Thyrotropin-releasing hormone stimulates growth hormone release from the anterior pituitary of hypothyroid rats in vitro

We have examined the interaction of thyroid hormone and TRH on GH release from rat pituitary monolayer cultures and perifused rat pituitary fragments. TRH (10(-9) and 10(-8)M) consistently stimulated the release of TSH and PRL, but not GH, in pituitary cell cultures of euthyroid male rats. Basal and TRH-stimulated TSH secretion were significantly increased in cells from thyroidectomized rats cultured in medium supplemented with hypothyroid serum, and a dose-related stimulation of GH release by 10(-9)-10(-8) M TRH was observed. The minimum duration of hypothyroidism required to demonstrate the onset of this GH stimulatory effect of TRH was 4 weeks, a period significantly longer than that required to cause intracellular GH depletion, decreased basal secretion of GH, elevated serum TSH, or increased basal secretion of TSH by cultured cells. In vivo T4 replacement of hypothyroid rats (20 micrograms/kg, ip, daily for 4 days) restored serum TSH, intracellular GH, and basal secretion of GH and TSH to normal levels, but suppressed only slightly the stimulatory effect of TRH on GH release. The GH response to TRH was maintained for up to 10 days of T4 replacement. In vitro addition of T3 (10(-6) M) during the 4-day primary culture period significantly stimulated basal GH release, but did not affect the GH response to TRH. A GH stimulatory effect of TRH was also demonstrated in cultured adenohypophyseal cells from rats rendered hypothyroid by oral administration of methimazole for 6 weeks. TRH stimulated GH secretion in perifused [3H]leucine-prelabeled anterior pituitary fragments from euthyroid rats. A 15-min pulse of 10(-8) M TRH stimulated the release of both immunoprecipitable [3H]rat GH and [3H]rat PRL. The GH release response was markedly enhanced in pituitary fragments from hypothyroid rats, and this enhanced response was significantly suppressed by T4 replacement for 4 days. The PRL response to TRH was enhanced to a lesser extent by thyroidectomy and was not affected by T4 replacement. These data suggest the existence of TRH receptors on somatotrophs which are suppressed by normal amounts of thyroid hormones and may provide an explanation for the TRH-stimulated GH secretion observed clinically in primary hypothyroidism.     

The influence of diabetes mellitus on thyrotropin response to thyrotropin-releasing hormone in untreated acromegalic patients

Impairment of thyrotropin (TSH) response to thyrotropin-releasing hormone (TRH) has been documented in patients with uncontrolled diabetes mellitus (DM). In acromegalic patients, however, there have been no data regarding TSH secretion studied taking the existence of DM into consideration. Therefore, we investigated the TSH response to TRH [expressed as TSH increment (delta TSH)] in 14 untreated acromegalic patients, who did not show the suprasellar extension of adenoma, divided into two groups on the basis of either presence or absence of uncontrolled DM, and in 28 normal subjects. The mean max delta TSH was significantly reduced (p less than 0.02) in acromegalic patients despite similar mean serum T4 and free T4 index (FT4l) levels. Furthermore, the mean basal and max delta TSH in 7 patients with DM (FBS, 120-300 mg/dl; HbA1, 8.8-15.2%) were significantly lower than those in 7 patients without DM (p less than 0.05 and p less than 0.02, respectively) despite similar the mean serum T3, T4, FT4l, growth hormone (GH) and prolactin (PRL) levels and sellar volume. In 4 patients with DM the TSH response to TRH 6-8 weeks after insulin therapy, when their HbA1 levels were normal, increased compared to that before insulin therapy. The mean max delta TSH after selective adenomectomy in 8 patients (3 in DM group and 5 in non-DM group), whose fasting basal GH fell to less than 5 ng/ml, was almost identical to that in normal subjects. In conclusion, the present study suggests that the abnormality in TSH secretion in acromegalic patients may be increased by the existence of uncontrolled DM.     

