Influence of nitric oxide on hypoglycemia--or angiotensin II-stimulated ACTH and GH secretion in normal men

Nitric oxide inhibits ghrelin-induced cell proliferation and ERK1/2 activation in GH3 cells

Ghrelin stimulates growth hormone release and cell proliferation, which strongly supports a significant role for this peptide in the control of growth hormone-releasing adenomas function and growth. Nitric oxide can influence the stimulatory effects of ghrelin on growth hormone secretion in growth hormone-releasing adenomas. However, the effect of nitric oxide (NO) on ghrelin-induced cell proliferation and the mechanism of this effect in the adenoma were not clarified. In this study, we observed that ghrelin, at a concentration of 10⁻⁹ to 10⁻⁶ M, significantly increased BrdU incorporation into rat GH3 cells. A NO donor, S-nitroso-N-acetylpenicillamine (SNAP), blunted basal, and ghrelin-induced cell proliferation. A blocker of NO synthase, Nw-nitro-L-arginine methyl ester hydrochloride (NAME), had no influence on these actions. The activation of extracellular signal-regulated kinase (ERK) 1/2 was examined by western blotting. The results showed that SNAP reduced ghrelin-stimulated ERK1/2 activation but NAME had no influence on this activation. Together, this study indicates that NO inhibited ghrelin-induced cell proliferation by blocking ERK1/2 activation in GH3 cells.

Neuronal nitric oxide synthase in the olfactory system, forebrain, pituitary and retina of the adult teleost Clarias batrachus

Immunocytochemical application of antibodies against nNOS to the brain sections of Clarias batrachus revealed intense immunoreactivity in several olfactory receptor neurons (ORNs), in their axons over the olfactory nerve, and terminals in the olfactory glomeruli. Several basal cells in the olfactory epithelium showed NOS immunoreactivity. Application of post-embedding immunoelectron microscopy showed nNOS labeled gold particles in apical cilia, dendrites and soma of the ORNs and also in the axon terminals in the glomeruli of the olfactory bulb. nNOS containing fibers were also encountered in the medial olfactory tracts (MOTs). Bilateral ablation of the olfactory organ resulted in total loss of nNOS immunoreactivity in the fascicles of the olfactory nerve layer and also in the MOT. nNOS immunoreactivity was seen in several cells of the nucleus preopticus (NPO) and their axons that innervate the pituitary gland. Some cells in the floor of the tuberal area were stained positive with nNOS antibodies. nNOS immunolabeled cells were seen in all the three components of the pituitary gland with light as well as post-embedding immunoelectron microscopy. While several nNOS immunoreactive fibers were seen in rostral pars distalis, a much limited fiber population was seen in the proximal pars distalis. In addition, conspicuous immunoreactivity was noticed in some ganglion cells in the retina and in some fibers of the optic nerve traceable to the optic tectum. The NO containing system in this fish appears to be similar to that in other fishes.

Nitric oxide stimulates embryonic somatotroph differentiation and growth hormone mRNA and protein expression through a cyclic guanosine monophosphate-independent mechanism

In the pituitary gland, NO is locally synthesized by gonadotroph and folliculo-stellate cells. Many reports have shown that NO can modulate the growth hormone (GH) secretion. However, its role on mice embryo GH regulation remains unclear. In addition, it is unknown whether the regulation is associated with the proliferation of pituitary cells. In this study, we have investigated the regulatory effects of NO on somatotroph differentiation, proliferation and GH mRNA and protein expression using primary cell cultures of mice fetal pituitaries (embryonic days 16.5, ED 16.5). Our results show that incubation of pituitary cells in the presence of sodium nitroprusside (SNP; 1mM), a NO donor, for 4.5h resulted in a significant increase in GH mRNA and protein expression (P<0.05) and the stimulation of SNP can be inhibited by hemoglobin, a NO scavenger. But the addition of cyclic guanosine monophosphate (cGMP; 3.0mM), the second messenger of multiple NO actions cannot influence GH mRNA and protein expression. The cyclic nucleotide cellular efflux pumps existed in the pituitary cells can transport the majority of de novo-produced cGMP and effectively block cGMP accumulation. For maintaining intracellular concentration of cGMP, probenecid (0.5mM), a blocker of cGMP efflux pump, combined with cGMP (3.0mM) was used to treat the pituitary cells. This also cannot influence GH mRNA and protein expression. In addition, the ratio of GH-positive cells is increased significantly after the stimulation of SNP (P<0.05). However, SNP cannot modulate the pituitary cell proliferation. From these results we conclude that NO can increase GH mRNA and protein expression in fetal pituitary cells and cGMP is not involved in this hormonal regulation. Stimulation of NO on the somatotroph differentiation does not occur due to pituitary cell proliferation.

