UNIPROT:P61278 - FACTA Search

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Query: UNIPROT:P61278 (somatostatin)
22,083 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The correlation between response of plasma GH to GHRH and the GHRH-induced stimulation of the intracellular adenylate cyclase (AC) activity in pituitary adenoma cell membranes in acromegalic patients was investigated. Each peak plasma GH level after iv administration of GHRH ranged from 1.1 to 13.8 times the basal level in 13 acromegalic patients. On the other hand, the maximal stimulation of intracellular AC activity (cAMP production) induced by GHRH varied from 1.4 to 6.4 times the control level in each GH-producing pituitary adenoma cell membrane. A significant positive correlation (r = 0.89, P less than 0.005) between plasma GH response to GHRH and intracellular cAMP production stimulated by GHRH was observed in nine of the acromegalic patients. In contrast, the response of plasma GH to GHRH was significantly blunted, despite a fairly large production of intracellular cAMP stimulated by GHRH, in the other four acromegalic patients. These results suggest that GHRH-induced GH release from GH-producing pituitary adenomas of patients with acromegaly may be regulated not only by GHRH receptor-adenylate cyclase system but also modified by several other factors including somatostatin and Sm-C.
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PMID:Growth hormone releasing hormone-sensitive adenylate cyclase activity in growth hormone-producing pituitary adenoma: correlation to the response of plasma growth hormone to growth hormone releasing hormone in patients with acromegaly. 255 Feb 7

Dispersed normal male rat anterior pituitary cells were prelabeled with 45Ca2+ and perifused to study the influence of GH-releasing factor (GRF) on fractional calcium efflux and GH release. The cells were exposed for 2 min to 0, 0.03, 0.1, 0.3, 1.0, or 10.0 nM GRF in separate perifusion columns, and the response to each concentration was determined by integration of the area under the curve. Concentrations of 0.1 nM GRF and higher produced a simultaneous and significant stimulation of calcium efflux and GH release. The increase in calcium efflux was proportional to GRF concentration and was maximally responsive at 1 nM GRF. The value for the entire integrated response of GH release increased continuously with GRF concentration, but GH released rapidly (0-4 min) in response to GRF achieved a maximal response at 1 nM GRF and was significantly correlated with calcium efflux. Somatostatin (100 nM) abolished the stimulation of GH release and calcium efflux due to 10 nM GRF. We conclude that GRF receptor activation is intimately associated with calcium mobilization, although the relative dependence upon intracellular or extracellular calcium sources has yet to be defined. This interaction occurs at a GRF concentration about 10 times lower than that observed to cause a measurable increase in intracellular biochemical messengers such as cAMP, phosphatidylinositol, or arachidonate. We postulate that GRF-stimulated calcium mobilization is a rapid and very sensitive event contributing to GRF-stimulated GH release.
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PMID:Association of 45Ca2+ mobilization with stimulation of growth hormone (GH) release by GH-releasing factor in dispersed normal male rat pituitary cells. 286 51

Continuous infusion of human GH-releasing hormone (GHRH) stimulates GH secretion in normal subjects, but a single supramaximal iv dose of GHRH thereafter elicits a diminished serum GH response compared to that after a saline infusion; the response to the single dose challenge is inversely related to the dose of GHRH previously infused. To determine if this attenuated GH response is a result of depletion of available GH or desensitization of the somatotroph, a 6-h infusion of saline or GHRH (10 ng/kg . min) was administered to 10 normal men, and an iv bolus dose of either GHRH (3.3 micrograms/kg) or regular insulin (0.15 U/kg) was given after 5.5 h of infusion. On both days of GHRH infusion, there was significant stimulation of GH secretion compared to that after saline infusion. The GH response to the supramaximal dose of GHRH was greater after saline infusion than after GHRH infusion, and the GH response to insulin-induced hypoglycemia was significantly greater after GHRH infusion compared with the responses on the other 3 study days. The greatest GH secretion occurred during GHRH infusion followed by insulin administration; therefore, pituitary reserve was not decreased by prior exposure to GHRH. These studies suggest that somatotrophs become partially refractory to GHRH stimulation over time, but remain responsive to an alternate stimulus of GH secretion. We suggest that the hypoglycemia-induced GH response occurs via a reduction in hypothalamic somatostatin secretion, and the attenuated GH response to the supramaximal GHRH dose after GHRH infusion probably represents either partial desensitization or down-regulation of the GHRH receptor.
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PMID:Dual effects of growth hormone (GH)-releasing hormone infusion in normal men: somatotroph desensitization and increase in releasable GH. 308 Apr 67

