GH and cortisol responses following an acute session of respiratory muscle endurance training in severely obese patients.

It is well established that obese patients are hypo-responsive to classical GH-releasing stimuli, including aerobic exercise. Recently, we have demonstrated that whole body vibration was able to markedly stimulate GH secretion in obese patients, thus suggesting that this refractoriness is not absolute but dependent on the GH-releasing stimulus. Furthermore, we have shown the ability of a respiratory muscle endurance training (RMET) to stimulate GH and cortisol secretion in healthy subjects. The objective of this study was to evaluate the effects of RMET on GH and cortisol responses in severely obese patients. Eight severely obese patients (4 M/4 F, mean age±SEM: 22.8±1.6 years, body mass index, BMI: 39.9±1.1 kg/m2) underwent an incremental progressive RMET protocol of 11 daily sessions, obtained through the use of a specifically designed respiratory device (Spiro Tiger®). The 12th session of RMET (15 min duration: 1 min at a respiration rate of 28 acts/min, 5 min at 32 acts/min, 5 min at 34 acts/min, 4 min at 36 acts/min) was associated with blood samplings for determination of GH, cortisol, and lactate (LA) levels. An age- and sex-matched normal-weighted control group (n=7, 4 M/3 F, age: 26.1±3.1 years, BMI: 22.4±0.6 kg/m2) was also recruited. In both normal-weighted subjects and obese patients, GH secretion significantly increased after a 15-min RMET session. Although serum GH levels at 30 min were higher in normal-weighted subjects than in obese patients, there was no statistically significant difference in either GH peaks or net GH areas under the curve between the 2 groups. RMET significantly increased serum cortisol levels in normal-weighted subjects, but was associated to a progressive cortisol decline in obese patients. RMET stimulated LA production, with no significant differences in normal-weighted subjects and in obese patients. A 15-min RMET session was capable to induce a GH response in severely obese patients, which was comparable to that recorded in normal-weighted subjects. A progressive decline in serum cortisol levels occurred in obese patients after RMET, while an opposite pattern (i. e., a significant cortisol increase) was found in normal-weighted subjects. Optimization of long-term RMET protocols could represent a valid strategy to (physiologically) stimulate GH/IGF-I system in those GH hyposecretory states such as obesity.

GH responses to two consecutive bouts of respiratory muscle endurance training in healthy adults.

Repetition of voluntary exercise bouts and of different pharmacological GH-releasing stimuli at 2-h intervals is associated with a complete abolishment of GH responsiveness. By contrast, a different pattern is observed after repeated neuromuscular electrostimulation, which is characterized by preservation of GH responsiveness. Aim of the study was to evaluate GH responses to repeated bouts of respiratory muscle endurance training (RMET) by mean of a specific commercially available device (Spiro Tiger®). Eight healthy men underwent an incremental progressive RMET protocol of 11 daily sessions. Blood samplings for GH, cortisol and lactate (LA) determinations were collected during the 12th session, which was composed of two consecutive bouts of RMET (of identical intensity and duration: 1 min at a respiration rate of 28 acts/min, 5 min at 32 acts/min, 5 min at 34 acts/min, 4 min at 36 acts/min) at a 2 h interval. Baseline GH levels (mean: 0.9±0.4 ng/ml) significantly (p<0.01) increased after the first bout of RMET (peak: 15.7±4.0 ng/ml). The administration of the second bout of RMET resulted in a significantly lower (p<0.05) GH increase (peak: 3.9±0.8 ng/ml) in comparison with the first one. Baseline LA levels (mean: 1.2±0.1 mmol/l) significantly increased (p<0.001) after the first bout of RMET (peak: 2.3±0.2 mmol/l). The administration of the second RMET bout resulted in a comparable LA increase (from a basal value of 1.2±0.1 mmol/l up to a peak of 2.0±0.1 mmol/l, p<0.001). The first bout of RMET caused a significant increase of cortisol levels (p<0.01), starting from a basal mean value of 142.9±9.4 ng/ml up to a peak of 188.8±10.3 ng/ml. By contrast, the second bout of RMET did not induce any significant change of cortisol levels (basal: 149.1±9.0 ng/ml, peak: 168.5±5.1 ng/ml). In conclusion, a single bout of RMET is capable of stimulating GH and cortisol secretions and LA production. When a second bout is repeated after 2 h, there is a blunting of GH and cortisol responses with a preservation of LA release. Further studies are needed to schedule long-term RMET protocols capable of persistently stimulating GH-IGF-I release and to maximally enhance the ergogenic and metabolic benefits of this intervention either in normal subjects (e.g. athletes) or patients with an impairment of motor capabilities requested to perform normal daily activities (i.e. severely obese and elderly people).

