GHRH Release Research Articles

Growth Hormone (GH) Responses to the Hexapeptide GH-Releasing Peptide and GH-Releasing Hormone (GHRH) in the Cynomolgus Macaque: Evidence for Non-GHRH-Mediated Responses*

GH-releasing peptide (GHRP; His-D-Trp-Ala-Trp-D-Phe-Lys-NH2), a hexapeptide derived from enkephalin, has been shown to have GH-releasing activity in man and several animal species. To characterize the GHRP dose-response curve and compare it with that of GH-releasing hormone [GHRH-(1-44)NH2], six unanesthetized young adult cynomolgus macaques were tested with a range of iv doses of GHRP or GHRH in random order. Animals were fitted with vests and tethers. Blood samples were obtained before and at 15-min intervals after the administration of drugs. Doses ranged from 0.03-3 mg/kg for GHRP and from 1-30 micrograms/kg for GHRH. The dose-response curves for the two peptides were not parallel. GHRP had lower potency, but evoked a much higher peak GH response than GHRH (greater than 55 vs. 12 micrograms/L). Because one of the proposed mechanisms of action of GHRP is the inhibition of somatostatin (SS), we tested the effects of propranolol, which inhibits SS, on the GH responses to GHRH and GHRP. Propranolol was given at a dose of 14 micrograms/kg, iv, 10 min before the injection of saline, GHRH (10 micrograms/kg), or GHRP (1 mg/kg). GH responses to propranolol alone did not differ from those to placebo (peak, 6 +/- 2 vs. 8 +/- 2 micrograms/L). However, propranolol pretreatment doubled the GH responses to both GHRH and GHRP compared with those to GHRH or GHRP alone 28 +/- 5 micrograms/L vs. 14 +/- 5 (P less than 0.05) and 54 +/- 2 vs. 25 +/- 6 micrograms/L (P less than 0.001), respectively]. These results show that GHRP causes a potent dose-dependent release of GH in this primate species. Since GHRP can produce a greater maximal GH response than GHRH, mechanisms other than release of endogenous GHRH must be involved.

Growth hormone secretion in stalk-sectioned rats

Idiopathic pituitary GH deficiency appears to result from neonatal disruption of hypophyseal portal vessels in the majority of patients. To examine the mechanism of GH deficiency associated with the disease, the effect of pituitary stalk section on GH secretion was studied in rats. Adult male rats were subjected to stalk section without inserting an impermeable membrane between the cut ends. They were studied 3 to 4 weeks after surgery. In stalk-sectioned rats, pituitary weight, body weight and hypothalamic SRIH content were significantly reduced as compared with sham-operated rats. Hypothalamic GHRH content, plasma T3, T4, corticosterone and testosterone levels, and weights of testes remove and adrenal glands were comparable in the two groups. Plasma GH profiles of sham-operated rats showed characteristic periodic pulses occurring at 2.5-3 h intervals with intervening trough period. In stalk-sectioned rats, plasma GH levels were low small fluctuations, but GH levels were significantly higher than trough levels of sham-operated rats. The amount of GH secreted during a 6-h period as measured by planimetry was significantly reduced. To ascertain the regeneration of hypophyseal portal vessels, post SRIH rebound in GH secretion, which requires the presence of endogenous GHRH, was examined. Withdrawal of exogenous SRIH infusion triggered a large rebound GH secretion whose magnitude did not differ between groups. In stalk-sectioned rats, GH response to met-enkephalin analogue, FK 33-824, was not observed, whereas prolactin response to the secretagogue was observed in the majority of rats.(ABSTRACT TRUNCATED AT 250 WORDS)

