Are the kidneys involved in the removal of endogenous pyrogens in the rabbit?
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To study the influence of different blood glucose (BG) concentrations on the release of pituitary hormones, the effect of the simultaneous iv administration of LRH (200 micrograms), TRH (400 micrograms), and arginine (30 g/30 min) upon the serum concentrations of LH, FSH, TSH, PRL, and GH was determined in six male insulin-dependent diabetics. BG concentration was clamped by feedback control and an automated glucose-controlled insulin infusion system at euglycemic (BG 4-5 mmol/liter) or hyperglycemic (BG, 14-18 mmol/liter) levels. Increments in serum concentrations of LH, FSH, TSH, and PRL were similar in the euglycemic and hyperglycemic steady states, whereas the GH response to arginine was suppressed during the hyperglycemic clamp (P less than 0.01). Omission of exogenous insulin during hyperglycemia did not modify the observed hormonal responses. Thus, the release of LH, FSH, TSH, and PRL in response to adequate acute stimuli at the pituitary level is not modulated by hyperglycemia in insulin-dependent diabetes, while arginine-induced GH release is suppressed. Since the effect of arginine on GH is most likely mediated by an action on the hypothalamus, the data suggest that elevated glucose concentrations may exert their modulatory influence on GH secretion at the hypothalamic rather than at the pituitary level.
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Corticosterone (CORT) and other glucocorticoids cause peripheral insulin resistance and compensatory increases in β-cell mass. A prolonged high-fat diet (HFD) induces insulin resistance and impairs β-cell insulin secretion. This study examined islet adaptive capacity in rats treated with CORT and a HFD. Male Sprague-Dawley rats (age ∼6 weeks) were given exogenous CORT (400 mg/rat) or wax (placebo) implants and placed on a HFD (60% calories from fat) or standard diet (SD) for 2 weeks (N = 10 per group). CORT-HFD rats developed fasting hyperglycemia (>11 mM) and hyperinsulinemia (∼5-fold higher than controls) and were 15-fold more insulin resistant than placebo-SD rats by the end of ∼2 weeks (Homeostatic Model Assessment for Insulin Resistance [HOMA-IR] levels, 15.08 ± 1.64 vs 1.0 ± 0.12, P < .05). Pancreatic β-cell function, as measured by HOMA-β, was lower in the CORT-HFD group as compared to the CORT-SD group (1.64 ± 0.22 vs 3.72 ± 0.64, P < .001) as well as acute insulin response (0.25 ± 0.22 vs 1.68 ± 0.41, P < .05). Moreover, β- and α-cell mass were 2.6- and 1.6-fold higher, respectively, in CORT-HFD animals compared to controls (both P < .05). CORT treatment increased p-protein kinase C-α content in SD but not HFD-fed rats, suggesting that a HFD may lower insulin secretory capacity via impaired glucose sensing. Isolated islets from CORT-HFD animals secreted more insulin in both low and high glucose conditions; however, total insulin content was relatively depleted after glucose challenge. Thus, CORT and HFD, synergistically not independently, act to promote severe insulin resistance, which overwhelms islet adaptive capacity, thereby resulting in overt hyperglycemia.
Hyperinsulinemia
Corticosterone
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The effect of 48 h of fasting in C57B1/6J-ob/ob and +/+ mice on body weight (BW), blood glucose (BG), serum immunreactive insulin (IRI), plasma immunoreactive glucagon (IRG) and on tissue levels of cyclic adenosine monophosphate (cAMP) were studied. Both groups of mice lost weight and demonstrated a decrease in BG and IRI with fasting. However, the BG and IRI of the ob/ob animals were initially highter and remained higher than those of the 2% of their initial weight while the +/+ lost 14 %. The +/+ mice exhibited an increase in cAMP levels in skeletal muscle, fat and liver with fasting, while the ob/ob mice had increased levels of cAMP in fat, but not in muscle. They also had a paradoxical decrease in liver cAMP levels with fasting, and associated with this was the lack of stimulation of glycogenolysis. Glycogenolysis was significant in the livers of fasted +/+ mice. The plasma IRG levels of the fed ob/ob mice were significantly higher (1.8) times) than those of the fed +/+ mice. Islet cAMP levels were decreased with fasting in ob/ob mice. However, the levels were significantly higher in 48-h faster ob/ob mice compared to the fasted +/+ group. The apparent paradoxical response to fasting observed in the livers of the ob/ob mice remains unexplained.
