Abnormalities of the thyroid hormone negative feedback regulation of TSH secretion in spontaneously hypertensive rats.

Spontaneously hypertensive rats (SHR) are characterized by several neuroendocrine abnormalities including a chronic hypersecretion of thyrotropin (TSH) of unknown etiology. We hypothesized that the inappropriately high TSH secretion in SHR may be the result of an impaired thyroid hormone negative feedback regulation of hypothalamic thyrotropin-releasing hormone (TRH) and/or pituitary TSH production. To test this hypothesis, SHR or their normotensive Wistar-Kyoto (WKY) controls were treated with either methimazole (0.02% in drinking water) to induce hypothyroidism or administered L-thyroxine (T4) at a dose of 0.8 or 2.0 micrograms/100 g body weight/day to induce hyperthyroidism. All treatments were continued for 14 days after which animals were killed under low stress conditions. TSH concentrations in plasma and anterior pituitary tissue were 2-fold higher (P less than 0.01) in euthyroid SHR compared to WKY control rats while thyroid hormone (T3 and T4) levels were in the normal range. Hypothyroidism induced by either methimazole or thyroidectomy caused a significant (P less than 0.01) rise of plasma TSH levels in both WKY and SHR rats. However, relative to the TSH concentrations in control animals, the increase of plasma TSH in SHR was significantly blunted (P less than 0.01) in comparison to the WKY group. Hypothyroidism caused a significant depletion of TRH in stalk-median eminence (SME) tissue in both groups of rats. However, no differences between SHR and WKY rats were observed. The administration of thyroid hormone caused a dose dependent suppression of plasma TSH levels in both strains of rats. However, at both doses tested plasma TSH concentrations in SHR rats were significantly less suppressed (P less than 0.05) than those in WKY animals. Under in vitro conditions basal and potassium induced TRH release from SMEs derived from SHR was significantly (P less than 0.05) higher than that from WKY rats, whether expressed in absolute terms or as percent of content. These findings suggest that the thyroid hormone negative feedback regulation of TSH secretion may be impaired in SHR rats. Our data do not allow conclusions as to whether defects in the regulation of TSH production are located exclusively at the hypothalamic level. Since the overproduction of hypothalamic TRH and hypophysial TSH should lead to an increased thyroid hormone biosynthesis other defects in the hypothalamus-pituitary-thyroid-axis may contribute to the abnormal regulation of TSH secretion in SHR rats.     

Plasma norepinephrine and dopamine-β-hydroxylase in genetic hypertensive rats

The relationship between blood pressure, plasma norepinephrine (NE), dopamine-β-hydroxylase (DBH) activity and age was investigated in spontaneously hypertensive rat (SHR), a stroke-prone substrain of the SHR and control Wistar-Kyoto rat (WKR). Blood pressure of both SHR strains increased with age and was significantly higher than that of the WKR at all ages tested (3 15 weeks). The blood pressure of stroke-prone SHR was significantly higher than that of the regular SHR after 6 weeks of age. Plasma DBH activity decreased with age in each strain, although the SHR, and especially the stroke-prone SHR, had significantly higher DBH than the controls at an early age. Plasma NE in the WKR did not change with age. Increased plasma NE was observed only in the young SHRs. The highest values were found in the 6 week old stroke-prone SHR. These data suggest that plasma DBH activity is not correlated directly with plasma NE or blood pressure, but that increased sympathetic nerve activity may occur during the development of hypertension in the SHR and the stroke-prone SHR.     

Potentiation by indomethacin of TRH-induced TSH secretion in the rat.

