Negative feedback suppression of sleep-related growth hormone secretion

Previous studies have demonstrated that injections of growth hormone (GH) can blunt subsequent GH secretory responses to daytime pharmacological stimulation. The current study was undertaken to determine whether GH administration to normal subjects would suppress sleep-related secretion. GH (2 U im) was given nine times over 5 days to each of six subjects, and sleep studies with blood sampling were performed 6 h after the last injection. Secretion during the first 2 h of sleep was decreased by 62.4%, indicating that sleep-related GH secretion may be responsive to a negative-feedback mechanism.     

Increased insulin-like growth factor II production and consequent suppression of growth hormone secretion: a dual mechanism for tumor-induced hypoglycemia

We investigated the pathophysiology of fasting hypoglycemia associated with large tumors of mesenchymal origin. We studied two patients with symptomatic fasting hypoglycemia (plasma glucose, 1.92 and 2.03 mmol/L) and a large mesenchymal neoplasm. Before therapy, the plasma insulin-like growth factor II (IGF-II) level measured by RIA was elevated (1879 and 1084 micrograms/L; normal range, 358-854 micrograms/L), the serum GH response to hypoglycemia was impaired, and the plasma IGF-I level was low in both patients. After treatment of the tumor, all of these abnormalities resolved in both patients. Northern blot analysis of tumor RNA revealed extremely high levels of IGF-II mRNA (greater than 100-fold higher than those in normal adult liver). Tumor fragments released IGF-II into tissue culture medium (2.1 and 7.2 micrograms IGF-II/g tissue.24 h). These findings indicate that secretion of IGF-II into the circulation by the tumor was the likely source of the elevated plasma IGF-II levels. We suggest that the primary event in tumor-induced hypoglycemia is overproduction of IGF-II by the tumor, which gives rise to hypoglycemia by a dual mechanism: increased glucose utilization mediated by the insulin-like actions of IGF-II and inhibition of GH secretion.     

Perfluorooctanoic acid-induced inhibition of placental prolactin-family hormone and fetal growth retardation in mice

Perfluorooctanoic acid (PFOA) is a persistent pollutant worldwide and even found in human cord blood and breast milk. Some animal studies have reported that PFOA causes developmental toxicity such as fetal weight loss, but the mechanism is still unclear. This study focused on developmental toxicity of PFOA, particularly impacts of PFOA on placental endocrine function such as placental prolactin (PRL)-family hormone gene expression and fetal growth in mouse. Time-mated CD-1 mice were dosed by gavage with 0, 2, 10 and 25 mg/kg B.W/day of PFOA (n-10) dissolved with de-ionized water from gestational day (GD) 11-16. During treatment, body weight of each pregnant mouse was measured daily. On day 16, caesarean sections were performed and developmental data were observed. Three placentas from three different pregnant mice were assigned to each of the following experiments. The mRNA levels of mouse placental lactogen (mPL)-II, prolactin like protein (mPLP)-E, -F and Pit-1α and β isotype mRNAs, a transacting factor of mPLs and mPLPs genes, were analyzed using northern blot, in situ hybridization and RT-PCR, respectively. Maternal body weight gain was significantly declined from GD 13 in the PFOA treated groups compared to control. Developmental data such as fetal and placental weights were significantly decreased in accordance with PFOA dosage. Number of dead fetuses and post-implantation losses were significantly increased in the PFOA-exposed groups. In addition, placental efficiency (fetal weight/placental weight) was significantly reduced in PFOA treated groups in accordance with PFOA dosage. Histopathologic changes were observed in placenta. Dose dependent necrotic changes were observed in both 10 mg and 25 mg PFOA treated groups. Cell frequency of glycogen trophoblast cell and parietal trophoblast giant cell were decreased dose dependently in the junctional zone. In the labyrinth zone, sinusoidal trophoblast giant cell frequency was decreased in the 25 mg PFOA treated group. Also, morphological change such as crushed nuclear (atrophy) of trophoblast cells was observed in 25 mg PFOA treated group. Finally, mRNA levels of the mPL-II, mPLP-E, -F and Pit-1α and β were significantly reduced in the PFOA treated groups dose dependently. In addition, the changing pattern between mPL-II, mPLP-E, -F mRNA levels and fetal body weight showed positive relationship. In conclusion, the inhibitory effects of PFOA on the placental prolactin-family hormone genes expression may be secondary effects to insufficient trophoblast cell type differentiation and/or increased trophoblast cell necrosis. The impacts of PFOA on placental development and endocrine function reduced the placental efficiency and partly contributed to the fetal growth retardation in the mouse.     

