Putative somatostatin suppression potentiates adrenocorticotropin secretion driven by ghrelin and human corticotropin-releasing hormone

CONTEXT: Ghrelin is a 28-amino-acid Ser(3)-octanoylated peptide, and CRH is a 41-amino-acid peptide, both of which stimulate ACTH secretion. In principle, actions of these agonists could be subject to inhibitory modulation by hypothalamic somatostatin (SS). OBJECTIVE: Our objective was to test the hypothesis that endogenous SS restrains ghrelin and CRH-stimulated ACTH secretion, thereby linking all three, ghrelin, CRH, and SS, with ACTH secretion. DESIGN AND SETTING: We conducted a randomized, double-blind, placebo-controlled, crossover interventional study at an academic medical center. PARTICIPANTS: Ten healthy postmenopausal women participated in the study. INTERVENTIONS: Interventions included iv injection of saline, ghrelin, human CRH, or both after an infusion of saline vs. l-arginine to putatively inhibit SS outflow (eight visits per subject). OUTCOME MEASURES: ACTH concentrations quantified by repetitive blood sampling and immunochemiluminometry. RESULTS: Infusion of ghrelin induced peak ACTH concentrations [median (range)] of 21 (17-28) compared with 16 (11-20) ng/liter after saline (P = 0.037). CRH and l-arginine infusion evoked ACTH peaks of 23 (14-48) and 31 (21-286) ng/liter, respectively (P = 0.037 and P = 0.005 vs. saline). l-Arginine enhanced stimulation by ghrelin by 1.43-fold (P = 0.028) and that by CRH by 1.91-fold (P = 0.005). Triple stimulation with ghrelin, CRH, and l-arginine potentiated the effect of combined ghrelin/CRH by 1.45-fold (P = 0.028). Downstream cortisol responses mimicked those of ACTH but were time delayed. CONCLUSIONS: The present outcomes indicate that the peptide ensemble comprising ghrelin, CRH, and SS (inferred by l-arginine infusion) can regulate ACTH and cortisol secretion in healthy adults.     

Involvement of corticotropin-releasing factor and somatostatin in stress-induced inhibition of growth hormone secretion in the rat

Corticotropin-releasing factor (CRF), which is released into the pituitary portal blood during exposure to noxious stimuli, can act centrally to inhibit GH secretion. We have investigated a possible role of endogenous CRF in mediating the stress-induced inhibition of GH release in the rat. While exposure to electroshocks markedly lowered plasma GH levels measured 20 min later, the central administration of the CRF antagonist alpha-Hel CRF-(9-41) totally abolished the effect of stress. To examine possible mechanisms through which CRF might mediate the inhibitory action of various stimuli on GH secretion, we have administered antisomatostatin (anti-SS) serum to CRF-injected rats and observed that immunoneutralization of endogenous SS blocked the inhibitory action of CRF on basal plasma GH values. Additionally, we have shown that CRF acted centrally to prevent the stimulatory action of both exogenously administered GH-releasing factor and the endogenous GH-releasing factor released by morphine sulfate. These effects were abolished by previous treatment with anti-SS serum. Such observations support the hypothesis that in the rat, endogenous CRF mediates the inhibitory action of noxious stimuli on GH secretion and further suggest that this effect may involve an increased release of endogenous SS.     

Influence of human corticotropin-releasing hormone and adrenocorticotropin upon spontaneous growth hormone secretion.