We have studied the effect of two inhibitors of prostaglandin synthesis on the basal and TRH-stimulated plasma TSH levels in the rat. Animals were injected sc daily with indomethacin 3 mg/0.5 ml) or aspirin (16--30 mg/0.5 ml) for 3 days. The plasma T4 and T3 were consistently lower in the indomethacin or aspirin groups than in the controls, while the basal TSH levels did not change. Indomethacin treatment significantly potentiated the TSH response to synthetic TRH (20 ng. iv) in intact and thyroidectomized rats. The pituitary TSH content was markedly increased by indomethacin, while hypothalamic TRH content did not change. In contrast, aspirin inhibited the TSH response to TRH in intact rats, when pituitary TSH content decreased significantly. No potentiation by aspirin of TRH-stimulated TSH response in the thyroidectomized rats was observed. The increased sensitivity of plasma TSH response to exogenous TRH in the indomethacin group is presumably due to higher pituitary TSH content than in the controls. The action of indomethacin appears to be mediated, at least in part, at the pituitary level. In addition, there is a dissociation between the action of indomethacin and the action of aspirin in the TSH response to TRH.     

Congenital abnormality of pituitary-thyroid axis in spontaneously hypertensive rats (SHR) and stroke-prone rats (SPR).

In an attempt to study whether TSH abnormality was genetically determined in SHR and SPR, plasma T4, T3, TSH and prolactin concentrations were measured in the animals with intervals of 1 to 3 months. Hypertension was found in 6-month-old SHR and SPR, but it was not found in younger animals. In contrast, a decrease of plasma T3 and an increase of plasma TSH were found in 15-day-old SHR. Also, an increase of TSH was found in 1-month-old SPR in spite of normal plasma T3 concentration. These abnormalities in SHR and SPR increased progressively with age. It is suggested that thyroid-pituitary abnormality was genetically determined in SHR and SPR.     

Thyroid hormone action on ACTH secretion

Thyroid hormone effects on pituitary ACTH have not been well established. Adult male Sprague-Dawley rats were rendered hypo- and hyperthyroid while undergoing treatment with 6-Propylthiouracil (PTU) and L-Thyroxine (T4). At the time of decapitation, plasma values for T4 (micrograms/100 ml) were 3.9 +/- 0.4 in the control, 17.3 +/- 2.2 in the T4 and less than 2 in the PTU treated group; plasma T3 and TSH confirmed hyper- and hypothyroidism in the T4 and PTU treated groups respectively. Plasma immunoassayable ACTH and corticosterone were significantly increased in hyperthyroid and decreased in the PTU treated animals. Pituitaries were removed and incubated in DMEM. After 3 h incubation, ACTH content and secretion to the medium were significantly lower in the PTU group. As expected, pituitary TSH content and secretion were decreased in the T4 treated animals. These data indicate that thyroid hormones influence pituitary-adrenal function by increasing ACTH secretion and consequently corticosterone production.     

Increase of thyrotropin response to thyrotropin-releasing hormone (TRH) and TRH release in rats during pregnancy

Regulation of thyrotropin (TSH) release by thyrotropin releasing hormone (TRH) in the anterior pituitary gland (AP) of pregnant rats was studied. The pregnant (day 7, 14, and 21) and diestrous rats were decapitated. AP was divided into 2 halves, and then incubated with Locke's solution at 37 degrees C for 30 min following a preincubation. After replacing with media, APs were incubated with Locke's solution containing 0, or 10 nM TRH for 30 min. Both basal and TRH-stimulated media were collected at the end of incubation. Medial basal hypothalamus (MBH) was incubated with Locke's medium at 37 degrees C for 30 min. Concentrations of TSH in medium and plasma samples as well as the cyclic 3':5' adenosine monophosphate (cAMP) content in APs and the levels of TRH in MBH medium were measured by radioimmunoassay. The levels of plasma TSH were higher in pregnant rats of day 21 than in diestrous rats. The spontaneous release of TSH in vitro was unaltered by pregnancy. TRH increased the release of TSH by AP, which was higher in pregnant than in diestrous rats. Maternal serum concentration of total T3 was decreased during the pregnancy. The basal release of hypothalamic TRH in vitro was greater in late pregnant rats than in diestrous rats. After TRH stimulation, the increase of the content of pituitary cAMP was greater in late pregnant rats than in diestrus animals. These results suggest that the greater secretion of TSH in pregnant rats is in part due to an increase of spontaneous release of TRH by MBH and a decrease of plasma thyroid hormones. Moreover, the higher level of plasma TSH in rats during late pregnancy is associated with the greater response of pituitary cAMP and TSH to TRH.     