NO Synthase Inhibition Increases Aldosterone in Humans

To test the hypothesis that NO influences aldosterone production in humans, we examined the effect of N G -nitro- l -arginine methyl ester ( l -NAME) on aldosterone concentrations in the presence and absence of the NO precursor l -arginine (3 g TID) and the angiotensin-converting enzyme inhibitor ramipril (10 mg QD). Ten normal subjects were given l -NAME (66 μg/kg per min for 30 minutes) or vehicle in random order on separate days during placebo and after randomized, double-blind treatment with l -arginine, ramipril, or l -arginine plus ramipril. Infusion of l -NAME significantly increased systolic blood pressure (all P <0.05) and decreased heart rate (all P ≤0.02) during all 4 treatment arms. After placebo pretreatment, serum aldosterone was significantly higher during l -NAME infusion than during vehicle (6.6±1.7 versus 3.3±0.5 ng/dL; P =0.045). Combined treatment with l -arginine plus ramipril abolished this effect. There was no effect of l -NAME on plasma renin activity (PRA; P =0.297) or angiotensin II concentrations ( P =0.537). However, there was a significant interactive effect of l -NAME and time on serum potassium ( P =0.039). There was a significant linear relationship between PRA and aldosterone concentration after vehicle infusion ([aldosterone]=3.9·PRA+1.9; r 2 =0.476; P =0.027) and l -NAME infusion ([aldosterone]=7.2·PRA+3.1; r 2 =0.457; P =0.032), and the intercepts of these lines were different ( P =0.029). There was a significant linear relationship between serum potassium and aldosterone during l -NAME ([aldosterone]=8.2 · [potassium]−28.9; r 2 =0.609; P =0.008) but not during vehicle ( P =0.313). These data suggest that endogenous NO modulates aldosterone synthesis in humans.

Evidence that nitric oxide is involved in the regulation of growth hormone secretion in goldfish

Whether nitric oxide (NO) plays a role in regulation of growth hormone (GH) secretion from somatotropes in the pituitary of the goldfish Carassius auratus was investigated. Immunocytochemistry with two antibodies against mammalian NO synthase (NOS) revealed the presence of a NOS-like enzyme in primary cultures of dispersed goldfish pituitary cells, including morphologically identified somatotropes. NO donors S-nitroso-N-acetylpenicillamine and sodium nitroprusside (SNP), as well as a cyclic guanosine monophosphate analogue (dibutyryl guanosine 3':5'-cyclic monophosphate), all significantly increased GH secretion from dispersed goldfish pituitary cells in static culture. Somatostatin abolished the response to SNP, and NOS inhibitors aminoguanadine hemisulfate (AGH) and N-(3-aminomethyl)benzylacetamidine, dihydrochloride (1400W) decreased the GH release response to known neuroendocrine factors stimulatory to GH release (gonadotropin-releasing hormone and a dopamine D1 agonist). AGH and 1400W did not alter basal GH secretion. These data suggest that NO plays a role in mediating the GH response to endogenous neuroendocrine factors in goldfish.

Effect of nitric oxide synthase inhibitors on short-term appetite and food intake in humans