Effect of acute hypercalcemia on thyrotropin (TSH) and triiodothyronine responses to TSH-releasing hormone in man

In chronic hypercalcemia, basal TSH has been found to be low, with normal serum circulating concentrations of T3 and T4. This observation suggested a potentiation by hypercalcemia of the thyroid secretory response to TSH. The present study was undertaken to assess the possible influence of hypercalcemia on the T3 secretory response to TSH. Since T3 secretion was studied after stimulation of endogenous TSH by TRH, it was first necessary to find a protocol enabling us to study the effect of calcium on T3 release without affecting TSH secretion. Eighteen subjects underwent two TRH tests, with and without simultaneous calcium infusion, at 2-week interval and in a randomized order. In group A (five subjects) calcium infusion started 1 min after TRH, in group B (five subjects) 10 min after TRH, and in group C (eight subjects) 20 min after TRH. In groups A and B, TSH secretion was markedly blunted by hypercalcemia. In contrast, when calcium infusion was started 20 min after TRH (group C), the TSH secretion profile was no longer different from that in the control study. However, in this situation the increments of T3 and free T3 120 and 180 min after TRH were significantly higher when the subjects were rendered hypercalcemic than in the control study. These findings suggest that calcium might act at two different levels, to enhance the thyroid secretory response to TSH and decrease TSH secretion by acting directly on the pituitary gland. Both effects would produce the association of low serum TSH and normal levels of T3 and T4 observed in chronic hypercalcemia.     

Pituitary responsiveness to GH-releasing hormone, GH-releasing peptide-2 and thyrotrophin-releasing hormone in critical illness

OBJECTIVE Protein hypercatabolism and preservation of fat depots are hallmarks of critical illness, which is associated with blunted pulsatile GH secretion and low circulating IGF-I, TSH, T4 and T3. Repetitive TRH administration is known to reactivate the pituitary-thyroid axis and to evoke paradoxical GH release in critical illness. We further explored the hypothalamic-pituitary function in critical illness by examining the effects of GH-releasing hormone (GHRH) and/or GH-releasing peptide-2 (GHRP-2) and TRH administration. PATIENTS AND DESIGN Critically ill adults (n=40; mean age 55 years) received two i.v. boluses with a 6-hour interval (0900 and 1500 h) within a cross-over design. Patients were randomized to receive consecutively placebo and GHRP-2 (n=10), GHRH and GHRP-2 (n=10), GHRP-2 and GHRH+GHRP-2 (n=10), GHRH+GHRP-2 and GHRH+GHRP-2+TRH (n=10). The GHRH and GHRP-2 doses were 1μg/kg and the TRH dose was 200μg. Blood samples were obtained before and 20, 40, 60 and 120 minutes after each injection. MEASUREMENTS Serum concentrations of GH, T4, T3, rT3, thyroid hormone binding globulin (TBG), IGF-I, insulin and cortisol were measured by RIA; PRL and TSH concentrations were determined by IRMA. RESULTS Critically ill patients presented a striking GH response to GHRP-2 (mean±SEM peak GH 51±9 μg/l in older patients and 102±2μg/l in younger patients; P=0.005 vs placebo). The mean GH response to GHRP-2 was more than fourfold higher than to GHRH (P=0.007). In turn, the mean GH response to GHRH+GHRP-2 was 2.5-fold higher than to GHRP-2 alone (P=0.01), indicating synergism. Adding TRH to the GHRH+GHRP-2 combination slightly blunted this mean response by 18% (P=0.01). GHRP-2 had no effect on serum TSH concentrations whereas both GHRH and GHRH+GHRP-2 evoked an increase in peak TSH levels of 53 and 32% respectively. The addition of TRH further increased this TSH response < ninefold (P=0.005), elicited a 60% rise in serum T3 (P=0.01) and an 18% increase in T4 (P=0.005) levels, without altering rT3 or TBG levels. GHRH and/or GHRP-2 induced a small increase in serum PRL levels. The addition of TRH magnified the PRL response 2.4-fold (P=0.007). GHRP-2 increased basal serum cortisol levels (531±29nmol/l) by 35% (P=0.02); GHRH provoked no additional response, but adding TRH further increased the cortisol response by 20% (P=0.05). CONCLUSIONS The specific character of hypothalamic-pituitary function in critical illness is herewith extended to the responsiveness to GHRH and/or GHRP-2 and TRH. The observation of striking bursts of GH secretion elicited by GHRP-2 and particularly by GHRH+GHRP-2 in patients with low spontaneous GH peaks opens the possibility of therapeutic perspectives for GH secretagogues in critical care medicine.     

