterone level measured at the age of five weeks. Neonatal FSH treatment increased the basal T4 level while TSH treatment decreased it. The effect of TSH treatment administered at the age of five weeks in increasing the testosterone level was weakened after neonatal pretreatment with any iodine hormone. The effect of TSH treatment could only be inhibited by neonatal FSH pretreatment. Neonatal pretreatment with any of the trophormones caused a diminution of the T4 level augmenting of FSH and TSH administered at the age of five weeks.     

Steroid synthesis in ovarian homogenates from immature mice treated with diethylstilboestrol in neonatal life

Female mice of the NMRI strain were treated with the synthetic oestrogen diethylstilboestrol (DES) for the first 5 days after birth. Pools of ovaries were removed from groups of 6-, 12-, 21-, 28- and 56-day-old females. An homogenate of an ovarian pool was incubated for 1 h in the presence of [3H]pregnenolone. Synthesized steroids were extracted and separated in a two-dimensional thin-layer chromatography system. Homogeneity of tentative steroids was verified with recrystallization to constant specific activity. Synthesis of [3H]progesterone and [3H]testosterone was demonstrated at 6 days, [3H]androstenedione at 12 days, [3H]17 alpha-hydroxyprogesterone at 21 days, and [3H]oestradiol-17 beta at 28 days. Up to 28 days (21 days for progesterone), the synthetic activity was lower in homogenates of DES-exposed ovaries than in control homogenates. After 28 days, values for recovered [3H]progesterone, [3H]androstenedione and [3H]oestradiol-17 beta were higher in DES homogenates than in control homogenates while the reverse was true for [3H]17 alpha-hydroxyprogesterone and [3H]testosterone. The results are compatible with an early and direct DES inhibitory effect on ovarian steroidogenesis and, later in immature life, a DES-induced disruption of the normal FSH-LH stimulation of ovarian development.     

Binding capacity of rat liver glucocorticoid receptor in different periods after single neonatal benzpyrene treatment (imprinting)

Newborn rats of both sexes were treated (imprinted) with 20 microg of benzpyrene. Two hours, 2 days, 1, 2, 3 weeks, 1 month and 2 months after imprinting the liver glucocorticoid receptors were studied for binding of dexamethasone. Two-hour and 2-day values were not appreciable. One week after treatment the receptor's affinity was extremely low both in control and treated treated animals. Two weeks after imprinting a significant difference in density (lower) and affinity (higher) was observed between the male treated and control animals. At 3 weeks and one month the binding capacity of treated and control animals was equal however, at 2 months Bmax of males increased and that of females decreased significantly in the neonatally benzpyrene treated animals. This means that for the development of perinatal imprinting effect a long time is needed, and the effect is manifested after a period of lability.     

Effect of gonadotropin (FSH-LH) and thyrotropin (TSH) treatment in adolescence on TSH-sensitivity in adult rats

Hormonal imprinting is characteristic of the neonatal age, in which the receptor of the target cell matures, i.e. acquires its adult binding capacity, and cellular response becomes established in presence of the adequate hormone. The normal course of imprinting may be altered by certain molecules (related hormones, hormone analogons) which are able to bind to the receptor of the adequate hormone. The chemically related gonadotropic and thyrotropic hormones may overlap on each other's receptors not only in the perinatal age, but also in the early adulthood, and this overlap of the binding may give rise to an imprinting-like effect. An example of this phenomenon was observed in the present study, in which rats of seven weeks of age treated with gonadotropin showed a significant decrease in thyroidic response to TSH, and exposure to TSH failed to increase their basic thyroxine concentration to the normal (control) level. This depressive effect of gonadotropin was slightly reduced in the presence of LPS (endotoxin), causing membrane perturbation, while pretreatment with LPS and TSH accounted for an increased sensitivity to TSH in later phases of the rat's life. These experimental observations support the possibility of a special form of imprinting in adolescence.     

Single treatment (hormonal imprinting) of newborn rats with serotonin increases the serotonin content of cells in adults

Hormonal imprinting takes place perinatally at the first encounter between the hormone and its target receptor, causing the finishment of the maturation of receptor-signal transduction system. In the presence of an excess of the target hormone or related molecules faulty imprinting develops with life-long consequences. In earlier experiments single neonatal treatment with minute dose of IL-6 caused also prolonged stimulation of IL-6 production. In the present experiment newborn female and male rats were treated with 20 microg serotonin (hormonal imprinting) and were studied for serotonin content of different cell types in adult age. Serotonin content was measured by flow cytometry and its localization was determined by confocal microscopy. Serotonin content was detected in white blood cells (lymphocytes, monocytes and granulocytes); in lymphocytes, monocytes (macrophages), granulocytes and mast cells of peritoneal fluid and thymic lymphocytes. Serotonin was present in all cell types of control animals studied. Serotonin content extremely elevated in the white blood cells and also increased in the peritoneal cells of neonatally treated female animals. There was no elevation in thymic lymphocytes. The mean values of male animals remained at the control level. The experiments call attention to the life-long effect of the perinatal hormonal imprinting manifested presently in the elevation of serotonin content and point to the gender differences of serotonin imprinting. Considering the role of serotonin in mood and psychiatric diseases, the observations could have some clinical importance.     

