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H. Sugihara
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S. Minami
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I. Wakabayashi
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ABSTRACT

To examine the characteristics of GH secretion following the termination of the infusion of somatostatin, unrestrained adult female Wistar rats were subjected to repeated infusions of somatostatin separated by 30-min control periods. When somatostatin was infused for 150 min at a dose of 3, 30 or 300 μg/kg body wt per h, the magnitude of the rebound GH secretion increased in a dose-dependent manner. The infusion of somatostatin at a dose of 300 μg/kg body wt per h for 60, 150 or 240 min progressively augmented the size of the rebound GH secretion. When an antiserum to rat GH-releasing factor (GRF) was injected i.v. 10 min before the end of the infusion, the peak amplitude of the rebound GH secretion (300 μg/kg body wt, 150 min) was reduced to less than 20% of that of control rats. The rebound GH secretion (300 μg/kg body wt per h, 150 min) was augmented by a bolus injection of human GRF (1 μg/kg body wt). The combined effect of the end of infusion of somatostatin and a bolus injection of GRF on the amount of GH secreted was additive. The plasma GH response to GRF was completely inhibited when human GRF (3 μg/kg body wt per h) and somatostatin (300 μg/kg body wt per h) were infused simultaneously for 150 min. The magnitude of the rebound GH secretion following the termination of the co-administration was larger than that following the somatostatin infusion alone, but this rebound was not enhanced by a bolus injection of human GRF. Moreover, the amount of GH secreted was significantly less than that after the termination of somatostatin infusion plus a bolus injection of human GRF in the absence of preceding GRF administration.

These results suggest that at least part of the influence of somatostatin on GH secretion is exerted at the level of the hypothalamus through modulating the release of GRF. In addition, it is inferred that the simultaneous infusion of GRF and somatostatin induces the attenuation of the GH response to GRF through a receptor effect.

Journal of Endocrinology (1989) 122, 583–591

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M. Mori
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M. Murakami
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T. Iriuchijima
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H. Ishihara
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I. Kobayashi
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S. Kobayashi
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K. Wakabayashi
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ABSTRACT

An influence of thyrotrophin-releasing hormone (TRH) on TSH heterogeneity in close association with de-novo biosynthesis was studied in rat anterior pituitary glands. Hemipituitary glands from adult male rats were incubated in Krebs–Henseleit–glucose media containing [3H]glucosamine and [14C]alanine for 3 and 6 h in the presence or absence of 10 ng TRH per ml. Fractions of TSH in the pituitary extracts were obtained using affinity chromatography coupled with an anti-rat TSH globulin. These TSH fractions were analysed by isoelectric focusing. The control pituitary glands were composed of four component peaks (isoelectric point (pI) 8·7, 7·8, 5·3 and 2·5) of [3H]glucosamine and [14C]alanine incorporated into TSH, and the amounts of radioactivity of these components were increased with the incubation time. Of these peaks, radioactive components of pI 8·7 and 7·8 coincided with the non-radioactive TSH components measured by radioimmunoassay. Addition of TRH increased incorporation of [14C]alanine into TSH in each of the components to a greater extent than that of [3H]glucosamine. In addition, new components with pI 7·2, 6·5 and 6·2, each component corresponding to each unlabelled TSH component, were demonstrated in the presence of TRH. Because addition of TRH did not change the amounts of [14C]alanine-labelled TSH in the media, the newly formed components were assumed to be connected with protein synthesis occurring in the anterior pituitary gland, which may be specific substances in response to TRH administration. These results indicate that TRH principally elicits an increase in protein synthesis in TSH at the anterior pituitary level, resulting in an alteration of TSH heterogeneity.

J. Endocr. (1984) 103, 165–171

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S Minami
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N Suzuki
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H Sugihara
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H Tamura
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N Emoto
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I Wakabayashi
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Abstract

It has been surmised that GH exerts feedback action on the hypothalamus and thereby regulates its own secretion. Our previous studies suggested that GH acts on somatostatin neurons in the hypothalamic periventricular nucleus (PeV) and neuropeptide Y (NPY) neurons in the hypothalamic arcuate nucleus (ARC). However, there remains uncertainty whether GH acts directly or indirectly through the generation of IGFs on the hypothalamus to regulate its own secretion. To examine this, rat GH (rGH) or human IGF-I was injected directly into a defined area of the hypothalamus, and the blood GH profile was observed in conscious male rats. In the rats given 0·5 μg rGH into the ARC or PeV bilaterally, GH secretion was inhibited, and the inhibition lasted for 12 h. During the period of inhibition, the duration and amplitude of GH pulses were significantly decreased and the episodic secretion of GH appeared irregularly compared with the vehicle-injected control rats. In control rats given the vehicle or those given rGH into the lateral hypothalamus, the blood GH profile did not change and pulsatile GH secretion was produced every 3 h. When 0·1 μg IGF-I was injected into the ARC or PeV bilaterally, the blood GH secretory pattern was not affected. Together with the results of our previous studies showing that c-fos gene expression was induced by systemic administration of GH and that GH receptor mRNA was contained in somatostatin neurons in the PeV and NPY neurons in the ARC, the data of the present study indicate that GH, but not IGF-I, acts on the cells in the ARC and the PeV or in their vicinity to inhibit its own secretion, presumably by activating the somatostatin and NPY neurons.

Journal of Endocrinology (1997) 153, 283–290

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BS Shepherd
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SM Eckert
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IS Parhar
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MM Vijayan
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I Wakabayashi
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T Hirano
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EG Grau
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TT Chen
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Abstract Studies in mammals have shown that synthetic Met-enkephalin derivatives, called growth hormone-releasing peptides (GHRPs), stimulate growth hormone (GH) release. The present study was conducted to determine whether the GHRP, KP-102, specifically stimulates GH release in a teleost. Tilapia (Oreochromis mossambicus) were given a single intraperitoneal injection of KP-102 (D-Ala-D-beta;-Nal-Ala-Trp-D-Phe-Lys-NH(2)) or bovine GHRH(1-29)-amide or vehicle and blood was sampled at 1, 6 and 12 h after injection. KP-102 was administered at two doses of 1 ng/g and 10 ng/g body weight, whereas GHRH (positive control) was administered at a single dose of 10 ng/g body weight. Plasma levels of tilapia GH and prolactins (tPRL(177) and tPRL(188)) were determined by radioimmunoassay. As expected, GHRH injection significantly (P<0.001) elevated plasma GH levels (ng/ml) in tilapia at 6 h post-injection. KP-102 also significantly elevated GH levels (at the low dose) at 6 (P<0.05) and 12 (P<0.01) hours post-injection. There were no significant effects on plasma PRL(s) levels, although mean levels of both PRLs were elevated at 6 h post-injection. These results show for the first time that GHRPs stimulate GH release in teleosts and suggest that the GHRP receptor and possibly a "Ghrelin-like" ligand are also present in lower vertebrates.

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