THYROTROPHIN, PROLACTIN AND GROWTH HORMONE RESPONSES TO TRH IN BARBITURATE COMA AND IN DEPRESSION

The effects of 200 microgram thyrotrophin-releasing hormone (TRH) i.v. on thyrotrophin (TSH), prolactin (PRL), growth hormone (GH) and triiodothyronine (T3) were studied in eight patients with barbiturate coma due to attempted suicide, in the same patients after recovery, in eight depressive patients and in eight normal controls. The patients with barbiturate coma presented normal basal TSH and PRL, elevated basal GH and normal PRL but blunted TSH responses to TRH; their GH concentrations varied widely without consistent relation to TRH administration. The same patients after recovery from coma presented normal TSH and PRL, slightly elevated basal GH, and normal PRL but blunted TSH responses to TRH; in four of these patients, a clear-cut rise in GH (i.e. more than 10 ng/ml) occurred after TRH administration. The depressive patients presented normal basal TSH and PRL, slightly elevated basal GH, and normal PRL but blunted TSH responses to TRH; in four of these patients, a moderated rise in GH (less than 10 ng/ml) occurred after TRH administration. The increment in T3 concentrations 120 min after TRH was found reduced in the comatose patients only. Basal cortisol was measured in all the subjects and found elevated in the comatose patients only. It is concluded that the abnormal TSH and GH responses to TRH observed in patients with barbiturate coma are more likely related to depressive illness than to an effect of barbiturates at the pituitary level. Barbiturates might affect thyroid secretion.     

Prolactin and TSH responses to TRH, chlorpromazine and L-dopa in children with human growth hormone deficiency.

Prolactin (PRL) and TSH responses to TRH, chlorpromazine (CPZ) and L-DOPA were studied in 23 children (15 male and 8 female) with human growth hormone (HGH) deficiency. Eight patients (group I) showed normal PRL response to TRH and CPZ but TSH response to TRH was delayed in 4 of this group. Twelve patients (group II) had normal (4 patients) or higher (8 patients) baseline PRL level and showed lower PRL response to CPZ than that to TRH. TSH response to TRH was normal in 3, blunted in 1, and delayed in 8 patients. Three patients (group III) had no PRL response to either TRH or CPZ. TSH response to TRH was normal in 1 but blunted in 2 patients. Of 8 patients with a higher baseline PRL level (group II and III), L-DOPA suppressed PRL secretion to less than 50% of the initial value in 7 patients, but not in 1 patient, in whom the diagnosis of hypothalamic tumour was established on brain surgery following these examinations. These results suggest that hypothalamic disorders are involved in more than half of 23 children with HGH deficiency.     

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.     

Thyrotropin suppression by 3,5-dimethyl-3'-isopropyl-L-thyronine in man.

The thyromimetic activity of 3,5-dimethyl-3'-isopropyl-L-thyronine (DIMIT), a nonhalogenated thyroid analog, was studied in adult men using suppression of TRH-induced TSH release to assess this activity. In nine men, aged 30-58 yr, the TSH increment after 500 microgram TRH iv was compared to the TSH response to TRH 24 h after oral administration of 1 mg DIMIT. Eight euthyroid subjects had normal baseline TSH levels of 1.5 +/- 0.2 (SE) microunit/ml that fell significantly to 0.7 +/- 0.2 microunit/ml 24 h after DIMIT (P less than 0.005). Their TSH increments after TRH fell from 15.3 +/- 2.8 to 6.7 +/- 1.6 microunit/ml 24 h after DIMIT (P less than 0.001). One subject with probable Hashimoto's thyroditis had an elevated TSH of 18 microunit/ml, with an exaggerated TSH response to TRH of 72 microunit/ml. His basal TSH fell to 7.6 and his TSH increment fell to 14.3 microunit/ml 24 h after DIMIT. The suppression of TSH was relatively prolonged. In four subjects, the TSH response to TRH was still blunted from 5-12 days after DIMIT. In one subject, the TSH increment returned to normal 15 days after DIMIT. DIMIT had no significant effect on PRL secretion. There was no evidence of toxicity in patients receiving DIMIT. DIMIT has effective thyromimetic activity in man, as shown by its significant and prolonged suppression of TSH secretion.     

