EFFECT OF DOPAMINE AND A DOPAMINE D-1 RECEPTOR AGONIST ON PULSATILE THYROTROPHIN SECRETION IN NORMAL WOMEN

The inhibitory effect of a pharmacological dose of dopamine and the specific dopamine D-1 receptor agonist fenoldopam on basal and pulsatile TSH secretion was investigated in normal women. The TSH response to fenoldopam and subsequent releasing hormone administration was also studied. Six women received placebo or dopamine infusion (4.0 micrograms/kg min) for 17 h. After 9 h, blood samples were collected every 10 min between 0800 and 1600 h for measurement of TSH. Eight women received 8-h (0900-1700 h) infusions of either fenoldopam (0.5 micrograms/kg min) or placebo. After 7 h of infusion 10 micrograms TRH, 5 micrograms GnRH and 25 micrograms CRF was given i.v. Blood samples were collected every 10 min. Dopamine infusion as well as fenoldopam infusion significantly reduced both mean basal TSH secretion and TSH pulse frequency compared with corresponding control infusions (P less than 0.05). However, while the effect on TSH pulsatility was comparable (P greater than 0.05), the percentage decrease in basal TSH levels after 16 h of dopamine infusion was 51 +/- 16% (mean +/- SD) and after 7 h of fenoldopam infusion 19 +/- 12% (P less than 0.05). Neither of the drugs affected TSH pulse amplitude and fenoldopam did not influence TRH-stimulated TSH release (P greater than 0.05). The results suggest that dopamine D-1 receptors are involved in modulation of TSH pulsatility probably at the hypothalamic level. It is argued that dopaminergic inhibition of basal TSH secretion and TSH pulsatility is predominantly regulated through dopamine D-2 receptors at the pituitary level, and through D-1 receptors at the hypothalamic level, respectively.     

Dopamine affects basal and augmented pituitary hormone secretion.

Although the role of the neurotransmitter, dopamine (DA), in the regulation of PRL has been well documented, controversy exists regarding its participation in the regulation of the other pituitary hormones. Consequently, we infused DA into six healthy male subjects (ages 19-32) and studied its effects on both basal pituitary hormone levels and augmented hormonal release induced by insulin hypoglycemia (ITT), TRH, and gonadotropin-releasing hormone (GnRH). DA alone produced a modest though significant increase in GH concentration from 2.2 +/- 0.5 to 11.9 +/- 3.7 ng/ml (P less than 0.05) by 60 min, but the peak incremental GH response to ITT was significantly inhibited by DA (43.5 +/- 5.0 vs. 16.3 +/- 3.3 ng/ml; P less than 0.01). PRL concentrations fell during the DA infusion (20.4 +/- 3.0 to 10.6 +/- 1.5 ng/ml; P less than 0.02) at 235 min, and the PRL responses to both ITT and TRH were completely abolished. Although the basal LH and FSH concentrations were unaffected by DA, the incremental LH response to GnRH was inhibited (45.5 +/- 10.6 to 24.4 +/- 5.4 mIU/ml; P less than 0.05), while the FSH response was unchanged. DA significantly reduced the basal TSH concentration from 3.9 +/- 0.2 to 2.5 +/- 0.2 micro U/ml (P less than 0.01) at 230 min and blunted the peak incremental TSH response to TRH (6.0 +/- 1.5 vs. 2.9 +/- 0.9 microU/ml; P less than 0.01). DA had no effect on basal cortisol levels, the cortisol response to ITT, basal plasma glucose, or the degree of hypoglycemia after ITT. Our data provide new evidence that DA has an inhibitory as well as a stimulatory role in the regulation of GH secretion in normal humans. It inhibits centrally as well as peripherally mediated PRL secretion and blunts the LH response to GnRH. In addition, DA lowers both basal and TRH-mediated TSH release, confirming the reports of other investigators.     

