Changes in glucocorticoid receptors in different regions of brain of immature and mature male rats

Specific cytosolic binding for synthetic glucocorticoid dexamethasone was studied in several brain regions (hypothalamus, hippocampus, caudate nucleus, cerebellum, cerebral cortex) of immature (3-week) and mature (26-week) male rats, intact and adrenalectomized. A significant regional difference was observed in the concentration of in vitro [3H] dexamethasone binding in the brain of adrenalectomized rats at both ages, with the highest levels in the hippocampus. A marked decrease in specific binding was observed in all brain regions of adrenalectomized mature rats as compared to immature. The dexamethasone binding was significantly lower in all brain regions of normal intact animals as compared to adrenalectomized rats in both ages.     

Age-dependent regulation of glucocorticoid receptors in the liver of male rats

Specific binding of [3H]dexamethasone to cytosol and the activation of bound hormone-receptor complexes were studied in the liver of immature (3 weeks old) and mature (26 weeks old) Long-Evans male rats. The concentration of specific binding sites was significantly higher (33%) in the liver of immature rats as compared to mature, while dissociation constants (Kd) remain unaltered at both ages. Heat activation (for 45 min at 25 degrees C) significantly enhances the binding of [3H]dexamethasone-receptor complexes to DNA-cellulose and purified nuclei at both the ages, with a greater magnitude in mature rats. Cross mixing experiments (i.e., binding of activated cytosol from mature rats to nuclei of immature and vice-versa) show receptor specificity. Ca2+ activation (20 mM Ca2+ for 45 min at 0 degree C) also enhances the nuclear and DNA-cellulose binding at both the ages, but to a similar extent. Differences in the number of specific binding sites and some of the physiochemical properties of glucocorticoid receptors presented here between immature and mature rats may underlie the functional changes in tissue response with age.     

Age-dependent activation of glucocorticoid receptors in the liver of male rats

The binding of hepatic [3H] dexamethasone-receptor complexes to DNA-cellulose and purified nuclei was studied in the immature (3-week) and mature (26-week) Long-Evans male rats to determine the age-associated changes, if any, in the physicochemical properties of glucocorticoid-receptors. Our data show that heat activation (for 45 min at 25 degrees C) significantly enhances the binding of [3H] dexamethasone-receptor complexes to DNA-cellulose and purified nuclei at both the ages, with a greater magnitude in mature rats. Cross-mixing experiments (i.e. binding of activated cytosol from mature rats to nuclei of immature and vice-versa) show receptor specificity. Ca2+ activation (20mM Ca2+ for 45 min at 0 degrees C) also enhances the nuclear and DNA-cellulose binding at both the ages but to a similar extent. These findings indicate that some of the physicochemical properties (e.g. heat activation) of glucocorticoid receptor change, while others (e.g. Ca2+ activation) remain unchanged at these phases of the life span. The observed changes may lead to functional alterations in the tissue response as a function of age.     

Intestinal cadmium permeability in mature and immature rats

To compare the intrinsic permeability properties of the small intestine in adult (average body wt 300 g) and 25- to 27-day-old (average body wt 50 g) male rats, the uptake rates of cycloleucine and of cadmium were measured in intestinal segments isolated in situ with their blood supply intact. Uptake rates were expressed on the basis of that of ethanol, a solute whose absorption depends primarily on the size, rather than the composition, of the available surface area and on the presence of unstirred layers. These layers may be concluded to affect movement of cycloleucine, cadmium, and ethanol to the same extent. The ratio of uptake rates, therefore, provides in arbitrary units a measure of the intrinsic permeability of the luminal surface area to cadmium and to cycloleucine. On this basis, no developmental change in cycloleucine permeability could be detected. In contrast, the rate of cadmium uptake relative to that for ethanol decreased with age by about 50%. Possible mechanisms are discussed for this significant change in the intrinsic cadmium permeability of the jejunum in post-"closure" animals.     

Regulation of bone stress and strain in the immature and mature rat femur

Bone in vivo stresses and moments were determined from rosette strain recordings obtained from the mid-diaphysis of growing exercising rats. Two activity groups were examined beginning at 3 weeks of age: 2 min day-1 and 45 min day-1 at 0.2 ms-1 in an exercise wheel. In vitro moment-strain curves were obtained during mechanical calibration tests on intact femora, and area inertial properties were determined from the mid-diaphysis cross-sections. The mechanical calibration and histomorphometry procedures were then used to compute functional stresses and moments based on the in vivo rosette strain recordings. During the period 6-30 weeks of age the rats increased in body weight over threefold, but no significant changes in principal strain and stress magnitude or orientation were found. Peak in vivo compressive and tensile moments increased during growth in proportion to the animal mass squared, but the ratio of these moments to animal body weight times bone length (BWBL) remained constant throughout growth and in the adult. The parameter BWBL appears, therefore, to be a useful predictor of long bone functional strength. Peak torsional moments remained a constant 8.1 +/- 3.0% of the ultimate torsional strength, providing a safety factor of approximately 12. Differences in the in vivo moments between the two activity groups were found, which were due primarily to adaptive, but not significant, changes in bone geometry. These findings support the hypothesis that long bones model and model during growth and altered activity in order to regulate the functional strains at a predefined level.     