Hormones of the hypothalamo-pituitary-adrenocortical (HPA-) axis are considered to be of physiological and clinical relevance in regulating spontaneous growth hormone (GH) secretion. To further investigate interdependencies between both systems, we studied the effects of adrenocorticotropin [ACTH(1-24)] and human corticotropin-releasing hormone (h-CRH) upon spontaneous GH secretion in 10 male volunteers. Administration of 1 microgram ACTH (1-24), 10 micrograms h-CRH or saline (control: CTL) every hour from 9.00 to 6.00 p.m. resulted in significant differences of cortisol secretion during the entire observation period (8.00 a.m.-3.00 a.m.) between the three groups (p less than 0.001, Friedman two-way ANOVA). Mean area under the time course curve (AUC) values (+/- SEM) for cortisol expressed as ng x 1,000 x min/ml showed also significant differences between the three treatments from 8.00 a.m. to 3.00 a.m.: CTL 64.0 +/- 6.4, ACTH(1-24) 178.5 +/- 9.4 (p less than 0.01, Wilcoxon test), h-CRH 88.5 +/- 5.6 (p less than 0.01). The main portion of cortisol was released during daytime from 8.00 a.m. to 11.00 p.m., where the most significant differences in the AUC values emerged: CTL 59.6 +/- 5.8, ACTH(1-24) 171.5 +/- 8.8 (p less than 0.01, Wilcoxon test), h-CRH 80.2 +/- 5.1 (p less than 0.01). With regard to GH secretion, significant differences became obvious between the three treatments during daytime from 8.00 a.m. to 11.00 p.m. and the sleep-related period from 11.00 p.m. to 3.00 a.m. (p less than 0.01 and p less than 0.02, Friedman two-way ANOVA).(ABSTRACT TRUNCATED AT 250 WORDS)     

Arginine stimulates growth hormone secretion by suppressing endogenous somatostatin secretion

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

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.     

Involvement of hypothalamic somatostatin in the suppression of growth hormone secretion by central corticotropin-releasing factor in conscious male rats

The role of central corticotropin-releasing factor (CRF) in the regulation growth hormone (GH) secretion was studied in freely moving conscious male rats with indwelling intra-atrial and intracerebroventricular (i.c.v.) cannulae. GH measurements in blood samples obtained every 20 min from 10.00 to 14.00 h in control animals injected with saline either intravenously (i.v.) or into the lateral cerebral ventricle revealed that spontaneous GH secretion was pulsatile, and occurred regularly at around 12.00 h. When ovine CRF (10 micrograms) was injected i.c.v., spontaneous GH secretion was inhibited (mean plasma GH [11.20-13.00 h]: 20 +/- 7 ng/ml vs. control: 126 +/- 22 ng/ml, p less than 0.01). In contrast, the intravenous injection of CRF (10 micrograms) did not affect spontaneous GH secretion (mean plasma GH [11.20-13.00 h]: 162 +/- 25 ng/ml vs. control: 193 +/- 31 ng/ml). This GH suppressive action of central CRF was blocked by the i.v. injection (0.5 ml) of antisomatostatin serum (AS), but not of normal sheep serum (NS), (mean plasma GH [11.20-13.00 h]: NS + CRF: 15 +/- 2 ng/ml vs. AS + CRF: 202 +/- 30 ng/ml, p less than 0.01). The mean plasma GH value [11.20-13.00 h] in animals receiving AS and CRF was not significantly different from those in animals receiving saline (i.v.) together with AS. These results suggest a potential inhibitory role of central CRF in the regulation of spontaneous GH secretion in the rat which is mediated by the stimulation of hypothalamic somatostatin.     

Intrahypothalamic actions of somatostatin and growth hormone releasing factor on growth hormone secretion

Possible effects of GRF on somatostatin neurons and of somatostatin on GRF neurons were examined by measuring the effects of localised intracerebral injections of these peptides on growth hormone (GH) secretion. Serial GH concentrations were measured in plasma in unanaesthetized male rats chronically prepared with venous and intracerebral cannulae, before and after treatment with bilateral intracerebral injections of somatostatin or GRF in the preoptic anterior hypothalamic area (PO/AHA) and medial basal hypothalamus. Injections of 0.1 and 1 nmol of GRF in medial basal hypothalamus or 10 nmol somatostatin in the PO/AHA, respectively, had stimulatory or inhibitory effects on GH, which were assumed to be due to diffusion of the peptide from the injection site to the median eminence and pituitary gland. Injection of lower doses of somatostatin around GRF neurons in the medial basal hypothalamus were without significant effect on secretion of GH, but 0.1 nmol somatostatin in the PO/AHA resulted in an increase in GH concentrations from 128 +/- 61 to 524 +/- 103 ng/ml, p less than 0.02. Injections of GRF in lower doses amongst somatostatin neurons in the PO/AH or amongst GRF neurons in the medial basal hypothalamus were both without effect on GH secretion. We conclude that somatostatin may stimulate GH secretion by an effect on or close to somatostatin neurons in the PO/AHA. Somatostatin, though present in terminals on GRF neurons, is without effect at this site in our model. Furthermore, we have been unable to demonstrate any significant intrahypothalamic effect of GRF on GH regulation.     