Effects of repetitive administration of thyrotropin-releasing hormone at short intervals in acromegaly

We investigated the pattern of GH secretion in response to repetitive TRH administration in patients with active acromegaly and in normal subjects. Nine acromegalic patients and 10 normal subjects received three doses of 200 micrograms of TRH iv at 90-min intervals. There was a marked serum GH rise in acromegalic patients after each TRH dose (net incremental area under the curve [nAUC]: first dose = 4448 +/- 1635 micrograms.min.l-1; second dose = 3647 +/- 1645 micrograms.min.l-1; third dose = 4497 +/- 2416 micrograms.min.l-1; NS), though individual GH responses were very variable. In normal subjects TRH did not elicit GH secretion even after repeated stimulation. Each TRH administration stimulated PRL release in acromegalic patients, though the nAUC of PRL was significantly higher after the first (1260 +/- 249 micrograms.min.l-1) than after the second and the third TRH administration (478 +/- 195 and 615 +/- 117 micrograms.min.l-1, respectively; P less than 0.01). In normal subjects too, PRL secretion was lower after repeated stimulation (first dose = 1712 +/- 438 micrograms.min.l-1; second dose = 797 +/- 177 micrograms.min.l-1; third dose = 903 +/- 229 micrograms.min.l-1 P less than 0.01), though different kinetics of PRL secretion were evident, when compared with acromegalic patients. TSH secretion, assessed in only 4 patients, was stimulated after each TRH dose, though a minimal but significant reduction of nAUC of TSH after repeated TRH challenge occurred. Both T3 and T4 increased steadily in the 4 patients. The same pattern of TSH, T3, and T4 secretion occurred in normal subjects.(ABSTRACT TRUNCATED AT 250 WORDS)     

Arginine stimulates growth hormone secretion by suppressing endogenous somatostatin secretion

To determine how arginine (Arg) stimulates GH secretion, we investigated its interaction with GHRH in vivo and in vitro. Six normal men were studied on four occasions: 1) Arg-TRH, 30 g arginine were administered in 500 mL saline in 30 min, followed by an injection of 200 micrograms TRH; 2) GHRH-Arg-TRH, 100 micrograms GHRH-(1-44) were given iv as a bolus immediately before the Arg infusion, followed by 200 micrograms TRH, iv; 3) GHRH test, 100 micrograms GHRH were given as an iv bolus; and 4) TRH test, 200 micrograms TRH were given iv as a bolus dose. Blood samples were collected at 15-min intervals for 30 min before and 120 min after the start of each infusion. Anterior pituitary cells from rats were coincubated with Arg (3, 6, 15, 30, and 60 mg/mL) and GHRH (0.05, 1, 5, and 10 nmol/L) for a period of 3 h. Rat GH was measured in the medium. After Arg-TRH the mean serum GH concentration increased significantly from 0.6 to 23.3 +/- 7.3 (+/- SE) micrograms/L at 60 min. TRH increased serum TSH and PRL significantly (maximum TSH, 11.1 +/- 1.8 mU/L; maximum PRL, 74.6 +/- 8.4 micrograms/L). After GHRH-Arg-TRH, the maximal serum GH level was significantly higher (72.7 +/- 13.4 micrograms/L) than that after Arg-TRH alone, whereas serum TSH and PRL increased to comparable levels (TSH, 10.2 +/- 3.0 mU/L; PRL, 64.4 +/- 13.6 micrograms/L). GHRH alone increased serum GH to 44.9 +/- 9.8 micrograms/L, significantly less than when GHRH, Arg, and TRH were given. TRH alone increased serum TSH to 6.6 +/- 0.6 mU/L, significantly less than the TSH response to Arg-TRH. The PRL increase after TRH only also was lower (47.2 +/- 6.8 micrograms/L) than the PRL response after Arg-TRH. In vitro Arg had no effect on basal and GHRH-stimulated GH secretion. Our results indicate that Arg administered with GHRH led to higher serum GH levels than did a maximally stimulatory dose of GHRH or Arg alone. The serum TSH response to Arg-TRH also was greater than that to TRH alone. We conclude that the stimulatory effects of Arg are mediated by suppression of endogenous somatostatin secretion.     

Thyrotropin and prolactin secretory patterns during 24-hours infusion of thyrotropin-releasing hormone in calves.