Pituitary stimulation by combined administration of four hypothalamic releasing hormones in normal men and patients

Ten normal young men (22-28 yr of age), within 10% of their ideal body weight, were given the four releasing hormones (TRH, 200 micrograms; GnRH, 100 micrograms; ovine corticotropin-releasing hormone, 50 micrograms; GH-releasing hormone, 80 micrograms) iv on separate days and then in combination on the same day. Plasma TSH, PRL, FSH, LH, cortisol, ACTH, and GH were measured by RIA in samples collected from 20 min before to 120 min after injection. There were no significant differences in responses to the separate and combined tests for FSH, LH, cortisol, ACTH, and GH. The plasma TSH (0.001 less than P less than 0.01) and PRL (P less than 0.001) responses were significantly higher after the combined test. The tolerance was identical to that of TRH alone. In eight patients studied after pituitary surgery, combined administration provided results comparable to those obtained after separate administration of TRH, GnRH, and insulin.     

Dopaminergic inhibition of glycoprotein hormone alpha-subunit in normal subjects.

The pituitary glycoprotein hormones thyrotropin (TSH), luteinizing hormone (LH), and follicle-stimulating hormone (FSH) consist of two noncovalently linked subunits, alpha and beta. In addition to producing intact hormone, the pituitary releases free alpha-subunit, which is stimulated by gonadotropin-releasing hormone (GnRH) and thyrotropin-releasing hormone (TRH). However, little is known about the dopaminergic regulation of free alpha-subunit in vivo. The effect of dopamine (DA), metoclopramide (MTC), and the specific DA D-1 receptor agonist, fenoldopam, on circulating alpha-subunit levels was studied in normal men and women. Normal women received 4-hour infusions of either glucose (n = 6) or DA at rates of 0.04 (n = 6), 0.4 (n = 6), and 4.0 micrograms/kg.min (n = 6). After 3 hours, 10 mg MTC was administered intravenously (IV). The high dose of DA significantly lowered alpha-subunit levels (P less than .05). No response to MTC was observed in any of the groups. Six women received glucose or DA infusion (4.0 micrograms/kg.min) for 18 hours. DA significantly reduced basal alpha-subunit levels compared with control infusion (P less than .05). MTC administration after 17 hours induced a significant increase in alpha-subunit levels on the day of DA infusion compared with control (P less than .05). In a third study, nine normal males received fenoldopam (0.5 microgram/kg.min) or placebo infusions for 4 hours. Fenoldopam did not affect basal alpha-subunit levels, but the alpha-subunit response to a GnRH/TRH bolus was significantly increased during fenoldopam compared with control (P less than .05). The results suggest that alpha-subunit release may be modulated by the dopaminergic system in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)     

Divergent influences of the structurally dissimilar calcium entry blockers, diltiazem and verapamil, on thyrotropin- and gonadotropin-releasing hormone-stimulated anterior pituitary hormone secretion in man

We have tested the influence of a new calcium ion channel antagonist, diltiazem, on hypothalamic releasing hormone-stimulated secretion of LH and other anterior pituitary hormones in man. To this end, six normal men received a continuous infusion of GnRH (1 microgram/min) and TRH (2 micrograms/min) for 3 h under three different experimental conditions: 1) saline (control) infusion; 2) iv diltiazem (0.3 mg/kg bolus dose, and 0.002 mg/kg . min) infusion for 4 h beginning 1 h before releasing hormone injection; and 3) oral diltiazem (60 mg, every 6 h) administration for 1 week before pituitary stimulation. Blood was sampled at 10-min intervals for the subsequent immunoassay of LH, FSH, TSH, PRL, and GH concentrations and at hourly intervals for the assay of plasma diltiazem concentrations by high performance liquid chromatography. Despite sustained plasma diltiazem concentrations of 80-120 ng/ml during either iv or oral drug administration, the GnRH/TRH-stimulated release of LH, FSH, TSH, and PRL or the basal secretion of GH did not differ significantly from that during saline infusion. In contrast, when these subjects underwent the same infusion schedule using a structurally dissimilar calcium influx blocker, verapamil (5-mg bolus dose and 15 mg/h, continuous infusion), there was significant suppression of the delayed component of GnRH/TRH-stimulated LH release, with simultaneous enhancement of PRL secretion. We conclude that exogenously stimulated anterior pituitary hormone secretion in man exhibits differential susceptibility to the structurally discrete calcium entry blockers diltiazem and verapamil. Moreover, the differential influence of these two calcium ion channel antagonists on gonadotropes is distinct from that described in cardiac and smooth muscle cells.     