Animal studies suggest that nitric oxide (NO) may be a physiological regulator of appetite; NO synthase (NOS) inhibition suppresses food intake in rats, mice, and chickens. It is not known whether NO has any effect on appetite in humans. We have used NG-monomethyl-L-arginine (L-NMMA) and NG-nitro-L-arginine methyl ester (L-NAME), both competitive, nonselective inhibitors of NOS, in two separate studies to evaluate the role of NO in the short-term regulation of appetite in humans. In study I, 13 men (18-25 yr) underwent paired studies, in randomized, double-blind fashion, after an overnight fast. L-NMMA (4 mg. kg-1. h-1) or saline (0.9%) was infused intravenously at a rate of 40 ml/h for 1.5 h. In study II, eight men (18-26 yr) underwent three randomized, double-blind studies after an overnight fast. L-NAME (75 or 180 micrograms . kg-1. h-1) or saline (0.9%) was infused intravenously at a rate of 20 ml/h for 120 min. Hunger and fullness were measured using visual analog scales; blood pressure and heart rate were monitored, and 30 min before the end of the infusion, subjects were offered a cold buffet meal. Total caloric intake and the macronutrient composition of the meal were determined. Both L-NMMA (P = 0.052) and L-NAME (P < 0.05; both doses) decreased heart rate, L-NMMA increased diastolic blood pressure (P < 0.01), and L-NAME increased systolic blood pressure (P = 0.052). Neither drug had any effect on caloric intake or sensations of hunger or fullness. Despite having significant effects on cardiovascular function in the doses used, neither L-NMMA nor L-NAME had any effect on feeding, suggesting that NO does not affect short-term appetite or food intake in humans.

Neuroendocrine control of growth hormone secretion

The secretion of growth hormone (GH) is regulated through a complex neuroendocrine control system, especially by the functional interplay of two hypothalamic hypophysiotropic hormones, GH-releasing hormone (GHRH) and somatostatin (SS), exerting stimulatory and inhibitory influences, respectively, on the somatotrope. The two hypothalamic neurohormones are subject to modulation by a host of neurotransmitters, especially the noradrenergic and cholinergic ones and other hypothalamic neuropeptides, and are the final mediators of metabolic, endocrine, neural, and immune influences for the secretion of GH. Since the identification of the GHRH peptide, recombinant DNA procedures have been used to characterize the corresponding cDNA and to clone GHRH receptor isoforms in rodent and human pituitaries. Parallel to research into the effects of SS and its analogs on endocrine and exocrine secretions, investigations into their mechanism of action have led to the discovery of five separate SS receptor genes encoding a family of G protein-coupled SS receptors, which are widely expressed in the pituitary, brain, and the periphery, and to the synthesis of analogs with subtype specificity. Better understanding of the function of GHRH, SS, and their receptors and, hence, of neural regulation of GH secretion in health and disease has been achieved with the discovery of a new class of fairly specific, orally active, small peptides and their congeners, the GH-releasing peptides, acting on specific, ubiquitous seven-transmembrane domain receptors, whose natural ligands are not yet known.

L-arginine-induced growth hormone secretion is not influenced by co-infusion of the nitric oxide synthase inhibitor N-monomethyl-L-arginine in healthy men

In animals, it has been demonstrated that nitric oxide (NO) is a potent neuroregulatory substance. By intravenous infusion, L-arginine is converted to NO and citrulline, but it is unknown whether NO is responsible for the GH stimulating effect of L-arginine in humans. We investigated whether intravenous infusion of the NO synthase inhibitor N-monomethyl-L-arginine (L-NMMA) influenced L-arginine stimulated GH secretion. Ten healthy men, aged 28.6 +/- 1.9 (mean +/- SEM) years were examined twice. L-arginine was infused intravenously in a dose of 0.5 g/kg, max 35 g, from 0 to 30 min, accompanied by either: (1) L-NMMA from -5 to 0 min, in a dose of 3 mg/kg, max 250 mg, and in a dose of 3.5 mg/kg, max 250 mg from 0 to 60 min; or (2) a saline infusion. Heart rate increased (P = 0.032), and diastolic blood pressure decreased (P < 0.001) in the two situations. Plasma cGMP was unchanged and identical in the two situations (P = 0.679). Urine cGMP/creatinine ratio increased during both examinations (P = 0.041). Growth hormone secretion increased significantly during L-arginine infusion (P = < 0.001) without any effect of L-NMMA (P = 0.848). We did not find evidence that NO influences GH secretion. It remains to be tested, however, whether a higher dose of L-NMMA may influence L-arginine stimulated GH secretion.

