Corticotropin-releasing hormone inhibition of growth hormone-releasing hormone-induced growth hormone release in man

Recent studies in the rat have shown that intracerebroventricular administration of CRH inhibited spontaneous pulsatile GH secretion and prevented GH-releasing hormone (GHRH)-induced GH release. We have studied the effect of CRH on GHRH-induced GH release in man. In the first study, CRH was injected iv at three different doses (100, 50, or 25 micrograms) at 0800 h together with 50 micrograms GHRH in six men and six women. In a second study, 100 micrograms CRH were given iv at 0800 h, 1 h before the administration of 50 micrograms GHRH in five men and five women. Each subject demonstrated a normal GH response after the administration of 50 micrograms GHRH plus saline. All doses of CRH administered simultaneously with GHRH significantly inhibited GHRH-induced GH release in women [peak value +/- SE after GHRH plus saline, 28.9 +/- 2.9 micrograms/L; after GHRH plus 100 micrograms CRH, 9.9 +/- 0.7 micrograms/L (P less than 0.001); after GHRH plus 50 micrograms CRH, 8.7 +/- 0.8 micrograms/L (P less than 0.001); after GHRH plus 25 microgram CRH, 9.5 +/- 1.6 microgram/L (P less than 0.001]). In contrast, in men, while a dose of 100 micrograms CRH was capable of suppressing GHRH-induced GH secretion (peak value +/- SE, 8.1 +/- 0.6 vs. 20 +/- 2.9 micrograms/L; P less than 0.001), no inhibition was observed after 50- and 25-micrograms doses. When 100 micrograms CRH were injected 1 h before the administration of 50 micrograms GHRH, it strongly inhibited GHRH-induced GH secretion in both men (peak value +/- SE, 6.2 +/- 2.8 vs. 24.6 +/- 5.9 micrograms/L; P less than 0.02) and women (peak value +/- SE, 14.2 +/- 4.5 vs. 37.8 +/- 6.7 micrograms/L; P less than 0.005), and this inhibition lasted up to 2 h post-CRH administration. These results demonstrate that CRH is capable of inhibiting GHRH-induced GH release in both men and women. Furthermore, the findings suggest that a sexual dimorphism in the neuroregulation of GH secretion may be present in man. In view of the inhibitory action of CRH on GH secretion, simultaneous administration of CRH and GHRH for testing should be avoided in clinical practice.     

Actions of growth hormone-releasing factor and somatostatin on adenylate cyclase and growth hormone release in rat anterior pituitary

The interaction of growth hormone-releasing factor (GRF) and somatostatin (SRIF) on adenylate cyclase activity and growth hormone release was investigated in pituitary homogenates and 2-day cultured rat anterior pituitary cells. GRF stimulated growth hormone release by about 3-fold (ED50 1.6 X 10(-12) M) and caused a rapid 15-fold increase in cyclic AMP production (ED50 6.0 X 10(-12) M). The increase in cyclic AMP was due to direct stimulation of adenylate cyclase by GRF, which caused a 4-fold increase in the activity of the enzyme measured in anterior pituitary homogenates. GRF-induced cyclic AMP formation and GRF-stimulated adenylate cyclase activity were maximally inhibited to the extent of about 50% by 10(-8) M somatostatin. In contrast, GRF-stimulated growth hormone release was completely inhibited by somatostatin (ID50 3.2 X 10(-11) M), suggesting a second site of action of somatostatin. These studies demonstrate that GRF stimulates growth hormone release via activation of adenylate cyclase and a rise in intracellular cyclic AMP. In addition, these findings indicate that the inhibitory action of somatostatin on growth hormone release is exerted at two levels, one at the level of adenylate cyclase affecting the production of cyclic AMP, and the other beyond the formation of the nucleotide, at a site which modulates the release of growth hormone from the cell.     

