Circadian rhythm of circulating glucose,insulin and growth hormone in spontaneously hypertensive rats

Circulating levels of growth hormone (GH), insulin, and glucose were measured at hourly intervals during a 24 h period to establish the diurnal rhythm of these hormones in spontaneously hypertensive rats (SHR). There was no statistically significant correlation between circulating GH levels and pituitary GH content. Serum GH appeared to be higher at night in female SHR and higher during day-light hrs in male SHR. GH levels fluctuated considerably, whereas insulin levels showed much less diurnal variation. Although there was no statistically significant correlation between blood glucose and insulin levels, glucose levels rose and fell considerably during the 24 hr period with a definite decline in blood glucose during the nocturnal hyperactivity observed in SHR. These findings are of interest in that SHR have giant-sized islets of Langerhans, develop hyperglycemia spontaneously, and are growth-retarded compared to most normotensive strains of rat.     

Effect of Pituitary Graft-Induced Hyperprolactinemia on Adrenal Orcadian Rhythmicity

Prolactin is involved in the regulation of several endocrine functions. In this study, the possible influence of hyperprolactinemia on circadian corticosterone secretion has been investigated. Pituitary grafted male and female rats exhibited increased plasma PRL levels at 1000 when compared to sham-operated controls. This increase was only maintained over the 24 h period in grafted female rats but not in males, thus suggesting a different sex dependent modification of the regulatory mechanisms of prolactin. The corticosterone secretion pattern in sham operated male and female rats was similar to those described earlier but was altered by hyperprolactinemia according to the sex of the animal. There was a significant decrease in the total amount of corticosterone secreted in a 24 h period in grafted males as compared to control animals, whereas no significant differences were observed in grafted female rats as compared to controls. Grafted females showed a 4 h delay in the 24 h secretion rhythm as compared to control animals. These data suggest that pituitary transplant induced hyperprolactinemia, directly or through modifications in catecholamine turnover, is able to modify adrenal rhythmicity.     

Effect of Pituitary Graft-Induced Hyperprolactinemia on Adrenal Orcadian Rhythmicity

Prolactin is involved in the regulation of several endocrine functions. In this study, the possible influence of hyperprolactinemia on circadian corticosterone secretion has been investigated. Pituitary grafted male and female rats exhibited increased plasma PRL levels at 1000 when compared to sham-operated controls. This increase was only maintained over the 24 h period in grafted female rats but not in males, thus suggesting a different sex dependent modification of the regulatory mechanisms of prolactin. The corticosterone secretion pattern in sham operated male and female rats was similar to those described earlier but was altered by hyperprolactinemia according to the sex of the animal. There was a significant decrease in the total amount of corticosterone secreted in a 24 h period in grafted males as compared to control animals, whereas no significant differences were observed in grafted female rats as compared to controls. Grafted females showed a 4 h delay in the 24 h secretion rhythm as compared to control animals. These data suggest that pituitary transplant induced hyperprolactinemia, directly or through modifications in catecholamine turnover, is able to modify adrenal rhythmicity.     

Stress response patterns of plasma corticosterone, prolactin, and growth hormone in the rat, following handling or exposure to novel environment.

Corticosterone, prolactin, and growth hormone responses to 5 s of handling or 3 min of novel environment were compared in rats at crest and trough of the diurnal adrenal rhythm 0, 5, 15, 30, and 60 min after stimulation. All hormones responded to stimulation, corticosterone and prolactin with a dramatic rise, and growth hormone with a precipitous fall. Resting corticosterone levels evidenced the expected diurnal variation, and prolactin but not growth hormone also showed a baseline diurnal variation of small magnitude at the times studied. Growth hormone response characteristics were unaffected by time of day or type of stimulation. Both corticosterone and prolactin response profiles differed at both times of day and following both types of stimulation. Corticosterone and prolactin levels were highly correlated and each was negatively correlated with growth hormone levels. This study confirms that hormone responses to stress are complex and depend not only on the stimulus but the context of stimulation.     