Nitric oxide modulation of the growth hormone-releasing activity of Hexarelin in young and old dogs

The growth hormone (GH)-releasing activity of Hexarelin, a potent GH-releasing peptide (GHRP) analog, was evaluated in eight young (aged 1 to 6 years) and five old (10 to 16 years) beagle dogs pretreated with erythrityl tetranitrate, a liposoluble nitric oxide (NO) donor, and/or indomethacin, an inhibitor of cyclooxygenase enzymes, and N-nitro-L- or N-nitro-D-arginine methylester (L-NAME and D-NAME), active and inactive NO synthase (NOS) inhibitors, respectively. Erythrityl tetranitrate (0.3 mg x kg(-1) oral [p.o.]) strikingly potentiated Hexarelin-stimulated GH secretion (31.25 microg x kg(-1) intravenous [i.v.]) in both young (area under the time-concentration curve at 0 to 90 minutes AUC(0-90)] 878.50 +/- 267.02 v 1,994.04 +/- 434.20 ng x mL(-1) x h, P < .01) and aged animals (314.82 +/- 117.11 v 1,314.12 +/- 484.75 ng x mL(-1) x h, P < .01). The NO donor alone did not modify baseline GH levels in either young dogs (188.68 +/- 85.24 ng x mL(-1) x h) or old dogs (120.49 +/- 22.03 ng x mL(-1) x h). L-NAME (5 mg x kg(-1) x 2 i.v.) suppressed GH release induced by the peptide in young dogs (1,367.68 +/- 251.87 v 411.12 +/- 68.49 ng x mL(-1) x h, P < .01), but potentiated it in old dogs (314.73 +/- 117.10 v 1,103.97 +/- 374.11 ng x mL(-1) x h, P < .01). D-NAME (5 mg x kg(-1) x 2 i.v.) did not affect the GH response to Hexarelin in either young (1,328.68 +/- 433.54 ng x mL(-1) x h) or aged (342.32 +/- 84.82 ng x mL(-1) x h) dogs. Indomethacin (1.5 mg x kg(-1) i.m.) abolished the NO-donor potentiation of the GH response induced by Hexarelin in both young dogs (1,627.25 +/- 260.90 v 1,163.37 +/- 334.84 ng x mL(-1) x h, P < .05) and old dogs (1,061.47 +/- 210.38 v 365.69 +/- 79.27 ng x mL(-1) x h, P < .01) without affecting the plasma GH peak evoked by the peptide alone (young dogs, 786.04 +/- 153.44 v 960.04 +/- 444.44 ng x mL(-1) x h, P = NS; old dogs, 474.55 +/- 47.30 v 490.82 +/- 144.86 ng x mL(-1) x h, P = NS). In conclusion, (1) NO donors are capable to further increase the strong GH-releasing activity of Hexarelin in both young and old dogs, although the site(s) and mechanism(s) of action of NO is still obscure; (2) the different GH response to the peptide after NOS inhibition in young and old dogs signifies in the latter an alteration of the somatotrope function; and (3) prostaglandins are the downstream effectors of the chain of events triggered by activation of the NO-ergic system.

Kalirin inhibition of inducible nitric-oxide synthase

Nitric oxide (NO) acts as a neurotransmitter. However, excess NO produced from neuronal NO synthase (nNOS) or inducible NOS (iNOS) during inflammation of the central nervous system can be neurotoxic, disrupting neurotransmitter and hormone production and killing neurons. A screen of a hippocampal cDNA library showed that a unique region of the iNOS protein interacts with Kalirin, previously identified as an interactor with a secretory granule peptide biosynthetic enzyme. Kalirin associates with iNOS in vitro and in vivo and inhibits iNOS activity by preventing the formation of iNOS homodimers. Expression of exogenous Kalirin in pituitary cells dramatically reduces iNOS inhibition of ACTH secretion. Thus Kalirin may play a neuroprotective role during inflammation of the central nervous system by inhibiting iNOS activity.

Pathophysiology of the neuroregulation of growth hormone secretion in experimental animals and the human