Plasma levels of thyrotropin (TSH), prolactin (Prl), growth hormone (GH), thyroxine (T4), and triiodothyronine (T3) were measured in response to continuous 24-h infusion of synthetic thyrotropin-releasing hormone (TRH) in normal and surgically thyroidectomized (THYX) calves in a series of 2 experiments. In the 1st experiment, the low dose of TRH (0.077 microgram/min) had no effect on any hormone levels measured. Plasma TSH concentration increased significantly (p less than 0.05) in response to TRH infusion (0.77 microgram/min) in both experiments, but plasma TSH levels plateaued and then declined in both cases despite continued TRH infusion and irrespective of the presence or absence of a thyroid gland. A similar pattern of secretion, though less markedly decreased over time, was observed for plasma Prl in both experiments. The higher dose (0.77 microgram/min) of TRH had no effect on plasma GH concentration in the 1st infusion, but did result in a significant (p less than 0.05) increase in overall mean concentration of GH in both normal and THYX calves in the 2nd experiment. Removal of the thyroid gland, thus removing the source of increasing T4 and T3 levels seen in normal calves infused with TRH, failed to alter the secretory patterns of TSH and Prl. These data suggest that feedback inhibition by increasing plasma thyroid hormone concentrations was not responsible for the failure of TSH and, to a lesser extent, Prl to maintain chronically elevated plasma levels in response to continuous 24-h TRH infusion. It is suggested that a depletion of pituitary TSH and Prl stores readily secretable in response to a constant dosage level of TRH may be responsible for the secretory patterns observed.     

PERSISTENT TRH-INDUCED GROWTH HORMONE RELEASE AFTER SHORT-TERM AND LONG-TERM L-THYROXINE REPLACEMENT THERAPY IN PRIMARY CONGENITAL HYPOTHYROIDISM

No appreciable changes in plasma GH levels after TRH stimulation have been observed in normal subjects, whereas acute GH release has been reported in primary hypothyroidism and other pathophysiological states. To evaluate the effect of the T4 replacement therapy on TRH-induced GH release, 28 patient volunteers with primary congenital hypothyroidism (PCH), were studied before (11 subjects), after 1 month (nine subjects) and after long-term T4 replacement therapy (eight subjects). All patients underwent a TRH test with measurement of TSH, PRL and GH levels, and were compared to 28 age-matched normal subjects. An increase of plasma GH after TRH was found in 46% of patients without any therapy, in 67% of patients after one month of T4 administration and in 75% of patients after long-term therapy. No changes were observed in plasma GH levels in controls. The TSH response to TRH was inhibited and the response of PRL was reduced step by step by T4 replacement therapy in our patients with PCH. Our results suggest that: (i) Replacement T4 therapy in PCH does not abolish the paradoxical GH response to TRH, in spite of inhibiting the TSH response and reducing the exaggerated PRL response; (ii) the GH response to TRH in PCH seems to be unrelated to low thyroid hormone levels and/or to high TSH levels, but it could be due to changes in hypothalamic-pituitary regulation which are not improved by T4 replacement therapy.     

Growth hormone response to thyrotropin-releasing hormone in diabetes

The effect of TRH on GH secretion was assessed in 13 insulin-dependent diabetics. PRL and TSH responses to TRH were also determined. Glycosylated hemoglobin levels and serial fasting glucose concentrations indicated that all but 1 of the patients had a period of poor diabetic control for several months before the study. Peak PRL and TSH levels after TRH injection in these diabetic patients did not differ significantly from values observed in nondiabetic individuals. Six of the patients responded to TRH with a significant rise in GH levels; basal GH concentrations were also elevated in these patients. Five of the 6 responders and none of the nonresponders had proliferative diabetic retinopathy. The results suggest that diabetics with elevated basal GH levels hyperrespond to TRH, and that nonspecific secretion of GH in response to TRH occurs in some patients with proliferative diabetic retinopathy. Chronic hyperglycemia does not appear to be the critical factor in determining this response.     

Decreased growth hormone (GH) response to oral clonidine in endemic cretinism: effect of L-T3 therapy

As GH secretion is dependent upon thyroid hormone availability, the GH responses to clonidine (150 micrograms/m2) and the TSH and PRL response to TRH were studied in eight endemic (EC) cretins (3 hypothyroid, 5 with a low thyroid reserve) before and after 4 days of 100 micrograms of L-T3. Five normal controls (N) were also treated in similar conditions. Both groups presented a marked increase in serum T3 after therapy (N = 515 +/- 89 ng/dl; EC = 647 +/- 149 ng/dl) followed by a decrease in basal and peak TSH response to TRH. However, in the EC patients an increase in serum T4 levels and in basal PRL and peak PRL response to TRH after L-T3 therapy was observed. One hypothyroid EC had a markedly elevated PRL peak response to TRH (330 ng/dl). There were no significant changes in basal or peak GH values to treatment with L-T3 in normal subjects. In the EC group the mean basal plasma GH (2.3 +/- 1.9 ng/ml) significantly rose to 8.8 +/- 3.2 ng/ml and the mean peak response to clonidine (12.7 +/- 7.7 ng/ml) increased to 36.9 +/- 3.1 ng/ml after L-T3. Plasma SM-C levels significantly increased in N from 1.79 +/- 0.50 U/ml to 2.42 +/- 0.40 U/ml after L-T3 (p less than 0.01) and this latter value was significantly higher (p less than 0.05) than mean Sm-C levels attained after L-T3 in the EC group (respectively: 1.14 +/- 0.59 and 1.78 +/- 0.68 U/ml). These data indicate that in EC the impaired GH response to a central nervous system mediated stimulus, the relatively low plasma Sm-C concentrations, and the presence of clinical or subclinical hypothyroidism may contribute to the severity of growth retardation present in this syndrome.     