Sex and sex hormones influence the development of albuminuria and renal macrophage infiltration in spontaneously hypertensive rats

There is a sex difference in hypertensive renal injury, with men experiencing greater severity and a more rapid progression of renal disease than women; however, the molecular mechanisms protecting against renal injury in women are unknown. The goal of this study was to determine whether sex hormones modulate blood pressure and the progression of albuminuria during the developmental phase of hypertension in male and female spontaneously hypertensive rats (SHR). Studies were also performed to examine how sex and sex hormones influence two major risk factors for albuminuria, overactivation of the renin-angiotensin system and oxidative stress. Blood pressure was measured by telemetry in gonad-intact and gonadectomized male and female SHR. Microalbumin excretion, measured over time, and macrophage infiltration were used to assess renal health. Male SHR had significantly higher blood pressures than female SHR, and gonadectomy decreased blood pressures in males with no effect in females. Male SHR displayed a gonad-sensitive increase in albuminuria over time, and female SHR had a gonad-sensitive suppression in macrophage infiltration. Female SHR had greater plasma ANG II levels and similar levels of renal cortical ANG II vs. levels shown in males but less AT(1)-receptor protein expression in the renal cortex. Female SHR also had a gonad-sensitive decrease in renal oxidative stress. Therefore, the renal protection afforded to female SHR is associated with lower blood pressure, decreased macrophage infiltration, and decreased levels of oxidative stress.     

Effect of constant light on prolactin and corticosterone rhythms evaluated using a noninvasive urine sampling protocol in the rat.

Circadian prolactin and corticosterone rhythms are usually investigated in the rat by analysis of plasma hormone profiles. In order to develop a nonstressful methodology for long-term studies, we validated prolactin and corticosterone radioimmunoassays in rat urine samples. Among the criteria of validation, prolactin was identified in urine by Western blot whereas both prolactin and corticosterone levels were undetectable in the urine of hypophysectomized rats. The determination of prolactin and corticosterone levels on serial urine samples showed daily variations in male rats entrained by the light-dark cycle. The acrophases of the 24-hour prolactin and corticosterone profiles were located at 03:26 h and 23:32 h respectively, a delay of 3-4 hours compared with the values of the 24-hour plasma profiles reported in the literature. Corticosterone and prolactin rhythms were abolished or dramatically delayed after 3 weeks of constant illumination. As expected, constant light suppressed the rhythm of 6-sulfatoxymelatonin, the major hepatic metabolite of melatonin. The noninvasive and nonstressful methodology we developed could be of interest for studying the regulation of hormone rhythms and their mutual endocrine interactions in physiological conditions, especially their evolution in the aging process.     

Propranolol-induced alterations in the pathophysiology of spontaneously hypertensive rats

Male and female, spontaneously hypertensive rats (SHR) were treated with propranolol (14 weeks) when they became 1, 4 and 8 months old prior to, during the steep ascent, and when severe high blood pressure becomes established. Propranolol prevented the usual increase in blood pressure at an early age but did not effectively lower blood pressure at all age levels. Propranolol-treated SHR manifested marked alterations in pituitary, adrenal, thymus, heart and gonadal weights. Despite progressively increasing hyperlipidemia and hyperglycemia, there were no significant differences between lipid, glucose, BUN, or serum enzyme levels in treated vs nontreated SHR. Circulating aldosterone and corticosterone levels were reduced in propranolol-treated SHR. Male SHR, treated or untreated, developed severe cardiovascular-renal lesions when they became 8 months old; none of the female SHR manifested any pathologic changes. It is suggested that the anti-hypertensive effects of propranolol were partially mediated by hormonal as well as by hemodynamic mechanisms.     