Glycogenolysis
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Diabetes mellitus is frequently associated with reduced levels of TSH, PRL, GH, and gonadotropins. In this study we have wanted to determine whether chemically induced diabetes mellitus is associated with a decreased hypothalamic release of TRH. Male rats were made diabetic with streptozotocin (STZ; 65 mg/kg), whereas controls received vehicle. After 2 weeks, STZ diabetic rats had 25% lower body weights, 3.5-fold higher blood glucose, and 40-60% lower plasma TSH, T3, and T4 levels than controls. The plasma T4 dialyzable fraction had increased 2.5-fold in STZ diabetic rats, and the plasma free T4 concentration was similar to that in controls. Thus, treatment with STZ results in decreased plasma TSH and T4 levels, but does not reduce free T4 concentrations. The content of TRH in hypothalami of 2-week STZ diabetic rats was similar to that in controls, but in vitro these hypothalami released less TRH than those of control rats. In 2-week STZ diabetic rats, TRH in hypophysial stalk blood was 30% lower than that in control rats. The in vitro TRH secretion from hypothalami of untreated rats was dependent on the glucose concentrations in the incubation medium; increasing the glucose concentration from 10 to 30 mM did not alter TRH secretion, but basal TRH release increased in the absence of glucose. In conclusion, STZ-induced diabetes in the rat is associated with reduced hypothalamic secretion of TRH, which, in turn, may be responsible for the reduced plasma TSH and thyroid hormone levels. Furthermore, it is suggested that the inhibitory effect of STZ-induced diabetes on TRH secretion is probably not due to hyperglycemia.
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Hypothalamic–pituitary–thyroid axis
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Abstract Dysregulation of the adipoinsular axis in male obese Zucker diabetic fatty (ZDF; fa/fa) rats, a model of type 2 diabetes, results in chronic hyperinsulinemia and increased de novo lipogenesis in islets, leading to β-cell failure and diabetes. Diazoxide (DZ; 150 mg/kg·d), an inhibitor of insulin secretion, was administered to prediabetic ZDF animals for 8 wk as a strategy for prevention of diabetes. DZ reduced food intake (P < 0.02) and rate of weight gain only in ZDF rats (P < 0.01). Plasma insulin response to glucose load was attenuated in DZ-Zucker lean rats (ZL; P < 0.01), whereas DZ-ZDF had higher insulin response to glucose than controls (P < 0.001). DZ improved hemoglobin A1c (P < 0.001) and glucose tolerance in ZDF (P < 0.001), but deteriorated hemoglobin A1c in ZL rats (P < 0.02) despite normal tolerance in the fasted state. DZ lowered plasma leptin (P < 0.001), free fatty acid, and triglyceride (P < 0.001) levels, but increased adiponectin levels (P < 0.02) only in ZDF rats. DZ enhanced β3-adrenoreceptor mRNA (P < 0.005) and adenylate cyclase activity (P < 0.01) in adipose tissue from ZDF rats only, whereas it enhanced islet β3- adrenergic receptor mRNA (P < 0.005) but paradoxically decreased islet adenylate cyclase activity (P < 0.005) in these animals. Islet fatty acid synthase mRNA (P < 0.03), acyl coenzyme A carboxylase mRNA (P < 0.01), uncoupling protein-2 mRNA (P < 0.01), and triglyceride content (P < 0.005) were only decreased in DZ-ZDF rats, whereas islet insulin mRNA and insulin content were increased in DZ-ZDF (P < 0.01) and DZ-ZL rats (P < 0.03). DZ-induced β-cell rest improved the lipid profile, enhanced the metabolic efficiency of insulin, and prevented β-cell dysfunction and diabetes in diabetes-prone animals. This therapeutic strategy may be beneficial in preventing β-cell failure and progression to diabetes in humans.
Hyperinsulinemia
Lipogenesis
Diazoxide
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Ghrelin, an endogenous ligand for the growth hormone (GH) secretagogue receptor, was originally purified from the rat stomach. We have previously reported that central administration of ghrelin increases food intake and body weight. To investigate the role of ghrelin in the hyperphagic response to uncontrolled diabetes, adult male rats were studied 14 days after administration of streptozotocin (STZ) or vehicle. STZ-treated diabetic rats were markedly hyperphagic. This hyperphagia was accompanied by hyperglycemia, hypoinsulinemia, and reduced plasma GH levels. Treatment of diabetic rats with insulin reversed these changes. Plasma ghrelin concentrations in untreated diabetic rats were significantly higher than in control rats and were normalized by insulin treatment. The ghrelin gene expression in the stomach was also higher in STZ diabetic rats than in control rats, but this difference was not significant. In contrast, plasma leptin was markedly reduced in STZ diabetic rats. This reduction in plasma leptin levels was reversed by insulin treatment. In addition, hypothalamic NPY mRNA levels were increased in STZ-treated diabetic rats and were reversed by insulin treatment. Furthermore, the hyperphagia was partially reversed by the administration of a ghrelin-receptor antagonist. Therefore, we conclude that the elevated plasma ghrelin levels, along with decreased plasma leptin levels, could contribute to the diabetic hyperphagia in part by increasing hypothalamic NPY. This is the first report to show the pathophysiological significance of ghrelin in diabetes.