Calmodulin dependence of somatostatin release stimulated by growth hormone-releasing factor

Experiments were performed in vitro to examine the possible role of calcium and calmodulin in GRF-induced somatostatin (SRIF) release from the median eminence. Adult male rats were used as tissue donors. The median eminences were first prestimulated in 0.4 ml Krebs Ringer bicarbonate glucose buffer (pH 7.4) containing bacitracin at 37C in an atmosphere of 95% O2, 5% CO2 with constant shaking for 30 min. When calcium was omitted, this medium was used during the prestimulation and stimulation periods. After prestimulation, the medium was discarded and replaced by medium containing the different substances to be tested (GRF, EGTA, calcium channel blockers, and calmodulin inhibitors). The stimulation of SRIF release induced by 10(-10) M GRF was not inhibited by omission of extracellular calcium or when the remaining CA+2 was chelated with 10(-4) M EGTA. The calcium channel blockers, nifendipine and verapamil (10(-6) M), failed to alter the increase of SRIF release induced by rGRF. Three calmodulin inhibitors were employed to examine the possible influence of calmodulin on GRF-induced SRIF release. Trifluoperazine (10(-6) M), triflupromazine (10(-6) M) and penfluridol (10(-7) M) had an inhibitory effect on the stimulation of SRIF release induced by GRF and failed to alter resting release. Thus, GRF can evoke SRIF release independently of extraterminal Ca+2 concentration and Ca+2 influx into the nerve terminals, but the releasing process involves translocation of Ca+2 from intracellular stores. The inhibitory effect of the calmodulin inhibitors on GRF-induced SRIF release, suggests that the translocated Ca+2 must bind to calmodulin in order to release SRIF.     

Interactions of growth hormone secretagogues and growth hormone-releasing hormone/somatostatin

The class of novel synthetic compounds termed growth hormone secretagogues (GHSs) act in the hypothalamus through, as yet, unknown pathways. We performed physiologic and histochemical studies to further understand how the GHS system interacts with the well-established somatostatin (SRIF)/growth hormone-releasing hormone (GHRH) neuroendocrine system for regulating pulsatile GH secretion. Comparison of the GH-releasing activities of the hexapeptide growth hormone-releasing peptide-6 (GHRP-6) and GHRH administered intravenously to conscious adult male rats showed that the pattern of GH responsiveness to GHRP-6 was markedly time-dependent, similar to that observed with GHRH. Immunoneutralization of endogenous SRIF reversed the blunted GH response to GHRP-6 at trough times, suggesting that GHRP-6 neither disrupts nor inhibits the cyclical release of endogenous hypothalamic SRIF. By striking contrast, passive immunization with anti-GHRH serum virtually obliterated the GH responses to GHRP-6, irrespective of the time of administration. These findings suggest that the GHSs do not act by altering SRIF release but, rather, stimulate GH release via GHRH-dependent pathways. Our dual chromogenic and autoradiographic in situ hybridization experiments revealed that a subpopulation of GHRH mRNA-containing neurons in the arcuate (Arc) nucleus and ventromedial nucleus (VMN) of the hypothalamus expressed the GHS receptor (GHS-R) gene. These results provide strong anatomic evidence that GHSs may directly stimulate GHRH release into hypophyseal portal blood, and thereby influence GH secretion, through interaction with the GHS-R on GHRH- containing neurons. Altogether, these findings support the notion that an additional neuroendocrine pathway may exist to regulate pulsatile GH secretion, possibly through the influence of the newly discovered GHS natural peptide, ghrelin.     