Estrogens need insulin-like growth factor I cooperation to exert their neuroprotective effects in post-menopausal women.

BACKGROUND: The abrupt fall in estrogens levels during the menopausal transition may connote an hormonal state predisposing to neurodegenerative disorders, e.g. Alzheimer's disease (AD). Reportedly, the neurotrophic activity of estrogen involves an interaction with IGF-I. AIM: To evaluate the leukocyte gene expression of progesterone receptor (PR-A/B) and interleukin 6 (IL-6), two parameters under the control of estrogens and involved in the pathogenesis of AD. SUBJECTS: The study was conducted in non-demented women divided into two groups according to their pre- or post-menopausal state; each group being further divided into two subgroups based on their circulating levels of IGF-I (normal or low). An additional sample of AD-affected women served as a comparison group. RESULTS: Estrogens maintained their full activity only when IGF-I levels were in the range of normalcy. On the contrary, if the concentrations of one or both hormones were reduced, estrogens were not anymore capable to control the gene expression of PR-A/B or IL-6. CONCLUSIONS: Before administering hormone-based replacement therapy, characterization of the somatotropic function should be performed in the early phase of the menopause.

Growth hormone response induced by a respiratory muscle endurance training in healthy subjects.

To date, the large majority of studies evaluating growth hormone (GH) response to acute physical exercise has been performed involving gross muscle groups. To the best of our knowledge, none has evaluated the effects of a respiratory muscle endurance training (RMET) on hormonal secretions, particularly on GH release, though some respiratory devices have been widely used in athletes to train respiratory muscles and to improve cardiopulmonary function and physical performance. 8 healthy men underwent an incremental progressive RMET protocol of 11 daily sessions, obtained through the use of a specifically designed respiratory device (Spiro Tiger®). The 12th session of RMET (15 min duration: 1 min at a respiration rate of 28 acts/min, 5 min at 32 acts/min, 5 min at 34 acts/min, 4 min at 36 acts/min) was associated with blood samplings for determination of GH, cortisol, ghrelin, glucose, and lactate (LA) levels. GH and cortisol responses significantly increased after a 15-minute RMET session, which, in contrast, inhibited ghrelin secretion. There was a minimal, though significant, increase in LA levels with a significant elevation in glycemia. A 15-minute RMET session, administered after a 11-days incremental progressive RMET protocol, was capable of stimulating GH and cortisol release and suppressing ghrelin secretion. Optimization of incremental progressive RMET protocols would be important to maximize the positive chronic effects of this intervention on somatotropic function and muscle performance.

Growth hormone variants: a potential avenue for a better diagnostic characterization of growth hormone deficiency in children.

Human GH (hGH) is a heterogeneous protein hormone consisting of several isoforms. This heterogeneity is the consequence of multiple hGH genes, mRNA splicing, post-translational modifications, and peripheral metabolism, and it represents one important reason for the disparity among GH assay results from different laboratories. However, other factors are involved: a) interference from endogenous GH binding proteins; b) different specificities of anti- GH (monoclonal and polyclonal) antibodies; c) different matrix effects among the calibrators; d) the use of different calibrators. The measurement of GH levels in response to provocative testing is an essential part of the diagnosis of GH deficiency. For this purpose, an accurate, reproducible and universally valid GH measurement would be highly desirable, but, despite a huge number of efforts in clinical biochemistry, this goal remains elusive.

