Octreotide suppresses both growth hormone (GH) and GH-releasing hormone (GHRH) in acromegaly due to ectopic GHRH secretion

Two patients with acromegaly secondary to ectopic GHRH secretion by metastatic carcinoid tumors were studied before and during therapy with the somatostatin analog octreotide (SMS 201-995). GH and GHRH secretory patterns were assessed during intermittent sc administration, continuous sc infusion (CSI), and continuous iv infusion of octreotide. Octreotide reduced serum GH and plasma GHRH levels in the two patients, although there was differential sensitivity of GH and GHRH. Intermittent sc therapy transiently lowered serum GH in both patients. A higher iv dose was required to reduce plasma GHRH by 50% than to reduce serum GH by 50% (2.0 vs. 0.05 micrograms/kg.h, respectively; patient 1). A similar pattern was found during CSI octreotide administration in the same patient. Chronic therapy with intermittent sc and CSI octreotide was assessed by serial 24-h profiles of GH and GHRH secretion in patient 2. Mean hourly serum GH levels decreased from a pretreatment level of 31.5 +/- 3.5 (+/- SE) to 9.5 +/- 1.5 micrograms/L during CSI therapy (1000 micrograms/day or 0.40 micrograms/kg.h). In contrast, plasma GHRH levels were less effectively suppressed. The mean serum GH levels and the variation in hourly GH values were reduced to a greater extent with CSI than with intermittent sc therapy. Serum insulin-like growth factor I also declined from 5.9 x 10(3) to 2.5 x 10(3) U/L during chronic CSI therapy (patient 2). CSI therapy with octreotide can be more effective than intermittent sc therapy in controlling GH excess in the rare syndrome of ectopic GHRH secretion, although serum GH may not decline to normal.     

The pulsatile GH secretion in acromegaly: Hypothalamic or pituitary origin?*

OBJECTIVE: We studied the effects of different modes of octreotide therapy on the pulsatile pattern of GH release in an attempt to define better its regulation by growth hormone-releasing hormone (GHRH) and somatostatin and its effects on IGF-I plasma levels in acromegaly. DESIGN: In six acromegalic patients not cured by previous treatment we compared the 24-hour GH secretion profiles under basal conditions with subcutaneous (s.c.) bolus injections of 100 micrograms octreotide every 8 hours and with continuous s.c. infusions of the same daily dose. Blood samples were taken every 10 minutes over 24 hours followed by a GHRH test (100 micrograms GHRH i.v.) with blood sampling every 15 minutes for another 2 hours. After a 4-week interval all patients were treated either by the bolus or continuous mode of octreotide application in a randomized cross-over design. On day 4 of treatment blood sampling and GHRH test were repeated. Octreotide treatment was withdrawn for another 4 weeks; all patients then received the alternate application mode and were measured under similar conditions. MEASUREMENTS: Serum GH and plasma IGF-I concentrations were analysed by serial array averaging. IGF-I levels were measured in two different assays with and without previous protein extraction. For GH pulse detection three different algorithms (Cluster, Pulsar, Desade) were applied. RESULTS: With both treatments, the initially elevated basal 24-hour mean serum GH concentrations (58.0 +/- 9.7 mU/l mean +/- SEM) decreased significantly (bolus: 11.5 +/- 4.9 mU/l, P < 0.001 vs basal; continuous infusion: 7.6 +/- 1.9 mU/l, P < 0.001 vs basal) after 4 days. GH suppression was significantly more pronounced following continuous infusion than bolus (P < 0.05). IGF-I plasma concentrations were lowered significantly (P < 0.05) with both forms of treatment which did not differ between themselves. Bolus and continuous infusion treatment significantly inhibited (P < 0.05) the amplitudes of pulsatile GH release, but did not change the pulse frequency. In two of the patients, GHRH stimulation did not increase GH serum levels suggesting a constitutive activation of adenylyl cyclase. CONCLUSION: Continuous subcutaneous octreotide treatment in acromegaly suppresses mean GH levels better than bolus injection. The number of GH pulses remains unaffected by both modes of treatment providing evidence against a somatostatinergic mechanism of pulsatile GH secretion in these patients. The unchanged frequency of pulsatile GH release in the patients unresponsive to exogenous GHRH indicates that this pattern might be independent of hypothalamic GHRH and somatostatin and suggests a pituitary-derived mechanism for GH pulse generation in acromegaly.     