Evidence that growth hormone-releasing factor stimulates somatostatin release in vitro via beta-endorphin

Previous results indicate that GH-releasing factor (GRF) induces a dose-related stimulation of somatostatin (SRIF) release from median eminence fragments incubated in vitro. In the present investigation we examined whether this action was mediated by other neurotransmitters or neuromodulators. Studies using receptor blockers for dopamine (pimozide), alpha-adrenergic receptors (phentolamine), and muscarinic cholinergic receptors (atropine) revealed that these receptor blockers, at a dose of 10(-6) M, which was capable of blocking the response to the relevant transmitter in previous studies, had no effect on basal release of SRIF in the static incubation system and failed to modify the response to GRF (10(-10) M). On the other hand, the opiate receptor blocker naloxone at a dose of 10(-6) M, although failing to alter basal release, completely blocked the response to 10(-10) M GRF. To determine the opioid peptide involved in mediating the SRIF release induced by GRF, highly specific antibodies directed against beta-endorphin were added to the in vitro incubation system. These antibodies significantly depressed basal release SRIF and completely blocked the response to 10(-10) M GRF. Incubations in the presence of normal rabbit serum or highly specific antiserum directed against alpha MSH had no effect on either basal release of SRIF or that induced by GRF. These results suggest that in this incubation system there is a beta-endorphin tone which is partially responsible for the basal release of SRIF and that the stimulation of SRIF release induced by GRF is mediated via beta-endorphin terminals, which presumably synapse on the terminals of the somatostatinergic neurons in the median eminence fragment.     

Signal transduction systems in growth hormone-releasing hormone and somatostatin release from perifused rat hypothalamic fragments.

The role of signal transduction systems was examined in the secretion of GH-releasing hormone (GHRH) and somatostatin (SS) from perifused rat hypothalamic fragments. Forskolin, an adenylate cyclase activator, stimulated the release of GHRH and SS in a concentration-dependent manner (10-100 microM) with greatest stimulation for GHRH at 100 microM (mean +/- SE, 249 +/- 14%) and for SS at 30 microM (172 +/- 18%). (Bu)2cAMP also augmented GHRH and SS release. The protein kinase-C activator phorbol 12-myristate 13-acetate did not significantly stimulate basal GHRH or SS release at concentrations of 10 nM to 1 microM. The calcium ionophore A23187 enhanced the release of GHRH and SS in a concentration-dependent manner (2-20 microM), with the greatest responses of 282 +/- 50% at 10 microM and 189 +/- 24% at 20 microM, respectively. Potentiation by phorbol 12-myristate 13-acetate of forskolin-stimulated GHRH and SS release was observed. A23187 at 10 microM did not enhance forskolin-stimulated GHRH release, but did potentiate forskolin-stimulated SS release in a more than additive response. We conclude that there is 1) cAMP stimulation of hypothalamic GHRH and SS release, 2) a modulating role of protein kinase-C on cAMP-stimulated release of GHRH and SS, 3) a stimulatory role of the calcium messenger system for GHRH and SS release, 4) interaction of the signal pathways with differences in net GHRH and SS responses, and 5) a modulatory effect of protein kinase-C in perifused hypothalamic fragments which differs from the stimulation of basal GHRH and SS release reported in fetal-derived hypothalamic cell cultures. Our observations suggest an important regulatory role of interacting signal transduction systems in the hypothalamic secretion of GHRH and SS.     

The inhibition of growth hormone release by gastrin-releasing peptide involves somatostatin release

Injection of gastrin-releasing peptide-27 (GRP) into the third ventricle (IVT) has been shown previously to lower plasma GH levels and block the GH release induced by GRF, suggesting that GRP might act via stimulation of the release of somatostatin (SRIF) into hypophysial portal vessels. Several experiments were performed to test this hypothesis. In the first experiment rat median eminence (ME) fragments were incubated in medium containing concentrations of GRP ranging from 1 pM to 1 microM, and SRIF levels were measured after the 30-min incubation period. GRP significantly stimulated SRIF release at doses of 0.1 nM to 1 microM. Microinjection of SRIF antiserum (3 microliters) IVT prevented GRP (2 micrograms, IVT) from inhibiting the GH surge induced by GRF (1 microgram/kg, iv). A slight but significant decrease in basal plasma GH levels was observed after GRP administration even in the presence of SRIF antiserum. Finally, to rule out a GRP-GRF interaction at the pituitary level, tubes containing dispersed rat pituitary cells (2.5 x 10(5) cells/tube) were incubated for 1.5 h in medium containing various concentrations of GRF (0.4-40 nM) alone or with 0.1 microM GRP. The addition of GRP to the medium had no significant effect on the dose-dependent stimulation of GH release by GRF. The results of these studies demonstrate that GRP can directly stimulate SRIF release in vitro. They further suggest that SRIF is a component of the mechanism whereby GRP inhibits GH release in vivo. Finally, the possibility that GRP acts at the pituitary level to inhibit GH release by blocking GRF receptors on somatotrophs has been ruled out.     