The cholestyramine-induced decrease of PYY postprandial response is negatively correlated with fat mass in obese women.

Obese patients have decreased fasting and postprandial levels of peptide YY (PYY), an anorexigenic peptide produced by the L cells of the gastrointestinal mucosa. Fatty nutrients are the most powerful stimulus for PYY release. Cholestyramine, an anion exchanger which adsorbs bile salts, reduces digestion of lipids. The aim of the present study was to investigate the effects of cholestyramine or placebo on PYY secretion in obese women administered a high-fat meal [n=8; age: 30.9±2.7 years; BMI: 47.3±3.3 kg/m2]. Postprandial PYY levels in obese women given placebo significantly increased in plasma at 30, 60, 90, and 120 min after meal ingestion. Cholestyramine administration significantly reduced postprandial PYY response at 15, 30, and 60 min. Percent fat mass (FM%) was negatively correlated with the percent increment of plasma PYY concentrations induced by meal administration at 30 min; conversely, there was a positive correlation between FM% and the percent decrement of plasma PYY concentrations induced by cholestyramine at the same time interval. These correlations failed to reach statistical significance when related to BMI. This study implies that in the obese state the altered PYY response to food consumption is a consequence of a dysfunction of L cells, which become less sensitive to the positive feedback effect of lipids.

Changes in plasma levels of ghrelin, leptin, and other hormonal and metabolic parameters following standardized breakfast, lunch, and physical exercise before and after a multidisciplinary weight-reduction intervention in obese adolescents.

OBJECTIVE: To investigate in severely obese adolescents the effects of a 3-week multidisciplinary weight-reduction intervention involving moderate energy restriction, individualised physical activity and behavior therapy on the response of some hormonal and metabolic parameters to meals and exercise. DESIGN: Clinical longitudinal study on inpatients in a specialised institution. SUBJECTS: A total of 20 obese adolescents (10 boys and 10 girls) aged 12-17 yr [body mass index (BMI): 37.7±6.1 kg/m2; fat mass (FM): 44.8±13.2 kg]. MEASUREMENTS: The changes in plasma concentration of leptin, ghrelin, GH, IGF-I, insulin, glucose, and non-esterified fatty acids (NEFA) in response to standardised meals and exercise bouts were measured before and after the weight-reduction intervention. At the same times, body composition was assessed by bioelectrical impedance as well as appetite sensations using a visual analog scale. RESULTS: At the end of the intervention, the adolescents had lost body weight and FM (expressed both in kg and %) (p<0.05), without any significant fat-free mass loss (in % terms). In response to both meals and exercise, after the 3-week intervention, plasma leptin concentration decreased significantly (p<0.05), whereas the other hormones (insulin, ghrelin, GH, and IGF-I) and metabolic parameters (glucose and NEFA) did not change. Interestingly, appetite was not affected by the intervention. CONCLUSION: This 3-week multidisciplinary intervention in obese adolescents induced a significant body weight loss with beneficial changes in body composition. However, despite there being no change in metabolic parameters and ghrelin in response to meals and exercise after the intervention, plasma concentrations of leptin were decreased. The failure of ghrelin levels to increase by this approach might explain the good control of appetite observed at the end of the study.

Young elite athletes of different sport disciplines present with an increase in pulsatile secretion of growth hormone compared with non-elite athletes and sedentary subjects.