TRH-induced TSH and prolactin responses in the elderly

Since there are divergencies in the thyrotropin (TSH) response to thyrotropin-releasing hormone (TRH) in old age, and since a hypothalamopituitary dysfunction has been suggested in the elderly, we have studied the thyroid function and the TRH responsiveness of TSH and prolactin (PRL) in 56 euthyroid patients over 70 years old, grouped according to age (70-79, 80-89, 90 or more years) and sex. Results were compared to those of 15 postmenopausal women and 11 men. In the elderly patients there was a decrease in plasma tri-iodothyronine (T3) and an increase in reverse T3 (rT3) levels while thyroxine (T4), basal TSH and PRL levels remained normal. The mean TSH and PRL responses to TRH (250 micrograms i.v.) were reduced but there was no age effect within the elderly. Only a sex effect was detected, TSH and PRL responses being appreciably lowered in men. In eight patients without severe disease or malnutrition, the response of TSH was not significant. We conclude that despite an apparent euthyroid status, TSH and PRL responses are blunted in elderly patients, and more in men than in women. These data, consistent with a hypothetical hypothalamopituitary dysfunction, indicate the difficulties of thyroid status assessment in the elderly.     

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)     

Regulation of thyrotropin-releasing hormone receptors and responses by L-triiodothyronine in dispersed rat pituitary cell cultures

The effects of physiological concentrations of L-T3 (T3) were examined in dispersed cell cultures of pituitaries obtained from 10- to 12-day-old rats. T3 inhibited TSH secretion by 50% and blunted the TSH response to TRH. The PRL response to TRH was also inhibited by T3, and GH secretion was increased 2-fold. These responses were half-maximal at 0.1 nM added T3 in medium supplemented with 10% hypothyroid calf serum, corresponding to a free T3 concentration of 5 pM. In the presence or absence of added T3, TRH effects were half-maximal at 0.5-3 nM, and T3 suppression was not overcome by high concentrations of TRH (up to 1 microM). Maximal inhibition of TSH responses to TRH occurred when cultures were preincubated with thyroid hormone for 24 h; a significant effect was observed after 8 h. The specific binding of [3H]TRH to dispersed rat pituitary cells was decreased 55-70% by T3 in a dose-dependent manner. Inhibition of TSH secretion by T3 was reversible within 24 h, and the fraction of thyrotrophs in the cultures (0.22) was not altered by T3 over the course of the experiments. The results demonstrate that physiological concentrations of T3 regulate TSH and PRL responses to TRH and control TRH receptor levels by a direct action on normal rat pituitary cells.     

Sustained rises in serum thyrotropin, thyroxine, and triiodothyronine during long term, continuous thyrotropin-releasing hormone treatment in patients with amyotrophic lateral sclerosis

In a pilot therapeutic trial, four patients with amyotrophic lateral sclerosis (ALS) were treated with long term, continuous infusions of TRH, three intrathecally and one epidurally. They had prompt increases in serum TSH and thyroid hormone concentrations, averaging 120% for TSH, 49% for serum T4, 68% for the serum free T4 index, 49% for serum T3, and 67% for the serum free T3 index. These elevations were statistically significant for all but serum T3 and persisted for the duration of treatment (4-7 months). Mean values during treatment were near the upper limit of normal for each of these hormone measurements. After TRH withdrawal, serum TSH fell transiently below the normal range. A comparison group of four patients with ALS treated by twice weekly intrathecal bolus doses of TRH had no significant changes in serum TSH, T4, or T3. During continuous TRH treatment, the responsiveness of both TSH and PRL to a standard iv TRH stimulation test was blunted, but not abolished. Basal serum PRL was occasionally elevated in the two women during continuous TRH treatment, but was normal in the men, and serum GH was normal in all patients. In the patients receiving continuous TRH treatment, indexes of end-organ effects of thyroid hormone were inconclusive; none had a rise in serum ferritin, one of four had a rise in serum sex hormone-binding globulin, and three had increased creatinuria. These results provide direct evidence in man that chronic TRH administration can cause modest sustained increases in serum TSH and thyroid hormones, though the metabolic consequences of these changes are uncertain, and appears to raise the set-point of the pituitary-thyroid axis, i.e. the serum T4 and T3 concentrations needed for a given degree of suppression of basal TSH secretion.     