Expression of Notch receptors and ligands on immature and mature T cells

Notch plays multiple roles in T cell development in the thymus and T cell differentiation in the periphery. In order to systematically examine the role of Notch in T cell biology, we determined the cell surface expression of all Notch receptors and ligands on various populations of T cells by using a panel of specific monoclonal antibodies we recently established. Notch1 and Notch3 were upregulated at double-negative (DN) 2-DN4 stages of immature thymocytes, then downregulated on mature single-positive thymocytes and peripheral T cells, but were rapidly upregulated again upon activation. Notch2 was consistently expressed on T cells while Notch4 was not. Jagged1 and Jagged2 were expressed at double-positive stage of immature T cells. Jagged2 was also inducible on mature T cells upon activation. In contrast, no Delta-like (Dll) 1 or Dll4 expression was observed on T cells. These comprehensive profiling of the expression of Notch receptors and ligands would be informative to fully understand the role of individual Notch receptors and ligands in T cell development and differentiation.     

Responses of immature male masu salmon parr to the urine of mature males

Responses of male masu salmon Oncorhynchus masou parr to mature male urine were investigated in a Y-maze trough. Immature masu salmon made fewer entries into the channel conditioned by mature male urine than that with control water. This phenomenon may suggest that immature males avoid sexually active males in the spawning season.     

Pituitary-testicular axis abnormalities in immature male hypothyroid rats

The pituitary-testicular disturbances which follow the onset of hypothyroidism were studied in immature male Wistar rats rendered hypothyroid by treatment with methimazole (MMI) given in drinking water, starting at 40 days of age. Half of the animals continued on MMI (MMI group) up to 140 days of age; the remaining rats were withdrawn MMI at 100 days and injected thereafter s.c. with 3 micrograms of T3 daily, during the last 40 days (MMI + T3 group). Ten rats were used as controls (C group). Hypothyroidism induced in immature animals significantly decreased serum T4, T3, LH, PRL, and testosterone levels, and also impaired the normal growth of body and sex accessory glands. T3 replacement therapy helped to normalize serum hormonal levels, but the body and sex accessory gland weights were not fully corrected. Hypothyroidism also reduced the [125I]LH/hCG binding sites of testicular homogenates. T3 replacement was not able to improve the binding; nonetheless, the hormone-receptor affinity constant remained unaltered among the groups. Leydig cell responsiveness to hCG stimulation in vitro (0-82 nM) showed impaired testosterone production in the MMI group (25% of that found in the C group) and also in the MMI + T3 group (80% of that found in the C group). These data demonstrate that induction of hypothyroidism in the immature male rat leads to alterations in serum LH, PRL and testosterone levels, and suggest that thyroid hormones have a modulating action on the testis as far as LH-mediated testosterone secretion is concerned.     

Decreased liver cytosol glucocorticoid receptors in protein-deficient rats

A low protein diet (5% as compared to a control 21% protein diet, $\text{ad libitum}$) caused a significant decrease in the concentration of liver cytoplasmic glucocorticoid receptors; the equilibrium dissociation constant (Kd) did not change. The maximum decrease occurred in two weeks and was reversible upon substitution of the low protein by a control diet. This influence of protein deficiency could not be attributed to elevated plasma corticosterone levels since a comparable increase in plasma corticosterone of calorie-deficient rats (21% protein diet in restricted quantity) did not decrease glucocorticoid receptors and the difference in receptor levels of control and protein deficient animals persisted following adrenalectomy. These results suggest that glucocorticoids might not exert their usual biologic effects in the presence of protein malnutrition.     

