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ABSTRACT
Studies were conducted in castrated golden hamsters to assess whether sexual dimorphism and sensitivity to sex steroid hormones in the rodent Harderian gland are mediated by an interaction of androgens with specific intracellular receptors. Physical properties, binding kinetics and stereospecificity of the androgen receptor were analysed using [3H]mibolerone as the radioligand. The presence of [3H]mibolerone–androgen receptor complexes with a sedimentation coefficient of 7–8S was demonstrated in Harderian gland cytosol by a linear sucrose gradient ultracentrifugation technique using a vertical rotor. Kinetic analysis revealed an androgen-binding site with an apparent dissociation constant of 0·3±0·07 (s.d.) nmol/l and a saturation binding capacity of 113±15 fmol/mg protein. Displacement studies indicated that unlabelled mibolerone, methyltrienolone, 5α-dihydrotestosterone and testosterone were efficient competitors for the androgen-binding sites, while progesterone, 17β-oestradiol, dexamethasone, dehydroepiandrosterone, ethiocholanolone and 5α-16-androsten-3-one were not. Experiments in long-term castrated animals revealed that the Harderian gland androgen receptor concentration and sedimentation coefficient remained unmodified. The results of these studies were interpreted as demonstrating the presence of a specific high-affinity intracellular androgen receptor in the male hamster Harderian gland.
J. Endocr. (1987) 112, 3–8
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ABSTRACT
Ultradian patterns of plasma GH concentration were determined in adult male and female mice. Serial blood samples were collected every 15 min over 8 h through surgically placed chronic indwelling right atrial catheters and assayed for GH content by an homologous radioimmunoassay. In both sexes, GH concentrations fluctuated episodically from baseline values that were often in the range of 2 μg/l which approached the limit of assay sensitivity, to peak values sometimes reaching 100 μg/l. Male mice, however, demonstrated a regular periodicity of GH peaks approximately every 2·5 h with interposed stable baseline concentrations that were significantly longer in duration than in females. The absence of extended baseline concentrations in females reduced cycle length to an average of 1·4 h and significantly increased the overall mean GH concentration. The duration, height and area of GH peaks and the average concentration between peaks were comparable in males and females. Sexual dimorphism in the ultradian patterns of serum GH concentrations have been shown in both mice and rats to regulate the expression of several sex-specific phenotypes. Comparing endogenous GH patterns in mice and rats demonstrates that males of both species have less frequent peaks than females over the same interval of time. This separation of GH peaks appears to be an essential element for the expression of masculine GH-dependent traits.
Journal of Endocrinology (1991) 131, 395–399
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SUMMARY
Plasma levels of luteinizing hormone (LH) were measured by radioimmunoassay in gonadectomized male and female Japanese quail, exposed either to 8 h light: 16 h darkness per day (8L:16D; short days) or to 20L:4D (long days). In both sexes, exposure to long days increased LH levels and in the gonadectomized quail LH continued to rise over several weeks. Eventually the castrated quail had levels about five times higher than the control birds and the ovariectomized quail had levels about 14 times higher than their controls.
Quail kept on short days had low LH levels while birds kept on long days and returned to short days resumed low levels after a delay of some days. Since very high levels of LH occurred in gonadectomized quail only when they were on long days, we conclude that the photoperiodic regulation of LH secretion does not operate solely by adjusting sensitivity to gonadal feedback, but works in a more direct manner.
Ovariectomized females whether on long days (high LH) or short days (low LH) grew masculine plumage and castrated males retained male plumage. This confirms that the ovary is responsible for sexual dimorphism of plumage and shows that the action of the ovary is not mediated by LH (through feedback).
The remaining rudimentary (right) gonad in ovariectomized females did not undergo visible hypertrophy and did not secrete enough hormone to stimulate the cloacal gland or oviduct.
