The influence of streptozotocin diabetes on adrenal function in male rats.

Male Wistar rats were treated with an i.v. dose of 100 mg/kg of Streptozotocin (STZ). Either 5 days or 1, 2 or 3 months after induction of diabetes, the adrenal function of these animals was studied. Short course diabetes (5 days) was accompanied by adrenal hypertrophy and high plasma corticosterone levels; during later periods the diabetic rats consistenly showed signs of adrenal hyperactivity, yet both adrenal weight and plasma corticosterone tended to be lower than in the 5 day-treated animals. Adrenal incubations with 14C-progesterone showed that 5 days and one month diabetic animals synthesized more deoxycorticosterone than controls; production of corticosterone and 18-hydroxydeoxycorticosterone was normal at all time periods studied. Synthesis of 18-hydroxycorticosterone, a compound which affects sodium metabolism, was increased in 5 day-treated rats; thereafter, the function of the zona glomerulosa seemed to be impaired in diabetic rats. These results suggest that early after induction of diabetes there is adrenal hyperfunction of the mixed type (i.e. gluco and mineralcorticoid), and that in the later periods (2-3 months), the deranged metabolism of the diabetic rat acts as a chronic stress.     

Production of corticosterone in male homozygous Brattleboro rats

Plasma concentration, metabolic clearance rate and in vitro adrenal production of corticosterone were measured in Brattleboro male rats homozygous for diabetes insipidus (DI) and in Long-Evans male rats (LE) as controls in resting conditions, under stress caused by pentobarbitone anesthesia and surgery and after three days water deprivation. In resting animals, plasma concentrations and in vitro adrenal production of corticosterone were higher in DI rats than in LE rats. Under pentobarbitone anesthesia and surgery, plasma concentrations and metabolic clearance rate of corticosterone were slightly but not statistically lower in DI rats; however, the in vivo production rate of corticosterone was significantly lower. After three days water deprivation, increasing plasma corticosterone level was consistently higher in DI than in Le rats. These results are not in favour of a reduced glucocorticoid activity of the adrenal of DI rats and of an important role played by vasopressin on the stimulation of the hypothalamopituitary adrenal activity at least in resting conditions; its role may depend upon stressful circumstances.     

Oleoyl-estrone increases adrenal corticosteroid synthesis gene expression in overweight male rats

Oleoyl-estrone (OE) induces a marked loss of body fat in rats by maintaining energy expenditure, body protein and blood glucose despite decreasing food intake. OE increases glucocorticoids, but they arrest OE lipid-mobilization. We studied here whether OE induces a direct effect on adrenal glands function as part of this feedback regulation. Dietary overweight male rats were given oral 10 nmol/g OE gavages for ten days. A group (PF) of pair-fed to OE rats, and controls received vehicle-only gavages. OE rats lost slightly more body than PF, but had larger adrenal glands. Tissue corticosterone levels, and gene expressions for glucocorticoid-synthesizing enzymes were increased in OE versus controls and PF; thus, we assumed that adrenal growth affected essentially its cortex since OE also lowered the expression of the medullar catecholamine synthesis enzyme genes. Serum corticosterone was higher in PF than in OE and controls, but liver expression of corticosteroid-disposing steroid 5α-reductase was 3× larger in OE than PF and controls. Circulating glucocorticoids changed little under OE, in spite of higher adrenal gland and liver content, hinting at modulation of glucocorticoid turnover as instrumental in their purported increased activity. In conclusion, we have observed that OE considerable enhanced the expression of the genes controlling the synthesis of glucocorticoids from cholesterol in the rat and increasing the adrenal glands’ corticosterone, size and cellularity, but also the liver disposal of corticosteroids, suggesting that OE increases corticosterone synthesis and degradation (i.e. serum turnover), a process not driven by limited energy availability but directly related to the administration of OE.     

Mirex-induced liver enlargement in rats is dependent upon an intact pituitary-adrenalcortical axis

The effect of prior hypophysectomy upon mirex-induced liver hypertrophy in male Sprague-Dawley rats was examined. Mirex had no effect upon adrenal weight, liver weight, plasma glucose or plasma corticosterone in hypophysectomized rats. However, daily corticosterone supplements (20 mg/kg body weight, sc) given to mirex-treated hypophysectomized animals yielded a 52% increase in liver weight to body weight ratios over those observed in mirex-treated hypophysectomized animals not receiving supplement. In intact rats, both liver weight to body weight ratios and plasma ACTH were significantly increased over controls 2 days after mirex treatment. These results indicate that mirex-induced liver enlargement not only requires corticosterone, but that the response is dependent upon an intact pituitary-adrenalcortical axis.     