Neuroendocrine aberrations in women with functional hypothalamic amenorrhea

To further elucidate the neuroendocrine regulation of anterior pituitary function in women with functional hypothalamic amenorrhea (FHA), we measured serum LH, FSH, cortisol, GH, PRL, TSH concentrations simultaneously at frequent intervals for 24 h in 10 women with FHA and in 10 normal women in the early follicular phase (NC). Using the same data, we separately analyzed the cortisol-PRL responses to meals in these women. In addition, the pituitary responses to the simultaneous administration of GnRH, CRH, GHRH, and TRH were assessed in 6 FHA and 6 normal women. The 24-h secretory pattern of each hormone except TSH was altered in the women with FHA. Compared to normal women, the women with FHA had a 53% reduction in LH pulse frequency (P less than 0.0001) and an increase in the mean LH interpulse interval (P less than 0.01); LH pulse amplitude was similar. The 24-h integrated LH and FSH concentrations were reduced 30% (P = 0.01) and 19% (P less than 0.05), respectively. The mean cortisol pulse frequency, amplitude, interpulse interval, and duration were similar in the two groups, but integrated 24-h cortisol secretion was 17% higher in the women with FHA (P less than 0.05). This increase was greatest from 0800-1600 h, but also was present from 2400-0800 h. Cortisol levels were similar in the two groups from 1600-2400 h, resulting in an amplified circadian excursion. In contrast, the 24-h serum PRL levels were markedly lower at all times (P less than 0.0001), the sleep-associated nocturnal elevation of PRL was proportionately greater (P less than 0.05), and serum GH levels were increased at night in the women with FHA (P less than 0.05). Although 24-h serum TSH levels were similar at all times, T3 (P less than 0.05) and T4 (P less than 0.01) levels were lower in the FHA women. The responses of serum cortisol to lunch (P less than 0.01) and dinner (P less than 0.05) and those of serum PRL to lunch (P less than 0.05) and dinner (P = 0.08) were blunted in the women with FHA. Pituitary hormone increments in response to the simultaneous iv administration of GnRH, CRH, GHRH, and TRH were similar in the two groups, except for a blunted PRL response to TRH in the women with FHA (P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Pituitary function in patients with newly diagnosed untreated systemic lupus erythematosus

OBJECTIVES: To determine whether hormonal dysfunction involving the hypothalamic-pituitary-adrenal (HPA) axis, prolactin (PRL) secretion, and sex hormone status contribute to development of systemic lupus erythematosus (SLE). METHODS: 11 patients with SLE and 9 healthy controls were tested for their total anterior pituitary gland reserve by simultaneous injection of corticotropin-, growth hormone- (GH), thyrotropin-, and gonadotropin-releasing hormone (GnRH). Serum concentrations of adrenocorticotropin (ACTH), cortisol, GH, thyroid stimulating hormone (TSH), PRL, luteinising hormone (LH), and follicle stimulating hormone (FSH) were measured at baseline and after injection. Baseline values of oestradiol, testosterone, and thyroxine were determined. RESULTS: Basal and stimulated serum concentrations of ACTH, cortisol, GH, and PRL were similar in both groups. In contrast, despite similar basal thyroxine levels the TSH response to TRH was significantly higher in patients than in controls. LH and FSH levels in premenopausal female patients of both groups were identical. In contrast, two of the three male patients were hypogonadal without compensatory increases of basal LH and FSH levels, but they retained excessive stimulatory capacity in response to GnRH. CONCLUSION: No significant alteration of the HPA axis was found in patients with SLE, which is inadequate in view of the continuing inflammation. GH and PRL secretion were normal. The pituitary-thyroid and pituitary-gonadal axes were affected in patients with newly diagnosed, untreated SLE.     

Naloxone increases the frequency of pulsatile luteinizing hormone secretion in women with hyperprolactinemia