Transgenic mice expressing a tyrosine hydroxylase-human (h) GH fusion gene in the hypothalamus exhibit a dwarf phenotype. The GH feedback mechanism(s) underlying the growth retardation in these animals was investigated by assessing peptide and messenger RNA (mRNA) levels of the hormones of the hypothalamic-GH-IGF-I axis. Pituitary GH content, hypothalamic GH-releasing hormone (GHRH) and somatostatin (SRIH) content, and serum IGF-I levels were measured by RIA. mRNA levels of hypothalamic GHRH and SRIH and of pituitary GH and the GHRH receptor were measured by Northern blot hybridization. Transgenic mice of both sexes and their wild-type littermates were studied at 2-4 months of age. The pituitary GH content was markedly reduced by 85% in male and by 87% in female transgenic mice compared to that in wild-type controls (P < 0.01 for both). The pituitary GH mRNA content was also decreased by 73% (P = 0.002) in transgenic male mice. Circulating IGF-I levels were significantly reduced by 66% and 68% in male and female transgenic mice, respectively (P = 0.001). The hypothalamic GHRH content was significantly reduced by 19% and 33% (P < 0.05) in male and female transgenic mice, respectively. No significant difference was detected, however, in the hypothalamic SRIH content between wild-type and transgenic mice. Hypothalamic GHRH mRNA levels were significantly decreased by 35% (P = 0.002) in transgenic male mice compared to those in wild-type littermates. In contrast, SRIH mRNA was not significantly changed. An even greater reduction (61%; P = 0.003) was observed in pituitary GHRH receptor mRNA in transgenic mice. These data indicate that the GH deficiency and dwarf phenotype of the tyrosine hydroxylase-hGH transgenic mouse can be attributed primarily to impaired hypothalamic GHRH production. The mechanism of GH feedback inhibition appears to involve direct suppression of GHRH gene expression by locally produced hGH in the hypothalamus.
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PMID:Autofeedback suppression of growth hormone (GH) secretion in transgenic mice expressing a human GH reporter targeted by tyrosine hydroxylase 5'-flanking sequences to the hypothalamus. 764 13

A binding assay for growth hormone releasing factor (GRF) has been developed using scintillation proximity assay (SPA) technology. Binding conditions were validated by several criteria. Equilibrium binding was attained within three hours at 22 degrees C in crude membrane fractions of HEK293 (293-P2) and GH4C1 (GH4-P1) cells transfected with the porcine GRF receptor. Saturation binding isotherms produced a KD of 296 pM and a Bmax of 4.7 pmols/mg membrane protein in 293-P2 cells. Cells not expressing the GRF receptor displayed no specific binding for the ligand. Competition binding curves produced the following rank order of potency for tested peptides: GRF analogs D-Ala2 = D-Arg2 (IC50 approximately 1 nM) >> PACAP > secretin, VIP (EC50 > 100 nM). Somatostatin (SRIF) binding was also adapted to the SPA format in a GH4C1 cell line transfected with the SRIF receptor subtype 2 (SSTR2) and in HEK293 cells transfected with the SRIF receptor subtype 5 (SSTR5). This assay represents a major improvement for binding measurements of these and potentially many other ligands for G-protein linked receptors, requiring no separation of bound from free hormone, allowing detailed pharmacological evaluations and enabling measurement of equilibrium binding in real time. In the 96-well format, it is suitable for high throughput screening.
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PMID:A rapid and sensitive binding assay for growth hormone releasing factor. 766 92

The molecular characterization of GHRH and the GHRH receptor provides a framework for understanding the hypothalamic regulation of pituitary somatotroph function. The signaling events discerned from our investigation of GHRH receptor structure and function form the basis of a model for GHRH action, which is shown in Fig. 20. GHRH interaction with its seven transmembrane domain Gs-coupled receptor on the somatotroph (step 1) leads to the release of growth hormone from secretory granules (step 2), which is likely to involve a G protein-mediated interaction with ion channels, and to a stimulation of intracellular cAMP accumulation (step 3) (Mayo, 1992; Lin et al., 1992; Gaylinn et al., 1993). In several cell types tested, elevated cAMP leads to the phosphorylation and activation of the transcription factor CREB by protein kinase A (Gonzalez and Montminy, 1989; Sheng et al., 1991), and one target gene for CREB action is the pituitary-specific transcription factor Pit-1 or GHF-1 (step 4) (Bodner et al., 1988; Ingraham et al., 1988; McCormick et al., 1990). Pit-1 is a prototypic POU domain protein that is required for the appropriate regulation of the growth hormone gene in somatotroph cells, thus providing a pathway by which a GHRH signal can lead to increased growth hormone synthesis in the pituitary (step 5). In addition, Pit-1 is likely to directly regulate the synthesis of the GHRH receptor (step 6), in that the receptor is not expressed in the pituitary of dw/dw mice that lack functional Pit-1 (Lin et al., 1992), and a cotransfected Pit-1 expression construct can activate the GHRH receptor promoter in transiently transfected CV1 cells (Lin et al., 1993). It remains to be determined whether additional direct regulation of the GHRH receptor gene in response to the cAMP signaling pathway occurs (step 7). The inhibitory peptide somatostatin presumably interacts with this same signaling pathway through G protein-mediated suppression of the cAMP pathway (Tallent and Reisine, 1992; Bell and Reisine, 1993). In agreement with the importance of this signaling system for normal growth, a transgene encoding a nonphosphorylatable mutant CREB protein, which blocks the function of the endogenous CREB protein, is able to cause somatotroph hypoplasia and dwarfism in mice when its expression is targeted to pituitary somatotrophs (Struthers et al., 1991). Several steps in the signaling pathway leading to growth hormone secretion are subject to disruption, resulting in growth hormone deficiency.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Growth hormone-releasing hormone: synthesis and signaling. 774 Jan 67