Adrenocorticotropin and corticosterone levels in pre-weanling spontaneously hypertensive rats

Circulating plasma ACTH and corticosterone levels were measured in spontaneously hypertensive rats (SHR) and the corresponding, normotensive Wistar-Kyoto (WKY) strain at 10 and 20 days of age. In addition, stored levels of ACTH were measured in the pituitary glands of these animals. Circulating corticosterone levels were significantly lower, in both strains, at 10 days than at 20 days. Although the glucocorticoid was undetectable in WKY animals at 10 days, significant levels were observed in age-matched SHR. No difference in corticosterone concentrations was observed between the two strains at 20 days. Circulating ACTH levels did not reflect the values for circulating glucocorticoids. There were no significant differences in the levels of ACTH between strains or between age groups. Moreover, pituitary stores of ACTH between animals of different strains and ages were not found to be significantly different among any of the groups tested. These results demonstrate that there is a difference in circulating corticosterone levels between spontaneously hypertensive and Wistar-Kyoto rats at 10 days postnatally which is not evident just prior to weaning (20 days). This difference is not due to variations in stored or circulating ACTH. Indeed, ACTH levels are high at a time (10 days) when corticosterone is low - thus suggesting that the difference may reside within the responsiveness of the adrenal cortex.     

Circadian Mechanisms of Food Anticipatory Rhythms in Rats Fed Once or Twice Daily: Clock Gene and Endocrine Correlates

Circadian clocks in many brain regions and peripheral tissues are entrained by the daily rhythm of food intake. Clocks in one or more of these locations generate a daily rhythm of locomotor activity that anticipates a regular mealtime. Rats and mice can also anticipate two daily meals. Whether this involves 1 or 2 circadian clocks is unknown. To gain insight into how the circadian system adjusts to 2 daily mealtimes, male rats in a 12∶12 light-dark cycle were fed a 2 h meal either 4 h after lights-on or 4 h after lights-off, or a 1 h meal at both times. After 30 days, brain, blood, adrenal and stomach tissue were collected at 6 time points. Multiple clock genes from adrenals and stomachs were assayed by RT-PCR. Blood was assayed for corticosterone and ghrelin. Bmal1 expression was quantified in 14 brain regions by in situ hybridization. Clock gene rhythms in adrenal and stomach from day-fed rats oscillated in antiphase with the rhythms in night-fed rats, and at an intermediate phase in rats fed twice daily. Corticosterone and ghrelin in 1-meal rats peaked at or prior to the expected mealtime. In 2-meal rats, corticosterone peaked only prior the nighttime meal, while ghrelin peaked prior to the daytime meal and then remained elevated. The olfactory bulb, nucleus accumbens, dorsal striatum, cerebellum and arcuate nucleus exhibited significant daily rhythms of Bmal1 in the night-fed groups that were approximately in antiphase in the day-fed groups, and at intermediate levels (arrhythmic) in rats anticipating 2 daily meals. The dissociations between anticipatory activity and the peripheral clocks and hormones in rats anticipating 2 daily meals argue against a role for these signals in the timing of behavioral rhythms. The absence of rhythmicity at the tissue level in brain regions from rats anticipating 2 daily meals support behavioral evidence that circadian clock cells in these tissues may reorganize into two populations coupled to different meals.     

Altered circadian rhythms of corticosterone, melatonin, and phagocytic activity in response to stress in rats

Corticosterone is thought to be the main glucocorticoid secreted in response to stressful exercise, while melatonin buffers the adverse immunological effects of stress. The present work was aimed to evaluate whether swimming-exercise-induced stress leads to changes in the chronobiology parameters of the circadian rhythms of melatonin and corticosterone, and in the number and phagocytosis of peritoneal macrophages in 3-month-old male Wistar rats. The animals were subjected to a physical activity trial consisting of 2 h of free swimming. Radioimmunoassay was used to determine the plasma levels of melatonin and corticosterone. Phagocytosis was measured by the latex-bead phagocytosis index (PI), i.e., the number of latex beads ingested by 100 macrophages, the phagocytosis percentage (PP), i.e., the percentage of cells that had phagocytosed at least one latex bead, and the phagocytosis efficiency (PE), i.e., the ratio PI: PP which indicates how effectively the phagocytes ingested the particles. Stress significantly decreased the MESOR and amplitude of the melatonin rhythm, and significantly increased the MESOR of the corticosterone rhythm. The control animals' peritoneal macrophage number and PI showed a circadian rhythm with maxima at 02:00 and 03:00, respectively. The stressed group displayed higher values of PI than the controls at most hours of the night, but the number of cells in the peritoneal cavity was practically the same at all hours studied. These data confirm that melatonin and corticosterone act as modulators of the innate immune response, and that the circadian rhythm of the two hormones are altered in situations of stress.     