Acute exercise is a well-known stimulus for GH secretion but the effect of chronic training on GH secretion still remains equivocal. The aim of our study was to analyse spontaneous pulsatile GH secretion (during a period of 2 hours in the morning) in a group of young elite athletes (EA) compared with non-elite athletes (NEA), and sedentary subjects (SS). Mean and peak GH levels proved significantly higher in EA than in NEA and SS (p=0.0004 and p<0.0001, respectively). The same differences in mean and peak GH levels were also demonstrated in males and females when considered separately (males: p=0.0062 and p=0.0025; females: p=0.0056 and p=0.0032). In addition, GH levels (mean and peak) were higher in females than in males in SS while no differences were demonstrated between the 2 sexes in the EA and NEA groups. IGF-I levels were within the normal range for age in all the subjects with no difference between the 3 groups. Body mass index (BMI) exhibited no difference between groups, while EA showed higher lean mass (p=0.0063) and lower fat mass (p=0.0139) than NEA and SS measured by dual-energy x-ray absorptiometry. A strong positive correlation between GH levels (mean and peak) and hours of training a week was demonstrated (p=0.0101; r2=0.1184; p=0.0022; r2=0.1640, respectively). In conclusion, GH levels were higher in EA than NEA and SS without any modification of IGF-I levels; a strong positive correlation was present between GH levels and intensity of training. An increase in the knowledge of the effect of chronic training on GH secretion could improve the training programme to elicit the greatest exercise- induced GH response.

Exercise-induced effects on growth hormone levels are associated with ghrelin changes only in presence of prolonged exercise bouts in male athletes.

AIM: The aim of this study was to evaluate growth hormone (GH) and ghrelin levels in response to physical exercise in athletes. METHODS: Two different exercise workloads were administered in two different groups of athletes. Group A athletes (19 males, 18 females; mean age +/- standard deviation: 25+/-6.7 years), performing a 60-90 min training session at approximately 80% of VO2max, were sampled for GH and ghrelin determinations before and immediately at the end of a training session on-the-field. Group B athletes (4 males; mean age: 28.2+/-7.2 years) performed two consecutive 30-min cycling sessions at 80% of individual VO2max at different time intervals between bouts (2 and 6 h) in two different days. GH and ghrelin concentrations were determined in blood samples collected at 15-min intervals during exercise and following 1 h of recovery. RESULTS: In group A athletes, GH levels increased after the training session (P<0.0001), with no differences between males and females. In male athletes, ghrelin levels significantly decreased after the training session (from 1 506.4+/-859 to 1 254.8+/-661.7 pg/mL, P<0.05), while no significant changes were found in females. No correlations were observed between GH and ghrelin levels at rest and after training. In group B athletes, GH levels significantly increased after the first exercise bouts (peak: 26.8+/-11.2 and 17.3+/-3.5 ng/mL, respectively), while the pattern of GH response was different after the second bout of exercise performed at 2-h or 6-h interval. In fact, peak GH concentration in response to the second bout (4.3+/-1.6 ng/mL) was lower (P<0.01) than that of the first bout when the interval elapsed was only 2 h, while a recovery of GH responsiveness was evident after the 6-h interval between the two exercise bouts (11.9+/-3.3 ng/mL). As far as ghrelin levels are concerned, no significant changes were observed during and after the two exercise bouts performed at the different time intervals. CONCLUSION: GH responses to prolonged exercise bouts (60-90 min) are associated with changes in ghrelin levels only in male athletes, while repeated exercise bouts of lower duration (30 min), capable to determine marked GH responses, are divorced from changes in ghrelin concentrations.

Neuroendocrine and autonomic control of metabolic functions: recent advances.

Many studies have been prompted in the last few years aimed at clarifying and disentangle the different components involved in the control of metabolism and body weight. Based on a host of neuroanatomic, immunohistochemical and physiological findings, it is now clear that the hypothalamus is activated or deactivated by a series of afferent signals either hormonal or neural originated by peripheral tissues, which reflect changes in the global energy state. These hormonal and neural signals mainly stem from the adipose tissue, which is now considered a true endocrine organ, and, alternatively, by the gastrointestinal tract, in relation to fasting, feeding or refeeding conditions, and are vehicled to the brain where they act on receptors of an increasing family of first and second order peptides. This contribution at first presents the key elements of the complex mechanisms of control of metabolism and body weight, and then reports on recent presented advances in neuroendocrine and autonomic regulation of metabolic functions.

Detection of Mycoplasma hyopneumoniae by polymerase chain reaction in swine presenting respiratory problems.