The effect of 3,5,3'-triiodothyronine or thyrotropin-releasing hormone on pituitary hormone responses to arginine infusions in hypothyroid patients

Serum PRL and GH responses to a control arginine infusion were determined in seven hypothyroid patients. During the infusion, basal TSH levels fell slightly but significantly. On a following day, a second arginine infusion was performed, 5 min after iv injection of 500 micrograms TRH. The mean peak PRL response was enhanced 6-fold and occurred earlier, while the mean peak GH response remained unaffected. Mean peak TSH levels were only 128% above baseline after TRH. On a third day, a third arginine infusion was performed 4 h after oral administration of 100 micrograms T3; mean serum T3 levels were increased from 57 to a peak of 481 ng/dl 5 h after T3. The mean GH response was significantly reduced by 71% at 90 min, with an overall reduction of the GH output of 47%, while the PRL response remained unaffected. Thus, acute elevation of serum T3 levels in hypothyroidism appear to inhibit the mean GH response to arginine.     

Effects of acute infusion of erythropoietin on paradoxical responses of growth hormone to thyrotropin-releasing hormone in acromegalic patients

OBJECTIVE: Our aim has been to evaluate the effects of i.v. infusion of recombinant human erythropoietin (rhEPO) on the responses of growth hormone (GH), prolactin (PRL) and thyrotropin (TSH) to thyrotropin-releasing hormone (TRH) stimulation in acromegalic patients. METHODS: We studied 16 patients (8 females, aged 29-68 years) with active acromegaly and 12 control subjects (7 females, 24-65 years). All participants were tested with TRH (400 microg i.v. as bolus) and with TRH plus rhEPO (40 U/kg at a constant infusion rate for 30 min, starting 15 min before TRH injection) on different days. Blood samples were obtained between -30 and 120 min for GH and PRL determinations, and between -30 and 90 min for TSH determinations. Hormone responses were studied by a time-averaged (area under the secretory curve (AUC)) and time-independent (peak values) analysis. RESULTS: Twelve patients exhibited a paradoxical GH reaction after TRH administration with great interindividual variability in GH levels. When patients were stimulated with rhEPO plus TRH there were no changes in the variability of GH responses or in the peak and AUC for GH secretion. Infusion with rhEPO did not induce any significant change in GH secretion in normal subjects. Baseline and TRH-stimulated PRL concentrations in patients did not differ from those values found in controls. When TRH was injected during the rhEPO infusion, a significant (P<0.05) increase in PRL concentrations at 15-120 min was found in acromegalic patients. Accordingly, the PRL peak and the AUC for PRL secretion were significantly increased in patients. Infusion with rhEPO had no effect on TRH-induced PRL release in control subjects. Baseline TSH concentrations, as well as the TSH peak and the AUC after TRH, were significantly lower in patients than in controls. Infusion with rhEPO modified neither the peak TSH reached nor the AUC for TSH secretion after TRH injection in acromegalic patients and in healthy volunteers. CONCLUSION: Results in patients with acromegaly suggest that (i) the paradoxical GH response to TRH is not modified by rhEPO infusion, (ii) rhEPO has no effect on TRH-induced TSH release, and (iii) acute rhEPO administration increases the TRH-induced PRL release in acromegalic patients.     

Effect of obesity and starvation on thyroid hormone, growth hormone, and cortisol secretion.