The ability to change the frequency and amplitude of pulsatile GnRH secretion may be an important mechanism in maintaining regular ovulatory cycles. Hyperprolactinemia is associated with anovulation and slow frequency LH (GnRH) secretion in women. To assess whether the slow frequency of LH (GnRH) secretion is due to increased opioid activity, we examined the effect of naloxone infusions in eight amenorrheic hyperprolactinemic women (mean +/- SE, serum PRL, 160 +/- 59 micrograms/L). After a baseline period, either saline or naloxone was infused for 8 h on separate days, and LH was measured in blood obtained at 15-min intervals. Additional samples were obtained for plasma FSH, PRL, estradiol, and progesterone. Responses to exogenous GnRH were assessed at the end of the infusions. LH pulse frequency increased in all subjects from a mean of 4.0 +/- 0.5 pulses/10 h (mean +/- SE) during saline infusion to 8.0 +/- 1.0 pulses/10 h during naloxone infusion (P less than 0.01). LH pulse amplitude did not change, and mean plasma LH increased from 7.4 +/- 0.8 IU/L (+/- SE) to 11.2 +/- 1.5 IU/L during naloxone (P less than 0.01). A small but significant increase was seen in mean plasma FSH. Plasma PRL, estradiol, and progesterone were unchanged by naloxone infusion. These data suggest that elevated serum PRL reduces the frequency of LH (GnRH) secretion by increasing hypothalamic opioid activity and suggest that the anovulation in hyperprolactinemia is consequent upon persistent slow frequency LH (GnRH) secretion.     

Divergent influences of calcium ions on releasing factor-stimulated anterior pituitary hormone secretion in normal man

To investigate the influence of calcium ions on the secretion of anterior pituitary hormones in response to stimulation by exogenous hypothalmic releasing factors in man, we measured serum concentrations of pituitary hormones serially during a continuous infusion of combined TRH (2 micrograms/min) and GnRH (1 microgram/min), with concomitant iv saline or calcium administration. Compared to saline, calcium administration was associated with a significant increase in GnRH-TRH-stimulated LH and FSH release and a corresponding rise in serum testosterone concentrations. The effect of calcium ions on gonadotropin secretion was specific, because releasing factor-stimulated secretion of TSH and PRL was suppressed by hypercalcemia. Serum concentrations of GH were not significantly altered under these conditions. In summary, the present results provide the first in vivo evidence that acute infusion of calcium ions augments GnRH-TRH-stimulated secretion of LH and FSH, with an accompanying increase in serum testosterone levels. In contrast, hypercalcemia did not alter serum GH concentrations, and it suppressed GnRH-TRH-stimulated release of PRL and TSH. We conclude that calcium ions can selectively influence releasing factor-stimulated secretion of certain anterior pituitary hormones in man.     

Evidence for a thyrotropin inhibitory effect of histamine in man.

Because of certain side effects of cimetidine therapy which may be hormonally mediated (e.g. gynecomastia), there has been recent interest in the possible endocrine effects of this H2 histamine receptor-blocking agent used in the treatment of peptic ulcer disease. Accordingly, the effect of chronic cimetidine therapy on anterior pituitary function was examined in 12 adult men with mild peptic ulcer disease. TRH and insulin-hypolycemic stimulation tests were performed by standard methods. Serum for TSH and PRL RIA was obtained after TRH; serum for GH, cortisol, and PRL RIA was obtained after insulin-induced hypoglycemia. In addition, serum for LH, FSH, testosterone, and PRL was obtained every 4 h for 24 h. After these baseline studies, 300 mg cimetidine were administered orally 4 times a day for 4--8 weeks and the studies were repeated as before. Chronic treatment with cimetidine caused a significant increase in the peak TSH response to TRH at 30 min (mean peak TSH value before cimetidine, 7.0 microU/ml; after cimetidine, 10.2 microU/ml; P less than 0.05) as well as a significant increase in the TSH area under the curve. There was no statistically significant effect of cimetidine on basal TSH or basal or stimulated PRL secretion. Cimetidine had no effect on the GH, PRL, or cortisol response to insulin-induced hypolycemia or the 24-h secretion of LH, FSH, testosterone, or PRL.     