On the Actions of the Growth Hormone-Releasing Hexapeptide, GHRP*

GH-releasing peptide (His-DTrp-Ala-Trp-DPhe-Lys-NH2 or GHRP) releases GH by a unique and complementary dual site of action on the hypothalamus and pituitary. These effects are mediated via non-GH-releasing hormone (non-GHRH) and nonopiate receptors in rats. Select types of opiates are known to release GH by a hypothalamic site of action, and thus, the dermorphin heptapeptide and benzomorphan opiate agonist 2549 used in this study presumably act on the hypothalamus to release GH. Neither dermorphin nor 2549 released GH or augmented the GH responses of GHRP or GHRH in vitro by a direct pituitary action, while GHRH antiserum inhibited the GH response of both dermorphin and 2549 in vivo. Evidence indicates that these opiates and GHRP administered together synergistically release GH, demonstrating the independent action(s) of GHRP and the opiates. Present data indicate that one of the major differences in the actions of dermorphin, 2549, and GHRP is the inhibition of somatostatin (SRIF) release by the opiates but not by GHRP. Although the actions of dermorphin, 2549, and GHRP on GH release are GHRH dependent, release of endogenous GHRH does not explain how GH is released synergistically by the combination of these peptides. It is proposed that dermorphin/2549 synergistically release GH with GHRP or GHRH because these opiates inhibit SRIF release. Since the GHRP plus GHRH synergistic GH release was not explained by inhibition of SRIF or stimulation of GHRH, an alternative mechanism is proposed to explain how GHRP synergistically release GH in combination with GHRH. The complementary, rather dramatic synergistic interaction of GHRP, GHRH, and dermorphin or GHRP, GHRH, and 2549 in releasing GH again strongly supports the independent actions of these compounds.

Acute Clonidine Administration Potentiates Spontaneous Diurnal, but not Nocturnal, Growth Hormone Secretion in Normal Short Children

It has been shown that alpha 2-adrenoreceptor activation induced by clonidine (CLON) increases plasma GH levels in both adults and children. In this study the effects of CLON (150 micrograms/m2, orally) on GH secretion were studied both in the morning (from 0800-1100 h) and at night (from 2300-0200 h) in nine short children previously shown to have normal spontaneous nocturnal GH secretion. In the morning, CLON induced a GH increase higher than placebo [peak (mean +/- SEM), 23.8 +/- 4.3 vs. 3.4 +/- 1.4 micrograms/L; P = 0.0001; area under curve (AUC), 624.4 +/- 62.7 vs. 135.6 +/- 33.3 micrograms/L.h; P less than 0.00001]. In the night, no difference was observed between GH secretion after CLON (peak, 15.4 +/- 3.2 micrograms/L; AUC, 562.2 +/- 57.5 micrograms/L.h) and placebo (peak, 13.1 +/- 4.7 micrograms/L; AUC, 497.2 +/- 83.5 micrograms/L.h). Spontaneous GH secretion was higher during the night than in the morning (P = 0.0001), whereas nocturnal GH secretion overlapped with that in the morning after CLON. The data presented show that alpha 2-adrenoreceptor activation is probably mediated by increased endogenous GHRH release; our results suggest that the endogenous GHRH secretion is maximally stimulated at night.

Effect of oral clonidine, insulin-induced hypoglycemia and exercise on plasma GHRH levels in short-stature children

Human growth hormone release is affected by a variety of pharmacological and physiological stimuli. We have studied the effect of oral clonidine, insulin hypoglycemia, and exercise on plasma hGH and GHRH levels in 31 healthy short-stature children. Thirteen underwent an oral clonidine test (0.15 mg/m2), 12 an iv. insulin test (0.1 U/kg), and 6 performed exercise (running for 10 min in a defined route). GHRH-1-44 was extracted from plasma on silica columns and determined by RIA. Although all three stimuli induced a marked increase in plasma hGH levels, only clonidine induced a significant increase in plasma GHRH levels. Maximal increment in GHRH during clonidine was 6.82 +/- 1.05 pmol/l (mean +/- SEM) as compared with 0.51 +/- 0.28 and 0.53 +/- 0.62 during hypoglycemia and exercise (p less than 0.0005 and p less than 0.005), respectively. An additional 24 subjects received TRH 0.2 mg/kg iv: 8 TRH alone, 8 TRH and insulin, and 8 TRH and clonidine. Only insulin potentiated the TRH-induced TSH response with a peak of 22.0 +/- 3.2 vs 16.0 +/- 0.8 and 15.3 +/- 1.5 mU/l (p less than 0.025) for TRH alone and TRH and clonidine, respectively. It is suggested that clonidine stimulates hGH secretion mainly through an enhancement of GHRH release, whereas stress stimuli such as hypoglycemia and exercise achieve hGH release by a different mechanism, possibly inhibition of somatostatin.

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.