Interaction of carp growth hormone-releasing factor and somatostatin on in vitro release of growth hormone in rainbow trout (Oncorhynchus mykiss).

Possible antagonism between somatostatin (SS) and carp growth hormone-releasing factor (GRF) on growth hormone (GH) secretion was examined by radioimmunoassay in a dispersed rainbow trout pituitary cell culture system. SS (3 nM) significantly antagonized carp GRF(1-29; 1 nM, 10 nM)-induced GH secretion. The slope of the dose-response curve for carp GRF(1-29) with SS was statistically different from that of carp GRF(1-29) alone (p less than 0.05) suggesting a noncompetitive antagonism of SS to carp GRF. The carp GRF(1-29) was also indicated to be a noncompetitive antagonist to SS (p = 0.056). Carp GRF(1-29; 100 nM) was unable to restore the inhibitory effect of SS on GH release after pre-exposure of SS (30 nM) to the pituitary cells. We conclude that SS antagonizes carp GRF on GH release at the pituitary level in rainbow trout and this antagonism is noncompetitive. SS has a postantagonism to carp GRF which may implicate some important physiological adaptations in teleosts.     

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.     

Growth hormone secretion from chicken adenohypophyseal cells in primary culture: effects of human pancreatic growth hormone-releasing factor, thyrotropin-releasing hormone, and somatostatin on growth hormone release

A primary culture of chicken adenohypophyseal cells has been developed to study the regulation of growth hormone (GH) secretion. Following collagenase dispersion, cells were exposed for 2 hr to vehicle (control) or test agents. Human pancreatic (tumor) growth hormone-releasing factor (hpGRF) and rat hypothalamic growth hormone-releasing factor stimulated GH release to similar levels. GH release was increased by the presence of dibutyryl cyclic AMP. Thyrotropin-releasing hormone (TRH) alone did not influence GH release; however, TRH plus hpGRF together exerted a synergistic (greater than additive) effect, increasing GH release by 100 to 300% over the sum of the values for each secretagogue acting alone. These relationships between TRH and hpGRF were further examined in cultured cells exposed to secretagogues for two consecutive 2-hr incubations. TRH pretreatment enhanced subsequent hpGRF-stimulated GH release by about 80% over that obtained if no secretagogue was present during the first incubation. In other experiments, somatostatin (SRIF) alone did not alter GH secretion. However, SRIF reduced hpGRF-stimulated GH release to levels found in controls. Furthermore, GH release stimulated by the presence of both TRH and hpGRF was lowered to control values by SRIF. The results of these studies demonstrate that a primary culture of chicken adenohypophyseal cells is a useful model for the study of GH secretion. Indeed, these results suggest that TRH and hpGRF regulate GH secretion by mechanisms which are not identical.     

The effect of galanin on growth hormone-releasing factor and somatostatin release from median eminence fragments in vitro.