Effects of water deprivation on corticosterone production in the male Brattleboro rat genetically deprived of vasopressin

Effects of 72 h water-deprivation on plasma corticosterone concentration have been investigated in male Brattleboro rats homozygous for hypothalamic diabetes insipidus (DI) and in male Long-Evans rats (LE), as controls. To determine the global effect of water deprivation, drinking water deprived rats were compared with hydrated animals. Because water deprived rats showed a depressed food intake, to elucidate the specific effect of dehydration alone, drinking water deprived rats were compared with similar food-restricted but water supplied animals. Increases in adrenal weights and in plasma corticosterone content, following 72 h water-deprivation, were greater in DI than in LE rats. In LE rats, they seemed to be the result of both dehydration and denutrition. Conversely in DI rats lacking vasopressin, dehydration alone increased neither adrenal weights nor plasma concentration of corticosterone; the whole plasma corticosterone content was reduced. So, in DI rats, the global response to drinking water deprivation was essentially due to food restriction, whose effect was partly suppressed by dehydration. Whatever the circumstances, plasma concentrations of corticosterone were higher in DI than in LE rats. Interrelationships between water deprivation, stress, vasopressin and glucocorticoids are discussed.     

Circadian rhythm of corticosterone in diabetic rats

We proposed that the circadian rhythm of corticosterone in diabetic rats would have a different pattern than that in non-diabetic control rats. To test this hypothesis, 20 male Sprague-Dawley rats were given ad libitum access to a stock diet and housed individually in a light and temperature controlled room. Ten rats were made diabetic by two subcutaneous injections of streptozotocin. Ten rats which were not injected served as controls. Thirteen days after induction of the diabetes, tail blood samples were taken every 4 h for 24 h. Plasma corticosterone levels were significantly higher in diabetic rats than in control rats at 3 time points during the light cycle; however, concentrations were similar during the dark cycle. We speculate that diabetes may cause alterations in the steroid feedback mechanism to the hypothalamus and/or pituitary, resulting in an abnormal circadian rhythm of plasma corticosterone.     

Melatonin and adrenal cortex steroid production: in vivo and in vitro studies.

The present study was designed to clarify the interaction between the pineal melatonin and adrenal cortex steroid production. Experiments with male rats under chronic stress conditions (sleep deprivation) revealed that melatonin circadian pattern was fully destroyed and daytime plasma concentration were significantly elevated. Constant illumination (2500 lux) during the nighttime was not able to suppress melatonin production in the stressed animals. Plasma concentration of corticosterone were increased in the stressed rats as well. The modulatory effect of melatonin on corticosterone and progesterone production by rat adrenals was studied in a superfusion system. During melatonin challenge progesterone secretion was two-three fold elevated with no effect on corticosterone content in the plasma samples. Pineal cytoplasmic glucocorticoid and progesterone receptors were investigated as well. A specific binding was not observed in that case. Presented data support the existence of direct communication between the pineal and adrenal glands.     

Stress-induced changes of glucocorticoid receptor in rat liver.

The effect of corticosterone injection and of acute and repeated stress on rat liver cytosol glucocorticoid receptor was studied to ascertain whether corticosterone-induced glucocorticoid receptor (GR) regulation also takes place in intact animals as it does in adrenalectomized ones. Adult male rats were exposed to six different stressors (swimming, 10 mg/kg histamine i.p., 500 mU/kg vasopressin s.c., heat, immobilization and cold) acutely or three times daily for 18 days (repeated stress). Each of the stressors applied acutely provoked a pronounced increase of plasma corticosterone with subsequent induction of hepatic tyrosine aminotransferase activity. Depletion of cytosol receptor was however only noticed after swimming and histamine injection. On the other hand, sustained hypersecretion of corticosterone evoked by repeated stress significantly reduced the number of GR in rat liver cytosol without any change in Kd. It is concluded that in the presence of intact adrenal glands cytosol receptors are more resistant to corticosterone-induced depletion than in their absence. Further, repeated stress causes down-regulation of GR in the liver, most probably by sustained corticosterone secretion, yet the effect of other stress factors cannot be excluded.     