The somatostatin analog octreotide inhibits the secretion of growth hormone (GH)-releasing hormone, thyrotropin, and GH in man

The effects of the somatostatin analog octreotide on plasma GH, TSH, and immunoreactive GH-releasing hormone (IR-GHRH) were studied in 10 normal men. After morning sc administration of 50 or 100 micrograms octreotide or placebo, plasma GH, TSH and GHRH were measured frequently for 6 h. Plasma GH or IR-GHRH concentrations did not change after placebo injection, but plasma TSH levels gradually decreased, in conformity with a circadian rhythm during the morning. The mean plasma GH levels after sc injection of 50 or 100 micrograms octreotide declined, and no spontaneous GH pulses occurred for 5 h. Plasma TSH decreased rapidly after both doses of octreotide and was significantly lower than the level after placebo treatment from 90-315 min (P less than 0.05) and 60-360 min (P less than 0.05 or P less than 0.01), respectively. Plasma IR-GHRH levels also were significantly lower from 30-360 min (P less than 0.05) in the group given 100 micrograms octreotide compared with the value in the placebo group. We conclude that octreotide inhibits not only GH and TSH secretion from the pituitary, but also GHRH release from the hypothalamus and/or peripheral tissues. These findings suggest that somatostatin controls GH secretion not only by suppressing pituitary secretion of GH but also by suppressing GHRH release from the hypothalamus.     

Serum ghrelin levels in acromegaly: effects of surgical and long-acting octreotide therapy

The orexigenic peptide, ghrelin, is regulated by acute and chronic nutritional state. Although exogenously administered ghrelin stimulates pituitary GH secretion, little is known about the role of ghrelin in endogenous GH secretion or how high GH and IGF-I levels in acromegaly could affect ghrelin secretion and vice versa. Therefore, we evaluated fasting and post oral glucose tolerance test serum ghrelin levels in 19 patients with active acromegaly at baseline and after either surgery in 9 of these or administration of long-acting octreotide (Sandostatin LAR) in the other 10 patients. After surgical cure, fasting ghrelin rose from 312 +/- 56 pg/ml to 548 +/- 97 pg/ml (P = 0.013). Fasting serum ghrelin levels were higher in all patients after surgery and ranged between 112% and 349% of presurgery levels. Ghrelin levels fell significantly during long-acting octreotide therapy from 447 +/- 34 pg/ml to 206 +/- 15 pg/ml (P < 0.0001); ghrelin levels on octreotide ranged between 26% and 70% of baseline levels. Serum ghrelin levels were suppressed significantly during the oral glucose tolerance test in both groups. Pretherapy ghrelin levels correlated negatively with serum insulin levels (r = -0.494; P = 0.03) and insulin resistance as estimated by the homeostasis model assessment score (r = -0.573; P = 0.01). In patients without diabetes mellitus, serum insulin levels in the surgical group were 19.7 +/- 5.4 microU/ml before surgery and fell to 9.7 +/- 0.93 microU/ml after surgery (P = 0.05); levels in the octreotide group were 13.9 +/- 2.8 microU/ml before and fell to 11.2 +/- 2.8 microU/ml on octreotide (P = 0.03). Pretherapy ghrelin levels did not correlate with weight or body mass index, but after therapy in the surgery group ghrelin correlated negatively with weight (r = -0.823, P = 0.012) as has been demonstrated by others in healthy subjects. Ghrelin secretion is dysregulated in active acromegaly; lowered serum levels of ghrelin in active acromegaly rise along with the postsurgery normalization of GH and IGF-I and improved insulin resistance. In contrast to surgical therapy, long-acting octreotide therapy persistently suppressed serum ghrelin levels. It remains to be determined whether altered circulating ghrelin concentrations could impact on body composition changes in acromegaly.     

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.     