Adaptation of male and female rats to iodine deficiency

The response of the hypothalamic pituitary axis to chronic iodine deficiency was compared in male and female Sprague-Dawley rats. The animals were kept on a low iodine diet for 12 weeks. Blood samples as well as thyroid and pituitary weights were obtained every two weeks. Baseline values of thyroid weight and serum thyroxine (T4) were similar in both sexes. However, females had lower serum TSH and higher serum triiodothyronine (T3), pituitary weight and pituitary TSH content. After initiation of the low iodine diet, both sexes showed similar decreases in serum T4 and similar increases of serum TSH and thyroid weight. Serum T3, pituitary weight and TSH content remained higher in females throughout the study. Pituitary TSH was directly correlated with serum TSH in both sexes. When adjusted for pituitary TSH and analyzed by a stepwise regression analysis, serum TSH was lower in females suggesting a difference in TSH secretion between males and females. Our studies demonstrate significant sex differences in the regulation of TSH secretion and maintenance of serum T3 level in response to a chronic stimulus.     

Are cadmium effects on plasma gonadotropins, prolactin, ACTH, GH and TSH levels, dose-dependent?

It is well established that cadmium affects plasma levels of the pituitary hormones studied. However, whether the effects of the metal are dose dependent needs to be clarify. This work was designed to evaluate the possible changes in plasma levels of gonadotropins, prolactin, ACTH, GH and TSH after oral cadmium exposure in adult male rats. Plasma levels of these hormones were measured in adult male rats exposed to cadmium chloride (CdCl₂) in the drinking water at the doses of 5, 10, 25, 50 or 100 ppm for one month. The lower dose of cadmium increased plasma prolactin levels and higher doses of the metal (25 or 50 ppm) decreased them. There was a continuous increase of plasma ACTH levels from the lower to 25 ppm dose of CdCl₂ and decreased them after to basal values with the highest dose. Plasma GH levels were increased with the dose of cadmium of 10 ppm, although the doses of 5, 25 and 50 ppm decreased them. Plasma LH levels were only reduced with the dose of 50 ppm of CdCl₂, whereas those of FSH increased. Plasma TSH levels were increased with the doses of 5, 25 and 100 ppm of CdCl₂. Cadmium concentration increased in pituitary with the doses of 125, 50 and 100 ppm of CdCl₂. These data suggest that cadmium differentially affects the secretory mechanisms of the pituitary hormones studied depending on the dose used. The effects of the metal on prolactin and ACTH are dose-dependent.     

Erythrocyte carbonic anhydrase I concentration in patients receiving thyroxine.

We recently reported that the red blood cell (RBC) carbonic anhydrase I (CAI) concentration in patients with hyperthyroidism is reduced and reflects the patient's mean thyroid hormone level over the preceding months. In this study, RBC CAI concentrations were measured in patients with thyroid nodules who were receiving suppressive doses of thyroxine (group I) and compared with those obtained in patients with primary hypothyroidism receiving replacement doses of thyroxine (group 2). Of the 17 patients in group 1, 16 (94%) had elevated plasma free T4 levels, but all 17 had normal free T3 levels. Of the 17 patients in group 2, 16 (94%) had normal free T4 levels and all 17 had normal free T3 levels. Plasma TSH concentrations in group 1 were all below the lower limit of sensitivity of 0.04 mU/l. In group 2, 11 had normal and 6 had slightly elevated plasma TSH concentrations. The mean (+/- SD) RBC CAI concentration in group 1 (300 +/- 53 nmol/g Hb) was significantly lower than that in group 2 (340 +/- 57 nmol/g Hb). The RBC CAI concentration was significantly correlated with both the concentration of plasma free T4 and free T3. These observations indicate that in patients receiving suppressive doses of thyroxine a slight increase in the plasma free T4 concentration produces a slight but significant decrease in RBC CAI levels.     