Since Mycoplasma hyopneumoniae isolation in appropriate media is a difficult task and impractical for daily routine diagnostics, Nested-PCR (N-PCR) techniques are currently used to improve the direct diagnostic sensitivity of Swine Enzootic Pneumonia. In a first experiment, this paper describes a N-PCR technique optimization based on three variables: different sampling sites, sample transport media, and DNA extraction methods, using eight pigs. Based on the optimization results, a second experiment was conducted for testing validity using 40 animals. In conclusion, the obtained results of the N-PCR optimization and validation allow us to recommend this test as a routine monitoring diagnostic method for Mycoplasma hyopneumoniae infection in swine herds.

Chronic intracerebroventricular TLQP-21 delivery does not modulate the GH/IGF-1-axis and muscle strength in mice.

OBJECTIVE: Biallelic ablation of VGF determines a dwarf phenotype. VGF precursor protein encodes for different biologically active peptides none of which has been related to growth or muscular abnormalities. Here we present the first attempt to fill this gap. We tested the hypothesis that a recently identified VGF-derived peptide, TLQP-21, shown to centrally modulate metabolic functions, could also modulate growth hormone (GH)-axis and muscle strength. DESIGN: Adult male mice were chronically icv injected with TLQP-21 (15 microg/day for 14 days). Physiological, molecular and behavioral parameters related to the GH/IGF-1-axis were investigated. RESULTS: Except for a reduction in the soleus weight, TLQP-21 did not affect GH/IGF-1-axis mediators, muscle strength and muscle weight. CONCLUSIONS: Results collected exclude a role for TLQP-21 in modulating the GH/IGF1-axis and muscle functions. VGF-derived peptides involved in the dwarf phenotype of VGF-/- mice have to be identified yet.

Deranged anterior pituitary responsiveness to hypothalamic hormones in depressed patients.

Abnormal anterior pituitary (AP) responsiveness to acute administration of thyrotropin-releasing hormone (TRH) and luteinizing hormone-follicle stimulating hormone-releasing hormone (LH-RH) was investigated in 14 patients (two men and 12 women) suffering from primary affective disorders. In ten, TRH, 500 microgram given intravenously, induced a rise in plasma growth hormone (GH) level, while in eight patients it induced a rise in plasma levels of FSH or LH or both. When LH-RH, 150 microgram was administered intravenously to ten patients, it induced a rise in plasma GH level in one patient and increased plasma prolactin level in three patients. Collectively, in only three of 14 patients was conventional AP responsiveness to hypothalamic neurohormones present. These findings demonstrate the existence of a profound derangement of AP responsiveness to hypothalamic neurohormones in depressed patients and suggest that a primary alteration in the physiologic links between the central nervous system and the AP may be at the origin of the neuroendocrine disturbance.

Inhibitory action of the alpha 1-adrenergic receptor on growth hormone secretion in the dog.

Intravenous administration of methoxamine ( METHOX , 5 mg, iv), a specific alpha 1-adrenergic agonist, reduced baseline GH levels of four unanesthetized beagle dogs 45 and 60 min post-injection and completely abolished the GH-releasing effect of the alpha 2-adrenergic agonist clonidine ( CLON , 4/ micrograms/kg, iv). Prazosin (PRA, 0.1 mg/kg, iv), an alpha 1-adrenergic antagonist, administered before METHOX re-instituted the GH-releasing effect of CLON . METHOX administered at the starting of an arginine infusion (ARG, 10% solution, 3.3 ml/min X 30 min) reduced consistently the GH releasing effect of the latter while, conversely, pretreatment with PRA, strikingly potentiated the GH-releasing effect of the amino acid (2 dogs). METHOX did not alter the GH-releasing effect of human pancreatic GH-releasing factor (hpGRF-40, 1/microgram/kg, iv), though it consistently delayed the occurrence of the GH secretory peak following hpGRF-40. These data indicate that alpha 1-adrenergic receptors located in the central nervous system, inhibit in the dog tonic and stimulated GH secretion.

gamma-Aminobutyric acid inhibits beta-endorphin secretion from the anterior pituitary but not the neurointermediate lobe in the rat.