Prolonged inhibition of growth hormone secretion by peripheral injection of bombesin is mediated by somatostatin in the rat

Peripherally injected bombesin inhibits GH secretion in conscious, freely moving rats and in sodium pentobarbital-anesthetized rats. This inhibition of GH secretion is unusually prolonged, lasting up to 90 min after a single ip injection. The duration of inhibition of GH secretion by bombesin is greater than that observed for somatostatin (SRIF) in the same bioassay. The inhibition of GH release occurs concomitantly with stimulation of gastrin release and is independent of stimulatory effects of bombesin on plasma glucose. The structurally related mammalian gastrin-releasing peptide also inhibits GH secretion in the pentobarbital-anesthetized rat after peripheral injection. Peripherally administered bombesin blocks GH-releasing factor stimulation of GH secretion. Prior treatment of pentobarbital-anesthetized rats with SRIF-specific anti-serum blocks the inhibitory effect of bombesin on GH secretion. No effect of bombesin on GH secretion was observed in primary cultures of rat anterior pituitary cells. These data suggest that peripherally administered bombesin stimulates SRIF secretion, most probably of hypothalamic origin, which, in turn, inhibits pituitary secretion of GH. This sensitivity of the hypothalamus to a peripherally rather than centrally administered peptide has important mechanistic and therapeutic implications.     

Differential inhibition of growth hormone secretion by analogs selective for somatostatin receptor subtypes 2 and 5 in human growth-hormone-secreting adenoma cells in vitro

Somatostatin (SRIH), a cyclic tetradecapeptide hormone originally isolated from mammalian hypothalamus, is a potent suppressor of pituitary growth hormone (GH) secretion. SRIH acts through a family of G-protein-coupled membrane receptors containing seven transmembrane domains. Five genes encoding distinct SRIH receptor (SSTR) subtypes have so far been cloned in human and other species and termed SSTR1-5. In human somatotrophe pituitary adenomas GH secretion is controlled by both SSTR2 and SSTR5. However, in clinical practice only somatostatin analogs selective for SSTR2 (octreotide and lanreotide) are available. This may explain why clinical and in vitro responses to these analogs in acromegaly are only partial. In this study, we investigated the inhibitory effect of two new SRIH analogs with high selectivity for SSTR2 (NC-4-28B) and SSTR5 (BIM-23268) and compared it to that of native somatostatin (SRIH-14) on a large number of GH-secreting adenomas obtained by transphenoidal neurosurgery. Tissues from 16 adenomas were enzymatically dispersed and plated in 24-well dishes at 50,000 cells/well. After 3 days, groups of three wells were incubated for 4 h with medium alone, SRIH-14 or analogs NC-4-28B or BIM-23268, at the concentrations of 0.01, 0.1 and 1 microM. Our results show that 9 out of 16 adenomas were responsive (GH suppression: 20-40% vs. control, p < 0.05) to SRIH. In this group only 4 adenomas showed similar responses to both selective analogs, with 2 nonresponders (expression of other SRIH receptor subtypes) and 2 responders (concomitant expression of SSTR2 and SSTR5) to both analogs. GH release was selectively inhibited by NC-4-28B in 3 adenomas and by BIM-23268 in the remaining 2 adenomas, suggesting predominant expression of SSTR2 and SSTR5, respectively. SRIH failed to inhibit GH release in 7 adenomas (43%). Interestingly, in that group a better inhibitory effect was obtained with BIM-23268 (5 out of 7 adenomas) than with NC-4-28B, suggesting expression of a few SSTR5 receptors only, or of both SSTR2 and SSTR5, respectively. We conclude that the availability of somatostatin analogs selective for SSTR5 will enhance the treatment potency and spectrum in acromegaly.     