The pituitary-thyroid axis in patients with pituitary disorders

The pituitary-thyroid axis of 12 patients, exposed to transsphenoidal pituitary microsurgery because of nonfunctioning adenomas (6), prolactinomas (3) and craniopharyngioma (1), or to major pituitary injury (1 apoplexy, 1 accidental injury), was controlled more than 6 months following the incidents. The patients did not receive thyroid replacement therapy and were evaluated by measurement of the serum concentration of thyroxine (T4), 3,5,3'-triiodothyronine (T3), 3,3',5'-triiodothyronine (rT3), T3-resin uptake test and thyrotropin (TSH, IRMA method) before and after 200 micrograms thyrotropin releasing hormone (TRH) iv. The examination also included measurement of prolactin (PRL) and cortisol (C) in serum. Apart from 1 patient with pituitary apoplexy all had normal basal TSH levels and 9 showed a significant TSH response to TRH. Compared to 40 normal control subjects the 12 patients had significantly decreased levels of T4, T3 and rT3 (expressed in free indices), while the TSH levels showed no change. Five of the patients, studied before and following surgery, had all decreased and subnormal FT4I (free T4 index) after surgery, but unchanged FT3I and TSH. The levels of FT4I were positively correlated to both those of FT3I and FrT3I, but not to TSH. The TSH and thyroid hormone values showed no relationship to the levels of PRL or C of the patients exposed to surgery. It is concluded that the risk of hypothyroidism in patients exposed to pituitary microsurgery is not appearing from the TSH response to TRH, but from the thyroid hormone levels.     

Assessment of the relationship between serum thyroid hormone levels and peripheral metabolism in patients with anorexia nervosa

It has been observed that basal and/or TRH-stimulated serum TSH levels occasionally conflict with the actual values of circulating thyroid hormones in patients with anorexia nervosa. In the present study sixteen female patients with anorexia nervosa during self-induced starvation displayed clinical findings suggesting hypothyroidism, e.g., cold intolerance, constipation, bradycardia, hypothermia and hypercholesterolemia in association with decreased serum total T3 (62.8 +/- 5.2 ng/dl) and T4 (6.6 +/- 0.3 micrograms/dl). Markedly decreased T3 correlated positively with average heart rate (r = 0.5655, P less than 0.025) and negatively with total cholesterol (r = -0.7413, P less than 0.005). This result may suggest that peripheral metabolic state of the underweight anorexics depends considerably upon the serum T3 concentration. Despite decreased total thyroid hormones, free T4 assayed by radioimmunoassay was normal in all five cases examined (1.4 +/- 0.2 ng/dl) and the free T4 index in fifteen cases was normal except in one case. Basal TSH was not increased and TSH response to exogenous TRH was not exaggerated in any. These results may be compatible with a theory that free T4 has a dominant influence on pituitary TSH secretion. Furthermore, glucocorticoids may also have some influence on depressed TSH response, because an inverse correlation between increased plasma cortisol and the sum of net TSH increase after TRH was observed in twelve cases examined. In conclusion, it is suggested that normal sensitivity of peripheral tissues and pituitary thyrotroph to different circulating thyroid hormones is maintained in anorexia nervosa patients even during severe self-induced starvation, and that the metabolic state in these patients is considerably under the influence of circulating T3.     

Delayed equilibrium of pituitary triiodothyronine (T3) following an acute T3 administration.

To reconcile the knowledge on tissue T3 concentration with cellular metabolism regulatory mechanism of thyroid hormone secretion, the pattern of the change of tissue T3 concentration following an acute administration of T3 was studied in mice. Basal T3 concentration in serum, liver, brain and pituitary was 61, 173, 198 and 1630ng/100g, respectively. After 0.5 mug T3 dose, T3 concentration in serum and liver reached the maximum level 1 to 3 hrs following the administration and decreased exponetially thereafter, thus, maintaining almost constant tissue/plasma T3 ratio. In contrast, T3 increase in brain or pituitary was far delayed, not until 7 to 12 hrs following T3 injection, and then decreased parallel to that in serum. Furthermore, the magnitude of increase in pituitary T3 was limited when compared to that in liver. Thus, tissue/plasma T3 ratio in pituitary decreased markedly after the dose of T3. This finding suggests the possibility that there is blood-brain barrier or blood-tissue barrier for the transport of T3 in pituitary or brain, resulting in delayed equilibrium with that in serum. These results may also explain the delay of inhibition of TRH-induced TSH release after single dose of T3 as recently reported by Azizi et al. (1975).     