Prolonged impact of pubertal serotonin treatment (hormonal imprinting) on the later serotonin content of white blood cells

The first encounter between the developing receptor and its target hormone establishes the hormonal imprinting which is needed for the normal function of the cell. In the presence of foreign-however able to bind-molecules, faulty imprinting develops with lifelong consequences. Hormonal imprinting influences not only the receptors, but also the later hormone production of cells. The critical time of hormonal imprinting is the perinatal period, however it can be executed sometimes (in continuously differentiating cells) also at puberty. As in earlier experiments single neonatal serotonin treatment caused a life-long alteration of white blood serotonin content in female rats, the early (10-19 day) and late (8 weeks) effect of single pubertal serotonin treatment was studied presently, by using flow cytometry. In contrast to the earlier (neonatal) results, pubertal treatment caused a radical reduction of serotonin content in male's lymphocytes, monocytes, granulocytes and mast cells, independent on the time of study. The effect in females was rather increasing, however uncertain. The experiments call attention to the possible different effects of neonatal and pubertal hormonal imprinting and to the imprintability of blood cells in adolescence.     

Diethylstilbestrol increases the density of prolactin cells in male mouse pituitary by inducing proliferation of prolactin cells and transdifferentiation of gonadotropic cells

Diethylstilbestrol (DES) has been implicated in mammalian abnormalities. We examined the effects of DES on follicle-stimulating hormone (FSH), luteinizing hormone (LH), and prolactin (PRL) cells in the pituitaries of male mice treated with various doses of DES for 20 days. DES reduced the density of FSH and LH cells in a dose-dependent manner, but increased that of PRL cells. When the expression of estrogen receptor (ER) α and β was assessed, an induction of ERβ by DES was found predominantly in PRL cells. However, since these effects were abolished in ERα knockout mice, DES appears to act primarily through ERα. When the expression of Ki-67 and Pit-1 in PRL cells was examined at various time-points after DES treatment, some PRL cells became Ki-67 positive at 10–15 days, and Pit-1-positive cells were increased at 5–15 days. Furthermore, some FSH and LH cells became Pit-1 positive, and co-localized with PRL at 5–10 days. Our results indicate that DES increases PRL cells by inducing proliferation of PRL cells and transdifferentiation of FSH/LH cells to PRL cells.     

Effects of growth hormone injection to embryos on growth and myosin heavy chain isoforms in growing turkeys (Meleagris gallopavo)

Effects of embryonic imprinting with growth hormone (GH) on growth and myosin heavy chain (MyHC) isoforms in pectoralis muscle were determined by injecting turkey embryos with ovine growth hormone (oGH) at a dose of 10 μg three times a day. Injections were made on days 20 and 26 (Treatment 1), days 14 and 20 (Treatment 2) or days 14 and 26 (Treatment 3) of incubation. In Treatement 1 poults, plasma GH concentrations were elevated at 3 days posthatch and in Treatment 3 poults, plasma GH concentrations were elevated at 15 days posthatch, as compared to control poults. At 4 weeks of age, in males, body weights, shank length and weights of pectoralis, gastrocnemius and sartorius muscles were increased in Treatment 3, and in females, body weights, shank length and weights of gastrocnemius muscle of female turkeys were increased in Treatment 1. The growth rate of female turkeys from 4 weeks through 16 weeks was increased by Treatment 1. Treatment 1 resulted in a delay in the transition from the embryonic MyHC isoform to the neonatal MyHC isoform and to the adult MyHC isoform. Treatment 3 induced an earlier appearance of the adult MyHC isoform. No effects on body and muscle growth and MyHC isoforms were observed by Treatment 2.     

Injection of diethylstilbestrol on the first day of incubation affects morphology of sex glands and reproductive behavior of Japanese quail

Japanese quail eggs were injected with DES (0.9-1,000 micrograms) dissolved in 50-microliter of corn oil on day 1 of incubation. Higher doses of DES (250-1,000 micrograms) reduced hatchability to 37-33% compared to 61% for corn oil-injected controls. Lower doses of DES (0.9-125 micrograms) had no effects on hatchability. In a second study, eggs were injected with 0.9 or 1.9 micrograms of DES and the survivors were assessed up to 12 weeks posthatch. DES did not affect hatchability, but did increase mortality during the first 4 weeks posthatch. Females were affected more than males. At 10 days of age, open-field activity of some birds was examined. The acquisition and reversal of a visual discrimination task was studied at 6 weeks of age. DES had no effect on these measurements. Ten females from each group were chosen randomly to determine egg production over a single 28-day period beginning at 6 weeks of age. Exposure to DES blocked egg production in these birds. The oviduct weights of 12-week-old females were decreased by 50%, but ovarian weights were not affected. Testicular weights were not affected. In a third study reproductive behaviors and social-dominance behaviors of males were markedly attenuated in birds exposed to 0.48 or 1.9 micrograms DES in ovo.