Adrenal glucocorticoid function and cytoplasmic dehydrogenase activity in the presnece of mechanical and toxic liver damage]

Against the background of low steroid metabolism in the liver there was noted some decrease in the rate of corticosterone synthesis by the adrenal gland sections, and also, a decrease in the dehydrogenase activity in the cytoplasm of adrenal cells in male rats 48 hours after partial hepatectomy, as compared to the sham-operated animals. These changes resulted from suppression of the central mechanisms of stress realization due to the lowered steroid metabolism. Intraperitoneal administration of carbon tetrachloride (0.1 ml per 100 g of body weight) at the same periods led to a significant intensification of the steroidogenesis in the adrenal tissue and to the activation of NAD-dependent dehydrogenases in the cytoplasm. The role of toxic injury of the glands in the changes of the functional state of the adrenal cortex cells is discussed.     

Altered stress responsiveness and hypothalamic‐pituitary‐adrenal axis function in male rat offspring of socially isolated parents

Social isolation in male rats at weaning results in reduced basal levels of the neuroactive steroid 3α,5α‐tetrahydroprogesterone (3α,5α‐TH PROG) in the brain and plasma as well as increased anxiety‐like behavior. We now show that socially isolated female rats also manifest a reduced basal cerebrocortical concentration of 3α,5α‐TH PROG as well as an anxiety‐like profile in the elevated plus‐maze and Vogel conflict tests compared with group‐housed controls. In contrast, despite the fact that they were raised under normal conditions, adult male offspring of male and female rats subjected to social isolation before mating exhibited an increased basal cerebrocortical level of 3α,5α‐TH PROG but no difference in emotional reactivity compared with the offspring of group‐housed parents. These animals also showed an increased basal activity of the hypothalamic‐pituitary‐adrenal axis as well as reduced abundance of corticotropin‐releasing factor in the hypothalamus and of corticotropin‐releasing factor receptor type 1 in the pituitary. Moreover, negative feedback regulation of hypothalamic‐pituitary‐adrenal axis activity by glucocorticoid was enhanced in association with up‐regulation of glucocorticoid receptor expression in the hippocampus. There was also attenuation of corticosterone release induced by foot‐shock stress in the offspring of socially isolated parents. The increase in the brain concentration of 3α,5α‐TH PROG induced by acute stress was also blunted in these animals. Our results thus show that a stressful experience before mating can influence neuroendocrine signaling in the next generation.     

Serum 11-deoxycorticosterone levels in adrenal-regeneration hypertension under conditions of quiescence and stress.

A time course study to measure adrenal cortical function was undertaken for the period prior to the development of hypertension until the onset of hypertension in the adrenal-regeneration hypertension (ARH) model. Quiescent rat kills were used so that all adrenal cortical parameters investigated would reflect basal or resting levels for controls. Thus a more accurate determination of the differences between control and experimental animals could be made. A radioimmunoassay procedure for deoxycorticosterone was developed to measure this steroid in individual rat serum samples. Elevated serum deoxycorticosterone levels were observed in rats with regenerating adrenals when they were killed under quiescent conditions. This agreed with our recently reported in vitro finding of restoration of cholesterol side chain cleavage activity while 11beta-hydroxylase activity remained imparied 25 days after adrenal enucleation. When rats were killed after ether stress, deoxycorticosterone levels were elevated in both control rats and in rats with regenerating adrenals but the difference was not significant. In contrast, after ether stress serum corticosterone levels were lower in rats with regenerating adrenals than in controls. These studies, in conjunction with our previous in vitro findings, point to the importance of deoxycorticosterone in the pathogenesis of adrenal regeneration hypertension and help to explain the anomalous corticosteroid secretion rate data found in this experimental hypertension model.     