Influence of type II 5′ deiodinase on TSH content in diabetic rats

The influence of hypothalamic and pituitary type II 5′ deiodinase (5′D-II) activities and T3 content on pituitary TSH content was investigated in streptozotocin (STZ)-induced diabetic rats (D). The results show, first, that hypothalamic and pituitary 5′D-II activities were lower in neonatal D rats versus control (C) rats, and the normal developmental pattern was altered. Secondly, when D and C rats were thyroidectomized (Tx) at 25 days of age (D+Tx, C+Tx), pituitary and hypothalamic 5′D-II activities increased ten days later in both populationsvs. intact rats, but the percentage of increase was smaller in D+Tx than in C+Tx. The hypothalamic T3 to T4 ratios were also decreased in D+Tx animals (0.38) as compared to C+Tx rats (1.64). The hypothalamic T3 content was reduced by 30% in D as compared to C rats and by 80% in D+Tx as compared to C+Tx rats, showing a defect in hypothalamic T4 deiodination. Pituitary TSH content increased after Tx in D+Tx, but not in C+Tx. These results in diabetic rats indicate that the hypothalamic and pituitary 5′D-II activity and hypothalamic T3 content are affected by diabetes and play a role in the regulation of pituitary TSH content.     

Substrain Differences, Gender, and Age of Spontaneously Hypertensive Rats Critically Determine Infarct Size Produced by Distal Middle Cerebral Artery Occlusion

1. The present work discussed the effects of substrain or genetic differences, gender, and age of the rat on infarct size produced by distal middle cerebral artery occlusion (MCAO) in spontaneously hypertensive rats (SHR). 2. In SHR/Kyushu, infarct volume was significantly larger than that of SHR/Izm, while blood pressure levels were essentially the same between the two substrains. Although SHR-SP/Izm had a higher blood pressure than SHR/Kyushu, infarct volumes were the same between SHR/Kyushu and SHR-SP/Izm. These results suggest the presence of blood pressure-independent factors which affect the infarct size after MCAO. 3. Estrogen accounted the large part of greater tolerability against focal brain ischemic injury in female compared with male SHR. 4. We found age-related vulnerability to focal cerebral ischemia in female SHR. This age-related vulnerability in aged female SHR was unrelated to the blood levels of sex hormones such as estrogens and progesterone. 5. Finally, we emphasized the importance of reproducible and least invasive focal ischemia models in stroke research.     

Increased pituitary thyroxine 5'-deiodinase activity in adult rats rendered hyper- or hypo-thyroid during perinatal life

Perinatal thyroid dysfunction in the rat leads to permanent alterations in pituitary TSH secretion in the adult animal. Thus, neonatal hyperthyroidism (NH) and perinatal hypothyroidism (PH) both result in apparent increased pituitary sensitivity to the feedback effects of thyroid hormones in the adult rat. To determine if increased intrapituitary generation of triiodothyronine (T3) might account for these observations, we measured thyroxine (T4) 5'-deiodinase activity in pituitary homogenates of adult NH and PH rats. NH was induced by injecting neonatal rats with 12 daily sc injections of T4 (0.4 microgram/g body weight (BW]. Control rats received vehicle alone. PH was induced by administering 0.05% 6-n-propylthiouracil in the drinking water to pregnant dams from the 16th day of gestation through the 12th day postpartum. Thereafter, a normal water supply was substituted. NH and PH rats were allowed to mature and were sacrificed at 105 days of age. Serum T4, T3, and TSH concentrations were measured by radioimmunoassay. Pituitary T4 5'-deiodinase activity was assessed by the measurement of T3 formation by pituitary homogenates incubated in the presence of 0.65 microM T4 and 100 mM dithiothreitol at 37 degrees C for 90 min. Body weights of adult NH and PH rats were slightly but not significantly decreased compared with control rats. Relative pituitary gland weight (milligrams per 100 g BW) was significantly decreased in adult PH rats (P less than 0.005) but not in adult NH rats. In adult NH rats, serum T4 and T3 concentrations were significantly decreased (P less than 0.01) compared with control rats. Serum TSH concentrations were similar.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nociceptin stimulates thyrotropin secretion in rats