We have evaluated the role of gamma-aminobutyric acid (GABA) in the neuroendocrine control of beta-endorphin (beta-EP) secretion in the rat. Plasma beta-EP and beta-lipotropin (beta-LPH) levels and beta-EP-like immunoreactivity (beta-EPLI) in the anterior pituitary (AP) and neurointermediate lobe (NIL) were determined after administration of GABA antagonist or agonist drugs in male rats under resting conditions or after potent physical stresses. Bicuculline (0.1-0.8 mg/kg BW ip), a GABA receptor antagonist, induced a dose-related rise in plasma beta-EP and beta-LPH levels and a concomitant decrease in beta-EPLI concentrations in the AP but not in the NIL. Muscimol, a potent GABA-mimetic drug, did not alter baseline plasma beta-EP and beta-LPH levels, whether given systemically (1.0-2.0 mg/kg BW ip) or intracerebroventricularly (500 ng/kg BW), but prevented the effect of bicuculline on plasma and AP-beta-EP and beta-LPH concentrations. Administration of foot shock or restraint stress induced a clear-cut activation of the AP-related beta-EP secretion, an effect that was prevented by pretreatment with muscimol. Together, these data show that GABA-ergic mechanisms, probably operating at a central nervous system level, exert an inhibitory action on resting and stimulated beta-EP and beta-LPH secretion. Since no alterations in beta-EP concentrations in the NIL occurred after manipulations with GABA-ergic drugs or stress, and these were detected only in the AP, an interaction between GABA-ergic neurons and CRF neurons is the most likely explanation for the reported findings.

In vivo studies with growth hormone (GH)-releasing factor and clonidine in rat pups: ontogenetic development of their effect on GH release and synthesis.

The demonstration that GH-releasing factor (GRF) stimulates GH synthesis and release in rat pups prompted studies to evaluate the effects on the same indices of clonidine (CLO), an alpha 2-adrenoceptor and potent GH secretagogue, purported to act in adult rats via GRF release. Our first aim was to ascertain whether CLO elicits GH release in rat pups via GRF, and if this is the case, to evaluate the ontogenetic development in 1- to 10-day-old pups of the GH response to acute CLO or GRF administration and, finally, the effects of short term CLO or GRF treatment on plasma and pituitary GH concentrations and on the GH response to an acute challenge with the homologous secretagogue. CLO (15 micrograms/100 g BW, sc) induced a clearcut GH rise in 10-day-old rats but not in pups pretreated with a specific anti-GRF serum. Moreover, unlike GRF (10(-8) M), CLO (10(-6) to 10(-5) M) did not stimulate GH release in vitro from anterior pituitaries of 10-day-old rats. In 1-day-old rats, neither CLO (15 micrograms/100 g BW, sc) nor GRF (20 ng/100 g BW, sc) stimulated GH release, whereas significant GH stimulation was elicited by GRF, but not CLO, in 5-day-old rats and by both secretagogues in 10-day-old rats. Short term treatment with CLO (15 micrograms/100 g BW, sc, twice daily) or GRF (20 ng/100 g BW, sc, twice daily) on postnatal days 1 through 5 did not modify either plasma or pituitary GH concentrations 14 h after the last drug administration, but did so when either secretagogue was administered on postnatal days 5 through 9. Finally, an acute challenge with GRF, but not with CLO, induced a further rise in the already elevated plasma GH levels of pups pretreated from postnatal day 5 through 9, but neither secretagogue did so in pups pretreated from postnatal days 1 to 5. Viewed together, these data indicate that in infant rats CLO releases GH via GRF release and that the somatotropes respond earlier to GRF (5 days) than the GRF-secreting structures do to alpha 2-adrenergic stimulation (10 days). Both GRF and CLO stimulate GH synthesis when administered repeatedly. However, whereas repeated GRF treatment has a priming effect on the somatotropes, CLO does not, probably because of down-regulation of hypothalamic alpha 2-adrenoceptors.

Pharmacological manipulations of alpha-adrenoceptors in the infant rat and effects on growth hormone secretion. Study of the underlying mechanisms of action.