Ghrelin immunoreactivity in human plasma is suppressed by somatostatin

OBJECTIVE: Ghrelin was recently identified as a specific endogenous ligand for the growth hormone secretagogue receptor (GHS-R). This new hormone was isolated from rat and human stomach and was reported to circulate in human plasma, but the regulation and physiological significance of ghrelin in humans have not been clarified. The present study was undertaken to test the following hypotheses: (1) prolonged fasting, which is known to stimulate GH secretion, is associated with changes in ghrelin immunoreactivity; (2) somatostatin in the systemic circulation regulates ghrelin secretion; and (3) GH affects ghrelin levels. DESIGN AND PATIENTS: The study population included normal subjects investigated on three occasions (fasting alone, fasting and somatostatin infusion +/- GH); GH-deficient adults investigated after 12 and 36 h of fasting +/- GH, as well as patients with active acromegaly before and after somatostatin analogue treatment. RESULTS: Somatostatin infusion lowered ghrelin levels 70-80% (P < 0.0001), whereas continued fasting +/- GH did not significantly affect ghrelin levels. In active acromegaly, suppression of plasma ghrelin levels was recorded after a single subcutaneous octreotide injection as well as during prolonged administration of slow-release octreotide. CONCLUSIONS: (1) Amplification of GH release during prolonged fasting is not caused by an increase in ghrelin immunoreactivity, (2) systemic somatostatin suppresses plasma ghrelin levels independently of GH status, and (3) the feasibility of measuring ghrelin in the circulation provides an opportunity for studying the interaction between hormones and nutrition.     

Acromegaly due to ectopic growth hormone (GH)-releasing hormone (GHRH) production: dynamic studies of GH and ectopic GHRH secretion

Dynamic studies of GH and GH-releasing hormone (GHRH) secretion were performed in a man with a GHRH-producing carcinoid tumor and acromegaly. Insulin hypoglycemia stimulated and metoclopramide inhibited both GH and GHRH acutely. Bromocriptine suppressed GH both acutely and chronically without altering circulating GHRH levels and also blunted the GH response to exogenous GHRH. TRH acutely stimulated GH, but not GHRH, secretion, and iv bolus doses of synthetic GHRH-(1-40) stimulated GH release acutely. Somatostatin infusion decreased both GH and GHRH concentrations and blunted the GH responses to TRH and GHRH-(1-40). We conclude that prolonged exposure of the pituitary gland to high concentrations of GHRH is associated with chronic GH hypersecretion and may be accompanied by a preserved acute GH response to exogenous GHRH; a paradoxical response of GH to TRH may be mediated at the pituitary level, consequent to prolonged pituitary exposure to GHRH; bromocriptine suppression of GH in acromegaly is due to a direct pituitary effect of the drug; and somatostatin inhibits both ectopic GHRH secretion as well as GH responsiveness to GHRH in vivo. Since GH secretory responses in patients with somatotroph adenomas are similar to those in this patient, augmented GHRH secretion may play a role in development of the "classic" form of acromegaly.     

Hypersecretion of growth hormone and prolactin in McCune-Albright syndrome

Acromegaly and hyperprolactinemia have been reported in association with the McCune-Albright syndrome, but the pathophysiology of the GH and PRL hypersecretion that occurs in patients with this disorder has not been defined. We studied GH and PRL secretory dynamics in three patients with McCune-Albright syndrome and hypersecretion of these hormones. Each patient had excessive linear growth, glucose-non-suppressible plasma GH concentration, and GH responsiveness to TRH and GHRH. In response to exogenous GHRH, plasma GH concentrations rose approximately 2-fold in all three patients. Plasma GHRH levels were 20-40 ng/L (normal, less than 30). Study of the spontaneous GH secretory pattern in two patients indicated nocturnal augmentation of GH release. Bromocriptine therapy failed to reduce plasma GH in all patients; in one patient treatment with octreotide, a long-acting somatostatin analog, partially suppressed plasma GH and insulin-like growth factor I levels. These results suggest that hypersecretion of GH in the McCune-Albright syndrome is not due to ectopic GHRH production or autonomous somatotroph function. The results are similar to those described in classic acromegaly due to GH-secreting pituitary tumors. However, the lack of radiographic pituitary enlargement, the variable pituitary pathology reported in similar patients, and frequent concordance of GH and PRL excess suggest that the pathogenesis of this disorder may differ fundamentally from other forms of acromegaly or gigantism. The pathophysiology may reflect abnormal hypothalamic regulation and/or an embryological defect in pituitary cellular differentiation and function.     