Effect of cyproheptadine on thyrotrophin and prolactin secretion in normal man.

In order to investigate the effect of cyproheptadine, a compound with antiserotoninergic activity, on the secretion of thyrotrophin (TSH) and prolactin (PRL), the nocturnal secretory patterns of these hormones have been studied in 4 normal men in the basal state and after an oral treatment with the drug. In addition, the TSH and PRL responses to TRH of 6 women were compared in the basal conditions and after cyproheptadine treatment. The TSH nocturnal secretion was slightly modified by drug treatment. The response to TRH as well as the basal levels were comparable in the treated and non-treated subjects. In contrast, the PRL secretion measured through the nocturnal investigation was significantly inhibited by cyproheptadine administration as were the PRL basal levels in the TRH test. The PRL response to TRH was comparable in both situations.     

Thyrotropin releasing hormone does not stimulate prolactin release in the preterm human fetus

Previous studies have suggested that fetal PRL secretion does not respond to stimuli such as TRH, metoclopramide, and cimetidine. It was postulated that the lack of response to TRH could be due to the possibility that, in the term fetus, lactotropes secrete PRL maximally and would be unresponsive to further stimulation. In order to study this hypothesis, 200 micrograms TRH or saline were administered to preterm pregnant women in labor. Maternal blood was obtained before TRH and saline administration. Maternal and cord blood were obtained at parturition. PRL, TSH, T4 and T3 concentrations were measured in all sera. TRH administration induced a significant increase in maternal serum PRL, TSH and T3 concentrations. In the cord blood of newborns whose mothers received TRH, serum TSH, T4 and T3 concentrations were significantly higher than in cord blood of newborns whose mothers received saline. Cord blood serum PRL concentrations were unchanged after TRH administration. This latter finding suggests that fetal lactotropes do not respond to TRH in the preterm fetus. Desensitization of fetal PRL secreting cells to TRH stimulation and/or the inhibitory effect of elevated fetal circulating corticosteroids on TRH-induced PRL secretion may explain the absent PRL response to TRH during fetal life.     

Hypothalamo-hypophyseal thyroid and gonadal function before and after erythropoietin therapy in dialysis patients.

We examined the effects of administration of two hypothalamic neurohormones, TRH and GnRH, for 3 days in five anemic male dialysis patients and five age-matched normal male volunteers. Patients on chronic hemodialysis have abnormal hypothalamo-hypophyseal thyroid and gonadal functions, including blunted TSH response to TRH, hyperprolactinemia, elevated basal levels of LH with exaggerated response to GnRH, and depressed FSH secretory response to GnRH. After correction of anemia with exogenous erythropoietin, these dialysis patients were given a single injection of the same hypothalamic hormones. The repeat studies after the correction of anemia showed normalization of 1) the TSH response to TRH, 2) basal GH and PRL levels, and 3) the FSH response to GnRH. Although these patients appear to have biochemical evidence of testicular failure, the gonadotropin response (FSH) to GnRH was not exaggerated. In addition, there was no increase in total T4 and free T4 after TRH administration. Although a free T3 response to TRH was present, it was remarkably blunted compared to that of controls. At the present time, it is not known whether these hormonal responses after the correction of anemia are due to better oxygenation or a trophic action of the erythropoietin.     

Growth hormone secretory status is a determinant of the thyrotropin response to thyrotropin-releasing hormone in euthyroid patients with hypothalamic-pituitary disease

To assess the influence of endogenous GH secretion on the TSH and T3 responses to TRH administration in patients with hypothalamic-pituitary disease, we analyzed tests in a selected group of 26 euthyroid patients with hypothalamic-pituitary disease and in 15 normal controls. Basal TSH levels and the TSH response to TRH were significantly greater in GH-deficient patients (group 1) than in patients with normal anterior pituitary function and unimpaired GH reserve (group II). However, the T3 response to TRH was significantly less in group 1 than in group II patients. In acromegaly (group III), the TSH response to TRH was blunted, while basal and stimulated T3 levels were no different compared to control levels. These findings suggest that endogenous GH depresses the TSH response to TRH while enhancing the thyroid secretion of T3 in response to the evoked TSH released.     