Endocrine responses to growth hormone‐releasing hormone, thyrotropin‐releasing hormone and corticotropin‐releasing hormone in depression

To explore and to compare hypothalamic-pituitary-somatotropic (HPS), hypothalamic-pituitary-thyroid (HPT) and hypothalamic-pituitary-adrenocortical (HPA) axis function in depression, 30 subjects (15 patients with a major depressive episode and individually matched controls) received 50 micrograms growth hormone-releasing hormone-44 amide at 9:00, 200 micrograms thyrotropin-releasing hormone (TRH) at 9:00 and 100 micrograms human corticotropin-releasing hormone (CRH) at 18:00 on consecutive days as an i.v. bolus dose. Compared with controls, depressed patients showed blunted growth hormone (GH) responses to GHRH, decreased TRH-induced thyrotropin (TSH) release and reduced corticotropin (ACTH) but normal cortisol secretion following CRH. ACTH secretion following CRH and TRH-induced TSH release were positively correlated across depressed patients and controls but no significant correlations between GH responses to GHRH and TRH-induced TSH release or ACTH and cortisol secretion following CRH administration were demonstrated. Our findings suggest that altered HPT and HPA axis function associated with depression are triggered by factors that are at least partly different from those that cause HPS system dysfunction. We conclude that the pathophysiological process resulting in aberrant neuroendocrine secretory dynamics associated with depression may primarily occur at a suprapituitary site, and that HPS, HPT and HPA axis dysfunction may be precipitated by complex central and peripheral regulatory mechanisms involving largely independent factors.

INTERACTION OF CLONIDINE AND GHRH ON GH SECRETION IN VIVO AND IN VITRO

To investigate the mechanism by which clonidine stimulates GH-secretion in vivo and in vitro, we studied its interaction with GHRH. In vivo: eight or six normal male subjects were submitted to five protocols: (1) 150 micrograms clonidine orally followed by 50 micrograms GHRH 1-44 i.v. 2 h later, (2) 50 micrograms GHRH 1-44 i.v. followed by 150 micrograms clonidine orally 2 h later, (3) 150 micrograms clonidine orally followed by GHRH i.v. 30 min later, (4) 300 micrograms clonidine orally followed by 50 micrograms GHRH i.v. 3 h later and (5) 50 micrograms GHRH i.v. followed by 300 micrograms clonidine orally 90 min later. In vitro: Rat anterior pituitary cells were coincubated with clonidine (10(-11), 10(-9), 10(-7) and 10(-5) M) and GHRH (0.005, 0.05, 10 nM) for 4 h. 150 micrograms clonidine alone does not stimulate GH-secretion. Furthermore, the GH-increase was not significantly different when GHRH bolus was given before, after or together with clonidine. When 300 micrograms clonidine was given before GHRH GH-levels were significantly higher (max 28.6 +/- 8.0 mU/l) at 90 min, compared to when clonidine was given after GHRH (max 7.8 +/- 3.6 mU/l). The GHRH bolus after clonidine led to a significantly lower GH-increase (max 31.6 +/- 17.0 mU/l) compared to the GHRH-induced GH-increase (max 47.2 +/- 13.0 mU/l) before clonidine. In vitro, clonidine had no stimulatory effect on GHRH-stimulated GH secretion. These findings are compatible with clonidine leading to stimulation of GH by inducing endogenous GHRH release.

Normal and Growth Hormone (GH)-Secreting Adenomatous Human Pituitaries Release Somatostatin and GH-Releasing Hormone

Neuropeptides such as vasoactive intestinal peptide, LHRH, or TRH have been found in rat pituitary tissue and could act via paracrine or autocrine actions in this tissue. In this study we investigated whether normal human pituitary tissue and GH-secreting human pituitary adenomas could release somatostatin (SRIH) and GHRH. Fragments from three human pituitaries and dispersed cells from six GH-secreting adenomas (four adenomas were studied for GHRH release and five for SRIH release) were perifused using a Krebs-Ringer culture medium, and the perifusion medium was collected every 2 min (1 mL/fraction for 5 h). GH, GHRH, and SRIH were measured by RIA under basal conditions and in the presence of 10(-6) mol/L TRH or SRIH. Both normal pituitaries and GH-secreting pituitary adenomas released SRIH and GHRH. SRIH release commenced 90-180 min after initiation of the perifusion, at which time GH secretion had decreased significantly. TRH stimulated SRIH release from normal pituitary tissue and inhibited SRIH release from adenoma tissue. GHRH was present at the start of the perifusion, but rapidly disappeared. However, SRIH stimulated GHRH release from normal pituitary tissue, but not from adenoma tissue. Significant amounts of GHRH and SRIH were released during the experiments, suggesting their local synthesis. These results indicate that pituitary cells can release hypothalamic peptides. The liberation of these neuropeptides is regulated, and moreover, their regulation differs between normal and adenomatous pituitaries.