PITUITARY FUNCTION IN ISOLATED GONADOTROPHIN DEFICIENCY

Hypothalamic-pituitary function was assessed in 24 individuals with isolated gonadotrophin deficiency (IGD). Thirteen had normal olfaction (Group I) while 11 (Group II) had anosmia (Kallmann's syndrome). In response to a 10 micrograms intravenous (i.v.) bolus of GnRH, the minimal dose required to evoke a consistent gonadotrophin response in normal subjects, the patients responded with significant LH and FSH increases over baseline (P less than 0.01). In Group II patients, large doses (150 micrograms) of GnRH, which elicit maximal release of gonadotrophin in normal subjects did not increase gonadotrophin release beyond that produced by a 10 micrograms bolus. In response to two 10 micrograms GnRH doses, at times 0 and 120 min, the IGD patients responded with similar LH increases to both boluses (both P less than 0.01 compared to baseline). The maximal PRL responses to arginine infusion and to TRH in the male patients were similar to those of normal males. However, in the IGD females, the PRL response to TRH was less than in normal females. The TSH responses to TRH in IGD males and females were similar to each other and similar to normal. The IGD male GH response to arginine infusion was comparable to that in normal males. We conclude that (1) IGD patients appear to retain minimal endogenous GnRH secretion so that the IGD pituitary responds to a minimal dose of GnRH without priming; (2) IGD is a heterogeneous syndrome in which affected individuals with and without normal olfaction represent parts of the spectrum of the same disease; and (3) except for the PRL response in females, the PRL, TSH and GH responses demonstrate that the IGD pituitaries are largely intact.     

THE EFFECT OF OXYTOCIN INFUSION ON ADENOHYPOPHYSEAL FUNCTION IN MAN

The responses of the adenohypophyseal hormones adrenocorticotrophin (ACTH), growth hormone (GH), thyroid stimulating hormone (TSH), prolactin, luteinizing hormone (LH) and follicle stimulating hormone (FSH) to sub-maximal doses of hypothalamic releasing factors were studied in six lean male volunteers (age 23-35 years) with and without infusions of oxytocin (OXT). OXT infusion (mean plasma concentration 133.6 +/- 2.6 pmol/l) completely inhibited the plasma ACTH responses to corticotrophin releasing hormone (CRH) (saline, peak increment ACTH 1.61 +/- 0.75 pmol/l; OXT, peak increment ACTH - 0.04 +/- 0.28 pmol/l; P less than 0.05). OXT infusion had no significant effect on the GH response to growth hormone releasing hormone (GHRH), the TSH and prolactin responses to thyrotrophin releasing hormone (thyroliberin, TRH) or the LH and FSH responses to gonadotrophin releasing hormone (luteoliberin, GnRH). The data support a role for OXT in the modulation of ACTH secretion in man.     

Growth hormone-releasing peptide-2 infusion synchronizes growth hormone, thyrotrophin and prolactin release in prolonged critical illness

OBJECTIVE: During prolonged critical illness, nocturnal pulsatile secretion of GH, TSH and prolactin (PRL) is uniformly reduced but remains responsive to the continuous infusion of GH secretagogues and TRH. Whether such (pertinent) secretagogues would synchronize pituitary secretion of GH, TSH and/or PRL is not known. DESIGN AND METHODS: We explored temporal coupling among GH, TSH and PRL release by calculating cross-correlation among GH, TSH and PRL serum concentration profiles in 86 time series obtained from prolonged critically ill patients by nocturnal blood sampling every 20 min for 9 h during 21-h infusions of either placebo (n=22), GHRH (1 microg/kg/h; n=10), GH-releasing peptide-2 (GHRP-2; 1 microg/kg/h; n=28), TRH (1 microg/kg/h; n=8) or combinations of these agonists (n=8). RESULTS: The normal synchrony among GH, TSH and PRL was absent during placebo delivery. Infusion of GHRP-2, but not GHRH or TRH, markedly synchronized serum profiles of GH, TSH and PRL (all P< or =0.007). After addition of GHRH and TRH to the infusion of GHRP-2, only the synchrony between GH and PRL was maintained (P=0.003 for GHRH + GHRP-2 and P=0.006 for TRH + GHRH + GHRP-2), and was more marked than with GHRP-2 infusion alone (P=0.0006 by ANOVA). CONCLUSIONS: The nocturnal GH, TSH and PRL secretory patterns during prolonged critical illness are herewith further characterized to include loss of synchrony among GH, TSH and PRL release. The synchronizing effect of an exogenous GHRP-2 drive, but not of GHRH or TRH, suggests that the presumed endogenous GHRP-like ligand may participate in the orchestration of coordinated anterior pituitary hormone release.     