Galanin has been reported to stimulate secretion of GH in humans and rats. Thus, to investigate whether the effect of galanin on GH release is the result of either a stimulation of GH-releasing factor (GRF) and/or an inhibition of somatostatin (SRIF) release, we have evaluated the action of galanin on the release of SRIF and GRF from median eminence (ME) fragments in vitro. The MEs from adult male rats were incubated in Krebs-Ringer bicarbonate-glucose buffer, pH 7.4, at 37 degrees C, in an atmosphere of 95% O2, 5% CO2 with constant shaking for 30 min. Medium was discarded and replaced by medium containing various concentrations of galanin (10(-10)-10(-7) M). Galanin stimulated SRIF and GRF release in a dose-related manner. This effect was significant at concentrations varying from 10(-8) to 10(-7) M. To determine the mechanism by which galanin stimulated SRIF and GRF release, MEs were incubated with pimozide (dopaminergic blocker), phentolamine (alpha-adrenergic blocker) or naloxone (opioid blocker), at concentrations of 10(-6) M, and the effect of galanin was then evaluated. Phentolamine and naloxone did not alter the stimulatory effect of galanin, but when galanin was tested with pimozide, the galanin-induced release of SRIF and GRF was blocked. To determine whether the effect of galanin is mediated through D-1 and/or D-2 dopamine receptors, selective antagonists of D-1 (SCH 23390) and D-2 receptors (domperidone) were used (10(-7) M) in the presence of galanin (10(-7) M).(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of the glucose-dependent release of growth hormone-releasing factor and somatostatin from superfused rat hypothalami

The glucose-dependent secretion of the neuropeptides, growth hormone-releasing factor (GRF) and somatostatin (SRIF), by hypothalamic fragments was studied in vitro using a superfusion system. After equilibration of mediobasal hypothalami in HEPES-buffered Krebs-Ringer solution containing 5.5 mM glucose, glucose levels in the superfusion medium were altered. Lowering the glucose concentration in the medium from 5.5 to 2.7 or 1.1 mM provoked a rapid increase in GRF and SRIF release in a concentration and Ca2+-dependent manner. At 1.1 mM glucose, neuropeptide secretion was elevated 3- to 4-fold. The increase of GRF and SRIF release induced by low glucose was transient since stimulated neuropeptide secretion declined to basal levels in the continued presence of low glucose. Furthermore, after reequilibration in 5.5 mM glucose, no second stimulation of neuropeptide release could be induced by reduced glucose. Intracellular glucopenia induced by addition of 2-deoxy-D-glucose (16.5 mM) to the superfusion medium containing 5.5 mM glucose, also evoked increases in GRF and SRIF release. The sensitivity of GRF and SRIF neurons to glucose was absent in the postnatal period until day 9 after birth and then gradually increased. The parallel increases of GRF and SRIF release in response to low glucose observed in the present in vitro study, together with the suppression of plasma GH levels occurring in hypoglycemia in the rat, suggest that, in this condition, the inhibition of GH release induced by elevated SRIF levels predominates whereas the increase of GRF release might serve to attenuate this effect of SRIF.     

Intracellular calcium concentration and growth hormone secretion in individual somatotropes: effects of growth hormone-releasing factor and somatostatin

The cytosolic free calcium concentration and cumulative GH release were measured simultaneously in normal pituitary cells. This was made possible by a novel combination of fluorescence microscopy using the calcium indicator fura-2 and a reverse hemolytic plaque assay. GRF (10 nM) rapidly increased the intracellular free calcium concentration ([ Ca2+]i) from a basal level of 234 +/- 17 nM (mean +/- SE) to a peak value of 480 +/- 61 nM 1 min after stimulation. This GRF-induced calcium rise was totally abolished in calcium-free medium or in the presence of calcium channel blockers cobalt chloride (2 mM) and verapamil (100 microM). When somatostatin (SRIF; 1 nM) was added after basal recordings, cytosolic calcium decreased to 96 +/- 23 nM in identified somatotropes. [Ca2+]i returned to baseline upon the removal of SRIF inhibition. This rebound was higher when a sequential treatment of SRIF followed by GRF was applied. Exposing cells to a combination of GRF (10 nM) plus SRIF (1 nM) resulted in a decrease in [Ca2+]i identical to that caused by SRIF treatment alone. Despite the 10-fold excess of GRF, SRIF not only inhibited hormone secretion, but also totally overcame the GRF-induced rise of [Ca2+]i. In summary, stimulation by GRF increases cytosolic calcium in normal somatotropes. This increase is proposed to be due to the influx of calcium through membrane ion channels. In contrast, SRIF decreases [Ca2+]i. This might explain the cAMP-independent effects of this peptide. The effect of SRIF dominates over that of GRF with respect to both changes in [Ca2+]i and hormone release. Changes in the GH secretory rate are, therefore, accompanied by parallel changes in [Ca2+]i, both of which are primarily regulated by SRIF.     