Acromegaly due to ectopic growth hormone-releasing hormone secretion by a bronchial carcinoid tumour. Dynamic hormonal responses to various stimuli.

Ectopic GHRH is a relatively uncommon cause of acromegaly, which should be differentiated from pituitary adenoma, in order to avoid damage to the pituitary gland from unnecessary interventions. We report here on a 66-year-old man with acromegaly due to a GHRH-secreting bronchial carcinoid tumour, who recovered completely following removal of the tumour. His hormonal status was studied before and after the operation. Basal GH, GHRH, IGF-I and PRL levels, as well as plasma GH response to glucose load and TRH administration were abnormal before the operation, and became normal thereafter. The somatostatin analogue SMS 201-995 was found to be a potent inhibitor of the ectopic GHRH and the GH secretion (greater than 500 to 42 ng/l and 15.4 micrograms/l to 0.8 microgram/l, respectively). The effect on GHRH proved to be due to direct effect of somatostatin on the tumour cells, as demonstrated in tissue culture studies. A mixed meal was found immediately to suppress GHRH levels without such an effect on GH secretion. We conclude that the neuroendocrine tests usually practised in acromegaly cannot differentiate between ectopic GHRH secretion and pituitary adenoma. High plasma GHRH levels may serve as a diagnostic test for excessive GHRH production, which is almost always ectopic. These high levels are suppressible by somatostatin and a mixed meal.     

Regulation of pulsatile growth hormone secretion by fasting in normal subjects and patients with acromegaly.

In acromegaly, GH hypersecretion occurs despite elevated insulin-like growth factor-I (IGF-I) levels, implying defective IGF-I feedback. To study the possible mechanisms of defective IGF-I negative feedback in acromegaly, we assessed parameters of pulsatile GH secretion during fasting-induced decrease in plasma IGF-I. Seven patients with active acromegaly and six normal controls were fasted for 6 days and GH secretory profiles were obtained by frequent (every 10 min) blood sampling for 24 h and analyzed by Cluster. Fasting resulted in similar decreases in IGF-I, body weight, and blood glucose levels, and increases in free fatty acid and beta-hydroxybutyrate in all subjects. Normal subjects showed increases in 24-h total and pulsatile GH production, GH pulse frequency, maximal pulse amplitude, interpulse and nadir levels, implying suppression of hypothalamic somatostatin secretion and increase in GH-releasing hormone (GHRH) pulse frequency. In acromegalic patients, GH (and, by inference, GHRH) pulse frequency was unchanged. Three patients had increases in GH production, interpulse, and nadir levels similar to the normals while the other four had no change or paradoxical decreases in these parameters. Percentage change in GH production was highly correlated with percentage change in interpulse and nadir levels in both normals and patients. Mean GH response to GHRH (0.33 micrograms/kg iv) did not change significantly in any group as a result of fasting. Our data suggest that in healthy humans IGF-I negative feedback on GH secretion involves suppression of GHRH pulse frequency. GH (and, by inference, GHRH) pulse frequency is resistant to decrease in IGF-I in acromegaly, suggesting that lowered sensitivity of GHRH neurons to IGF-I may be the mechanism of high GH pulse frequency in this disease.     

Time mode of growth hormone (GH) entry into the bloodstream and steady-state plasma GH concentrations, rather than sex, estradiol, or menstrual cycle stage, primarily determine the GH elimination rate in healthy young women and men.