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Abstract
The prolactin receptor (PRLR) is a member of the cytokine/prolactin/GH receptor family, and it is widely expressed in various mammalian tissues. Expression of the two different forms of PRLR, differing in the length of their cytoplasmic domains, was studied in rat gonads during fetal and postnatal development. The two forms of PRLR mRNA were analyzed by reverse transcription (RT)-PCR using primer pairs specific for the different forms. The specificity of the cDNA species generated by RT-PCR was verified by Southern hybridization using nested 32P-labeled oligonucleotides. The results indicated that both forms of PRLR mRNA are expressed in the rat testis and ovary, which is in agreement with previous reports. The onset of expression of the two PRLR forms occurs on day 14·5 of fetal life in rat testis. In the ovary, the long form of PRLR mRNA appears 1 day before the short form, i.e. these forms begin to be expressed on fetal days 14·5 and 15·5 respectively. In situ hybridization with antisense cRNA probes specific to each form of the PRLR mRNAs demonstrated specific hybridization of both forms, localized in Leydig cells from day 18·5 of fetal life and at the postnatal ages studied. Compared with our previous findings concerning the ontogeny of LH receptor gene expression, PRLR gene expression starts earlier in development and exhibits no sexual dimorphism. The presence of two forms of PRLR mRNA in the fetal gonads suggest that they might play differential roles in gonadal development and function.
Journal of Endocrinology (1995) 147, 497–505
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Ghrelin was recently isolated from the rat stomach as an endogenous ligand for the GH secretagogue receptor. Although it is well known that a large amount of ghrelin is produced in the gastrointestinal tract, developmental changes in ghrelin mRNA expression and differentiation of ghrelin-immunopositive (ghrelin-ip) and mRNA-expressing (ghrelin-ex) cells in the stomach have not been elucidated. In this study, we therefore investigated the changes in ghrelin mRNA expression levels and in the numbers of ghrelin-ip and -ex cells in the stomachs of 1- to 8-week-old male and female rats by Northern blot analysis, immunohistochemistry and in situ hybridization. Northern blot analysis showed that the level of weak ghrelin mRNA expression was low in the postnatal period but then increased in a dimorphic pattern, i.e. transient stagnation at 4 weeks in the male rats and at 5 weeks in the female rats. The number of ghrelin-ip and ghrelin-ex cells also increased after birth, and more numerous ghrelin cells were found in female rats than in male rats, and this finding was confirmed by Northern blot analysis. Ghrelin-ip and -ex cells first appeared in the glandular base of the fundic gland and then they were found in the glandular base and the glandular neck at 3 weeks of age, suggesting that the distribution of ghrelin cells is extended from the glandular base to the glandular neck during the postneonatal development period. This is the first report on detailed changes in postneonatal ghrelin expression level and in the number of ghrelin cells in the rat stomach. The sexual dimorphism of ghrelin expression and ghrelin cell differentiation suggest that ghrelin plays an important physiological role in the stomach.
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A sexual dimorphism in gastric acid secretion has been known for many years, with women secreting less acid ( approximately 40%) than men. The mechanisms mediating this sex difference are unknown, but a role for estrogens is suggested from animal models. Two estrogen receptor (ER) subtypes, ER alpha and ER beta, mediate genomic effects of estrogens, and mRNA for both subtypes has been detected in the rat stomach. The objective of this study was to determine the cellular distribution of ER alpha and ER beta proteins in the rat stomach. ER alpha and ER beta proteins were detected in nuclei of fundic parietal cells and epithelial cells in the progenitor zone. In the antrum, several cells were immunoreactive for ER beta in regions containing stem and neuroendocrine cell types but ER alpha protein was not detected in antral glands. Both ER alpha and ER beta proteins were expressed in enteric neurons within the nucleus and cytoplasm, with specific punctate staining for ER alpha in cell bodies and fibers. These studies are the first to show differences between ER alpha and ER beta proteins in the epithelial cellular distribution in the fundus and antrum and to detect co-expression in enteric neurons. These results suggest that estrogens may inhibit gastric acid secretion via genomic effects in fundic parietal cells through either ER subtype and in antral neuroendocrine cells via ER beta. Moreover, co-expression of ER alpha and ER beta in enteric neurons indicates that estrogenic effects could also be mediated through neurogenic reflexes. Our findings imply that direct regulation of multiple cell types by estrogens may contribute to the modulation of gastric functions that have been recognized during the estrous cycle and between the sexes.