The impact of euglycemia and hyperglycemia on stimulated pituitary hormone release in insulin-dependent diabetics

To study the influence of different blood glucose (BG) concentrations on the release of pituitary hormones, the effect of the simultaneous iv administration of LRH (200 micrograms), TRH (400 micrograms), and arginine (30 g/30 min) upon the serum concentrations of LH, FSH, TSH, PRL, and GH was determined in six male insulin-dependent diabetics. BG concentration was clamped by feedback control and an automated glucose-controlled insulin infusion system at euglycemic (BG 4-5 mmol/liter) or hyperglycemic (BG, 14-18 mmol/liter) levels. Increments in serum concentrations of LH, FSH, TSH, and PRL were similar in the euglycemic and hyperglycemic steady states, whereas the GH response to arginine was suppressed during the hyperglycemic clamp (P less than 0.01). Omission of exogenous insulin during hyperglycemia did not modify the observed hormonal responses. Thus, the release of LH, FSH, TSH, and PRL in response to adequate acute stimuli at the pituitary level is not modulated by hyperglycemia in insulin-dependent diabetes, while arginine-induced GH release is suppressed. Since the effect of arginine on GH is most likely mediated by an action on the hypothalamus, the data suggest that elevated glucose concentrations may exert their modulatory influence on GH secretion at the hypothalamic rather than at the pituitary level.     

Human pituitary null cell adenomas and oncocytomas in vitro: effects of adenohypophysiotropic hormones and gonadal steroids on hormone secretion and tumor cell morphology.

Human pituitary null cell adenomas and oncocytomas are not associated with evidence of excess hormone secretion in vivo; their cellular derivation has not been clarified by morphologic investigation. In this study we examined 41 null cell adenomas and 58 oncocytomas in vitro to determine hormone release and its response to several adenohypophysiotropic hormones and gonadal steroids. In vitro, 96/99 tumors released LH, FSH, and/or alpha-subunit of glycoprotein hormones. TSH was released by 11 tumors. GH, PRL, and ACTH were found in small quantities in 11, 8, and 5 tumors, respectively. Only 3 tumors released no detectable hormones. Incubations with test substances were examined at 2- and 24-h periods for up to 72 h. All but 3 of 53 tumors showed marked and persistent increases in the release of LH, FSH, and/or alpha-subunit in response to GnRH in short and long duration experiments. Secretion of LH, FSH, or alpha-subunit was stimulated to more than 150% of control by TRH in 37/48 tumors, by CRH in 10/20, by GRH in 7/20. Estradiol, progesterone, and testosterone increased release of FSH, LH, and/or alpha-subunit in 23/32, 3/12, and 3/12 tumors, respectively, and reduced their release in 6/32, 5/12, and 7/12, respectively. In tumors which showed no response to gonadal steroids, GnRH in combination with estradiol, progesterone, or testosterone yielded the same result as GnRH alone; in tumors inhibited by gonadal steroids, GnRH in combination with one of those substances reduced the response to GnRH. No secretion of GH, PRL, ACTH, or TSH was detected after incubation with GRH, estradiol, CRH, or TRH except in the tumors which initially released GH, PRL, or TSH. Ultrastructural examination of cultured cells from 15 cases revealed morphologic alterations that correlated with changes in hormone release and could be quantified by morphometry. This study represents the largest analysis of hormone production and release in vitro and morphologic correlation of clinically nonfunctioning pituitary adenomas. The responsiveness of gonadotropin secretion by null cell adenomas and oncocytomas to GnRH and gonadal steroids resembles that of gonadotroph adenomas. However, the unexpected increases in gonadotropin release attributable to several other adenohypophysiotropic hormones and the release of multiple hormones suggests that null cell adenomas and oncocytomas may represent neoplasms derived from uncommitted or committed precursor cells that can undergo differentiation towards several cell lines.     

Influence of blindness on plasma luteinizing hormone, follicle-stimulating hormone, prolactin, and testosterone levels in prepubertal boys

The aim of this study was to determine if changes in LH, FSH, PRL, and testosterone (T) secretion occur in blind prepubertal boys. Eight blind and six normal boys, aged 7-10 yr, living at an institute for blind subjects in Naples, Italy, were studied. Each had a combined GnRH (100 micrograms) and TRH (200 micrograms) test at 0800 h after nocturnal rest. Plasma LH, FSH, PRL, and T levels were measured by RIA. The blind boys had basal plasma LH, FSH, and T levels significantly lower than those in the normal boys (P less than 0.01 for all three); plasma PRL basal levels were similar to those in the normal boys. The blind boys, moreover, had lower peak LH, FSH, and PRL (P less than 0.01 for all three peaks) levels in response to GnRH-TRH. Our results, similar to those found by others in patients with delayed puberty or with hypogonadotropic hypogonadism, suggest that light stimuli influence neuroendocrine-gonadal activity in humans, as in other mammals; and in blind prepubertal boys, impaired hormone secretion could cause a delay of pubertal development or more severe hypogonadism.     