Prolactin and TSH response to TRH and metoclopramide before and after l-thyroxine therapy in subclinical hypothyroidism

The effects of the dopamine (DA) receptor antagonist metoclopramide on the plasma thyroid stimulating hormone (TSH) and prolactin (PRL) levels were studied in 8 patients with subclinical hypothyroidism (defined as absence of clinical signs of hypothyroidism with normal thyroid hormone levels, normal or slightly increased basal plasma TSH levels and increased and long-lasting TSH response to TRH) before and after l-thyroxine replacement therapy. Metoclopramide induced a significant (p less than 0.01) TSH release in the subclinical hypothyroid patients. Two weeks after l-thyroxine replacement therapy (50 micrograms/day), the TSH response to metoclopramide was completely blunted in subclinical hypothyroidism. In these patients a significant (p less than 0.01) inhibition of TSH response to intravenous thyrotropin-releasing hormone (TRH) was also observed after treatment with thyroid hormone. In analogy to the TSH behavior, plasma PRL secretion in response to metoclopramide and TRH administration was significantly (p less than 0.05) inhibited in the subclinical hypothyroid patients after l-thyroxine replacement therapy.     

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.     

Blunted prolactin response to thyrotropin-releasing hormone stimulation in cystinotic children receiving cysteamine

We investigated whether long term cysteamine therapy in cystinotic children altered their basal and stimulated serum PRL levels. Five subjects who had normal plasma PRL responses to TRH stimulation before cysteamine treatment each had a lower basal PRL level and a blunted PRL response during long term (19-59 months) cysteamine therapy. A blunted PRL response was not found in 12 cystinotic subjects of the same age and stage of disease who had not received cysteamine. The effect on PRL release was not found in 2 subjects who received short term (1-2 weeks) treatment with full-dose cysteamine (50 mg/kg . day). The TSH response to TRH stimulation was not blunted during long term cysteamine therapy. These findings suggest that cysteamine alters PRL secretion in humans.     

Circadian and pulsatile thyrotropin secretion in euthyroid man under the influence of thyroid hormone and glucocorticoid administration

The inhibitory action of thyroid hormones (TH) and glucocorticoids on circadian and pulsatile TSH secretion was investigated in groups of five normal men by sampling blood every 10 min for 24 h (start, 1750 h). Serum TSH was measured by a sensitive immunoradiometric assay. Continuous infusion of 50 micrograms T3 or 250 micrograms T4 for 8 h (1900-0300 h) significantly suppressed serum TSH levels (T3, P less than 0.025; T4, P less than 0.05; by paired t test). Administration of 3 g sodium ipodate 7 h before TH infusion did not alter the TSH response to T3, but T4-dependent suppression was abolished. Pulsatile TSH secretion [basally, 5.8 +/- 1.3 (+/- SD) pulses/24 h, as analyzed by the PULSAR program; 6.8 +/- 1.9 by the Cluster program] was not significantly altered by any of the experimental conditions. The additional finding of blunting of the TSH response to TRH after TH alone or ipodate and T3 suggests a predominantly pituitary feedback action of TH exerted via conversion of T4 to T3. In contrast, bolus injections of 4 mg dexamethasone (dex) at 1900 and 2200 h abolished TSH pulses for at least 6 h (PULSAR, 6.6 +/- 1.6 pulses/24 h basally vs. 3.6 +/- 3.0 under dex; Cluster, 7.0 +/- 2.7 pulses/24 h basally vs. 1.6 +/- 1.6 under dex). Dex administration also resulted in a prompt, sustained, and significant suppression of basal TSH (P less than 0.0005). Together with a normal serum TSH response to TRH (in separate experiments 1, 9, and 19 h after dex administration), these data suggest that glucocorticoid feedback occurs at a suprapituitary level.     