The aim of this study was to evaluate whether in infant rats, as in adult rats, the brain adrenergic mechanisms regulate plasma GH levels and, if so, to determine the contribution of GH-releasing hormone (GHRH) and/or somatostatin (SS) pathways. In 10-day-old rats, activation of alpha 2-adrenoceptors by clonidine (CLO) was effective to stimulate GH release starting from 50 micrograms/kg ip and up to 450 micrograms/kg ip, though no dose-related effect was evident. Conversely, alpha 2-adrenoceptor blockade by yohimbine (YOH, 10 mg/kg, ip) decreased baseline GH levels. Administration of methoxamine (METHOX, 10 micrograms/rat, ip), a alpha 1-adrenoceptor agonist, significantly reduced plasma GH concentrations, while prazosin (5 mg/kg BW, ip), a specific alpha 1-adrenoceptor antagonist, stimulated plasma GH secretion. Administration of an anti-SS serum (SS-ab, 300 microliters, ip) induced a significant rise in plasma GH levels, while administration of an anti-GHRH serum (GHRH-ab, 100 microliters, ip) was associated with a striking fall in GH levels. In rats pretreated with SS-ab, administration of CLO induced a further rise in plasma GH levels. GHRH-ab significantly reduced plasma GH levels, and this effect was not altered by subsequent CLO administration. Administration of SS-ab and YOH resulted in plasma GH levels intermediate between those of rats treated with SS-ab alone or YOH alone, while pretreatment with GHRH-ab induced a lowering of plasma GH greater than when YOH was given alone. in rats pretreated with SS-ab, the GH-lowering effect of METHOX was completely lacking, while GHRH-ab and METHOX induced a lowering of plasma GH similar to that ensuing after METHOX alone or GHRH-ab alone. Administration of prazosin in rats pretreated with SS-ab did not elicit any further rise in plasma GH, while combined administration with GHRH-ab elicited a GH-lowering effect comparable to that elicited by GHRH-ab alone. These data demonstrate that in the infant rat: brain adrenergic mechanisms involved in the neural regulation of GH secretion are operative; different neuropeptide mechanisms mediate the effect of activation or inhibition of alpha 1- and alpha 2-adrenoceptors. In particular, activation of alpha 2-adrenoceptors stimulates GH secretion via endogenous GHRH release, although a mechanism operating to inhibit hypothalamic SS release cannot be excluded; stimulation of alpha 1-adrenoceptors is inhibitory to GH secretion exclusively via an increased release of hypothalamic SS.

Different regulation of growth hormone-releasing factor-sensitive adenylate cyclase in the anterior pituitary of young and aged rats.

Low basal GH secretion and reduced GH responsiveness to different GH secretagogues, including GHRF, have been reported in aged animals and humans. Parallel to the in vivo findings, an impaired GH responsiveness to GHRF is evident in somatotropes from old rats of either sex. We report here that in anterior pituitaries (APs) from aged male and female rats GHRF-induced stimulation of adenylate cyclase (AC) activity was strikingly reduced (male rats, change from baseline 700% in young and 100% in old rats) or lacking (female rats, change from baseline 430% in young and 13% in old rats) when compared to that evoked by GHRF in the APs from young counterparts. Pretreatment with GHRH (5 micrograms/rat iv for 3 days) decreased the high basal AC activity of old male rats [from 33.38 +/- 3.60 to 15.99 +/- 5.75 (SEM) pmol cAMP/min.mg protein], did not alter the GHRF-stimulated rise in AC activity in old male rats, and induced a small but unequivocal rise in AC activity in old female rats (change from baseline 35% vs. 13%, respectively). Pretreatment with GHRF markedly reduced the acute effect of GHRF in the APs from young rats of both sexes (male rats, change from baseline 360% and 700%; female rats, change from baseline 230% and 430% in GHRF-pretreated and control rats, respectively). In parallel studies performed in female rats, it was shown that in vivo pretreatment with GHRF at the same schedule markedly reduced the effect of acute GHRF stimulation on GH secretion from cultured pituitary cells of young rats but left unchanged GHRF-induced stimulation of GH secretion from pituitary cells of old rats. In all, these data suggest that deficiency of endogenous GHRF synthesis and/or release may underlie defective GH secretion in old rats and that a GHRF replacement regimen that reduces the sensitivity of the young somatotrope cells does not alter the sensitivity of (male rats) or exerts a priming effect (female rats) on the old somatotrope cell.