INTRASELLAR GANGLIOCYTOMA CONTAINING GASTRIN AND GROWTH HORMONE‐RELEASING HORMONE ASSOCIATED WITH A GROWTH HORMONE‐SECRETING PITUITARY ADENOMA

A 74-year-old acromegalic found to have an intrasellar gangliocytocytoma and GH-secreting pituitary adenoma is described. The gangliocytoma contained immunoreactive gastrin and, to a lesser extent, GHRH, and the adenoma immunostained for GH. Gastrin has not been previously reported in hypothalamic gangliocytomas. Since this peptide has been demonstrated in normal hypothalamus and pituitary, and provokes GH release when administered intraventricularly, it may have caused GHRH release from the gangliocytoma by a local paracrine action and led to adenoma formation and acromegaly.

The Effects of PGE<SUB>2</SUB>, 2-DG and L-arginine on Hypothalamic GHRH and SRIF Releases in Conscious Rats, with Respect to GH Secretion

The effects of prostaglandin E2 (PGE2), 2-deoxy-D-glucose (2-DG) and L-arginine on hypothalamic GHRH and SRIF release with respect to GH secretion were studied in conscious male rats. Intracerebroventricular (icv) injection of 5 micrograms PGE2 and intravenous (iv) infusion of 1 g/kgBW L-arginine caused an increase in plasma GH levels, but icv (36 micrograms) or iv (400 mg/kgBW) injection of 2-DG suppressed spontaneous GH surge in conscious rats. The concentration of hypothalamic GHRH was decreased in all three groups of the animals, but the concentration of hypothalamic SRIF was decreased only in 2-DG-treated animals. In the perifusion system using rat hypothalamus, PGE2 (0.28 microM, 2.8 microM), 2-DG (22 mM) and L-arginine (3 mM) stimulated GHRH release from rat hypothalamus. 2-DG also stimulated SRIF release more predominantly than GHRH release. Passive immunization with anti-GHRH serum inhibited the GH secretion induced by icv injection of 5 micrograms PGE2 and by iv infusion of 1 g/kgBW L-arginine in conscious rats. In contrast, GH secretion induced by iv injection of 50 micrograms/kgBW PGE2 was not affected by the pretreatment with the antiserum. These results suggest that the central effect of PGE2 and peripheral effect of L-arginine to stimulate GH secretion are mediated by hypothalamic GHRH release, and that the inhibitory effect of 2-DG on GH secretion is predominantly mediated by hypothalamic SRIF release rather than GHRH release in rats.

Growth Hormone (GH) Response to GH-Releasing Hormone by Perifused Pituitary Cells from Male, Female, and Testicular Feminized Rats*

To determine whether a normal complement of androgen receptors is required to permit full expression of sex-related differences in pituitary GH secretion, we compared the GHRH-stimulated GH secretory responses of continuously perifused anterior pituitary cells from normal male, normal female, and androgen-resistant testicular feminized (Tfm) rats. In each experimental replicate, acutely dispersed pituitary cells were exposed to GHRH (0.03-100 nM) administered as 2.5-min pulses in random order at 30-min intervals. The eluate was collected in 5-min fractions for GH determination by RIA. Basal unstimulated secretion of GH by cells from male rats was greater than that by cells from female (P = 0.007) and Tfm (P = 0.03) rats; basal secretion by the other two groups was similar (P = 0.55). Linear concentration-response relationships between GHRH and GH release were defined for cells from male (P = 0.0002), female (P = 0.0001), and Tfm (P = 0.0002) rats. Overall GHRH-stimulated GH secretion by cells from male rats was greater (P less than 0.0001) than that by cells from female rats. Overall secretion by cells from Tfm rats was less (P less than 0.001) than that by cells from male rats but greater (P less than 0.001) than that by cells from female rats. For all experimental groups, body weight was strongly correlated with both basal (r2 = 0.42; P = 0.001) and GHRH-stimulated (r2 = 0.53; P = 0.0001) GH secretion by the dispersed pituitary cells. These data suggest that a deficiency of androgen receptors results in a diminution of the in vitro GH secretory capability of anterior pituitary cells to a level below that by cells from normal males, but not to the level in normal females. The intermediate position of cells from the Tfm rat may represent a partial masculinization or defeminization within this generally female phenotype.