Selenium deficiency impairs corticosterone and leptin responses to adrenocorticotropin in the rat

Selenium deficiency causes oxidative stress and impairs steroidogenesis in vitro. Leptin is closely related to the hypothalamo-pituitary-adrenal (HPA) axis. Leptin inhibits the HPA axis at the central level while corticosteroids have been shown to stimulate leptin secretion in most studies. We hypothesized that oxidative stress impairs adrenal steroidogenesis and decreases leptin production in vivo. The goal of this study was to investigate in rats the effects of selenium deficiency and oxidative stress on adrenal function and on leptin concentrations. Weanling rats were fed a selenium-deficient (Se-) or selenium-sufficient (Se+) diet for 4-10 weeks. Selenium deficiency caused a marked decrease in liver (> or = 99%) and adrenal (> or = 81%) glutathione peroxidase (GPx) activities. Selenium deficiency did not affect basal and short-term adrenocorticotropin (ACTH) stimulated corticosterone or leptin concentrations. In contrast, after long-term ACTH stimulation, selenium deficiency caused a doubling in adrenal isoprostane content and blunted the increase in corticosterone and leptin concentrations observed in Se+ animals. Plasma leptin concentrations were 50% lower in Se- compared to Se+ animals following long-term ACTH. Our results suggest that oxidative stress causes a decrease in circulating corticosterone in response to ACTH, and, as a consequence, a decrease in plasma leptin concentrations.     

Accelerative effect of olive oil on liver glycogen synthesis in rats subjected to water-immersion restraint stress

The effects of dietary oils on stress-induced changes in the liver glycogen metabolism of male Wistar rats at 6 weeks of age were investigated. The rats were subjected to repetitive water-immersion restraint and fed with a 20% saturated fatty acid mixture (PSC), olive oil (OLI), safflower oil (SAF), or linseed oil (LIS) diet. Stress loading decresed the body weight gain, although the food intake was hardly changed, and the weights of the liver and spleen generally declined regardless of the elapsed time after stress loading and the type of dietary oil. The adrenal weight was generally enhanced by stress in all deitary groups, and particularly tended to be greater in the OLI and PSC groups than in the other two. The plasma corticosterone concentration increased immediately after stressing (Stress-1), but approached the level of the rats with no stress (No stress) 2 h after releasing the stress load (Stress-2) in all groups. The enhancement of corticosterone level in the Stress-1 animals was large in the PSC and OLI groups, and the decline of this level in the Stress-2 animals was small in the OLI group when compared with the other groups. Although the concentrations of total cholesterol (T-CHOL) and triacylglycerol (TG) in the plasma were decreased by stress loading in all groups, these concentrations in the PSC and OLI groups were nearly always higher than in the other groups. The liver serine dehydratase (SDH) activity enhanced by stress was high in the OLI group and tended to be high in the PSC group when compared with the other groups. The contents of liver glycogen were reduced in the Stress-1 animals and extremely elevated in the Stress-2 animals of all groups, and particularly in the OLI group, the reduction in the Stress-1 animals was smaller and the enhancement in the Stress-2 animals was greater than in the other groups. These results suggest that feeding oleic acid to rats exposed to water-immersion restraint further accelerated liver glycogen synthesis through the rise in liver SDH activity due to increased corticosterone secretion when compared with the effect from linoleic and alpha-linolenic acids.     

Plasma Corticosterone, Motor Activity and Metabolic Circadian Patterns in Streptozotocin-Induced Diabetic Rats

Experiments were conducted in male rats to study the effects of streptozotocin-induced diabetes on circadian rhythms of (a) plasma corticosterone concentrations; (b) motor activity; and (c) metabolic patterns. Animals were entrained to LD cycles of 12: 12 hr and fed ad libitum.

A daily rhythm of plasma corticosterone concentrations was found in controls animals with peak levels at 2400 hr and low values during the remaining hours. This rhythm was statistically confirmed by the cosinor method and had an amplitude of 3.37μg/100 ml and the acrophase at 100 hr. A loss of the normal circadian variation was observed in diabetic animals, with a nadir at the onset of light period and high values throughout the remaining hours; cosinor analysis of these data showed no circadian rhythm, delete and a higher mean level than controls.