Serum prolactin levels in rats following isoproterenol-induced myocardial infarction.

Circulating prolactin levels were monitored in nonarteriosclerotic, arteriosclerotic, and hormonally sterilized male and female Sprague-Dawley rats during the acute necrosis and repair phases of myocardial infarction induced by isoproterenol. Male rats are particularly prone to succumb to acute myocardial ischemia but reduction of androgen levels by neonatal sterilization improved survival considerably. Circulating prolactin levels are greatly increased, particularly in females, during acute myocardial ischemia. Since androgens suppress the hypothalamic center for prolactin release, prolactin levels were delayed and transitory in males. It is suggested that the superior survival of female rats may be related to their greater production of prolactin during acute stages of myocardial ischemia, which would dampen the tachycardia-inducing effects of the potent beta-adrenergic stimulating agent, isoproterenol.     

Circadian rhythm of plasma sodium is disrupted in spontaneously hypertensive rats fed a high-NaCl diet

High-NaCl diets elevate arterial pressure in NaCl-sensitive individuals, and increases in plasma sodium may trigger this effect. The present study tests the hypotheses that 1) plasma sodium displays a circadian rhythm in rats, 2) the plasma sodium rhythm is disturbed in spontaneously hypertensive rats (SHR), and 3) excess dietary NaCl elevates plasma sodium concentration in SHR. The results demonstrate that plasma sodium has a circadian rhythm that is inversely related to the circadian rhythm of arterial pressure. Although the plasma sodium rhythms of SHR and control rats are nearly identical, the plasma sodium concentrations are significantly higher in SHR throughout the 24-h cycle. Maintenance on a high-NaCl diet increases plasma sodium concentration similarly in both SHR and control rats, but it blunts the plasma sodium rhythm only in SHR. These results demonstrate that in rats, plasma sodium has a circadian rhythm and that high-NaCl diets increase plasma sodium concentration.     

Effect of thyroidectomy on rhythmic gonadotropin release.

Nonstress blood samples were obtained from intact and thyroidectomized (TE) male rats at 3-hr intervals over a 24-hr period via rapid decapitation. The animals were thyroidectomized when 40 days old and used 6 weeks later. Intact animals showed periodicity in serum LH (P less than 0.01) and prolactin (P less than 0.01). Both gonadotropins began increasing after 8 PM and peak levels occurred at 11 PM. In contrast, 24-hr periodicity was not observed in serum FSH. Corticosterone levels in these same serum samples showed the expected circadian periodicity. After TE, the 24-hr pattern in all gonadotropins was altered significantly. Serum LH increased (P less than 0.01) and circadian periodicity appeared to be absent. FSH and prolactin levels were increased and decreased, respectively (P less than 0.01), with serum prolactin showing a 9-hr phase shift. Prolactin began increasing at 2 AM and reached a peak at 8 AM. Corticosterone in TE animals showed a 24-hr rhythm similar to that of intact rats. These findings confirm our previous observations that nonstress serum LH and prolactin levels fluctuate with a 24-hr periodicity and suggest that the level of, and the phase angle betweeen, these rhythms is markedly influenced by pituitary-thyroid activity.     