A role for dopamine in growth hormone regulation in the dog.

The role of dopamine (DA) in the secretion of GH in most animal species is still controversial. We examined in the dog the effect on GH release of nomifensine, a drug which activates both noradrenergic and dopaminergic neurotransmission. Nomifensine (0.4-2.8 mg/kg, iv), administered into 12 unanesthetized male and female beagles, induced short-dose-related rises in canine GH (cGH) levels. Blockade of alpha-adrenergic receptors by phentolamine prevented the GH stimulatory effect of 2.8 mg/kg nomifensine, and an iv bolus injection of haloperidol (a neuroleptic which antagonizes both norepinephrine and DA receptor function) given 45 min before was equally effective. Selective blockade of DA receptors by pimozide significantly reduced the GH-releasing effect of nomifensine. In sum, these data indicated that the effect of nomifensine was the consequence of an enhanced noradrenergic and dopaminergic-neurotransmission. Pretreatment with domperidone, a DA receptor blocker unable to cross the blood-brain barrier, failed to modify the GH-releasing effect of nomifensine, suggesting that the DA component subserving the neuroendocrine effect of the drug lies within the blood-brain barrier. Further evidence for a stimulatory role of DA on GH release was the fact that apomorphine, a direct stimulant of DA receptors, induced a rise in cGH levels when administered to dogs pretreated with domperidone. The latter drug was used to prevent emesis and distress due to activation of peripheral DA receptors by apomorphine. However, apomorphine was only active in the dog at doses (250 and 500 microgram/kg, sc) greatly exceeding those active in releasing GH in man, suggesting that the role of DA in cGH regulation is ancillary to that exerted by noradrenergic neurotransmission. In a final study, atropine, a muscarinic cholinergic receptor antagonist, abolished the neuroendocrine effect of nomifensine, a finding which suggests that cholinergic medication plays an important role in cGH regulation.

Role of central nervous system-derived or circulating gamma-aminobutyric acid on prolactin secretion in the rat.

To investigate the respective role in PRL secretion of gamma-aminobutyric acid (GABA), either derived from the central nervous system or circulating in plasma, experiments were performed using ethanolamine-O-sulfate (EOS), a specific inhibitor of GABA catabolism. Intracerebroventricular injection of EOS (2 mg/kg) induced in unanesthetized male rats 2-8 h post injection a clear-cut rise in hypothalamic, anterior pituitary (AP), and plasma GABA concentrations. Rises in GABA titers occurred earlier in the hypothalamus and AP (2 h) than in the plasma (4 h). Concomitant to alterations of GABA, there was a striking lowering of plasma PRL evident at 2 h and still present 24 h after EOS administration. In contrast, systemic administration of graded doses of EOS (200-400 mg/kg, iv) did not induce significant changes in plasma GABA concentrations 4 h post injection; only the 600 mg/kg dose of EOS increased GABA concentrations 4 h post injection in the hypothalamo-AP system and decreased plasma PRL concentrations. Finally, in hypophysectomized rats bearing ecotopic pituitaries, despite the occurrence of rises in the hypothalamic GABA after intracerebroventricular or systemic (600 mg/kg) administration of EOS, AP, plasma GABA, and plasma PRL concentrations were not altered. In all these findings indicate that: 1) changes in plasma PRL are best correlated to variations in the amino acid titers occurring in the hypothalamo-AP systems; and 2) circulating GABA does not play a functional role in the control of PRL secretion. Finally, since alterations in blood GABA levels after central or systemic administration of EOS appear to reflect primary changes occurring in the brain concentration of the amino acid, circulating GABA may be a reliable indicator of central nervous system GABAergic function.