The role of endogenous growth hormone-releasing hormone in acromegaly.

CONTEXT: Some indirect evidence suggests hypothalamic control of GH secretion in acromegaly. OBJECTIVE: The objective of the study is to examine whether GH secretion in acromegaly is dependent on endogenous GHRH. PATIENTS AND STUDY DESIGN: We studied eight patients with untreated acromegaly due to a GH-producing pituitary tumor. All patients received an iv infusion of normal saline for 24 h and GHRH-antagonist (GHRH-ant) at 50 microg/kg x h for 7 d. GH was measured every 10 min for 24 h during the normal saline infusion and on the last day of the GHRH-ant infusion. A group of nine different patients with untreated acromegaly served as the control group and underwent blood sampling for GH every 10 min for two 24-h periods to assess the day-to-day variability of GH secretion. SETTING: The study was set in a university referral center. MAIN OUTCOME MEASURE: Twenty-four-hour mean GH was the main outcome measured. RESULTS: In six of eight subjects treated with GHRH-ant, 24-h mean GH decreased by 5.8-30.0% during iv GHRH-ant and, in three subjects, the change in the 24-h mean GH was greater than the upper limit of the 95% confidence interval of the spontaneous day-to-day variability of the mean GH in patients with acromegaly. Based on the binomial distribution, the probability of this magnitude of change to occur in three of eight subjects by chance alone is 0.0008. CONCLUSION: In some patients with acromegaly due to a pituitary adenoma, GH secretion is under partial control by endogenous GHRH.

Role of endogenous ghrelin in growth hormone secretion, appetite regulation and metabolism.

Ghrelin, a 28-amino acid hormone that is acylated post-translation, is the endogenous ligand for the growth hormone (GH) secretagogue (GHS) receptor (GHS-R). The highest concentrations of ghrelin are found in the stomach; however ghrelin peptide is also present in hypothalamic nuclei known to be important in the control of GH and feeding behavior. Exogenous ghrelin potently stimulates pituitary GH release through a mechanism that is dependent, in part, on endogenous GH-releasing hormone. Whether endogenous ghrelin plays a role in the control of GH secretion and growth is not clear and ghrelin deficient animals appear to grow normally. In contrast, experimental animal and clinical data suggest that abnormalities in GHS-R signaling could impact growth. Ghrelin or other GHS are clinically useful for GH-testing and limited data suggest that they might be useful in the treatment of some patients with GH deficiency. Substantial data have implicated ghrelin as an important regulator of feeding behavior and energy equilibrium. Ghrelin has a potent orexigenic effect in both animals and humans and this effect is mediated through hypothalamic neuropeptide Y (NPY) and Agouti-related peptide (AgRP). Appetite simulation coupled with other metabolic effects promotes weight gain during chronic treatment with ghrelin. These metabolic effects are in part mediated through an increase in respiratory quotient (VQ). Presence of ghrelin appears to be necessary for the development of obesity in some animal models. Whether abnormalities in ghrelin signaling are involved in human obesity is not yet known.

The pattern of growth hormone secretion during the menstrual cycle in normal and depressed women.

OBJECTIVE: Major depression is associated to altered hypothalamic-pituitary function. Stress is linked to elevated cortisol as well as menstrual cycle disturbance; however, there is no known relationship between depression and menstrual cycle disruption. The aim of this study was to investigate changes of growth hormone (GH) secretion during the menstrual cycle in normal and depressed women. DESIGN: Case-control study. PATIENTS AND METHODS: Nineteen women affected with depression and 24 normal controls were included. The two groups had comparable body mass index (BMI), and age (29.4 +/- 9.8 vs. 28.6 +/- 9.7 years). Nine depressed and 10 controls were studied in the follicular phase, while 10 depressed and 14 controls were studied in the luteal phase of the cycle. GH was sampled every 10 min for 24 h, and the data were analysed by the cluster pulse detection method. RESULTS: There was no difference in 24-h mean GH concentrations between depressed and control subjects (P = 0.93), even after accounting for menstrual cycle phase (P = 0.38). GH pulse frequency was higher during the follicular phase of the cycle (P = 0.032), and nocturnal GH was higher in the follicular phase of the cycle (P = 0.05, and after adjusting for 24-h GH, P = 0.0138) regardless of whether the subjects were depressed or healthy. CONCLUSIONS: In studies of GH secretion in women with or without depression, it is necessary to control for the phase of menstrual cycle.

Clinically silent somatotropinomas may be biochemically active.