The combined administration of GH-releasing peptide-2 (GHRP-2), TRH and GnRH to men with prolonged critical illness evokes superior endocrine and metabolic effects compared to treatment with GHRP-2 alone

OBJECTIVE: Central hyposomatotrophism, hypothyroidism and hypogonadism are present concomitantly in men with prolonged critical illness. This study evaluated the impact of combined treatment with GH-releasing peptide-2 (GHRP-2), TRH and GnRH for 5 days compared with GHRP-2 + TRH and with GHRP-2 alone. PATIENTS AND DESIGN: Thirty-three men with prolonged critical illness participated at baseline compared to 50 age- and body mass index (BMI)-matched controls. Patients were randomly assigned to 5 days of placebo (n = 7), GHRP-2 (1 microg/kg/h; n = 9), GHRP-2 + TRH infusion (1 + 1 microg/kg/h; n = 9) or pulsatile GnRH (0.1 microg/kg every 90 min) together with GHRP-2 + TRH infusion (n = 8). MEASUREMENTS: GH, TSH and LH secretion were quantified by deconvolution analysis of serum concentration time series obtained by sampling every 20 min from 2100 to 0600 h at baseline and on nights 1 and 5 of treatment. Serum concentrations of IGF-I, IGFBPs, thyroid hormones, gonadal and adrenal steroids, proinflammatory cytokines and selected metabolic and inflammation markers were measured daily. RESULTS: Patients revealed suppressed pulsatile GH, TSH and LH secretion in the face of low serum concentrations of IGF-I, IGFBP-3 and the acid-labile subunit (ALS) (P < 0.0001 each), thyroid hormones (P < 0.0001) and total and estimated free testosterone (P < 0.0001) levels, whereas free oestradiol (E2) estimates were normal. Serum dehydroepiandrosterone sulphate (DHEAS) levels were also suppressed whereas morning cortisol was normal. Serum levels of type I procollagen (PICP) and bone alkaline phosphatase (sALP) were elevated whereas osteocalcin (OC) was low (P = 0.03). Ureagenesis (P < 0.0001) and breakdown of bone tissue (P < 0.0001) were increased. Baseline serum TNF-alpha, IL-6 and C-reactive protein level and white blood cell (WBC) count were elevated; serum lactate was normal. Only low T4 and high IGFBP-1 levels independently predicted mortality. GHRP-2 infusion reactivated GH secretion and normalized serum IGF-I, IGFBP-3 and ALS. GHRP-2 + TRH infusion reactivated both the GH axis and the thyroid axis, with normal levels of T4 and T3 reached within 1 day. Only GHRP-2 + TRH infusion combined with GnRH pulses reactivated the GH and TSH axis and at the same time increased pulsatile LH secretion compared to placebo. Only GnRH pulses together with GHRP-2 + TRH infusion increased testosterone significantly from day 2 (peak increase of + 312%) through day 5 and serum E2 with > 80% from day 1 through day 3 (all P = 0.05). Ureagenesis was reduced by GHRP-2 + TRH + GnRH (P = 0.01) and by GHRP-2 + TRH (P = 0.009) but not by GHRP-2 alone. Serum OC levels were increased only by GHRP-2 + TRH + GnRH (P = 0.03), with a trend for GHRP-2 + TRH (P = 0.09), but not by GHRP-2 alone. On day 5, serum lactate levels and WBC count were increased by GHRP-2 infused alone and in combination with TRH but not by GHRP-2 + TRH + GnRH. CONCLUSIONS: Coadministration of GHRP-2, TRH and GnRH reactivated the GH, TSH and LH axes in prolonged critically ill men and evoked beneficial metabolic effects which were absent with GHRP-2 infusion alone and only partially present with GHRP-2 + TRH. These data underline the importance of correcting the multiple hormonal deficits in patients with prolonged critical illness to counteract the hypercatabolic state.     