Secretagogue
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In normal rats, females have higher circulating GH-binding protein (GHBP) levels than males, whereas in the GH-deficient dwarf (Dw) rat, there is no sexual dimorphism in plasma GHBP, suggesting that GH secretion may be involved in this difference. In order to study the relationship between gonadal steroids and GH on GHBP and GH receptor regulation, the levels of plasma GHBP, hepatic bovine GH, and human GH (hGH) binding as well as GHBP and GH receptor messenger RNA (mRNA) have now been studied in normal, Dw, hypophysectomized (Hx), or ovariectomized (Ovx) rats, subjected to different GH and gonadal steroid exposure. In normal male rats, estradiol (E2, 12.5-25 micrograms/day for 1 or 2 weeks) markedly increased plasma GHBP and hepatic hGH, and bGH binding. These effects of E2 were diminished in Dw rats, absent in Hx rats, but restored in Hx rats given exogenous hGH. Plasma GHBP rose in female rats given E2, and fell in females given the anti-estrogen tamoxifen. Ovx animals had lower plasma GHBP and hepatic GH binding which was reversed by E2, but not testosterone treatment. Continuous hGH infusions in Ovx rats restored hepatic GH binding, and increased plasma GHBP. In Dw males, hGH increased plasma GHBP and hepatic GH binding, whereas testosterone had no effect on GHBP or GH receptors and did not affect their up-regulation by hGH. Hepatic levels of GHBP-, and GH receptor mRNA transcripts showed the same trends in response to steroid or GH treatment, but the differences were rarely significant, except in Ovx animals which had higher GHBP mRNA transcripts after GH or E2 treatment. Thus E2 and GH increase both plasma GHBP and hepatic GH receptor binding. GH up-regulates GHBP in the absence of E2, whereas E2 treatment does not raise GHBP in the absence of GH. Whereas some of the effects of estrogen could be mediated via alterations in GH secretion, estrogen may also directly influence GHBP production at the liver, but only in the presence of GH.
Growth hormone-binding protein
Sexual dimorphism
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GH secretion is markedly blunted in obesity; however, the mechanism(s) mediating this response remains to be elucidated. In the present study we examined the involvement of the two hypothalamic GH-regulatory hormones, GH-releasing factor (GRF) and somatostatin (SRIF), using the genetically obese male Zucker rat. Spontaneous GH, insulin, and glucose secretory profiles obtained from free moving, chronically cannulated rats revealed a marked suppression in amplitude and duration of GH pulses in obese Zucker rats compared to their lean littermates (mean 6-h plasma GH level, 3.9 ± 0.4 us. 21.5 ± 3.8 ng/ml; P < 0.001). Obese rats also exhibited significant hyperinsulinemia in the presence of normoglycemia. The plasma GH response to an iv bolus of 1 ng rat GRF-(1-29) NH2, administered during peak and trough periods of the GH rhythm, was significantly attenuated in obese rats at peak (137.4 ± 26.1 vs. 266.9 ± 40.7 ng/ml; P < 0.02), although not at trough, times. Passive immunization of obese rats with a specific antiserum to SRIF failed to restore the amplitude of GH pulses to normal values; the mean 6-h plasma GH level of obese rats given SRIF antiserum was not significantly different from that of obese rats administered normal sheep serum. Both pituitary wet weight and pituitary GH content and concentration were reduced in the obese group. Measurement of hypothalamic GRF immunoreactivity revealed a significant (P < 0.05) reduction in the mediobasal hypothalamic GRF content in obese rats (503.2 ± 60.1 pg/fragment) compared to that in lean controls (678.1 ± 50.2 pg/fragment), although no significant difference was observed in hypothalamic SRIF concentration. Peripheral SRIF immunoreactive levels were significantly (P < 0.01) elevated in both the pancreas and stomach of obese rats. These results demonstrate that the genetically obese Zucker rat exhibits 1) marked impairment in both spontaneous and GRF-induced GH release, which cannot be reversed by SRIF immunoneutralization, 2) significant reduction in pituitary GH concentration, 3) depressed hypothalamic GRF content, and 4) elevated gastric and pancreatic, but not hypothalamic, SRIF levels. The findings suggest that the defect in pituitary GH secretion observed in the genetically obese Zucker rat is due, at least partially, to insufficient stimulation by hypothalamic GRF, and that SRIF does not play a significant role. (Endocrinology127: 3087–3095, 1990)