Sexual dimorphism of somatostatin and growth hormone-releasing factor signaling in the control of pulsatile growth hormone secretion in the rat.

A striking sexual dimorphism exists in the pattern of GH secretion and rate of somatic growth; however, the mechanism(s) mediating this sex difference is unknown. To elucidate the physiological roles of the hypothalamic neuropeptides, somatostatin (SRIF) and GRF, and their interrelation, in generating the sexually dimorphic GH secretory pattern we examined: 1) GH responsiveness to exogenous GRF and 2) the effects of immunoneutralization of endogenous SRIF and GRF on GH secretory dynamics, in free-moving male and female rats. In males, the GH response to 1 microgram rat(r)GRF(1-29)NH2 iv was significantly greater at peak compared to trough times of GH secretion (925.2 +/- 250.8 vs. 95.6 +/- 27.8 ng/ml; P less than 0.02), the latter known to be due to antagonization by the cyclic increased release of endogenous SRIF. In contrast, females failed to exhibit a time-dependent difference in GH responsiveness to GRF. Passive immunization with a specific antiserum to SRIF in males resulted in significant elevation of GH nadir levels but had no effect on GH peak amplitude. In contrast, immunoneutralization of endogenous SRIF in females caused a marked augmentation of plasma GH levels at all time points; there was a significant increase in GH peak amplitude (171.3 +/- 39.9 vs. 67.5 +/- 11.3 ng/ml; P less than 0.05), GH nadir (18.3 +/- 2.7 vs. 5.8 +/- 1.1 ng/ml; P less than 0.01) and mean 6-h plasma GH level (78.7 +/- 4.1 vs. 33.1 +/- 5.8 ng/ml; P less than 0.001), compared to normal sheep serum-treated controls. These results indicate that the pattern of hypothalamic SRIF secretion in females does not follow the male-like ultradian rhythm. Passive immunization with a specific antiserum to GRF obliterated spontaneous GH pulses in both sexes. Moreover, in females, anti-GRF serum attenuated GH nadir levels (4.3 +/- 1.7 vs. 21.4 +/- 3.5 ng/ml; P less than 0.01) indicating a physiological role for GRF in maintaining the elevated basal GH level of females, in addition to its important role in generating the episodic GH pulses. Taken together, these findings provide support for the hypothesis that, in female rats, the pattern of hypothalamic SRIF secretion into hypophyseal portal blood is continuous, rather than cyclical, as in the male; whereas in the case of GRF secretion, in addition to steady-state release which occurs at a higher level in females than males, there is also episodic GRF bursting which does not follow a specific rhythm, as in the male.(ABSTRACT TRUNCATED AT 400 WORDS)     

Sexual differentiation of growth hormone feedback effects on hypothalamic growth hormone-releasing hormone and somatostatin