Delay of puberty onset in males due to suppression of growth hormone

Infection with Spirometra mansonoides at 22 days of age was associated with delayed sexual maturation in the male rat. Balanopreputial separation occurred at 46.7 +/- 0.8 days in controls and at 50.6 +/- 0.9 days in worm-treated rats (p less than 0.02). This was accompanied by a delay in the normal prepubertal testicular and seminal vesicle weight increases. LH remained normal but serum FSH was depressed as early as 25 days of age. The castration response in worm-treated rats was comparable to that of controls, when the FSH levels were normalized as percentages of resting level. The LH response to castration was diminished. The acute FSH and LH response to GnRH was normal and pituitary stores of gonadotrophin, as estimated by radioimmunoassayable concentrations of FSH and LH, were normal. It can be concluded that puberty onset in males is not linked to body weight gain pe se, and that the absence of endogenous GH secretion affects both sexual maturation and gonadotrophin secretion in the prepubertal period.     

Cellular and intracellular distribution of growth hormone in the adult chicken testis

Endocrine actions of growth hormone (GH) have been implicated during the development of adult testicular function in several mammalian species, and recently intracrine, autocrine, and paracrine effects have been proposed for locally expressed GH. Previous reports have shown the distribution of GH mRNA and the molecular heterogeneity of GH protein in both adult chicken testes and vas deferens. This study provides evidence of the presence and distribution of GH and its receptor (GHR) during all stages of spermatogenesis in adult chicken testes. This hormone and its receptor are not restricted to the cytoplasm; they are also found in the nuclei of spermatogonia, spermatocytes, and spermatids. The pattern of GH isoforms was characterized in the different, isolated germ cell subpopulations, and the major molecular variant in all subpopulations was 17 kDa GH, as reported in other chicken extra-pituitary tissues. Another molecular variant, the 29 kDa moiety, was found mainly in the enriched spermatocyte population, suggesting that it acts at specific developmental stages. The co-localization of GH with the proliferative cell nuclear antigen PCNA (a DNA replication marker present in spermatogonial cells) was demonstrated by immunohistochemistry. These results show for the first time that GH and GHR are present in the nuclei of adult chicken germinal cells, and suggest that GH could participate in proliferation and differentiation during the complex process of spermatogenesis.     

Cellular processing of growth hormone in IM-9 cells: evidence for exocytosis of internalized hormone.

IM-9 cells extensively internalize [125I]human (h) GH at physiological temperatures, yet little is known regarding the final destination of internalized hormone and its receptor. We studied this by first binding [125I]hGH to the cell surface at 4 C, and then following its fate during a subsequent incubation at 30 C in isotope-free medium. Cell-associated radioactivity decreased with time at 30 C, with a biphasic pattern suggestive of a rapid (but minor) and a slow component. The kinetics of the latter were critically influenced by NH4Cl and were abolished at 20 C. Intracellular (acid-resistant) [125I]hGH first increased with time at 30 C until it reached a maximum after 1 h, then declined continuously upon prolonged incubation. The radioactivity released by the cells was recovered in the medium as both trichloroacetic acid-precipitable material and trichloroacetic acid-soluble fragments. After sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions, one major band migrating with an estimated mol wt of 22,000 was identified, presumably corresponding to intact [125I]hGH. These data suggest exocytosis of intact hormone via recycling endosomes and degradation in the lysosomes, respectively. Computer modelling was consistent with two intracellular compartments acting partially in series and probably corresponding to these two organelles. When analyzed by computer curve fitting, this model accurately described the kinetics of [125I]hGH internalization. So, receptor-mediated endocytosis and subsequent exocytosis are part of the GH pathway in IM-9 cells. In as much as they reflect pathways of GH receptors, these processes contribute to receptor down-regulation and could provide an explanation for release into the medium of the high affinity GH-binding protein.     

Hypothalamic somatostatin mediates the suppression of growth hormone secretion by centrally administered thyrotropin-releasing hormone in conscious rats