Wachstumshormon-Releasinghormon Übersicht

Growth hormone-releasing hormone was isolated 1982 from human pancreatic tumours. They were found to consist of three peptides (GHRH1-44, GHRH1-40, GHRH1-37) which in vivo and in vitro were specific stimulators of pituitary growth hormone secretion. These tumor-derived GHRHs were demonstrated to be identical to human hypothalamic GHRHs. Extrahypothalamic GHRH is present in some brain regions and in the gastrointestinal tract. Circulating GHRH is detectable in human plasma, but little is known about its function. Above all binding of GHRH to a specific receptor stimulates growth hormone secretion through formation of cyclic AMP. GHRH secretion is modulated by somatostatin, the somatomedins and growth hormone itself. Following single injection of GHRH1-44 i.v. the equilibration half-time is 1.0 +/- 0.2 min and elimination half-time is 6.8 +/- 1.2 min. Maximal growth hormone response is achieved after injection of 1 microgram/kg GHRH. Using higher GHRH-doses growth hormone can be stimulated via subcutaneous or intranasal application. A single i.v. GHRH-test is not sufficient to prove a pituitary defect since growth hormone can be stimulated following repetitive injections in some cases. About 50% of patients with growth hormone deficiency have a hypothalamic defect of GHRH release. In some of these patients GHRH s.c. can promote linear growth to the same degree as growth hormone treatment.

Secretion of growth hormone-releasing hormone in patients with idiopathic pituitary dwarfism and acromegaly.

The plasma levels of immunoreactive-GHRH in patients with idiopathic pituitary dwarfism and acromegaly were studied in the basal state and during various tests by a sensitive and specific RIA. The fasting plasma GHRH level in 22 patients with idiopathic pituitary dwarfism was 6.3 +/- 2.3 ng/l (mean +/- SD), which was significantly lower than that in normal children (9.8 +/- 2.8 ng/l, N = 21), and eight of them had undetectable concentrations (less than 4.0 ng/l). Little or no response of plasma GHRH to oral administration of L-dopa was observed in 7 of 10 pituitary dwarfs, and 3 of the 7 patients showed a response of plasma GH to iv administration of GHRH (1 microgram/kg). These findings suggest that one of the causes of idiopathic pituitary dwarfism is insufficient GHRH release from the hypothalamus. The fasting plasma GHRH level in 14 patients with acromegaly and one patient with gigantism was 8.0 +/- 3.9 ng/l, which was slightly lower than that in normal adults (10.4 +/- 4.1 ng/l, N = 72). One acromegalic patient with multiple endocrine neoplasia type I had a high level of plasma GHRH (270 ng/l) with no change in response to L-dopa and TRH test. In 3 untreated patients with acromegaly L-dopa did not induce any response of plasma GHRH in spite of inconsistent GH release, and in 4 patients with acromegaly, TRH evoked no response of plasma GHRH in spite of a marked GH release, suggesting that the GH responses are not mediated by hypothalamic GHRH.(ABSTRACT TRUNCATED AT 250 WORDS)

Dichotomic action of glucocorticoids on growth hormone secretion.

The mechanism of apparently discrepant actions of glucocorticoids (GC) on GH secretion, in vivo suppression and in vitro potentiation, was studied in rats. Dexamethasone (Dex), at the concentration of 50 nmol/l, potentiated basal and GHRH-stimulated GH release from monolayer culture of normal rat pituitary cells in 48 h. On the other hand, in vivo administration of Dex, 165 micrograms daily for 3 days, consistently suppressed serum GH levels in female rats. In these rats, the hypothalamic content of immunoreactive (IR) SRIH was significantly increased, whereas that of IR-GHRH was significantly decreased in comparison with the untreated rats. Bioassayable GH-releasing activity was also lower in Dex-treated rats. These findings indicate that the suppressing effect of GC on GH release in vivo is, at least partially, due to the increase in hypothalamic SRIH release and probably also to the decrease in GHRH release, and these effects surpass the potentiating effect of GC on GH release at the pituitary level, resulting in a net inhibitory effect in vivo.

Stimulated release of hypothalamic growth hormone-releasing activity by morphine and pentobarbital

Two minutes after the intravenous administration of 1 ml of sheep somatostatin antiserum in the rat, plasma growth hormone (GH) levels had reached a maximal 10–15-fold increase which remained approximately constant up to 90 min. The injection of sodium pentobarbital (2 mg/100 g body wt) led to a rapid and transient rise of plasma GH levels with a maximal effect being measured at 10 min. After a delay of 5 min, morphine led to a rise of plasma GH levels of similar magnitude (10-fold) reached 20 to 40 min after injection of the narcotic. The important finding is, however, that the combined administration of somatostatin antiserum and pentobarbital or morphine led to an almost exact additive effect on the plasma GH concentrations. These data, beside providing additional evidence for the existence of GH-releasing activity (GH-RH), indicate that morphine and pentobarbital stimulate GH secretion through increased release of GH-RH.