Obesity and starvation have opposing affects on normal physiology and are associated with adaptive changes in hormone secretion. The effects of obesity and starvation on thyroid hormone, GH, and cortisol secretion are summarized in Table 1. Although hypothyroidism is associated with some weight gain, surveys of obese individuals show that less than 10% are hypothyroid. Discrepancies have been reported in some studies, but in untreated obesity, total and free T4, total and free T3, TSH levels, and the TSH response to TRH are normal. Some reports suggest an increase in total T3 and decrease in rT3 induced by overfeeding. Treatment of obesity with hypocaloric diets causes changes in thyroid function that resemble sick euthyroid syndrome. Changes consist of a decrease in total T4 and total and free T3 with a corresponding increase in rT3. untreated obesity is also associated with low GH levels; however, levels of IGF-1 are normal. GH-binding protein levels are increased and the GH response to GHRH is decreased. These changes are reversed by drastic weight reduction. Cortisol levels are abnormal in people with abdominal obesity who exhibit an increase in urinary free cortisol but exhibit normal or decreased serum cortisol and normal ACTH levels. These changes are explained by an increase in cortisol clearance. There is also an increased response to CRH. Treatment of obesity with very low calorie diets causes a decrease in serum cortisol explained by a decrease in cortisol-binding proteins. The increase in cortisol secretion seen in patients with abdominal obesity may contribute to the metabolic syndrome (insulin resistance, glucose intolerance, dyslipidemia, and hypertension). States of chronic starvation such as seen in anorexia nervosa are also associated with changes in thyroid hormone, GH, and cortisol secretion. There is a decrease in total and free T4 and T3, and an increase in rT3 similar to findings in sick euthyroid syndrome. The TSH response to TRH is diminished and, in severe cases, thyroid-binding protein levels are decreased. In regards to GH, there is an increase in GH secretion with a decrease in IGF-1 levels. GH responses to GHRH are increased. The [table: see text] changes in cortisol secretion in patients with anorexia nervosa resemble depression. They present with increased urinary free cortisol and serum cortisol levels but without changes in ACTH levels. In contrast to the findings observed in obesity, the ACTH response to CRH is suppressed, suggesting an increased secretion of CRH. The endocrine changes observed in obesity and starvation may complicate the diagnosis of primary endocrine diseases. The increase in cortisol secretion in obesity needs to be distinguished from Cushing's syndrome, the decrease in thyroid hormone levels in anorexia nervosa needs to be distinguished from secondary hypothyroidism, and the increase in cortisol secretion observed in anorexia nervosa requires a differential diagnosis with primary depressive disorder.     

Serum thyrotropin and prolactin in the syndrome of generalized resistance to thyroid hormone: responses to thyrotropin-releasing hormone stimulation and short term triiodothyronine suppression

Serum TSH and PRL levels and their response to TRH were measured in 11 patients with generalized resistance to thyroid hormone (GRTH), 6 euthyroid subjects, and 6 patients with primary hypothyroidism. TSH and PRL levels and their response to TRH were also measured after the consecutive administration of 50, 100, and 200 micrograms T3 daily, each for a period of 3 days. Using a sensitive TSH assay, all GRTH patients had TSH values that were elevated or within the normal range. On the basis of a normal or elevated TSH level, GRTH patients were classified as GRTH-N1 TSH (5 patients) or GRTH-Hi TSH (6 patients), respectively. Only GRTH patients with previous thyroid ablative therapy had basal TSH values greater than 20 mU/L. TSH responses, in terms of percent increment above baseline, were appropriate for the basal TSH level in all subjects. No GRTH patient had an elevated basal PRL level. PRL responses to TRH were significantly increased only in the hypothyroid controls compared to values in all other groups. On 50 micrograms T3, 7 of 12 (58%) nonresistant (euthyroid and hypothyroid) and 1 of 11 (9%) resistant subjects had a greater than 75% suppression of the TSH response to TRH. On the same T3 dose, 2 of 12 (17%) nonresistant and 4 of 11 (36%) resistant subjects had a greater than 50% suppression of the PRL response to TRH. On 200 micrograms T3, all subjects, except for 1 with GRTH, had a greater than 75% suppression of the TSH response to TRH. On the same T3 dose, while 11 of 12 (92%) nonresistant subjects had a greater than 50% reduction of the PRL response to TRH, only 3 of 10 (30%) resistant patients showed this degree of suppression (P less than 0.005). Without previous ablative therapy, serum TSH in patients with GRTH is usually normal or mildly elevated. The TSH response to TRH is proportional to the basal TSH level and is suppressed by exogenous T3. However, on 200 micrograms T3 basal TSH was not detectable (less than 0.1 mU/L) in all euthyroid subjects, but it was measurable in three of four GRTH patients with normal TSH levels before T3 treatment. PRL levels in GRTH are normal even when TSH is elevated. The PRL response to TRH is not increased in GRTH. In all subjects, exogenous T3 suppresses the PRL response to TRH to a lesser degree than the TSH response, but this difference is much greater in patients with GRTH.     

Corticotropin-releasing hormone inhibition of paradoxical growth hormone response to thyrotropin-releasing hormone in insulin-dependent diabetics.