We have investigated whether a reduced MCR of GH in women will account for their higher serum GH concentrations premenopausally compared with those in men. To this end, we directly compared the half-life (t 1/2) of GH and its volume of distribution (Vo) in 13 young men and 6 comparably aged women, each evaluated at three stages of the normal menstrual cycle (viz. the early follicular, late follicular, and midluteal phases). To estimate nonequilibrium GH kinetics, each subject received octreotide pretreatment to suppress endogenous GH release and then 3 randomly ordered iv bolus doses of recombinant human GH (1, 2, and 4 microg/kg). The resultant peak serum GH concentrations were 18 +/- 4, 36+/-8, and 70+/-9 microg/L in six women and 17+/-2, 30+/-4, and 84+/-25 microg/L in six men (P = NS, gender contrast). Corresponding Vo values were 66+/-1, 71+/-1, and 60+/-1 mL/kg in women and 69+/-1, 78+/-1, and 73+/-1 mL/kg in men (P = NS). Matching monoexponential GH t1/2 values were 7.6+/-0.3, 8.2+/-0.4, and 8.8+/-0.7 min in women and 9.8+/-0.8, 10+/-1, and 9.5+/-1 min in men (average 1.7 min longer in men). Regression analysis disclosed no relationship between serum estradiol concentrations and peak serum GH levels, GH t 1/2, or Vo. GH t 1/2 values were also invariant of menstrual cycle stage, e.g. t 1/2 values of 8.1+/-0.5, 9.1+/-1.0, and 8.1+/-0.4 min for the early follicular, late follicular, and midluteal phases, respectively. Corresponding normalized MCRs were 319+/-39 (early follicular), 340+/-48 (late follicular), and 340+/-71 (midluteal) L/m2 x day in women and 336+/-50 L/m2 x day in men (P = NS). In parallel equilibrium infusion studies in men, we administered GH by constant iv infusions for 240 min during octreotide suppression. At doses of 0.5, 1.5, and 4.5 microg/kg x min, steady state GH t 1/2 values were 9+/-1, 12+/-1, and 15+/-1 min (at respective steady state serum GH concentrations of 0.5+/-0.05, 2.1+/-0.2, and 7.5+/-0.5 microg/L). In a third analysis in the same volunteers, stopping the constant iv infusions revealed t 1/2 values of GH decay from equilibrium of 26+/-5 and 23+/-2.3 min for the two higher GH infusion rates. In a fourth paradigm, endogenous GH t 1/2 values, as assessed in the same individuals by deconvolution analysis of overnight (10-min sampled) serum GH concentration profiles, averaged 18+/-1.3 min. This value was intermediate between that of poststeady state decay and iv bolus elimination of GH. In summary, the foregoing clinical experiments in healthy men and women indicate that 1) the nonequilibrium GH t 1/2, (body surface area-normalized) Vo, and MCR are independent of GH dose, sex, menstrual cycle stage, and serum estradiol concentrations; 2) the GH t 1/2 calculated after iv bolus injection is significantly (50%) shorter than that assessed during or after steady-state GH infusions or endogenously (overnight) by deconvolution analysis; and 3) the descending rank order of GH t 1/2 values in healthy volunteers is approximately: decay from steady state (23+/-2.3 min) > endogenously secreted GH (18+/-1.3 min) > during equilibrium infusion (15+/-1 min) > after bolus infusion (9.8+/-0.8 min). We thus conclude that for any given body surface area, the elimination properties of GH in men and women reflect predominantly the time mode of hormone entry into the circulation, rather than gender, menstrual cycle stage, or prevailing serum estradiol concentration. Accordingly, differences in serum GH concentrations in premenopausal women compared to those in young men and across the normal menstrual cycle reflect commensurate differences in pituitary GH secretion rates.     

THE EFFECT OF CALCITONIN ON GROWTH HORMONE SECRETION IN ACROMEGALY

To determine whether human calcitonin inhibits GH secretion in acromegaly, as previously described for healthy subjects, the effect of an i.v. bolus injection of calcitonin or saline on GH levels in patients with active acromegaly was studied and compared to that of an i.v. bolus injection of the synthetic somatostatin analogue, octreotide. After the injection of calcitonin, GH levels decreased by 46% of initial values, whereas octreotide reduced GH levels by 87% and saline had no significant effect. Administration of calcitonin to acromegalics did not cause the transient rise in plasma PRL and TSH levels seen in normal subjects. Octreotide induced a decrease in plasma PRL in three out of seven patients. It is concluded that human calcitonin suppresses GH secretion in acromegaly, but not to normal levels; moreover the effect is less than that found for octreotide. In addition, acromegalic patients did not exhibit the PRL and TSH-releasing activity of calcitonin found in normal subjects, while octreotide inhibited PRL secretion in some acromegalic patients.     