Effects of starvation in rats on serum levels of follicle stimulating hormone, luteinizing hormone, thyrotropin, growth hormone and prolactin; response to LH-releasing hormone and thyrotropin-releasing hormone.

Adult male Sprague-Dawley rats averaging 300 g each were subjected to complete food removal for 7 days (acutely starved), 7 days complete food removal followed by 2 weeks of 1/4 ad libitum food intake (chronically strved), 7 days complete food removal and 2 weeks of 1/4 ad libitum intake followed by ad libitum feeding for 7 days (refed), or fed ad libitum throughout (controls). Serum LH, FSH, TSH, PRL, and GH levels were measured by radioimmunoassays for each group of rats. The in vivo response to the combination of synthetic LHRH and TRH also was tested in each group of rats. Circulating LH, TSH, GH, and PRL were significantly depressed in acutely and chronically starved rats, and FSH was lowered only in acutely starved rats. After 7 days of refeeding, serum levels of LH and FSH were significantly greater than in ad libitum fed controls, PRL returned to control levels, and TSH and GH increased but were still below control levels. After LHRH + TRH injection serum LH and TSH were increased significantly in all groups of rats, FSH and PRL rose in acutely but not in chronically starved rats, and GH was not elevated in any group. The increases in serum LH, FSH, TSH and prolactin in response to LHRH + TRH injection in acutely or chronically starved rats were equal to or greater than in the ad libitum fed controls. These data indicate that severe reductions in food intake result in decreased release of at least 5 anterior pituitary hormones, and this is due primarily to reduced hypothalamic stimulation rather than to inability of the pituitary to secrete hormones.     

Acute effects of alcohol on anterior pituitary secretion of the tropic hormones.

The plasma or serum concentrations of GH, TSH, LH, PRL, testosterone, cortisol, T4, and T3, and the values of the T3 uptake test were monitored in 12 healthy male volunteers for a period of 20 h after administration of one large dose of ethanol (1.5 g/kg BW). The effects of TRH and LRH on the secretion of TSH, PRL, and LH were studied in these subjects once during the period of acute alcohol intoxication (4 h after the start of drinking) and once during the hangover period (14 h after the start of drinking). Each subject served as his own control by drinking water only during another experimental session. Alcohol had no significant effect on basal concentrations of GH, TSH, LH, T4, T3, or testosterone. The concentration of cortisol in plasma was elevated during the whole 20-h period after ingestion of alcohol, as compared with the control values. Alcohol also did not significantly alter the effects of TRH and LRH on plasma TSH and LH levels at 4 and 14 h. During the hangover period, the PRL response to TRH was totally blocked, but during alcohol intoxication, there was a slight increase in the PRL response to TRH. The lack of response of PRL to TRH during the hangover suggests that withdrawal symptoms are associated with increased dopaminergic activity in the hypothalamus.     

Multiple abnormalities of anterior pituitary hormone secretion in association with pseudohypoparathyroidism

A male with pseudohypoparathyroidism presented with several hormonal abnormalities. He was clinically euthyroid with no palpable goiter, His serum T4, total T3, T3 Sephadex retention, and 131I uptake were normal. However, elevated basal TSH levels and exaggerated TSH responses to TRH which normalized during the administration of thyroid extract suggested reduced thyroidal reserve. Despite these finding the 131I uptake increased after exogeneous TSH, and the T3 level rose after TRH. Basal testosterone levels and response to hCG were normal however, gonadotropins were elevated and there was an exaggerated response after LRH treatment. Both LH and FSH levels were suppressed by testosterone propionate. The patient demonstrated intermittent basal hyperprolactinemia and impaired PRL responsiveness after metolopramide, chlorpromazine, and insulin administration. There was, however, an intact response to TRH. Basal PRL, TSH, and LH levels decreased after the administration of L-dopa and bromocriptine. Although the precise mechanism underlying these finding is unknown, the elevated basal levels of TSH, LH, and FSH and the exaggerated responses to their respective releasing hormones suggest the presence of partial degree of end-organ resistance to these pituitary trophic hormones. Together with the resistance to PTH, this may imply a common defect, presumably at a postreceptor level. However, hyporesponsiveness of PRL to metoclopramide and chlorpromazine and normal responsiveness to TRH suggest that an abnormality of dopamine tone also exists in pseudohypoparathyroidism.