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Abstract
It has been shown that prolactin (PRL) induces glucose intolerance, hyperinsulinaemia and insulin resistance in several animal species, including rats. However, the sex differences regarding glucose homeostasis and insulin release in hyperprolactinaemic subjects have not been assessed to date. In the present study, hyperprolactinaemic (pituitary-grafted) or control (sham-operated) male and female rats were submitted to an i.v. glucose tolerance test (30 mg/100 g body weight, 30% glucose). Grafted female rats had fasting plasma glucose concentrations 26% above control (P<0·01). After the glucose load there was a rapid and pronounced increase in plasma glucose levels in all animal groups, followed by a return to basal values within 30 min. However, the glucose concentrations in hyperprolactinaemic rats were significantly greater than those in controls at 5 min (males, P<0·05) and 30 min (females, P<0·05). The glucose disappearance rate was significantly increased in the grafted females compared with control (P<0·01) and slightly increased in the grafted males. Plasma insulin concentration increased just after glucose load and returned to basal values within 5 min in all groups except for the grafted females, which had recovered their basal insulin levels at 15 min. The grafted male rats had insulin concentrations higher than those of sham-operated controls at 2 min (28·9 ± 3·6 vs 17·3 ± 2·1 μU/ml, P<0·01), whereas females had plasma insulin concentrations greater than those in sham-operated controls 10 min after the glucose load (15·9 ± 1·9 vs 10·1 ± 1·4 μU/ml, P<0·05). The areas under the plasma insulin concentration–time curves were also significantly increased in the hyperprolactinaemic rats and were positively correlated with plasma PRL concentrations (r=0·613, P<0·01). These results demonstrate that moderate chronic hyperprolactinaemia is associated with increased glucose-induced insulin release, which was altered at different times after the glucose load in grafted male and female rats, whereas fasting hyperglycaemia was observed only in grafted females, indicating a sexual dimorphism in the diabetogenic effects of PRL in rats.
Journal of Endocrinology (1997) 153, 423–428
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ABSTRACT
The role of sex steroids in the programming of the level of serum corticosteroid-binding globulin (CBG) in the rat has been studied at different stages of ontogenesis.
The CBG content in the serum of mature female rats was 2·5 times higher than that in male rats. Sexual dimorphism of CBG content was absent in immature animals of 3–4 weeks of age. Castration of mature rats led to a 40–50% increase in CBG content. The CBG concentration in mature females or castrated adult males treated with testosterone propionate (TP; 3 mg/day for 4 days) was decreased by 40–50% compared with vehicle-treated rats. Oestradiol injection (1 μg/day for 4 days) had no influence on CBG levels in mature male and ovariectomized adult female rats.
Immature rats were castrated on days 1, 7, 14, 21, 28 or 35 of age and the CBG level was determined at 10–12 weeks of age. The CBG content of rats castrated up to day 28 of age was 2·5 times higher than that in mature males and did not differ from that in mature females. The CBG content of male rats castrated on day 35 of age was the same as that of adult castrated males. The CBG level in castrated rats treated with TP (1·25 mg for days 1–3 or 300 μg/day for 5 days after castration at day 7 up to day 26) did not differ from that in controls (i.e. vehicle-treated rats). TP injection into castrated rats on days 29–33 of age (300 μg/day) led to a 40–50% decrease in CBG level when compared with controls.
Ovariectomy of rats at different ages (on days 1 or 28 or 3 months) did not affect CBG concentration. TP injection (300 μg/day) into ovariectomized rats on days 29–33 had the same effect on CBG concentration as in males.
Gonadectomized rats treated with diethylstilboestrol on days 29–33 (100 μg/day) had the same CBG concentrations as TP-treated rats.
It was concluded that there is a short period during ontogenesis, from days 29 to 35 of age, which is critical for irreversible masculinization of the CBG concentration in male rats.
Journal of Endocrinology (1992) 132, 235–240
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metabolism, especially cytochrome P450s (Cyps) ( Waxman & O'Connor 2006 ). These sexual differences are dictated by the sexual dimorphism of plasma GH profiles, which is especially prominent in rats and mice. Plasma GH secretion is highly pulsatile in males
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scrotum, structures that are never seen in XX female young. A full colour version of this figure is available at https://doi.org/10.1530/JOE-22-0296 . Sexual differentiation and direct genetic control of sexual dimorphisms In humans, male