The GH-releasing effect of ghrelin,a natural GH secretagogue,is only blunted by the infusion of exogenous somatostatin in humans

OBJECTIVE: Ghrelin, a 28-amino-acid peptide purified from the stomach and showing a unique structure with an n-octanoyl ester at the serine 3 residue, is a natural ligand of the GH secretagogue (GHS) receptor (GHS-R). Ghrelin strongly stimulates GH secretion in both animals and humans, showing a synergistic effect with GH-releasing hormone (GHRH) but no interaction with synthetic GHS. However, the activity of ghrelin as well as that of non-natural GHS is not fully specific for GH; ghrelin also induces a stimulatory effect on lactotroph and corticotroph secretion, at least in humans. DESIGN: To further clarify the mechanisms underlying the GH-releasing activity of this natural GHS, we studied the effects of somatostatin (SS, 2.0 microg/kg/h from -30 to +90 min) on the endocrine responses to ghrelin (1.0 microg/kg i.v. at 0 min) in seven normal young male volunteers [age (mean +/- SEM) 28.6 +/- 2.9 years; body mass index (BMI) 22.1 +/- 0.8 kg/m2]. In the same subjects, the effect of SS on the GH response to GHRH (1.0 microm/kg i.v. at 0 min) was also studied. MEASUREMENTS: Blood samples were taken every 15 min from -30 up to +120 min. GH levels were assayed at each time point in all sessions; PRL, ACTH and cortisol levels were assayed after ghrelin administration alone and during SS infusion. RESULTS: The GH response to ghrelin (hAUC0'-->120' 2695.0 +/- 492.6 microg min/l) was higher (P < 0.01) than that after GHRH (757.1 +/- 44.1 microg min/l). SS infusion almost abolished the GH response to GHRH (177.0 +/- 37.7 microg min/l, P < 0.01); the GH response to ghrelin was inhibited by SS (993.8 +/- 248.5 microg min/l, P < 0.01) but GH levels remained higher (P < 0.05) than with GHRH. Ghrelin induced significant increases in PRL, ACTH and cortisol levels and these responses were not modified by SS. CONCLUSIONS: Ghrelin, a natural GHS-R ligand, exerts a strong stimulatory effect on GH secretion in humans and this effect is only blunted by an exogenous somatostatin dose which almost abolishes the GH response to GHRH. The stimulatory effect of ghrelin on lactotroph and corticotroph secretion is refractory to exogenous somatostatin, indicating that these effects occur through pathways independent of somatostatinergic influence.     

Agouti-related peptide,neuropeptide Y,and somatostatin-producing neurons are targets for ghrelin actions in the rat hypothalamus

Ghrelin, the endogenous ligand of the GH secretagogue receptor, acts at central level to elicit GH release and regulate food intake. To elucidate the neural circuit that exerts its effects, we measured the expression of hypothalamic neuropeptides involved in weight regulation and GH secretion after ghrelin administration. Adult male rats, fed or fasted for 72 h, were treated centrally (intracerebroventicularly) with a single dose of ghrelin (5 micro g). After 2, 4, and 6 or 8 h, agouti-related peptide, melanin-concentrating hormone, neuropeptide Y, prepro-orexin, GHRH, and somatostatin mRNA levels were measured by in situ hybridization. We found that ghrelin increased agouti-related peptide and neuropeptide Y expression in the arcuate nucleus of the hypothalamus of fed and fasted rats. In contrast, no change was demonstrated in the mRNA levels of the other neuropeptides studied at any time evaluated. Finally, we examined the effect of ghrelin on GHRH and somatostatin mRNA levels in GH-deficient (dwarf) rats. Our results show that ghrelin increases somatostatin mRNA levels in the hypothalamus of these rats. This study furthers our understanding of the molecular basis and mechanisms involved in the effect of ghrelin on food intake and GH secretion.     

