Somatostatin as a physiological regulator of pulsatile growth hormone secretion

Somatostatin plays an important role in the regulation of the episodic and ultradian rhythm of growth hormone (GH) secretion. Passive immunization of rats with specific antibodies to the 14 and 28 amino acid sequences caused a significant GH elevation. The fact that somatostatin antiserum was unable to block episodic GH surges indicates that this hormone's release must be regulated by a dual mechanism. Indeed, GH-releasing factor (GRF) seems to be instrumental in the maintenance of pulsatile GH secretion. Moreover, exogenous GRF induced a further GH increase predominantly during the period of active secretion. Neutralization of endogenous somatostatin eliminated this time-dependent effect, indicating that this peptide blocks periodical spontaneous GH release. Food deprivation and changes in glucose homeostasis virtually obliterate the ultradian GH rhythm. In this context, peripheral somatostatin seems to play an important role. Also the central GRF/somatostatin interplay is responsible for a short-loop feedback control on pituitary somatotrops.     

Growth hormone secretion pattern is an independent regulator of growth hormone actions in humans

The importance of gender-specific growth hormone (GH) secretion pattern in the regulation of growth and metabolism has been demonstrated clearly in rodents. We recently showed that GH secretion in humans is also sexually dimorphic. Whether GH secretion pattern regulates the metabolic effects of GH in humans is largely unknown. To address this question, we administered the same daily intravenous dose of GH (0.5 mg. m(-2). day(-1)) for 8 days in different patterns to nine GH-deficient adults. Each subject was studied on four occasions: protocol 1 (no treatment), protocol 2 (80% daily dose at 0100 and 10% daily dose at 0900 and 1700), protocol 3 (8 equal boluses every 3 h), and protocol 4 (continuous GH infusion). The effects of GH pattern on serum IGF-I, IGF-binding protein (IGFBP)-3, osteocalcin, and urine deoxypyridinoline were measured. Hepatic CYP1A2 and CYP3A4 activities were assessed by the caffeine and erythromycin breath tests, respectively. Protocols 3 and 4 were the most effective in increasing serum IGF-I and IGFBP-3, whereas protocols administering pulsatile GH had the greatest effects on markers of bone formation and resorption. All GH treatments decreased CYP1A2 activity, and the effect was greatest for pulsatile GH. Pulsatile GH decreased, whereas continuous GH infusion increased, CYP3A4 activity. These data demonstrate that GH pulse pattern is an independent parameter of GH action in humans. Gender differences in drug metabolism and, potentially, gender differences in growth rate may be explained by sex-specific GH secretion patterns.     

Thyrotropin-releasing hormone injected intracerebroventricularly in the rat stimulates exocrine pancreatic secretion via the vagus nerve

The effects of intracerebroventricular (i.c.v.) injection of synthetic thyrotropin-releasing hormone (TRH) and its analogue (gamma-butyrolactone-gamma-carbonyl-His-Pro-NH2) were tested in anesthetized rats fitted with pancreatic cannula. TRH injection induced dose-related increases in flow of pancreatic juice, protein output, and amylase output, each reaching a maximum within 10 min. Higher doses of TRH induced longer responses. Injection of the TRH analogue also caused dose-related secretory responses of the exocrine pancreas. The dose-related secretory responses to TRH and the TRH analogue were similar except that the responses to the highest dose of TRH analogue (1600 pmol/100 g b.w.) were significantly higher. Intravenous injection of TRH and the TRH analogue induced little, if any, secretory response of the exocrine pancreas. The effects of i.c.v. injection of TRH and the TRH analogue were completely abolished after bilateral subdiaphragmatic vagotomy. In addition to the secretory effects on the exocrine pancreas, i.c.v. injection of TRH and the analogue caused hyperglycemia, tachycardia, and tear secretion, but the intravenous injection of these peptides had no effect.     

The immune system as a regulator of thyroid hormone activity

It has been known for decades that the neuroendocrine system can both directly and indirectly influence the developmental and functional activity of the immune system. In contrast, far less is known about the extent to which the immune system collaborates in the regulation of endocrine activity. This is particularly true for immune-endocrine interactions of the hypothalamus-pituitary-thyroid axis. Although thyroid-stimulating hormone (TSH) can be produced by many types of extra-pituitary cells--including T cells, B cells, splenic dendritic cells, bone marrow hematopoietic cells, intestinal epithelial cells, and lymphocytes--the functional significance of those TSH pathways remains elusive and historically has been largely ignored from a research perspective. There is now, however, evidence linking cells of the immune system to the regulation of thyroid hormone activity in normal physiological conditions as well as during times of immunological stress. Although the mechanisms behind this are poorly understood, they appear to reflect a process of local intrathyroidal synthesis of TSH mediated by a population of bone marrow cells that traffic to the thyroid. This hitherto undescribed cell population has the potential to microregulate thyroid hormone secretion leading to critical alterations in metabolic activity independent of pituitary TSH output, and it has expansive implications for understanding mechanisms by which the immune system may act to modulate neuroendocrine function during times of host stress. In this article, the basic underpinnings of the hematopoietic-thyroid connection are described, and a model is presented in which the immune system participates in the regulation of thyroid hormone activity during acute infection.     