Partial characterization and ontogeny of renal cytosolic glucocorticoid receptors in mouse kidney

The glucocorticoid receptor (GR) was partially characterized in mouse renal cytosol. A sensitive and reproducible [3H]dexamethasone binding assay suitable for use with small quantities of cytosolic protein, was developed. Studies defined the optimal equilibrium binding conditions, metabolism of [3H]dexamethasone in adult renal cytosol, specificity of binding of the GR, and molecular weight of the GR-[3H]dexamethasone complex by gel filtration chromatography. The assay was subsequently used to measure the renal GR during different stages of foetal and postnatal development, as well as in glomerular and renal tubular preparations from adult mice. An almost linear increase in GR occurred from day 13 to day 18 of gestation with levels rising from 100 to 201 fmol/mg cytosol protein; this was followed by a sharp rise in receptor concentration just after birth to 343 fmol/mg cytosol protein. Adult levels, 410-433 fmol/mg cytosol protein, were reached by 2 weeks after birth. The equilibrium dissociation constants (Kd) of the [3H]dexamethasone-receptor complex were similar in adult and in embryonic cytosols (range, 2.8-11.8 nM; mean +/- SD = 6.5 +/- 2.9 nM). Specific binding was assessed to be 3- to 5-fold greater in tubular than in glomerular preparations. These data on the localization and ontogeny of GR during murine metanephric development provide a basis for study of glucocorticoid-mediated effects on various models of congenital and acquired renal disease.     

Regulation of hepatic glucocorticoid receptors in mice during dietary restriction.

The specific binding of [3H] dexamethasone to its receptor, activation of the hormone-receptor complexes and DNase I digestion of nuclear bound hormone-receptor complexes were studied in the liver of mice during dietary restriction (alternate days of feeding for 3 months) compared to animals fed ad libitum. Results indicate an increase of receptor level (fmol/mg protein) in the diet-restricted (DR) animals as compared to those fed ad libitum (AL). Scatchard analyses confirm the increase in the level of receptors in DR animals, while the affinity (Kd) remained same in both groups of mice. Protein slot-blot analysis also depicts the increase of the receptor level in DR fed compared to the AL fed animals. The extent of temperature- and salt-dependent activation of receptors showed no marked difference in AL- and DR-fed mice. DNase I extraction of bound hormone-receptor complexes from nuclei revealed similar pattern of digestion in both groups of animals.     

Glucocorticoid negative feedback and glucocorticoid receptors after hippocampectomy in rats

In rats with dorsal hippocampectomy, glucocorticoid receptors in the hypothalamus and anterior pituitary, as well as the pituitary transcortin-like compound, are preserved, in spite of a 60% depletion of glucocorticoid receptors in the hippocampus. In the hippocampectomized group, basal levels of serum corticosterone (CORT) were increased, although there was a normal response to ether stress. Inhibition of the response to ether with dexamethasone (DEX) was dose-dependent: whereas 100 micrograms/kg completely suppressed serum CORT, 10 micrograms/kg were ineffective. However, we observed a reduced sensitivity to DEX inhibition with 25 micrograms/kg in hippocampectomized animals. These results indicate that the hippocampus is involved in negative feedback mechanisms, although different doses of DEX are needed for this demonstration. The inhibition of serum CORT due to 100 micrograms/kg DEX suggests that negative feedback at sites other than the hippocampus was still operative, in agreement with normal levels of glucocorticoid receptors in the anterior pituitary and hypothalamus of hippocampectomized rats.     

Regulation of glucocorticoid receptors in human mononuclear cells: effects of glucocorticoid treatment, Cushing's disease and ketoconazole

Glucocorticoid receptors (GcR) were determined by a whole cell assay in human mononulear leukocytes (hMNL) from control subjects, patients receiving glucocorticoid therapy for systemic diseases and Cushing's disease patients with or without ketoconazole therapy. Prolonged corticosteroid treatment resulted in down-regulation of GcR, while the mean level of GcR in Cushing's disease was normal. In this group, however, receptor levels and morning plasma cortisol values showed a negative correlation, indicating a subtle down-regulatory effect. Furthermore, GcR were unaltered after these patients received ketoconazole, in spite of a marked reduction in morning plasma cortisol and urinary free cortisol. We also observed that ketoconazole was a weak competitor of GcR in intact cells, although it significantly inhibited [3H] dexamethasone binding in cytosolic preparations from rat tissues. The results suggested that GcR in hMNL are down-regulated by synthetic steroids given in vivo, but they showed very mild down-regulation in hypercortisolemic patients suffering from Cushing's disease. Finally, we did not observed either up-regulation or antagonism of GcR by ketoconazole treatment, at the time that cortisol levels of patients with Cushing's disease were reduced. This indicates that the beneficial effects of ketoconazole in Cushing's disease are due to adrenal cortisol suppression and not to interaction with GcR of target cells, and that the process of GcR regulation in hMNL is a complex phenomenon awaiting further elucidation.