During the last decade, the GH axis has become the compelling focus of remarkably active and broad-ranging basic and clinical research. Molecular and genetic models, the discovery of human GHRH and its receptor, the cloning of the GHRP receptor, and the clinical availability of recombinant GH and IGF-I have allowed surprisingly rapid advances in our knowledge of the neuroregulation of the GH-IGF-I axis in many pathophysiological contexts. The complexity of the GHRH/somatostatin-GH-IGF-I axis thus commends itself to more formalized modeling (154, 155), since the multivalent feedback-control activities are difficult to assimilate fully on an intuitive scale. Understanding the dynamic neuroendocrine mechanisms that direct the pulsatile secretion of this fundamental growth-promoting and metabolic hormone remains a critical goal, the realization of which is challenged by the exponentially accumulating matrix of experimental and clinical data in this arena. To the above end, we review here the pathophysiology of the GHRH somatostatin-GH-IGF-I feedback axis consisting of corresponding key neurotransmitters, neuromodulators, and metabolic effectors, and their cloned receptors and signaling pathways. We propose that this system is best viewed as a multivalent feedback network that is exquisitely sensitive to an array of neuroregulators and environmental stressors and genetic restraints. Feedback and feedforward mechanisms acting within the intact somatotropic axis mediate homeostatic control throughout the human lifetime and are disrupted in disease. Novel effectors of the GH axis, such as GHRPs, also offer promise as investigative probes and possible therapeutic agents. Further understanding of the mechanisms of GH neuroregulation will likely allow development of progressively more specific molecular and clinical tools for the diagnosis and treatment of various conditions in which GH secretion is regulated abnormally. Thus, we predict that unexpected and enriching insights in the domain of the neuroendocrine pathophysiology of the GH axis are likely be achieved in the succeeding decades of basic and clinical research.

Effect of nitric oxide on basal and TRH-or metoclopramide-stimulated prolactin release in normal men. volpi@ipruniv.cce.unipr.it

In order to establish whether nitric oxide (NO) is involved in the regulation of basal and/or TRH- or metoclopramide (MCP)-stimulated PRL secretion, normal male subjects were treated i.v. with the NO-synthase (NOS) inhibitor N-nitro-L-arginine methyl ester (L-NAME) (40 mg/kg injected plus 50 mg/kg infused over 60 min) in basal conditions (N.7 subjects) or just before the PRL releasing hormone TRH (20 or 200 microg iv) (N.7 subjects) or the antidopaminergic agent MCP (1 or 10 mg iv) (N.7 subjects). In control experiments, subjects received normal saline instead of L-NAME. The administration of L-NAME modified neither the basal secretion of PRL, nor the PRL release induced by TRH (20 or 200 microg) or MCP (1 or 10 mg). These data suggest that in humans, NO is not involved in the control of PRL release at the anterior pituitary level.

Involvement of nitric oxide in vasoactive intestinal peptide-stimulated prolactin secretion in normal men

To establish whether nitric-oxide (NO) participates in the regulation of prolactin (PRL) secretion in humans in basal conditions and/or under stimulation with vasoactive intestinal polypeptide (VIP), seven normal men were treated with a placebo (normal saline) or the NO synthase (NOS) inhibitor L-NAME (40 microg/kg injected plus 50 microg/kg infused intravenously over 60 minutes), which in previous studies has been found able to modify other pituitary hormone secretions. Experiments were performed either in basal conditions or during stimulation of PRL secretion with an intravenous infusion of VIP (4 pmol/kg min over 60 minutes). The administration of L-NAME was unable to change the basal secretion of PRL. In contrast, L-NAME significantly enhanced the PRL increase induced by VIP. These data argue against an involvement of NO in regulation of basal PRL secretion. In contrast, the stimulatory effect of L-NAME on VIP-induced PRL secretion suggests that NO exerts an inhibitory control of the PRL response to VIP.

Stimulation of ACTH and GH release by angiotensin II in normal men is mediated by the AT1 receptor subtype

This study was performed in order to determine whether the stimulatory effect of plasma angiotensin II (ANG II) on Adrenocorticotropic hormone (ACTH) and growth hormone (GH) secretion in humans is mediated by AT1 subtype receptors. For this purpose, the effects of the administration of the AT1 receptor antagonist, losartan (50 mg p.o.) or a placebo on the ACTH and GH responses to ANG II (i.v. infusion for 60 min of successively increasing doses (4, 8 and 16 ng/kg/min); each dose for 20 min) were evaluated in eight normal men. ANG II infusion induced significant increases in both serum ACTH and GH levels (mean peaks were 1.6- and four-times higher than baseline, respectively). The ACTH response to ANG II was completely abolished by pretreatment with losartan. Also, the ANG II-induced GH rise was reduced by administration of losartan, but the GH response was still significantly higher than the basal value (mean peak was twice as high as the baseline). These data provide evidence of AT1 receptor involvement in mediation of the ANG-II stimulating effect on ACTH and GH secretion.