As expected, normal rats presented most of their motor activity during the dark period with 80+ of total daily activity; the cosinor method demonstrated a circadian rhythm with an amplitude of 60+ of the mean level and the acrophase at 0852 hr. Both diabetic and control rats showed a similar activity during the light phase, but diabetic animals had less activity than controls during the night and their percentage of total daily activity was similar in both phases of the LD cycle (50+ for each one). With the cosinor method we were able to show the persistence of a circadian rhythm in the motor activity of diabetic rats, but with a mesor and amplitude lower than in controls (amplitude rested at 60+ of the mean level) and its acrophase advanced to 0148 hr.

The metabolic activity pattern of diabetic rats also changed: whereas controls showed a greater metabolic activity during the night (70+ food; 82+ water; 54+ urine; 67+ faeces), diabetics did not show differences between both phases of the LD cycle. Water ingested and urine excreted by the diabetic group were higher than normal during light and dark periods; food consumed and faeces excreted were higher than controls only in the light phase.

These data suggest that alterations in circadian rhythms of plasma corticosterone and motor activity are consecutive to the loss of the feeding circadian pattern, due to polyphagia and polydipsia showed by these animals, which need to extend intakes during the light and dark phases.     

Influence of stress and phenobarbital on corticosterone metabolism during early postnatal life of rat

Postnatal changes in liver corticosterone metabolism in vitro were investigated in male rats pretreated for three days twice daily by physiological saline i.p./stress/ or by phenobarbital /20 mg/kg/. Perinatally, both stress and phenobarbital decrease corticosterone side chain metabolism while no change was observed in A ring reduction rate. In older animals no effect of the stress on corticosterone metabolism was observed. The inhibitory influence of phenobarbital on the side chain metabolism was still apparent at age of 14 days, but not in adult animals. The A ring reduction rate was increased by phenobarbital at age of 14 days and in adult animals.Measurements of serum corticosterone and corticosterone production by adrenal glands in vitro confirmed earlier reports showing that during perinatal period increased level of circulating corticosterone can be associated with minor or transient changes in adrenal cortex activity.It is concluded that changes in liver corticosterone metabolism are likely to play an important role in regulation of glucocorticoid activity perinatally when the responsiveness of pituitary-adrenal system to environmental stimuli is decreased.     

Effect of the growth hormone-secreting tumor StW5 on pituitary and adrenal gland function in rats

A growth hormone-secreting tumor (StW5 was implanted into male rats and resulted in a tripling of adrenal weight concomitant with a 30% decrement in pituitary weight. Plasma concentrations of corticosterone in tumor-bearing (TB) rats were significantly elevated at rest or after ACTH injections or the stress of either anesthesia. The rise in plasma concentrations of corticosterone was due mainly to the large increment in adrenal size although a significant increase in adrenal responsiveness to ACTH was demonstrated in vitro. In addition, plasma corticosterone concentrations were higher in TB rats despite both a doubling of the blood volume and a 50% increase in liver capacity to metabolize corticosterone. Pituitary ACTH content was significantly lower in TB rats, but these pituitary glands could still release near-normal quantities of ACTH as shown both by in vitro incubations and adrenal corticosterone output following ether stress.     

Adrenal function of rats in hypokinesia

Histological and biochemical examinations of the adrenals and plasma of rats for 3 months exposed to hypokinesia have shown that low motor activity led to a decrease in blood corticosterone level in spite of adrenal cortex hypertrophy. The decreased corticosterone blood level was not indicative of adrenal exhaustion, as the adrenals produced a greater amount of corticosterone in response to additional stress stimulus (5-hour immobilisation of animals in an extended state), as compared to the control. The increased production of corticosterone in response to stress stimulus caused no structural transformations or delipoidization of the cortical substance. This indicated that the reserve potentials of the adrenals increased with the animal adaptation to hypokinesia. The major morphological indication of higher adrenal functional activity in hypokinetic animals was an enhanced destruction of lymphocytes in the thymus cortex, the target organ for corticosteroids produced by the adrenals in response to an additional stress stimulus.     