Circadian Neuroendocrine Role in Age-Related Changes in Body Fat Stores and Insulin Sensitivity of the Male Sprague-Dawley Rat

A role for circadian neuroendocrine rhythms in the age-related development of obesity and insulin resistance was investigated in the male Sprague-Dawley rat. The phases and amplitudes of the plasma rhythms of several metabolic hormones (i.e. corticosterone, prolactin, insulin, and triiodothyronine) differed in lean, insulin-sensitive (3-week-old rats). insulin-resistant (8-week-old rats) and obese, insulin-resistant (44-week-old rats) animals. Simulation of the daily rhythms of endogenous corticosterone and prolactin by daily injections of the hormones at times corresponding to the peak levels found in 3-week-old rats reversed age-related increases in insulin resistance and body fat in older (5-6-month-old) rats. Ten such daily injections of corticosterone and prolactin in 12-14-week-old rats produced long-term reductions in body fat stores (30%). plasma insulin concentration (40%'). and insulin resistance (60%) (determined by a glucose tolerance test) measured 11-14 weeks after the treatment. Alterations in circadian neuroendocrine rhythms may account for age-related changes in carbohydrate and lipid metabolism in the male Sprague-Dawley rat, and resetting of these rhythms by appropriately timed daily injections of corticosterone and prolactin may help maintain metabolism characteristic of younger animals.     

Circadian Neuroendocrine Role in Age-Related Changes in Body Fat Stores and Insulin Sensitivity of the Male Sprague-Dawley Rat

A role for circadian neuroendocrine rhythms in the age-related development of obesity and insulin resistance was investigated in the male Sprague-Dawley rat. The phases and amplitudes of the plasma rhythms of several metabolic hormones (i.e. corticosterone, prolactin, insulin, and triiodothyronine) differed in lean, insulin-sensitive (3-week-old rats). insulin-resistant (8-week-old rats) and obese, insulin-resistant (44-week-old rats) animals. Simulation of the daily rhythms of endogenous corticosterone and prolactin by daily injections of the hormones at times corresponding to the peak levels found in 3-week-old rats reversed age-related increases in insulin resistance and body fat in older (5-6-month-old) rats. Ten such daily injections of corticosterone and prolactin in 12-14-week-old rats produced long-term reductions in body fat stores (30%). plasma insulin concentration (40%″). and insulin resistance (60%) (determined by a glucose tolerance test) measured 11-14 weeks after the treatment. Alterations in circadian neuroendocrine rhythms may account for age-related changes in carbohydrate and lipid metabolism in the male Sprague-Dawley rat, and resetting of these rhythms by appropriately timed daily injections of corticosterone and prolactin may help maintain metabolism characteristic of younger animals.     

Sex differences in adrenal function in the lizard Cnemidophorus sexlineatus: II. Responses to acute stress in the laboratory.

Circulating concentrations of plasma corticosterone and gonadal steroids were measured in intact and gonadectomized male and female lizards (Cnemidophorus sexlineatus) following acute stress (handling) in the laboratory. There was a significant increase in plasma corticosterone after stress. Whereas intact females exhibited greater concentrations of corticosterone relative to intact males, ovariectomized females exhibited lower concentrations of corticosterone relative to castrated males. In addition to sex differences in corticosterone responses to gonadectomy, progesterone was elevated by stress in both intact and ovariectomized females but not in males. Corticosterone adjusted for castration and handling in males was negatively correlated with the plasma androgen level. The adrenal responsiveness of males to acute stress may be attenuated by androgens presumably secreted by the testis. Not only does adrenal function influence reproduction, but adrenal responses differ between males and females, and appear to be influenced by the gonadal axis. The sex differences in adrenal responses to stress likely reflect different reproductive strategies and nutritional requirements of males and females during the breeding season.     

Influence of melatonin on rat thyroid, adrenals and testis secretion during the day.

The effect of pinealectomy and exogenous melatonin on circadian rhythm of triiodothyronine (T3), thyroxin (T4), corticosterone and testosterone in sham-operated and pinealectomized rats were investigated. The hormones concentration were RIA-measured and the circadian rhythm secretion were analysed by cosinor method. The findings suggest that pinealectomy abolishes the rhythmical character of corticosterone secretion and disturbs the circadian rhythm of T3, T4 and testosterone. Exogenous melatonin has the suppressive effect of diurnal secretion of T3, T4 and testosterone in pinealectomized rats but stimulates the rhythmical corticosterone secretion.     