The effect and mechanism of action of central TRH on the regulation of GH secretion was studied in conscious male rats with indwelling intraatrial and intracerebroventricular (icv) cannulae. Plasma GH was measured every 10-20 min from 1000 h-1400 h by repeated blood sampling. In animals that received saline iv or icv, GH secretion was pulsatile, with peak hormone levels occurring at 1120-1200 h. TRH (10 micrograms), injected icv at 1100 h, inhibited spontaneous GH secretion, and mean plasma GH levels remained suppressed (less than 20 ng/ml) for at least 3 h after injection. In contrast, an iv injection of the same dose of TRH at 1100 h did not significantly affect spontaneous GH secretion. Intravenous injection of human GH-releasing factor [1-40] (hGRF, 1 micrograms) at 1100 h in animals injected 5 min earlier with saline (10 microliters, icv) stimulated GH release, with peak values (748 +/- 63 ng/ml, mean +/- SE) observed 10 min after injection. However, animals injected icv with TRH (10 micrograms) 5 min before the iv injection of hGRF exhibited an attenuated GH response to hGRF (peak values, 115 +/- 28 ng/ml; P less than 0.001 vs. saline icv + hGRF). The inhibition of GH secretion by central TRH was abolished by pretreatment of animals with antisomatostatin serum (0.5 ml, iv) but not with normal serum (P less than 0.001). These results suggest an inhibitory role of central TRH in the regulation of spontaneous GH secretion in the rat that is mediated by stimulation of hypothalamic somatostatin.     

Reduction of lung distensibility in acromegaly after suppression of growth hormone hypersecretion.

Whether the growth of the lungs in acromegaly is due to alveolar hypertrophy or alveolar hyperplasia is a subject of debate. To discriminate these hypotheses, we compared pulmonary distensibility and diffusing capacity among 11 patients with active acromegaly and 11 matched control subjects, evaluating the response of pulmonary distensibility and diffusing capacity to suppression of growth hormone (GH) hypersecretion. We performed lineal and exponential analyses of quasistatic pressure-volume curves. Patients with active acromegaly had a greater TLC, lung compliance, and shape constant, K, than did normal subjects. We found no significant differences between the study groups in carbon monoxide diffusing capacity or diffusing capacity per unit of alveolar volume. After treatment, patients with inactive acromegaly showed a reduced TLC (6.95 +/- 1.40 [mean +/- SD] L versus 6.35 +/- 1.23 L), reduced lung compliance (3.61 +/- 0.90 L/kPa versus 2.36 +/- 0.79 L/ kPa), reduced K coefficient (2.62 +/- 0.65 kPa(-)(1) versus 1.35 +/- 0.40 kPa(-)(1)), and increased maximal recoil pressure (1.74 +/- 0.38 kPa versus 2.28 +/- 0.25 kPa). We conclude that the increased lung distensibility with normal diffusion capacity demonstrated in patients with active acromegaly, which was partly reversible after suppression of GH hypersecretion, suggests that lung growth in acromegaly may result from an increase in alveolar size.     

Half-life of exogenous growth hormone following suppression of endogenous growth hormone secretion with somatostatin in type I (insulin-dependent) diabetes mellitus

OBJECTIVE: To estimate the half-life of growth hormone in young adult patients with type I (insulin-dependent) diabetes mellitus following bolus injection and prolonged exposure for the purpose of deconvolution analysis of plasma growth hormone profiles to determine growth hormone secretory rates. DESIGN: In the bolus study, an intravenous bolus injection of 100 mU of biosynthetic human growth hormone was given while endogenous growth hormone was suppressed by a continuous infusion of somatostatin under three different glucose clamp conditions: normoglycaemia (5 mmol/l) with normoinsulinaemia (65 pmol/l); hyperglycaemia (12 mmol/l) with normoinsulinaemia; and normoglycaemia with hyperinsulinaemia (360 pmol/l). In the infusion study, the effect of prolonged and repeated growth hormone exposure upon the growth hormone half-life was estimated. Three pulses of 60 minutes growth hormone infusion (6 mU/kg/pulse) two hours apart under euglycaemic somatostatin suppression were applied. PATIENTS: Six young adult patients with type I (insulin-dependent) diabetes mellitus were studied in both the bolus and the infusion study. RESULTS: Mean GH half-lives by mono-exponential analysis were not significantly different remaining unaltered by the short-term metabolic changes of hyperglycaemia and hyperinsulinaemia. Data were therefore pooled yielding an overall mean GH half-life of 13.6 minutes (range 11.9-19.4). Applying a bi-exponential model mean GH half-lives were 3.1 minutes (range 2.5-5.9) for the rapid phase of distribution of the hormone and 13.8 minutes (range 9.6-16.9) for the decay of GH from the circulation. The GH half-life during the infusions studies did not vary with repeated exposure but was significantly longer (mean half-life of 25.7 minutes; range 19.4-37.1) than during the bolus studies (P less than 0.001). CONCLUSIONS: The half-life of exogenous r-hGH is not affected by glucose or insulin concentrations but increases after prolonged GH exposure in young adults with type I (insulin-dependent) diabetes mellitus.