The influence of age on human pancreatic growth hormone releasing hormone stimulated growth hormone secretion

63 non-obese healthy subjects aged 18 to 95 years were investigated for age-dependence of GHRH-stimulated GH-secretion. In addition, priming of GH-secretion with three oral doses of propranolol (3 x 80 mg, the last dose 2 hours prior to the second GHRH-bolus) was carried out in 15 subjects below 40 years and 13 subjects older than 70 years. We found that mean maximal incremental GH-levels were inversely correlated with chronological age (r = -0.44, P = 0.001) of the probands. Propranolol premedication caused a significant rise of both basal and peak GHRH-induced relative increases in all subjects tested, whereas GHRH-induced relative increases of GH remained unchanged. In a well selected group of non-obese healthy subjects stimulated GH-secretion is found to undergo an aging process that is supposed to be of pituitary and suprapituitary origin. Priming GH-secretion with a beta-Blocker is possible both in young and very old healthy subjects and is likely to affect the basal GH secretory tone and not GHRH-stimulated GH-secretion.     

The green algal pigment caulerpin as a plant growth regulator

Caulerpin, a green algal pigment possessing a unique bis-indole structure, has been shown to be a plant growth regulator. Root growth assays were conducted with caulerpin and its hydrolysis product, and the results were compared with data obtained with indole-3-acetic acid (IAA), indole-3-pyruvic acid (IPA) and indole-3-acrylic acid (IAcA). This study has indicated that caulerpin, in essence a dimer of indole-3-acrylic acid, behaves much like the indole auxins.     

Pharmacokinetics of growth hormone secretion in humans induced by growth hormone releasing hormone

This investigation compares the age- and sex-related changes in growth hormone (GH) response to growth hormone releasing hormone (GHRH) in normal subjects using an appropriate pharmacokinetic model. Twenty-five subjects (14 males and 11 females) aged 23-89 yr received a single intravenous bolus dose (1 microgram/kg) of GHRH-40 solution. Plasma GH concentration-time profiles are best characterized by a biexponential equation (or one-compartment model) with first-order release and disappearance rates and an equilibration lag time. The harmonic mean release rate half-life is similar for both sexes (males: 12.6 min vs. females; 11.4 min) but significantly different across age groups (23-35 yr: 7.2 min vs. 50-89 yr: 16.8 min). The mean disappearance rate half-life and GHRH-equilibration time lag for females (33.6 and 20.4 min, respectively) and the higher age group subjects (32.4 and 21.6 min, respectively) are significantly longer than those of males (22.8 and 9 min, respectively) and the lower age-group subjects (21.6 and 8.4 min, respectively). The mean metabolic clearance rate of GH is significantly lower (p less than 0.02) for females than for males (3.1 vs. 4.83 ml/hr.m2). However, the production rate and the amount of GH released by the pituitary for our subjects appear to be very similar for both males (8.7 micrograms/hr.m2 and 4.65 micrograms/m2) and females (9.33 micrograms/hr.m2 and 5.11 micrograms/m2).     

Pharmacological testing of growth hormone secretion

The laboratory confirmation of growth hormone (GH) deficiency (GHD) has been extensively studied. Multiple stimuli induce GH release, but insulin-induced hypoglycemia usually is considered the 'gold standard'. Seventy-five to 90% of normal children have significant increments of hGH to any single test. Complete and partial syndromes of GHD have been defined, but some patients with a clinical appearance of GHD release hGH during provocative testing. Discordant results on varied tests may occur in the same child. Sequential and simultaneous tests have been attempted with diverse time patterns; testing sequence may significantly affect data interpretation. Persistent problems with GH provocative tests remain: normal data not strictly defined throughout childhood, multiple tests with discordant results, and substantial discrepancies of immunopotency estimates with different radioimmunoassays. Some children with 'normal' hGH increments during provocative tests, despite clinical GHD, may require short-term treatment with hGH to finally establish the diagnosis.     

Insulin-like growth factor inhibition of growth hormone secretion

Somatomedins-insulin-like growth factors (SM/IGF) are growth hormone (GH) dependent serum growth factors. There is some evidence that IGF inhibit GH release (negative feedback) in 3- to 24-h incubations of cultured rat adenohypophysial cells. We have used acutely dispersed noncultured rat adenohypophysial cells to study the dynamics of IGF on GH secretion. In this system both IGF-I and IGF-II (100 ng/mL) slightly, but significantly, decrease the cumulative GH released by human pancreas growth hormone releasing factor 1-40 (GRF) and the phosphodiesterase inhibitor 3-isobutyl-1-methyl xanthine. The inhibition is small (16%) and usually not statistically significant until 2 h of incubation. The inhibition with IGF is additive to that produced with low concentrations of somatostatin. The IGF also significantly decrease the rate of GH release in all time periods tested (0-1, 1-2, 2-3 h). In addition, the IGF decrease the quantity of [14C]leucine protein eluted at the position of labelled rat GH on Sephadex G75, which would include newly synthesized GH extracted from the cells. Thus we conclude that the decreased GH released may be due to an effect of IGF on both rate of release and on GH synthesis.     