Somatropin
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The role of the hypothalamic paraventricular nucleus (PVN) in thyroid hormone regulation of TSH synthesis during hypothyroidism was studied in adult male rats that were normal (n = 10), had primary hypothyroidism with sham lesions in the hypothalamus (n = 17), and had primary hypothyroidism with PVN lesions (n = 14). Two and 4 weeks after initiation of treatment, plasma levels of thyroid hormones (TSH, corticosterone and PRL) and pituitary content of TSH beta and alpha-subunit mRNA were measured. TRH mRNA levels in the PVN were determined by in situ hybridization histochemistry. At 2 weeks, despite a decrease in plasma free T4 in both hypothyroid groups, plasma TSH levels increased, but to a lesser degree, in the hypothyroid PVN lesioned compared to hypothyroid sham-lesioned group (7.8 +/- 1.3 vs. 20.5 +/- 1.1 ng/dl; P less than 0.05). Similarly, at 4 weeks, the hypothyroid PVN-lesioned group demonstrated a blunted TSH response compared to the hypothyroid sham-lesioned group (6.8 +/- 0.7 vs. 24.0 +/- 1.3 ng/dl; P less than 0.05). Plasma corticosterone and PRL did not significantly differ between sham-lesioned and PVN-lesioned groups. TSH beta mRNA levels markedly increased in hypothyroid sham-lesioned rats compared to those in euthyroid controls at 2 weeks (476 +/- 21% vs. 100 +/- 39%; P less than 0.05) and 4 weeks (1680 +/- 270% vs. 100 +/- 35%; P less than 0.05). In contrast, TSH beta mRNA levels did not increase with hypothyroidism in the PVN-lesioned group compared to those in euthyroid controls at 2 weeks (140 +/- 16%, P = NS) and only partially increased at 4 weeks (507 +/- 135; P less than 0.05). alpha mRNA levels at 4 weeks markedly increased in hypothyroid sham-lesioned rats compared to those in euthyroid controls (1121 +/- 226% vs. 100 +/- 48%; P less than 0.05), but did not increase in the hypothyroid PVN-lesioned rats (61 +/- 15%; P = NS). TRH mRNA in the PVN increased in the hypothyroid sham-lesioned rats compared to those in euthyroid controls (16.6 +/- 1.3 vs. 4.8 +/- 1.2 arbitrary densitometric units; P less than 0.05), and TRH mRNA was not detectable in the PVN of hypothyroid-lesioned rats at 2 weeks. In summary, lesions in rat PVN prevented the full increase in plasma TSH, pituitary TSH beta mRNA, and alpha mRNA levels in response to hypothyroidism. Thus, factors in the PVN are important in thyroid hormone feedback regulation of both TSH synthesis and secretion.
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Diabetes mellitus is frequently associated with reduced levels of TSH, PRL, GH, and gonadotropins. In this study we have wanted to determine whether chemically induced diabetes mellitus is associated with a decreased hypothalamic release of TRH. Male rats were made diabetic with streptozotocin (STZ; 65 mg/kg), whereas controls received vehicle. After 2 weeks, STZ diabetic rats had 25% lower body weights, 3.5-fold higher blood glucose, and 40-60% lower plasma TSH, T3, and T4 levels than controls. The plasma T4 dialyzable fraction had increased 2.5-fold in STZ diabetic rats, and the plasma free T4 concentration was similar to that in controls. Thus, treatment with STZ results in decreased plasma TSH and T4 levels, but does not reduce free T4 concentrations. The content of TRH in hypothalami of 2-week STZ diabetic rats was similar to that in controls, but in vitro these hypothalami released less TRH than those of control rats. In 2-week STZ diabetic rats, TRH in hypophysial stalk blood was 30% lower than that in control rats. The in vitro TRH secretion from hypothalami of untreated rats was dependent on the glucose concentrations in the incubation medium; increasing the glucose concentration from 10 to 30 mM did not alter TRH secretion, but basal TRH release increased in the absence of glucose. In conclusion, STZ-induced diabetes in the rat is associated with reduced hypothalamic secretion of TRH, which, in turn, may be responsible for the reduced plasma TSH and thyroid hormone levels. Furthermore, it is suggested that the inhibitory effect of STZ-induced diabetes on TRH secretion is probably not due to hyperglycemia.
Basal (medicine)
Hypothalamic–pituitary–thyroid axis
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