Complementary secretagogue pairs unmask prominent gender-related contrasts in mechanisms of growth hormone pulse renewal in young adults

The present study examines the thesis that pulsatile GH secretion is controlled simultaneously by three principal signals; viz., GHRH, GH-releasing peptide (GHRP, ghrelin), and somatostatin (SS). According to this ensemble notion, no single regulatory peptide acts alone or can be interpreted in isolation. Therefore, to investigate gender-specific control of pulsatile GH secretion, we designed dual-effector stimulation paradigms in eight young men and six women as follows: 1) L-arginine/GHRH (to clamp low SS and high GHRH input); 2) L-arginine/GHRP-2 (to clamp low SS and high GHRP drive); 3) GHRH/GHRP-2 (to clamp high GHRH and high GHRP feedforward); vs. 4) saline (unclamped). Statistical comparisons revealed that: 1) fasting pulsatile GH secretion was 7.6-fold higher in women than men (P < 0.001); 2) L-arginine/GHRH and L-arginine/GHRP-2 evoked, respectively, 4.6- and 2.2-fold greater burst-like GH release in women than men (P < 0.001 and P = 0.015); and 3) GHRH/GHRP-2 elicited comparable GH secretion by gender. In the combined cohorts, estradiol concentrations positively predicted responses to L-arginine/GHRP-2 (r2= 0.49, P = 0.005), whereas testosterone negatively predicted those to L-arginine/GHRH (r2= 0.56, P = 0.002). Based upon a simplified biomathematical model of three-peptide control, the current outcomes suggest that women maintain greater GHRH potency, GHRP efficacy, and opposing SS outflow than men. This inference upholds recent clinical precedence and yields valid predictions of sex differences in self-renewable GH pulsatility.     

Effect of galanin on the growth hormone response to growth hormone-releasing hormone in acromegaly.

Galanin enhances growth hormone (GH)-releasing hormone (GHRH)-stimulated GH secretion in normal man. In acromegaly, circulating GH levels are increased and the GH response to GHRH may be exaggerated. Galanin has been recently shown to decrease circulating GH levels in acromegaly. The aim of our study was to investigate the effects of galanin on the GH response to GHRH in acromegalic subjects. Five acromegalic patients (three men and two women) and seven healthy adult subjects (five men and two women) were studied. GHRH-induced GH secretion was evaluated during a 40-minute intravenous (IV) infusion of saline (100 mL) or porcine galanin (12.5 micrograms/min in 100 mL saline). In normal subjects, delta GH levels after GHRH+porcine galanin administration (47 +/- 7.5 micrograms/L) were significantly higher in comparison to levels obtained with GHRH+saline (21.7 +/- 3.5 micrograms/L, P < .05). In acromegalic patients, GH responses to GHRH (delta GH, 18.8 +/- 8.6 micrograms/L) were not altered by galanin infusion (delta GH, 17.6 +/- 5 micrograms/L). Our results give the first evidence that the same dose of galanin that induces a significant enhancement of the GH response to GHRH in normal subjects has no effect on the GH response to GHRH in acromegalic patients. It can be hypothesized that galanin may interact at the pituitary level with its own receptors expressed by somatotropes independent of GHRH. Failure of galanin to enhance GH response to GHRH in acromegalic patients could be due to a change in function of the galanin receptor on GH-secreting adenomatous cells.     

Circulating ghrelin levels are suppressed by meals and octreotide therapy in children with Prader-Willi syndrome

Prader-Willi syndrome (PWS) is characterized by severe obesity, hyperphagia, hypogonadism, and GH deficiency. Unlike individuals with common obesity, who have low fasting-plasma ghrelin concentrations, those with PWS have high fasting-ghrelin concentrations that might contribute to their hyperphagia. Treatment with octreotide, a somatostatin agonist, decreases ghrelin concentrations in healthy and acromegalic adults and induces weight loss in children with hypothalamic obesity. This pilot study was performed to determine whether octreotide administration (5 microg/kg.d) for 5-7 d lowers ghrelin concentrations and affects body composition, resting energy expenditure, and GH markers in children with PWS. Octreotide treatment decreased mean fasting plasma ghrelin concentration by 67% (P < 0.05). Meal-related ghrelin suppression (-35%; P < 0.001) was still present after intervention but was blunted (-11%; P = 0.19). Body weight, body composition, leptin, insulin, resting energy expenditure, and GH parameters did not change. However, one subject's parent noted fewer tantrums over denial of food during octreotide intervention. In conclusion, short-term octreotide treatment markedly decreased fasting ghrelin concentrations in children with PWS but did not fully ablate the normal meal-related suppression of ghrelin. Further investigation is warranted to determine whether long-term octreotide treatment causes sustained ghrelin suppression, changes eating behavior, and induces weight loss in this population.     