The diagnosis of acromegaly is suspected based on the typical clinical presentation and is subsequently confirmed biochemically by elevated GH and IGF-I concentrations. We report three female patients with pituitary tumors who presented without any signs or symptoms of acromegaly but with elevated IGF-I levels. Plasma GH was measured every 10 min for 24 h, and an oral glucose tolerance test was performed. All patients had abnormally elevated mean and trough plasma GH levels as well as post-glucose nadir GH concentrations. All patients had magnetic resonance imaging scans revealing pituitary tumors and underwent transsphenoidal surgery. Histologically, they had GH-producing pituitary tumors. Plasma IGF-I levels returned to normal in two patients after surgery. Some pituitary adenomas are true GH-secreting tumors despite not being accompanied by obvious clinical stigmata of acromegaly. Natural history of this disease is unknown because of the small number of reported patients and inconsistent results of biochemical testing. Based on the results of this and previous reports, we propose that all patients with known pituitary tumors, especially younger women with normal or mildly elevated prolactin level, be evaluated for GH excess.

Raloxifene decreases serum IGF-I in male patients with active acromegaly.

OBJECTIVE: Most patients with acromegaly require additional treatments after trans-sphenoidal surgery. Although traditional methods of treatment aim at suppressing GH hypersecretion from the pituitary tumor, recent studies on the use of the GH receptor antagonist have shown that targeting the action of GH on peripheral tissues may be more effective. Estrogens and the selective estrogen receptor modulator tamoxifen have been used previously to suppress circulating IGF-I levels in patients with acromegaly. Positive effects of raloxifene in women with active acromegaly have been reported recently. This study was designed to examine the potential role of raloxifene in the treatment of acromegaly in male patients. DESIGN: We studied eight men with active acromegaly despite the fact that they were receiving traditional treatments. All subjects were treated with raloxifene (60 mg twice a day) for a median of 5 weeks. METHODS: The effects of raloxifene on GH secretion were assessed by obtaining 24-h GH profiles and studying the response of GH to various stimuli before and after treatment with raloxifene. Serum IGF-I was measured before and after raloxifene treatment. RESULTS: Raloxifene did not affect basal GH secretion or response of GH to TRH, GHRH or glucose, but it decreased circulating IGF-I by 16+/-4% (P=0.001), and normalized plasma IGF-I in two patients. No changes in clinical parameters were observed. Prolactin levels, the prolactin response to TRH and free testosterone levels remained unchanged. Raloxifene was well tolerated. CONCLUSION: Raloxifene might be useful in the treatment of male patients with active acromegaly, but longer term studies are clearly needed.

Sexual dimorphism of growth hormone (GH) regulation in humans: endogenous GH-releasing hormone maintains basal GH in women but not in men.

GH secretory patterns in humans are sexually dimorphic in terms of pulse regularity, amplitude of the diurnal rhythm, and magnitude of basal (trough) secretion. The neuroendocrine mechanisms of gender-specific GH regulation in humans are currently unknown, but the interpulse GH levels are generally assumed to be controlled by somatostatin. In rats, however, administration of antiserum to GHRH lowers GH interpulse levels in females but not males. In this study, using a competitive antagonist to GHRH in humans, we investigated whether endogenous GHRH has differential, gender-specific effects on the interpulse GH levels. Six healthy men and five healthy women (20-28 yr old) who were nonobese, did not smoke, and were on no medications known to influence GH secretion were studied. Each served as his or her own control during an infusion of GHRH antagonist or saline for a 27-h period. A control bolus of GHRH was given near the end of the infusion. In both sexes during GHRH antagonist infusion, mean GH, pulse amplitude, and GH response to GHRH decreased significantly, whereas pulse frequency remained unchanged. However, during the GHRH antagonist infusion, trough GH did not significantly change in men (P = 0.54) but significantly decreased in women (P = 0.008). Deconvolution analysis confirmed the lack of a significant change in basal secretion in men (P = 0.81) as opposed to women (P = 0.006). We conclude that sexual dimorphism in the neuroendocrine regulation of GH secretion in humans involves a differential role of endogenous GHRH in maintaining baseline GH.

Troglitazone induces CYP3A4 activity leading to falsely abnormal dexamethasone suppression test.