Ghrelin and growth hormone secretagogues (GHS): modulation of growth hormone secretion and therapeutic applications

Growth hormone-releasing hormone (GHRH) and somatostatin modulate growth hormone (GH) secretion. A third mechanism was discovered in the last decade, involving the action of growth hormone secretagogues (GHS). Ghrelin, the endogenous ligand of the GHS-receptor, is an acylated peptide mainly produced by the stomach, but also synthesized in the hypothalamus. This compound increases both GH release and food intake. Endogenous ghrelin might amplify the basic pattern of GH secretion, optimizing somatotroph responsiveness to GHRH, activating multiple interdependent intracellular pathways. However, its main site of action is the hypothalamus. In the current paper it is reviewed the available data on the discovery of this peptide, the mechanisms of action and possible physiological roles of the GHS and ghrelin on GH secretion, and finally, the possible therapeutic applications of these compounds.     

Regulation of growth hormone and thyrotropin secretion by somatostatin systems in rat brain

Somatostatin inhibits growth hormone (GH) and thyrotropin (TSH) secretion in the rat. Previous studies have shown that small discrete lesions of the periventricular hypothalamic (PV) and medial-basal amygdaloid (AMG) nuclei, which contain high concentrations of somatostatin neurons, reduce somatostatin-like immunoreactivity (SLI) in the median eminence (ME) by approximately two thirds and one third, respectively. The present study assessed the function of the PV and AMG somatostatin systems in the regulation of basal episodic GH and TSH secretion. Three experiments were performed in freely behaving, chronically cannulated adult male rats. In experiment 1, bilateral electrolytic lesions (20 mC) were placed in the PV at the level of the paraventricular nucleus. In experiment 2, bilateral thermal lesions (55 degrees C X 1 min) were placed in the AMG. In experiment 3, thermal lesions were placed in both the PV and AMG (PV/AMG). Blood samples were removed from animals every 15 min for 5.5 h 14-21 days postoperatively. The ME was microdissected for determination of SLI content. PV, AMG and PV/AMG lesions reduced ME SLI by 59, 26, and 91%, respectively. PV or AMG lesions had no effect on the amplitude or frequency of GH secretory peaks, GH trough levels or the total amount of GH secreted, whereas combined PV/AMG lesions reduced GH peak levels. Lesions of the AMG caused a 34% increase in mean plasma TSH levels, while PV or PV/AMG lesions reduced TSH. The latter effect was probably caused by damage to thyrotropin-releasing hormone neurons and/or axons, which are also located in the PV region. These results suggest that PV and AMG somatostatin systems may not have a significant role in the regulation of basal episodic GH secretion and the putative AMG somatostatin system exerts a significant inhibitory influence on TSH secretion.     

Inhibition of the acetylcholine-induced secretion of bovine growth hormone by somatostatin.

The effects of calcium deprivation, somatostatin and verapamil on the stimulation of growth-hormone release and the alteration of pituitary metabolism in response to acetylcholine were investigated. Calcium deprivation decreased the rises in growth-hormone secretion and in cyclic GMP content in response to 25 μM acetylcholine but did not prevent the increased incorporation of ³²P into phosphatidyl inositol. Somatostatin (1 μg/ml) prevented the rise in growth-hormone secretion and inhibited the efflux of ⁴⁵Ca in response to acetylcholine (25 μM) but did not modify the increase in cyclic GMP content or phosphatidyl inositol labelling. Verapamil (50 μM) did not affect any of the responses to acetylcholine (25 μM). The data suggest that acetylcholine stimulates calcium mobilization from tissue stores and that somatostatin can prevent this mobilization. The relevance of this to the inhibition of secretion by somatostatin is discussed.     