A paradoxical growth hormone (GH) response to thyrotropin-releasing hormone (TRH) has been observed in type 1 diabetic patients and was hypothetically attributed to a reduced hypothalamic somatostatin tone. We have previously reported that corticotropin-releasing hormone (CRH) inhibits GH response to growth hormone-releasing hormone (GHRH) in normal subjects, possibly by an increased release of somatostatin. To study the effect of CRH on anomalous GH response to TRH, we tested with TRH (200 micrograms intravenously [IV]) and CRH (100 micrograms IV) + TRH (200 micrograms IV) 13 patients (six males and seven women) affected by insulin-dependent diabetes mellitus. A paradoxical GH response to TRH was observed in seven of 13 patients, one man and six women. In these subjects, the simultaneous administration of CRH and TRH significantly reduced the GH response to TRH, as assessed by both the maximal GH mean peak +/- SE (2.18 +/- 0.67 v 9.2 +/- 1.26 micrograms/L, P less than 0.005) and the area under the curve (AUC) +/- SE (187 +/- 32 v 567 +/- 35 micrograms.min/L, P less than .001). CRH had no effect on TRH-induced thyroid-stimulating hormone (TSH) release. Our data demonstrate that the paradoxical GH response to TRH in patients with type 1 diabetes mellitus is blocked by CRH administration. This CRH action may be due to an enhanced somatostatin release. Our data also show that exogenous CRH has no effect on TSH response to TRH, thus suggesting the existence of separate pathways in the neuroregulation of GH and TSH secretion.     

Preserved thyroidal secretion of thyroxione in acromegalic patients with suppressed hypophyseal secretion of thyrotrophin

OBJECTIVE--We have assessed the mechanisms which maintain euthyroidism in acromegalic patients despite the suppression of thyrotrophin (TSH) secretion. MATERIALS--Fourteen untreated patients with acromegaly were analysed. Ten patients were also studied after pituitary surgery. METHODS--Thyroid hormones, growth hormone (GH), insulin-like growth factor-I (IGF-I) and thyroidal uptake of radioactive iodine, thyrotrophin releasing hormone (TRH) test and basal metabolic rate (BMR) were measured before and after pituitary surgery. RESULTS--Nine patients had palpable goitres. The TSH response to TRH stimulation was suppressed in eight patients, who maintained normal serum levels of total T3, T4 and free T4. The patients with normal TSH response had lower levels of free and total T4 than controls. The response of TSH to TRH correlated inversely with the serum level of total and free T4, and also with the plasma level of IGF-I (r = -0.74, P less than 0.05, n = 9). After pituitary surgery, the serum levels of total and free T4 were elevated for at least up to 6 months, with a decrease in the T3/T4 ratio and the BMR. CONCLUSION--GH may have a direct stimulatory action on the thyroid secretion of T4 possibly via increased IGF-I, despite suppressed TSH secretion. The post-operative elevation of serum T4 suggests the persistent secretion of T4 from the thyroid gland, in spite of instantaneous normalization of the accelerated conversion of T4 to T3, even after reduction of excess GH secretion.     

Association of thyroid-stimulating immunoglobulins and thyrotropin-releasing hormone responsiveness in women with euthyroid goiter

Thyroid-stimulating immunoglobulins (TSI) were measured, using a highly sensitive cytochemical bioassay, in plasma from 26 euthyroid women with idiopathic diffuse or multinodular goiter selected on the basis of their serum TSH responses to TRH stimulation. Thirteen were chosen because they were previously identified to have impairment in TRH responsiveness and were compared with 13 consecutive patients who had normal responses to TRH. TSI were present in a significantly greater number of those who had subnormal TRH responses (11:13) compared to those who had normal responses (3:13) P less than 0.005. Although serum T4, T3, and basal TSH values were all within the normal range, mean serum T4 and T3 values were significantly higher and basal TSH significantly lower in the 14 patients who had TSI than in the 12 in whom TSI was absent. The coexistence of impaired TRH responsiveness and TSI was associated with a family history of thyroid disease. The data suggest that TSI in patients with euthyroid goiter cause a modest increase in thyroid secretion sufficient to blunt the TSH response to TRH but not to cause clinical hyperthyroidism.     