To investigate possible sex differences in the feedback regulation of growth hormone (GH) secretion, concentrations of immunoreactive GH-releasing hormone (GRF) and somatostatin (SS) were measured in the median eminence (ME) and the hypothalamus of male and female rats bearing the MtTW15 tumor, which secretes high amounts of GH and prolactin (PRL). Four weeks after tumor implantation in male rats, the GRF concentration in the whole hypothalamus, including the ME, was decreased by 37% (0.29 +/- 0.02 vs. 0.46 +/- 0.02 ng/mg protein in intact male controls; p less than 0.001) and the concentration of SS was increased by 40% (11.5 +/- 0.7 vs. 8.1 +/- 0.3 ng/mg protein in male controls; p less than 0.01). In female rats, the presence of tumor for 4 weeks caused a smaller (18%) reduction in GRF concentrations (0.27 +/- 0.02 vs. 0.33 +/- 0.03 ng/mg protein in intact female controls; p less than 0.05) and no significant change in SS concentrations (10.2 +/- 0.08 vs. 9.7 +/- 0.8 ng/mg protein in female controls). Tumor-related changes in GRF and SS concentrations were also more pronounced in male rats than in females, when determined separately in the microdissected ME and in the remaining hypothalamus. These differences occurred despite similar increases in serum GH, PRL and insulin-like growth factor I concentrations in male and female tumor-bearing rats. To assess which hormone (GH or PRL) was responsible for these changes, intact male rats were treated for 10 days with 2 daily s.c. injections of rat GH (rGH; 100 and 250 micrograms/day), rat PRL (100 and 250 micrograms/day) or vehicle.(ABSTRACT TRUNCATED AT 250 WORDS)     

On the mechanism of growth hormone autofeedback regulation: possible role of somatostatin and growth hormone-releasing factor

To determine the role of somatostatin (SRIF) and GH-releasing factor (GRF) in GH autofeedback, 20 micrograms rat GH in 2 microliter were injected into the third ventricle (IVT) 1 or 3 h before injection of the alpha 2-receptor stimulator clonidine (50 micrograms/kg, iv), which elevates plasma GH and TSH levels in normal rats. GH preinjected 1 or 3 h before clonidine significantly suppressed the clonidine-induced GH surge, whereas TSH release was not affected by GH. Preinjection of ovine LH IVT following the same protocol did not inhibit the clonidine-induced GH surge, suggesting a specific effect of IVT GH. Passive immunization with 400 microliters sheep antisomatostatin serum did not reverse the inhibition of the clonidine-induced GH surge by exogenous GH administered IVT either 1 or 3 h before clonidine. The TSH response was augmented by this procedure. Furthermore, IVT GH did not reduce the surges of GH and TSH elicited by GRF (250 ng/kg, iv) and TRH (150 ng/kg, iv) administered 1 or 3 h after IVT rat GH. These results suggest that GH autofeedback is mediated by reduced GRF secretion, rather than enhanced SRIF release.     

Human pancreatic growth hormone-releasing factor stimulates release of growth hormone in conscious unrestrained male rabbits

The effect on GH secretion of GH-releasing factor (GRF), a 44-amino acid peptide recently isolated from a human pancreatic tumor (hpGRF), was examined in conscious male rabbits. During a 6-h period (1030-1630 h) of the control study individual rabbits exhibited pulsatile GH release with a surge at 1030-1200 h, a trough at 1200-1400 h, and a second peak at 1400-1630 h. Intravenous bolus injections of 1 and 10 micrograms hpGRF caused significant and dose-related increases in plasma GH during both the period of the trough (1300 h) and the surge (1530 h), although the GH responses were obviously higher during the latter than the former period. Passive immunization with anti-somatostatin (SRIF) sheep serum resulted in a prompt increase in plasma GH immediately after an injection of the antiserum. When 0.1, 1, and 10 micrograms hpGRF were successively injected iv at 1215, 1345, and 1515 h, respectively, maximum levels of plasma GH after hpGRF in anti-SRIF sheep serum-treated rabbits were significantly higher than in animals given normal sheep serum. The plasma GH responses to 10 micrograms hpGRF, given iv only once at 1515 h in normal sheep serum-treated animals, were not different from those to 10 micrograms hpGRF injected at 1515 h after the prior administration either of the smaller hpGRF dose (0.1 micrograms, 1215 h; 1 microgram, 1345 h), nor of the large dose (10 micrograms, 1100 h). These findings suggest the following: 1) that the secretion of GH is pulsatile in conscious, unrestrained male rabbits; 2) that hpGRF is a potent secretagogue for GH release in rabbits as well as other species; 3) that the magnitude of plasma GH response to hpGRF is different according to timing of the injection during the course of pulsatile GH secretion but is not influenced by the prior administration of hpGRF (no priming effect); and 4) that the responsiveness of plasma GH to hpGRF is affected by circulating endogenous SRIF.     