Thyroid hormones are important to growth in mammals and have been shown to rapidly stimulate the rate of GH gene transcription. In this study, we investigated whether thyroid hormones modulate GH secretion through their effects on the gene expression of GRF, somatostatin (SS), GRF receptor, and receptor subtype 2 for SS (SSTR2). Male adult Sprague-Dawley rats were rendered hypothyroid with a single injection of propylthiouracil followed by methimazole in drinking water (0.02%) for 1 day to 12 weeks. Total RNA extracted from the anterior pituitary and hypothalamus was analyzed by Northern hybridization. GH messenger RNA (mRNA) level in the anterior pituitary was significantly reduced in the hypothyroid animals (P < 0.0001 vs. controls for all treatment duration > or = 1 week). An increase in hypothalamic GRF mRNA level, by 2- and 4-fold, respectively, was seen after 3 and 12 weeks of antithyroid treatment (both P < 0.001 vs. controls). Hypothalamic GRF content, studied in 12-week hypothyroid rats only, was decreased compared with controls (P < 0.05). A reduction in pituitary GRF receptor mRNA level was observed after 1 week of antithyroid treatment (P < 0.01 after 1 week, P < 0.001 after 3 weeks). Total hypothalamic SS content and SS mRNA level in hypothalamic fragments consisting predominantly of the paraventricular and periventricular nuclei became significantly decreased (P < 0.05 and P < 0.005 respectively) after 12-weeks of antithyroid treatment. The reduction in SS gene expression in the periventricular nuclei was confirmed by in situ hybridization. No significant change in the mRNA level of pituitary SSTR2 was observed up to 12 weeks of antithyroid treatment. In conclusion, we have demonstrated a reduction in the gene expression of GRF receptor and SS in the hypothyroid rat. Our results suggest that the changes in hypothalamic GRF and SS gene expression in hypothyroid rats may be compensatory in nature and are likely to be secondary to the reduction in GH synthesis and secretion in these animals. The reduction in basal and GRF-stimulated GH secretion in hypothyroidism can be explained by the observed reduction in GH and GRF receptor gene expression.
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PMID:Gene expression of hypothalamic somatostatin, growth hormone releasing factor, and their pituitary receptors in hypothyroidism. 859 84

The mechanism of action of GH-releasing peptide-6 (GHRP-6) and GHRP-2 on GH release was investigated in ovine and rat pituitary cells in vitro. In partially purified sheep somatotrophs, GHRP-2 and GH-releasing factor (GRF) increased intracellular cyclic AMP (cAMP) concentrations and caused GH release in a dose-dependent manner; GHRP-6 did not increase cAMP levels. An additive effect of maximal doses of GRF and GHRP-2 was observed in both cAMP and GH levels whereas combined GHRP-6 and GHRP-2 at maximal doses produced an additive effect on GH release only. Pretreatment of the cells with MDL 12,330A, an adenylyl cyclase inhibitor, prevented cAMP accumulation and the subsequent release of GH that was caused by either GHRP-2 or GRF. The cAMP antagonist, Rp-cAMP also blocked GH release in response to GHRP-2 and GRF. The cAMP antagonist did not prevent the effect of GHRP-6 on GH secretion whereas MDL 12,330A partially reduced the effect. An antagonist for the GRF receptor, [Ac-Tyr1,D-Arg2]-GRF 1-29, significantly diminished the effect of GHRP-2 and GRF on cAMP accumulation and GH release, but did not affect GH release induced by GHRP-6. Somatostatin prevented cAMP accumulation and GH release responses to GHRP-2, GRF and GHRP-6. Ca2+ channel blockade did not affect the cAMP increase in response to GHRP-2 or GRF but totally prevented GH release in response to GHRP-2, GRF and GHRP-6. These results indicated that GHRP-2 acts on ovine pituitary somatotrophs to increase cAMP concentration in a manner similar to that of GRF; this occurs even during the blockade of Ca2+ influx. GHRP-6 caused GH release without an increase in intracellular cAMP levels. GH release in response to all three secretagogues was reduced by somatostatin and was dependent upon the influx of extracellular Ca2+. The additive effect of GHRP-2 and GRF or GHRP-6 suggested that the three peptides may act on different receptors. In rat pituitary cell cultures, GHRP-6 had no effect on cAMP levels, but potentiated the effect of GRF on cAMP accumulation. The synergistic effect of GRF and GHRP-6 on cAMP accumulation did not occur in sheep somatotrophs. Whereas GHRP-2 caused cAMP accumulation in sheep somatotrophs, it did not do so in rat pituitary cells. These data indicate species differences in the response of pituitary somatotrophs to the GHRPs and this is probably due to different subtypes of GHRP receptor in rat or sheep.
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PMID:The effects of GH-releasing peptide-6 (GHRP-6) and GHRP-2 on intracellular adenosine 3',5'-monophosphate (cAMP) levels and GH secretion in ovine and rat somatotrophs. 869 33