Estradiol potentiates ghrelin-stimulated pulsatile growth hormone secretion in postmenopausal women

CONTEXT: Ghrelin and an estrogen-rich milieu individually amplify pulsatile GH secretion by increasing the amount of hormone released per burst. However, how these distinct agonists interact in controlling pulsatile GH output is not known. OBJECTIVE: The objective of the study was to test the hypothesis that elevated estradiol (E(2)) concentrations potentiate hypothalamo-pituitary responses to a near-physiological ghrelin stimulus. DESIGN: This was a double-blind, placebo-controlled, prospectively randomized, parallel-cohort study. SETTING: The study was conducted at an academic medical center. SUBJECTS: Twenty-one postmenopausal women participated in the study. INTERVENTIONS: Eleven subjects received placebo (Pl) and 10 others E(2) transdermally in escalating doses over 3 wk to mimic late follicular-phase E(2) concentrations. Saline or a submaximally stimulatory amount of ghrelin (0.3 microg/kg) was infused iv on separate randomly ordered mornings fasting after 17-21 d of Pl or E(2) administration. OUTCOMES: Outcomes included serum concentrations of E(2), ghrelin, GH, IGF-I, IGF binding protein (IGFBP)-1 and IGFBP-3, and the estimated mass and waveform of stimulated GH secretory bursts. RESULTS: Administration of E(2) yielded late follicular-phase E(2) concentrations. Compared with Pl, E(2) did not alter ghrelin concentrations but reduced IGF-I and IGFBP-3 and elevated IGFBP-1 concentrations. Compared with saline, ghrelin infusion amplified pulsatile GH secretion by 7.1-fold (P < 0.01). The effect of E(2) alone was 2.0-fold placebo and that of combined ghrelin/E(2) 10.4-fold (P < 0.01). Ghrelin and E(2) accelerated initial GH release individually but nonadditively by more than 2-fold (P < 0.01). CONCLUSIONS: Estrogen augments ghrelin's near-physiological stimulation of pulsatile GH secretion and mimics ghrelin's acceleration of initial GH release. Thus, we hypothesize that estrogen and a GH secretagogue act via independent as well as convergent mechanisms.     

Ghrelin secretion is inhibited by either somatostatin or cortistatin in humans

Ghrelin possesses endocrine and non-endocrine actions mediated by the GH Secretagogue (GHS)-Receptors (GHS-R). The regulation of ghrelin secretion is still largely unknown. Somatostatin (SRIF) modulates central and gastroenteropancreatic hormonal secretions and functions. SRIF actions are partially shared by cortistatin (CST), a natural SRIF analogue, that binds all SRIF receptors and also GHS-R. Herein, we studied the effects of SRIF-14 or CST-14 (2.0 micro g/kg/h i.v. over 120 min) and of placebo on ghrelin, GH, insulin, glucagon and glucose levels in 6 normal young men. Placebo unaffected GH, insulin, glucagon, glucose and ghrelin levels. SRIF and CST similarly inhibited (p < 0.05) spontaneous GH secretion of about 90%. After SRIF or CST withdrawal, GH levels recovered to baseline levels. Both SRIF and CST similarly inhibited (p<0.01) insulin secretion of about 45%. In both sessions, after SRIF or CST withdrawal, insulin overrode baseline levels. Both SRIF and CST similarly inhibited (p < 0.01) glucagon levels of about 40%. After SRIF or CST withdrawal, glucagon persisted lower (p < 0.05) than at baseline. Neither SRIF nor CST modified glucose levels. Both SRIF and CST similarly inhibited (p < 0.01) circulating ghrelin levels of about 55%. Ghrelin levels progressively decreased from time +15 min, reaching the nadir at 120 and 105 min for SRIF and CST, respectively. Even 30 min after SRIF or CST withdrawal, ghrelin levels persisted lower (p < 0.05) than those at baseline. In conclusion, this study first shows that SRIF and CST strongly inhibits ghrelin secretion that, differently from GH and insulin secretion, persists inhibited even after stopping the infusion of SRIF or CST.     

Suppression of rat and human growth hormone and prolactin secretion by a novel somatostatin/dopaminergic chimeric ligand