After evaluating a patient who appeared to have a falsely abnormal response to the dexamethasone suppression test while taking troglitazone, we examined the effects of troglitazone on the activity of hepatic CYP3A4 and the screening tests for Cushing's syndrome. We studied five healthy women and three healthy men, aged 25 +/- 2 yr, before and after treatment with troglitazone (600 mg daily) for 28 d. Baseline 0800 h cortisol and corticosterone were similar before and after troglitazone treatment. Before troglitazone treatment, all subjects suppressed 0800 h cortisol below 1.8 micro g/dl (mean, 0.66 +/- 0.08 micro g/dl) during the 1-mg overnight dexamethasone suppression test (DST), whereas during troglitazone treatment none of the subjects suppressed 0800 h cortisol below 1.8 micro g/dl (mean, 9.0 +/- 1.8 micro g/dl). Serum dexamethasone levels decreased by 66 +/- 4%, and the erythromycin breath test measurements increased by 27 +/- 8%, indicating increased CYP3A4 activity during troglitazone treatment. The hydrocortisone suppression test (HST) was performed by administering 50 mg hydrocortisone at 2300 h. Using the criterion of suppression of 0800 h plasma corticosterone by more than 50%, the specificity of the HST was 100% both before and after troglitazone treatment. In conclusion, troglitazone induced the activity of CYP3A4 leading to falsely abnormal DST. HST is a useful alternative to the DST in patients taking medications that increase the activity of CYP3A4.

Ghrelin secretion in humans is sexually dimorphic, suppressed by somatostatin, and not affected by the ambient growth hormone levels.

We studied plasma ghrelin and GH concentrations over a 24-h period in young healthy men and women and in patients with acromegaly. Healthy subjects were restudied after administration of GH-lowering agents, octreotide or GHRH antagonist. Ghrelin concentrations in women studied during the late follicular stage of the cycle were about 3-fold higher than in men. Suppression of GH secretion by GHRH antagonist did not alter ghrelin concentration profiles. In the presence of high GH levels (acromegaly), ghrelin levels were similar to those found in healthy men. Administration of somatostatin analog octreotide suppressed both GH and ghrelin concentration profiles. We conclude that: 1) ghrelin secretion is sexually dimorphic in humans, with women in the late follicular stage having higher levels than men; 2) ghrelin secretion is suppressed by somatostatin; and 3) GH has no influence over ghrelin secretion.

Pulsatile and nocturnal growth hormone secretions in men do not require periodic declines of somatostatin.

Using a continuous subcutaneous octreotide infusion to create constant supraphysiological somatostatinergic tone, we have previously shown that growth hormone (GH) pulse generation in women is independent of endogenous somatostatin (SRIH) declines. Generalization of these results to men is problematic, because GH regulation is sexually dimorphic. We have therefore studied nine healthy young men (age 26 +/- 6 yr, body mass index 23.3 +/- 1.2 kg/m2) during normal saline and octreotide infusion (8.4 microg/h) that provided stable plasma octreotide levels (764.5 +/- 11.6 pg/ml). GH was measured in blood samples obtained every 10 min for 24 h. Octreotide suppressed 24-h mean GH by 52 +/- 13% (P = 0.016), GH pulse amplitude by 47 +/- 12% (P = 0.012), and trough GH by 39 +/- 12% (P = 0.030), whereas GH pulse frequency and the diurnal rhythm of GH secretion remained essentially unchanged. The response of GH to GH-releasing hormone (GHRH) was suppressed by 38 +/- 15% (P = 0.012), but the GH response to GH-releasing peptide-2 was unaffected. We conclude that, in men as in women, declines in hypothalamic SRIH secretion are not required for pulse generation and are not the cause of the nocturnal augmentation of GH secretion. We propose that GH pulses are driven primarily by GHRH, whereas ghrelin might be responsible for the diurnal rhythm of GH.

Acromegaly with apparently normal GH secretion: implications for diagnosis and follow-up.

The biochemical diagnosis of acromegaly is conventionally based on elevated plasma GH levels that fail to suppress after an oral glucose load. We studied 16 newly diagnosed patients with acromegaly with normal mean plasma GH but elevated age and gender-adjusted plasma IGF-I concentrations (476 +/- 29 microg/liter, mean +/- SE). Plasma GH was sampled every 10 min for 24 h, and an oral glucose tolerance test was performed. The control group included 46 healthy subjects. All patients had 24-h mean GH values that overlapped with those of the healthy controls. Mean plasma GH was less than 2.5 microg/liter in 12 patients. Patients had higher 24-h nadir GH values than healthy controls (P < 0.001). During the oral glucose tolerance test, nadir plasma GH was less than 1 micro g/liter in eight patients. Plasma IGF-I normalized in 11 of 14 patients after transsphenoidal surgery. Four patients with normal IGF-I after transsphenoidal surgery were restudied. Mean and nadir GH decreased in all of them. In our experience in many patients with acromegaly, the diagnosis could be missed if only the existing GH-based criteria are used. Revised GH criteria in combination with plasma IGF-I should be used for the diagnosis and follow-up of acromegaly.