Effect of lysine vasopressin on basal and TRH stimulated TSH and PRL release in normal men

In order to test the possible effects of lysine vasopressin (LVP) on basal and TRH stimulated TSH and PRL release, an iv bolus of LVP (0.06 IU/kg bw) was injected alone or just before TRH (20 or 400 micrograms iv) in 18 normal male subjects. The administration of LVP modified neither the basal secretion of TSH and PRL nor the TSH and PRL release induced by 20 or 400 micrograms TRH. These data suggest that in humans, vasopressin is not involved in the control of TSH and PRL release at the anterior pituitary level.     

Effect of thyroid hormones on the prolactin response to thyrotropin-releasing hormone in normal persons and euthyroid goitrous patients.

In nine euthyroid goitrous patients, increasing doses of T4 caused a significant decrease in the PRL response to TRH; the PRL response fell significantly at a dose of T4 of 100 micrograms/day for 1 month (P less than 0.02) and fell further with increasing doses so that at 300 micrograms T4/day, the PRL response was 40% of that in the untreated state. T4 treatment also blunted the PRL response to chlorpromazine (P less than 0.05) in a separate group of euthyroid goitrous patients. In contrast, there was only a small drop of the PRL response to TRH in normal subjects treated with T4 (n = 9) and none at all with T3 (n = 7). These data, together with previously published reports, suggest that thyroid hormone may affect PRL secretion in the presence of thyroid disease (hyperthyroidism, hypothyroidism, or euthyroid goiter), but that physiological amounts of thyroid hormone have little or no modulating effect on PRL secretion in normal persons.     

Morphine-induced TSH release in normal and hypothyroid subjects

The effects of morphine (10 mg i.v.), an opioid agonist, and of naloxone (10 mg i.v.), an opioid antagonist, on serum levels of TSH and PRL were studied in 7 hypothyroid patients and in 5 normal volunteers. Morphine administration induced a prompt, significant increase in serum TSH and PRL in all subjects. The degree of PRL release after morphine was similar in the two groups, while, as regards TSH, the increase was more evident in hypothyroid subjects. Pretreatment with naloxone (4 mg i.v. 5 min before morphine administration) blocked these effects in all subjects. In contrast, naloxone alone was not able to affect significantly TSH and PRL secretion. Moreover, in 5 other euthyroid volunteers, morphine significantly enhanced the response of TSH and PRL to TRH stimulation (200 micrograms i.v.). These data demonstrate that morphine exerts a stimulatory action on TSH and PRL secretion: the possible mode of action of this drug and the physiologic significance of these findings are discussed.     

Regulation of prolactin secretion in patients with Cushing's disease. A comparative study on the effects of dexamethasone, lysine vasopressin and ACTH on prolactin secretion by the rat pituitary gland in vitro

In 15 untreated patients with Cushing's disease the regulation of prolactin (PRL) was evaluated. Plasma PRL was 11.5 +/- 4.8 vs. 5.3 +/- 3.6 ng/ml (patients with Cushing's disease vs. control; mean +/- S.D.; p less than 0.001). The maximal increment of plasma PRL in response to TRH was 32.3 +/- 17.3 vs. 27.9 +/- 17.2 ng/ml (NS); the maximal increment of plasma PRL in response to an insulin-induced hypoglycemia was 3.8 +/- 4.6 vs. 22.7 +/- 12.4 ng/ml (p less than 0.001). Additionally the effect of dexamethasone, lysine vasopressin and ACTH on the secretion of PRL by rat pituitary glands in vitro was studied. Dexamethasone (1.25--10 microM) inhibited the secretion of PRL. However, in the presence of dexamethasone modulation of PRL release by TRH and dopamine remained unaltered. Lysine vasopressin (5 nM - 5 microM) and ACTH (0.5--12.5 microM) did not have a direct effect on PRL release by normal rat pituitary glands in vitro and these substances also did not interfere with dopamine-mediated inhibition of PRL release. Conclusions: In Cushing's disease the PRL responses to TRH (normal) and to insulin-induced hypoglycemia (blunted) are differentially affected. Therefore, hypercortisolism probably selectively interferes with the regulation of PRL secretion at a suprahypophyseal level. It is concluded that TRH and dopamine regulate PRL release at sites which are not under corticosteroid regulation, while corticosteroids modulate PRL secretion in response to stress.