24-hour changes in ACTH, corticosterone, growth hormone, and leptin levels in young male rats subjected to calorie restriction

Calorie restriction of young male rats increases plasma prolactin, decreases luteinizing hormone (LH) and testosterone, and disrupts their 24 h secretory pattern. To study whether this could be the consequence of stress, we examined the 24 h variations of plasma adrenocorticotropic hormone (ACTH) corticosterone, growth hormone (GH), leptin, and adrenal corticosterone. Rats were submitted to a calorie restriction equivalent to a 66% of usual intake for 4 weeks, starting on day 35 of life. Controls were kept in individual cages and allowed to eat a normal calorie regimen. Significantly lower ACTH levels were detected in calorie-restricted rats. Plasma corticosterone levels during the light phase of the daily cycle were significantly higher in calorie-restricted rats. Time-of-day variation in plasma ACTH and corticosterone levels attained significance in calorie-restricted rats only, with a maximum toward the end of the resting phase. The daily pattern of adrenal gland corticosterone mirrored that of circulating corticosterone; however, calorie restriction reduced its levels. Plasma ACTH and corticosterone correlated significantly in controls only. Calorie restriction decreased plasma GH and leptin, and it distorted 24 h rhythmicity. In a second study, plasma ACTH and corticosterone levels were measured in group-caged rats, isolated control rats, and calorie-restricted rats during the light phase of the daily cycle. Plasma ACTH of calorie-restricted rats was lower, and plasma corticosterone was higher, compared with isolated or group-caged controls. The changes in the secretory pattern of hormones hereby reported may be part of the neuroendocrine and metabolic mechanisms evolved to maximize survival during periods of food shortage.     

Central injection of morphine stimulates plasma corticosterone and interleukin (IL)-6 and IL-6 R mRNAs in the pituitary and adrenals in adjuvant-induced arthritis.

Adjuvant-induced arthritis (AA) in the rat is a T-cell mediated, chronic inflammatory stress in which circulating interleukin (IL)-6 levels are elevated. In addition, there are profound neuroendocrine changes associated with the development of hind-paw inflammation which have major implications for the ability of the rat to respond the to stress. Central injection of morphine is also able to increase circulating IL-6 concentration in control animals. In the present study we have determined the effects of a single injection of morphine into the lateral ventricle of control and AA animals on plasma corticosterone levels, on changes in plasma corticosterone and on IL-6 and IL-6 receptor mRNAs in the pituitary and adrenal gland. IL-6 and IL-6 receptor mRNAs were increased in the anterior pituitary of AA rats given moprhine compared with saline-treated AA rats. In the adrenal cortex, IL-6 mRNA was unaltered and IL-6 receptor mRNA was significantly decreased under these same conditions. AA rats were unable to mount corticosterone response to acute stress but were able to respond to acute stimulation with e.g. LPS. In the present study we found a sustained increase in plasma corticosterone in control animals which was still significantly elevated 2 hours following morphine injection, with a further significant increase in AA rats. These data suggest that alternative systems distinct from those activated in response to acute stress are activated by morphine in the AA animals. The similarity with the sustained increase in corticosterone following LPS injection suggest that either similar pathways are involved, or that central opiates may be involved in mediating HPA axis response to stress.     

The neonatal glucocorticoid treatment-produced long-term changes of the pituitary-adrenal function and brain corticosteroid receptors in rats.

Two distinct periods of sensitivity to elevated glucocorticoid hormone levels during postnatal development of the pituitary-adrenal axis were studied. Wistar rats were injected subcutaneously (s.c.) with cortisol (1 mg/kg) on postnatal days 1-5 or 14-18. The steroid treatment during the first postnatal week resulted in a decrease of the morning basal and stress-induced plasma corticosterone levels in 30 day-old male rats, as well as in rats that were injected with cortisol on the third postnatal week. Stress-induced corticosterone levels in 90-day old cortisol-treated rats were determined in blood samples drawn from the tail vein before the restraint stress, immediately after the 20-min long stress, then 60 and 180 min afterwards. Only the rats treated with cortisol during the third week showed a prolonged stress-induced corticosterone secretion, with the highest corticosterone level in 180 min after the restraint stress. The early neonatal cortisol treatment had no effect on (3)H-corticosterone binding in all studied brain areas of the 90-day old rats. The rats treated with cortisol at the 14-17th postnatal days showed a significantly lower (3)H-corticosterone binding in the frontal cortex, hippocampus, and hypothalamus. These findings suggest that the third week of life in rats is more sensitive to elevated levels of corticosterone than the first one. The high level of glucocorticoids at this period has long-term effects on the efficiency of the negative feedback mechanisms provided by hypothalamus-pituitary-adrenal axis.