Many important advances in our understanding of the growth hormone (GH) axis have occurred during the last decade. A number of neurotransmitters and neuropeptides are implicated in the control of growth hormone-releasing hormone (GHRH) and somatostatin release; however, the role of many of these, such as serotonin, gamma-aminobutyric acid and dopamine, is still a matter of discussion. As a newly isolated hypothalamic peptide with a possible role in the control of GH secretion, pituitary adenylate cyclase activating peptide has received considerable attention. Synthetic hexapeptides that stimulate GH release (GH-releasing peptides 1, 2 and 6) have been identified. Pituitary-specific transcription factors involved in the expression of the GH gene have been identified, the GHRH receptor gene has been cloned, as well as a number of somatostatin receptor genes, and advances in our understanding of the insulin-like growth factor-binding proteins, and growth hormone-binding proteins have been made.
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PMID:The growth hormone axis: control and effects. 880 20

Repeated stimulation of pituitary cell cultures with GH-releasing hormone (GHRH) results in diminished responsiveness, a phenomenon referred to as homologous desensitization. One component of GHRH-induced desensitization is a reduction in GHRH-binding sites, which is reflected by the decreased ability of GHRH to stimulate a rise in intracellular cAMP. In the present study, we sought to determine if homologous down-regulation of GHRH receptor number is due to a decrease in GHRH receptor synthesis. To this end, we developed and validated a quantitative RT-PCR assay system that was capable of assessing differences in GHRH-R messenger RNA (mRNA) levels in total RNA samples obtained from rat pituitary cell cultures. Treatment of pituitary cells with GHRH, for as little as 4 h, resulted in a dose-dependent decrease in GHRH-R mRNA levels. The maximum effect was observed with 0.1 and 1 nM GHRH, which reduced GHRH-R mRNA levels to 49 +/- 4% (mean +/- SEM) and 54 +/- 11% of control values, respectively (n = three separate experiments; P < 0.05). Accompanying the decline in GHRH-R mRNA levels was a rise in GH release; reaching 320 +/- 31% of control values (P < 0.01). Because of the possibility that the rise in medium GH level is the primary regulator of GHRH-R mRNA, we pretreated pituitary cultures for 4 h with GH to achieve a concentration comparable with that induced by a maximal stimulation with GHRH (8 micrograms GH/ml medium). Following pretreatment, cultures were stimulated for 15 min with GHRH and intracellular cAMP accumulation was measured by RIA. GH pretreatment did not impair the ability of GHRH to induce a rise in cAMP concentrations. However, as anticipated, GHRH pretreatment (10 nM) significantly reduced subsequent GHRH-stimulated cAMP to 46% of untreated controls. These data suggest that GHRH, but not GH, directly reduces GHRH-R mRNA levels. To determine whether this effect was mediated through cAMP, cultures were treated with forskolin, a direct stimulator of adenylate cyclase. Forskolin (10 microM) significantly reduced GHRH-R mRNA concentrations (37 +/- 6% of control values) indicating that GHRH acts through the cAMP-second messenger system cascade to regulate GHRH-R mRNA. The somatostatin analogue, octreotide (10 nM), which has been previously reported to decrease adenylate cyclase activity, did not affect GHRH-R mRNA levels. Taken together, these results indicate that GHRH inhibits the production of its own receptor by a receptor-mediated, cAMP-dependent reduction of GHRH-R mRNA accumulation.
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PMID:Homologous down-regulation of growth hormone-releasing hormone receptor messenger ribonucleic acid levels. 904 9

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