Ectopic acromegaly.

Ectopic acromegaly is a rare syndrome (less than 1% of acromegalic patients) caused by ectopic growth hormone-releasing hormone (GHRH) or growth hormone (GH)-producing tumors. Its recognition is clinically important because acromegaly may be a symptom of an aggressive tumor, and different therapeutic approaches are required. Most cases are caused by either extra- or intracranial GHRH-producing tumors, whereas in rare instances the underlying disease is an ectopic GH-secreting tumor. The routine evaluation of circulating GHRH in all acromegalic patients may allow its early recognition, because plasma levels greater than 0.3 ng/mL are virtually diagnostic of a GHRH-producing tumor (frequently a bronchial or pancreatic carcinoid), whereas suppressed levels may suggest an ectopic GH-producing tumor. In addition to classic imaging techniques, whole body scintiscan with labeled octreotide may help in the localization of ectopic tumors. Surgical removal of the ectopic tumor is the therapy of choice, but it is not always feasible because patients often present with widespread metastases. Patients with GHRH-induced acromegaly benefit from the administration of the long-acting somatostatin analog, octreotide, which reduces GH, IGF-I, and GHRH, and may shrink the ectopic tumor, its metastases, and the secondary pituitary enlargement.     

Acromegaly caused by growth hormone-releasing hormone-producing tumors: long-term observational studies in three patients

We report on three newly diagnosed patients with extracranial ectopic GHRH-associated acromegaly with long-term follow-up after surgery of the primary tumor. One patient with a pancreatic tumor and two parathyroid adenomas was the index case of a large kindred of MEN-I syndrome. The other two patients had a large bronchial carcinoid. The first patient is still in remission now almost 22 years after surgery. In the two other patients GHRH did not normalize completely after surgery and they are now treated with slow-release octreotide. IGF-I normalized in all patients. During medical treatment basal GH secretion remained (slightly) elevated and secretory regularity was decreased in 24 h blood sampling studies. We did not observe development of tachyphylaxis towards the drug or radiological evidence of (growing) metastases. We propose life-long suppressive therapy with somatostatin analogs in cases with persisting elevated serum GHRH concentrations after removal of the primary tumor. Independent parameters of residual disease are elevated basal (nonpulsatile) GH secretion and decreased GH secretory regularity.     

Serum leptin levels in acromegalic patients before and during somatostatin analogs therapy

GH excess is characterized by alterations of body composition such as decreased body fat mass; however, scant data are present regarding its effect on serum leptin levels. To better elucidate this topic, leptin secretion was studied in 20 acromegalic patients, before and after 6 months of treatment with somatostatin analogs (SR-lanreotide 30 mg and octreotide LAR). Basal GH, IGF-I, insulin, blood glucose and lipid levels were measured and the area under the curve (AUC) for insulin and glucose and oral glucose insulin sensitivity (OGIS) during oral glucose tolerance test (OGTT) were calculated. After 6 months of somatostatin analogs therapy, a significant reduction in GH and IGF-I plasma levels was observed (p<0.0005, both) with a significant increase of leptin levels (7.4+/-1.3 vs 13.2+/-1.6 ng/ml; p<0.05). Interestingly, the typical correlation of leptin with body mass index (BMI) was not present in active acromegaly, whereas it was restored after somatostatin analogs treatment; moreover, the gender difference in leptin secretion between men and women was preserved in active and controlled acromegaly. In conclusion, the gender-based leptin differences are preserved and leptin secretion/BMI ratio is normalized in acromegalic patients after somatostatin analogs therapy.