Body development and puberty in spontaneously hypertensive rats

The body growth and the onset of puberty in spontaneously hypertensive rats (SHR) and in normotensive controls (WKY) have been studied. In female rats the onset of puberty was determined by both the age and the body weight at which the vaginal opening and first estrus appeared, as well as the ability of estradiol and progesterone to induce pituitary LH release. For this purpose females were injected with estradiol benzoate (0.1 mg/kg) and progesterone (1 mg/rat). Control animals received only oil vehicle. In male rats, puberty was assessed by studying the age and body weight at the time of balano-preputial separation. In another experiment, SH and WKY rats were decapitated on day 30 to determine FSH, LH, PRL, GH and testosterone plasma levels in males and FSH and LH in females. The results obtained show: a) A greater body weight, at all the ages studied (every 4 days between days 28 and 92) in SHR animals. b) A delay in vaginal opening and first estrus presentation in SHR females. c) Absence of spontaneous LH peaks in WKY females. d) Advancement in balano-preputial separation in SHR males and e) Higher plasma FSH levels in SHR males than in WKY males, without differences in other hormones.     

Comparative Studies on the Orcadian Rhythm of Corticosterone Lipid and Cholesterol Levels in Adrenals and Blood of Rats

The time-dependent relationship of corticosterone, lipids and cholesterol over a 48-hr period was studied in the adrenals and blood of rats. In addition an attempt was made to determine whether there was a reciprocal dependence among these compounds and also a correlation between corticosterone and cholesterol in the adrenals and blood.

Corticosterone and cholesterol exhibit a circadian rhythm in the adrenals and blood. The same is true for lipids in the serum. A reciprocal dependence between the compounds in the adrenals and blood could not be demonstrated. Only the time-dependent processes of the corticosterone content in the adrenals and plasma are well correlated with each other. High levels of these steroids in the adrenals are associated with high levels of these steroids in the plasma and vice versa.

An inverse correlation between corticosterone and cholesterol exists in the adrenals and in blood. Maximal levels of corticosterone correspond to minimal levels of cholesterol and vice versa.     

Temporal Synergism of Corticosterone and Prolactin in the Syrian Hamster, Mesocricetus auratus

To augment the limited work reported in the literature regarding testing of the hormonal temporal synergism hypothesis in Syrian hamsters (Joseph MM, Meier AH. Proc Soc Exp Biol Med. 1974;146:1150-5), a large experiment with female hamsters was conducted. Forty-eight received corticosterone at 18:00 h on January 21, 23, 25, 27, and 29 and ovine prolactin at one of six times of day beginning January 22 for 8 days; 36 received saline (at 18:00) and prolactin at one of the six times of day for 8 days; 35 received only prolactin at one of the six times of day for 8 days; and 16 received no injections. Twelve hamsters receiving corticosterone and prolactin and eight uninjected hamsters were on running wheels. The corticosterone and prolactin group not on wheels had a body weight gain and no circadian rhythm of weight gain, but did have circadian rhythms of response in organ weight, per 100 g of body weight, and in weights of fat pads and uteri. The corticosterone and prolactin group with access to running wheels gained in body weight and had larger ovaries and smaller fat pads. Hamsters receiving saline and prolactin had a body weight gain, but had no circadian rhythms of response in organ weights. The hamsters receiving only prolactin gained in body weight but had no rhythms of response, except for unexpected circadian rhythms in body weight gain and weights of fat pads. The uninjected hamsters had a modest weight gain. Most or all hamsters with access to running wheels freeran, and the corticosterone injections did not appear to synchronize the locomotor activity rhythms. In conclusion, corticosterone does interact with the injection time effect of prolactin on weights of fat pads, paired ovaries, and uteri. The mechanism of that effect, in terms of circadian rhythm theory, is unclear.