Effects of nociceptin on thyrotropin (TSH) and thyrotropin-releasing hormone (TRH) secretion in rats were studied. Nociceptin (150 microgram/kg) was injected intravenously and rats were serially decapitated after the injection. The effects of nociceptin on TRH release from the hypothalamus and TSH release from the anterior pituitary in vitro were also investigated. TRH and thyroid hormones were measured by individual radioimmunoassays. TSH was determined by enzyme immunoassay. TRH contents in the hypothalamus decreased significantly after nociceptin injection, whereas plasma TRH concentrations showed no changes. Plasma TSH concentrations increased significantly in a dose-related manner. The TRH release from the hypothalamus was enhanced significantly in a dose-related manner with the addition of nociceptin. The TSH release from the anterior pituitary in vitro was not affected by the addition of nociceptin. The plasma thyroxine and 3,3',5-triiodothyronine levels did not change significantly after nociceptin administration. The inactivation of TRH by plasma or hypothalamus in vitro after nociceptin injection did not differ from that of controls. The findings suggest that nociceptin acts on the hypothalamus to stimulate TRH and TSH secretion.     

Sex differences in adrenocortical structure and function. XXVIII. ACTH and corticosterone in intact, gonadectomised and gonadal hormone replaced rats

Plasma ACTH and corticosterone (B) concentration, ACTH content in the anterior pituitary gland and B content in the adrenals were measured in intact, gonadectomised and testosterone or estradiol replaced rats. Plasma ACTH and B levels and adrenal B content were higher in female than male rats. Neither orchiectomy nor testosterone replacement had an effect on plasma ACTH and B concentration. Orchiectomy did not affect adrenal B content and decreased pituitary ACTH while testosterone significantly lowered ACTH and B content in studied glands. On the other hand ovariectomy did not change pituitary ACTH and adrenal B content and notably lowered concentrations of these hormones in the blood. Estradiol replacement resulted in an increase in plasma ACTH and B concentrations, an effect accompanied by a marked drop in pituitary ACTH and an increase in adrenal B. These findings indicate the distinct sex differences in basal plasma ACTH and B concentrations with higher values in female rats, an effect dependent on the stimulatory action of estradiol on pituitary-adrenocortical axis.     

Seasonal characteristics of the effect of melatonin on thyroid function

Changes in pituitary-thyroid axis sensitivity to bioactive component of pineal gland, melatonin, have been detected. In winter (short days) melatonin (100 micrograms/100 g of rat body weight) decreased T3 T4, TSH content and 131I uptake by thyroid tissue. However, it was noted that in summer (long photoperiod) the same injection caused suppression of T3 plasma level and 131I uptake ability of the thyroid gland, with T4 and TSH blood levels remaining significantly increased.     

Effect of chronic metoclopramide therapy on serum pituitary hormone concentrations

The effect of chronic (3--9 months) therapy with metoclopramide on serum levels of pituitary and thyroid hormones was studied in 4 males and 1 female. The mean serum prolactin concentration during metoclopramide therapy was significantly higher than after discontinuation of metoclopramide. Serum prolactin concentrations increased acutely after each dose of metoclopramide. Serum prolactin concentrations increased acutely after each dose of metoclopramide, and gradually returned to normal by 6--12 h. There was no sifgnificant differences in the serum TSH, T3, T4, GH, and gonadotrophin levels during and after metoclopramide administration. In the male subjects the mean serum testosterone was normal, but significantly lower during metoclopramide therapy.