Growth hormone-releasing factor and fibroblast growth factor regulate somatostatin gene expression

A multiple peptide-synthesizing clonal rat cell line was used to study the effect(s) of GRF and basic fibroblast growth factor (bFGF) on the synthesis and secretion of somatostatin (SS). The presence of SS-specific mRNA in 44-2C cells was shown morphologically by in situ hybridization. The release and cellular content of SS increased significantly after treatment with rat hypothalamic GRF (rGRF), the ED50 for rGRF stimulation of intracellular SS was 1.9 X 10(-11) M. GRF stimulated SS production in serum-supplemented and serum-free cultures. Results obtained after incubation of 44-2C cells with 125I-labeled rGRF indicated uptake and nuclear localization of rGRF by 44-2C cells. FGF stimulated the secretion and cellular content of SS. We propose that bFGF regulates the short term secretion and accumulation of SS and mediates rGRF-stimulated SS expression.     

Mechanisms of impaired growth hormone secretion in genetically obese Zucker rats: roles of growth hormone-releasing factor and somatostatin

GH secretion is markedly blunted in obesity; however, the mechanism(s) mediating this response remains to be elucidated. In the present study we examined the involvement of the two hypothalamic GH-regulatory hormones, GH-releasing factor (GRF) and somatostatin (SRIF), using the genetically obese male Zucker rat. Spontaneous GH, insulin, and glucose secretory profiles obtained from free moving, chronically cannulated rats revealed a marked suppression in amplitude and duration of GH pulses in obese Zucker rats compared to their lean littermates (mean 6-h plasma GH level, 3.9 +/- 0.4 vs. 21.5 +/- 3.8 ng/ml; P less than 0.001). Obese rats also exhibited significant hyperinsulinemia in the presence of normoglycemia. The plasma GH response to an iv bolus of 1 microgram rat GRF-(1-29)NH2, administered during peak and trough periods of the GH rhythm, was significantly attenuated in obese rats at peak (137.4 +/- 26.1 vs. 266.9 +/- 40.7 ng/ml; P less than 0.02), although not at trough, times. Passive immunization of obese rats with a specific antiserum to SRIF failed to restore the amplitude of GH pulses to normal values; the mean 6-h plasma GH level of obese rats given SRIF antiserum was not significantly different from that of obese rats administered normal sheep serum. Both pituitary wet weight and pituitary GH content and concentration were reduced in the obese group. Measurement of hypothalamic GRF immunoreactivity revealed a significant (P less than 0.05) reduction in the mediobasal hypothalamic GRF content in obese rats (503.2 +/- 60.1 pg/fragment) compared to that in lean controls (678.1 +/- 50.2 pg/fragment), although no significant difference was observed in hypothalamic SRIF concentration. Peripheral SRIF immunoreactive levels were significantly (P less than 0.01) elevated in both the pancreas and stomach of obese rats. These results demonstrate that the genetically obese Zucker rat exhibits 1) marked impairment in both spontaneous and GRF-induced GH release, which cannot be reversed by SRIF immunoneutralization, 2) significant reduction in pituitary GH concentration, 3) depressed hypothalamic GRF content, and 4) elevated gastric and pancreatic, but not hypothalamic, SRIF levels. The findings suggest that the defect in pituitary GH secretion observed in the genetically obese Zucker rat is due, at least partially, to insufficient stimulation by hypothalamic GRF, and that SRIF does not play a significant role.