Pulsatile growth hormone secretion persists in genetic growth hormone-releasing hormone resistance

Growth hormone (GH) secretion is regulated by GH-releasing hormone (GHRH), somatostatin, and possibly ghrelin, but uncertainty remains about the relative contributions of these hypophysiotropic factors to GH pulsatility. Patients with genetic GHRH receptor (GHRH-R) deficiency present an opportunity to examine GH secretory dynamics in the selective absence of GHRH input. We studied circadian GH profiles in four young men homozygous for a null mutation in the GHRH-R gene by use of an ultrasensitive GH assay. Residual GH secretion was pulsatile, with normal pulse frequency, but severely reduced amplitude (<1% normal) and greater than normal process disorder (as assessed by approximate entropy). Nocturnal GH secretion, both basal and pulsatile, was enhanced compared with daytime. We conclude that rhythmic GH secretion persists in an amplitude-miniaturized version in the absence of a GHRH-R signal. The nocturnal enhancement of GH secretion is likely mediated by decreased somatostatin tone. Pulsatility of residual GH secretion may be caused by oscillations in somatostatin and/or ghrelin; it may also reflect intrinsic oscillations in somatotropes.     

The role of the vagus nerve in depression

The etiopathogenesis of depression is a highly complex process characterized by several neurobiological alterations including decreased monoamine neurotransmission in the brain, dysregulated hypothalamic-pituitary-adrenal axis activity, decreased neuronal plasticity, and chronic inflammation in the brain and peripheral tissues. Experimental and clinical studies indicate that the vagus nerve may influence these processes. The importance of the vagus nerve in the etiopathogenesis of depression is further supported by its involvement in the induction of sickness behavior, as well as by clinical studies confirming a beneficial effect of vagus nerve stimulation in depressed patients. The aim of this article is to describe current knowledge of afferent and efferent vagal pathways role in the development and progression of depression.     

Msx-1 acts as a regulator for blastema growth

Msx-1 is known to regulate ectoderm-mesenchyme and mesenchyme-mesenchyme tissue interactions in the developing vertebrate limb bud. In this study, the spatial and temporal expression pattern ofMsx-1 in the regenerating limbs of axolotls (Ambystoma mexicanum) was examined by whole mountin situ hybridization and RT-PCR. In addition, the effects of retinoic acid (RA) and denervation on theMsx-1 expression were examined as well. In the regenerating normal limbs, the weak expression ofMsx-1 was detected in the mesenchymal cells under the apical ectodermal cap. From the early bud stage, the elevated level ofMsx-1 expression was maintained until the early digit stage. However,Msx-1 expression was rapidly declined by the completion of regeneration. Compared to the normal limb regeneration,Msx-1 expression in RA treated limb regenerates was low until 9 days after RA treatment but increased during blastema growth period both m the lower and the upper arm regenerates. These results suggest that theMsx-1 regulates the proliferation and growth of blastema cells, and its expression may not be responsible for the dedifferentiation process. On the other hand, high level ofMsx-1 expression was noted in the limb stump tissue after denervation. This result indicates thatMsx-1 is also related to the regression of denervated mature tissue.     

Juvenile hormone as a physiological regulator mediating phenotypic plasticity in pancrustaceans

Phenotypic plasticity and polyphenism, in which phenotypes can be changed depending on environmental conditions, are common in insects. Several studies focusing on physiological, developmental, and molecular processes underlying the plastic responses have revealed that similar endocrine mechanisms using juvenile hormone (JH) are used to coordinate the flexible developmental processes. This review discusses accumulated knowledge on the caste polyphenism in social insects (especially termites), the wing and the reproductive polyphenisms in aphids, and the nutritional polyphenism and sexual dimorphism in stag beetles. For the comparison with non-insect arthropods, extensive studies on the inducible defense (and reproductive polyphenism) in daphnids (crustacean) are also addressed. In all the cases, JH (and methyl farnesoate in daphnids) plays a central role in mediating environmental stimuli with morphogenetic processes. Since the synthetic pathways for juvenoids, i.e., the mevalonate pathway and downstream pathways to sesquiterpenoids, are conserved across pancrustacean lineages (crustaceans and hexapods including insects), the evolution of developmental regulation by juvenoids that control molting (ecdysis) and metamorphosis is suggested to have occurred in the ancestral arthropods. The discontinuous postembryonic development (i.e., molting) and the regulatory physiological factors (juvenoids) would have enabled plastic developmental systems observed in many arthropod lineages.