Pyridostigmine and metoclopramide do not restore the TSH response to TRH inhibited by L-thyroxine treatment in children with goiter

To define the role of somatostatin and dopamine in TSH suppression induced by L-thyroxine, 16 children (12 F, 4 M) on suppressive doses of L-thyroxine (3-4 microg/kg/day) for endemic goiter were studied. Firstly a conventional TRH test was performed in all subjects, in order to evaluate TSH, PRL and GH (basal study). A week later a second TRH test was carried out; one hour before the test, however, group A (9 patients) was given 60 mg pyridostigmine bromide po (pyridostigmine study) and group B (7 patients) 10 mg metoclopramide po (metoclopramide study). In the basal study, TSH was suppressed in both groups and levels did not increase following TRH administration, while PRL increased significantly and GH levels remained stable. In the pyridostigmine study, TSH levels did not increase following TRH administration, while PRL and GH levels were both significantly raised. In the metoclopramide study, TSH and GH levels were not raised following TRH administration, while a significantly greater increase of PRL was observed. In conclusion, suppressive doses of L-thyroxine inhibit the TSH response to TRH, while they do not seem to affect GH and PRL secretion. Somatostatin and/or dopamine do not seem to play a significant role in the L-thyroxine-induced TSH suppression.     

Histamine-induced paradoxical growth hormone response to thyrotropin-releasing hormone in normal men

GH responses to TRH occur in patients with certain diseases, such as acromegaly, severe liver disease, uremia, and mental disorders, and presumably reflect disruption of normal hypothalamic control of GH secretion. Since histamine (HA) inhibits hypothalamic stimulation of GH secretion, we investigated the combined effect of HA receptor activation and TRH administration on GH secretion in normal men. Eight men were given 4-h infusions of the following: saline, HA, HA plus mepyramine (Me; and H1-antagonist), HA plus cimetidine (C; an H2-antagonist), and C alone. TRH (200 micrograms) was injected iv 2 h after the start of each infusion. HA alone or in combination with either antagonist had no effect on basal or TRH-stimulated TSH secretion and no effect on basal GH secretion. However, when TRH was injected during H1 stimulation by HA plus C, GH secretion increased significantly [from 0.7 +/- 0.1 to 7.1 +/- 1.8 (+/- SEM) ng/ml; P less than 0.01] in seven of eight subjects. This GH response was reproducible and did not occur when saline was administered instead of TRH. A smaller and delayed GH response to TRH occurred during infusions of HA alone (from 0.8 +/- 0.1 to 4.9 +/- 1.0 ng/ml; P less than 0.05). No effect of TRH on GH secretion occurred during the infusion of saline (1.2 +/- 0.3 ng/ml), HA plus Me (0.9 +/- 0.1 ng/ml), or C (2.2 +/- 1.0 ng/ml). There was a significant increase in GH secretion after cessation of the infusions of HA (from 3.4 +/- 1.1 to 7.5 +/- 2.2 ng/ml) and HA plus Me (from 0.8 +/- 0.1 to 5.1 +/- 1.8 ng/ml). This rebound in GH secretion might indicate an inhibitory effect of TRH during H2-receptor stimulation. This concept is supported by the significantly smaller GH response to TRH during HA infusion than during HA plus C infusion (P less than 0.01). The study indicates that H1-receptor stimulation induces a stimulatory effect of TRH on GH secretion in normal men and that H2-receptor stimulation possibly induces an inhibitory effect of TRH on GH secretion.     

Early effects of cranial irradiation on hypothalamic-pituitary function

Hypothalamic-pituitary function was studied in 31 patients before and after cranial irradiation for nasopharyngeal carcinoma. The estimated radiotherapy (RT) doses to the hypothalamus and pituitary were 3979 +/- 78 (+/- SD) and 6167 +/- 122 centiGrays, respectively. All patients had normal pituitary function before RT. One year after RT, there was a significant decrease in the integrated serum GH response to insulin-induced hypoglycemia. In the male patients, basal serum FSH significantly increased, while basal serum LH and testosterone did not change. Moreover, in response to LHRH, the integrated FSH response was increased while that of LH was decreased. Such discordant changes in FSH and LH may be explained by a defect in LHRH pulsatile release involving predominantly a decrease in pulse frequency. The peak serum TSH response to TRH became delayed in 28 patients, suggesting a defect in TRH release. Twenty-one patients were reassessed 2 yr after RT. Their mean basal serum T4 and plasma cortisol levels had significantly decreased. Hyperprolactinemia associated with oligomenorrhoea was found in 3 women. Further impairment in the secretion of GH, FSH, LH, TSH, and ACTH had occurred, and 4 patients had hypopituitarism. Thus, progressive impairment in hypothalamic-pituitary function occurs after cranial irradiation and can be demonstrated as early as 1 yr after RT.