As cotreatment of somatostatin (SRIF) and dopamine (DA) agonists reduces GH in acromegaly more effectively than either agonist alone, SRIF and DA receptors (SSTR and DAR) may interact with enhanced functional activity. The selective SSTR2 agonist, BIM-23023 (50% effective dose, 0.42), and the DAR2 agonist, BIM-53097 (50% effective dose, 22.1), dose- dependently inhibited GH secretion in cultured primary rat and human fetal as well as in human pituitary tumor cells derived from GH-secreting adenomas. The combination of individual SSTR2 and DAR2 agonists was additive for suppressing GH secretion in both rat and human pituitary cells. BIM-23A387 is a chimeric compound that contains structural elements of both SRIF and DA in a single molecule and retains potent, selective binding to DAR2 and SSTR2. BIM-23A387 (50% effective dose, 0.16 for SSTR2 and 24.5 for DAR2), displayed similar efficacy in suppressing GH secretion from rat pituitary cells as the combination of the two individual agonists. In contrast, the chimeric molecule was more potent than individual selective analogs in suppressing GH secretion by human fetal pituitary and GH-secreting adenoma cells (P < 0.05). Although the DAR2 antagonist, sulpiride, reversed BIM-23A387-induced GH suppression, blockade of SSTR2 by the selective SSTR antagonist, BIM-23454, did not block BIM-23A387-suppressed GH secretion. These results indicate that mechanisms by which the chimeric molecule suppresses pituitary GH secretion may not be mediated by individual SSTR2 or DAR2 signaling, respectively. Functional interaction of the two receptors may explain the clinical observation that more effective GH suppression is achieved when DAR2 and SSTR2 agonists are administered in combination. The SRIF/DA chimeric molecule, BIM-23A387, represents a novel tool for effective drug treatment of acromegaly and for prolactinomas otherwise resistant to dopaminergic therapy.     

The stimulation of growth hormone release by ACTH and its inhibition by somatostatin.

The rapid injection of 0.5 or 1.0 mg of tetracosacitid (Synacthen?) was followed by a distinct increase of plasma growth hormone (GH) within 30 or 45 min in 5 of 7 normal volunteers. A second control test was performed in 3 of the 5 "responders" and 1 "non-responder" and showed a consistent reaction in all of them. The tests were then repeated in the 5 "responders" during an infusion of somatostatin (150 mug/h) and the GH response was totally abolished (3 subjects) or markedly reduced (2 subjects). Thus the ACTH induced GH release behaves in a manner similar to most other physiological or pharmacological stimuli of GH release. The cortisol output after ACTH was not altered by somatostatin.     

Functional association of somatostatin receptor subtypes 2 and 5 in inhibiting human growth hormone secretion

We previously demonstrated that somatostatin (SRIF)-induced inhibition of GH secretion from human pituitary cells is mediated through both the SRIF receptor (SSTR) 2 and 5 subtypes. The interplay between these two SSTR subtypes in regulating GH was therefore tested in primary human fetal pituitary cultures (18-30 wk gestation). GHRH (10 nM)-stimulated GH secretion (51% increase, P < 0.05) was suppressed equally by either SSTR2 or SSTR5-selective agonists (10 nM). GH suppression correlated with agonist affinity for their respective receptor subtypes. Combined addition of SSTR2- and SSTR5-specific agonists was synergistic for GH suppression, achieving 73% (P < 0.05) inhibition as compared with inhibition attained with SSTR2 (32%) and SSTR5 (34%) agonists used alone (P < 0.05). The SSTR2 selective antagonist BIM-23454 dose-dependently blocked SSTR2 but not SSTR5-induced suppression of GH secretion. BIM-23454 also completely reversed GH suppression in response to the combined activation of SSTR2 and SSTR5. The IC(50) for BIM-23454 reversal of agonist-induced GH suppression was 55 nM and 33 nM for two SSTR2 agonists, 45 nM and 40 nM for the combination of SSTR2 and SSTR5 agonists, respectively, and 45 nM for the SSTR2/SSTR5 agonist BIM-23244, all of which were similar to the affinity of BIM-23454 for SSTR2 (32 nM). These results suggest the following: 1) activation of both SSTR2 and SSTR5 induces a functional association of receptor subtypes, resulting in synergistic GH suppression; 2) BIM-23454 is a potent SSTR2-selective antagonist capable of reversing SRIF-induced GH suppression; and 3) the ability of a selective SSTR2 antagonist to inhibit the GH suppressing action of SSTR2 agonist alone, SSTR2/SSTR5 biselective agonists, or SSTR2 and SSTR5 agonists in combination support the concept of a functional interaction between somatotroph SSTR2 and SSTR5 subtypes in primary human fetal pituitary cells.