The interaction of growth hormone releasing hormone and somatostatin in the generation of a GH pulse in man

The multiple roles of GH in neural ageing and injury

Advanced age is typically associated with a decrease in cognitive function including impairment in the formation and retention of new memories. The hippocampus is critical for learning and memory, especially spatial learning, and is particularly affected by ageing. With advanced age, multiple neural components can be detrimentally affected including a reduction in the number of neural stem and precursor cells, a decrease in the formation of adult born neurons (neurogenesis), and deficits in neural circuitry, all of which ultimately contribute to impaired cognitive function. Importantly, physical exercise has been shown to ameliorate many of these impairments and is able to improve learning and memory. Relevantly, growth hormone (GH) is an important protein hormone that decreases with ageing and increases following physical exercise. Originally described due to its role in longitudinal growth, GH has now been identified to play several additional key roles, especially in relation to the brain. Indeed, the regular decrease in GH levels following puberty is one of the most well documented components of neuroendocrine ageing. Growth hormone deficiency (GHD) has been described to have adverse effects on brain function, which can be ameliorated via GH replacement therapy. Physical exercise has been shown to increase circulating GH levels. Furthermore, we recently demonstrated the increase in exercise-mediated GH is critical for improved cognitive function in the aged mouse. Here we examine the multiple roles that GH plays, particularly in the aged brain and following trauma, irradiation and stroke, and how increasing GH levels can ameliorate deficits in cognition.

Dexamethasone Stimulation Test in the Diagnostic Work-Up of Growth Hormone Deficiency in Childhood: Clinical Value and Comparison With Insulin-Induced Hypoglycemia

CONTEXT

dexamethasone has been demonstrated to elicit GH secretion in adults, but few data are available about its effectiveness as a provocative stimulus in the diagnostic work-up of GH deficiency (GHD) in childhood.

OBJECTIVE

to assess the clinical value of dexamethasone stimulation test (DST) as a diagnostic tool for pediatric GHD.

DESIGN AND SETTING

retrospective single-center analysis. The study population included 166 patients with a pathological response to arginine stimulation test (AST, first-line test) and subsequently tested with either insulin tolerance test (ITT) or DST as a second-line investigation between 2008 and 2019.

MAIN OUTCOME MEASURES

comparison between GH peaks and secretory curves induced by ITT and DST; degree of agreement between DST and AST versus ITT and AST.

RESULTS

the pathological response to AST (GH peak < 8 ng/mL) was confirmed by an ITT in 80.2% (89/111) of patients and by a DST in 76.4% (42/55), with no statistical difference between the two groups (p value 0.69). Mean GH peaks achieved after ITT and DST were entirely comparable (6.59 ± 3.59 versus 6.50 ± 4.09 ng/ml, respectively, p 0.97) and statistically higher than those elicited by arginine (p < 0.01 for both), irrespectively of the average GH peaks recorded for each patient (Bland-Altman method). Dexamethasone elicited a longer lasting and later secretory response than AST and ITT. No side effects were recorded after DST.

CONCLUSIONS

DST and ITT confirmed GHD in a superimposable percentage of patients with a pathological first-line test. DST and ITT share a similar secretagogue potency, overall greater than AST.

ARNT2 mutation causes hypopituitarism, post-natal microcephaly, visual and renal anomalies

We describe a previously unreported syndrome characterized by secondary (post-natal) microcephaly with fronto-temporal lobe hypoplasia, multiple pituitary hormone deficiency, seizures, severe visual impairment and abnormalities of the kidneys and urinary tract in a highly consanguineous family with six affected children. Homozygosity mapping and exome sequencing revealed a novel homozygous frameshift mutation in the basic helix-loop-helix transcription factor gene ARNT2 (c.1373_1374dupTC) in affected individuals. This mutation results in absence of detectable levels of ARNT2 transcript and protein from patient fibroblasts compared with controls, consistent with nonsense-mediated decay of the mutant transcript and loss of ARNT2 function. We also show expression of ARNT2 within the central nervous system, including the hypothalamus, as well as the renal tract during human embryonic development. The progressive neurological abnormalities, congenital hypopituitarism and post-retinal visual pathway dysfunction in affected individuals demonstrates for the first time the essential role of ARNT2 in the development of the hypothalamo-pituitary axis, post-natal brain growth, and visual and renal function in humans.

Novel ontogenetic patterns of sexual differentiation in arcuate nucleus GHRH neurons revealed in GHRH-enhanced green fluorescent protein transgenic mice

GH secretion and growth rates are developmentally regulated and sexually dimorphic, but the neuroregulatory mechanisms between birth and puberty are unclear. Using the GHRH-enhanced green fluorescent protein (eGFP) transgenic mouse, in which eGFP provides a strong surrogate signal for identifying GHRH neurons, we showed that numbers in the male arcuate nucleus were double those seen in females at x postnatal day (P)1 and P10, during which time numbers increased 2- to 3-fold. Thereafter (P20, P30, P60, P365) there was a significant trend for numbers to decrease in males and increase in females, such that sex differences were, surprisingly, absent in young and late adulthood. Conversely, we identified the emergence of male-dominant sex differences in the number of processes extended per GHRH perikarya across puberty. Intriguingly, prepubertal gonadectomy (P28), unlike adult gonadectomy, caused a dramatic 40% loss of GHRH cells in both sexes in adulthood and a significant (30%) increase in processes emanating from cell bodies only in females. These findings establish a novel ontogenetic profile for GHRH neurons and suggest previously undiscovered roles for peripubertal gonadal factors in establishing population size in both sexes. They also provide the first demonstration of emergent sex-specific GHRH architecture, which may signal the onset of sex-dependent regulation of activity reported for adult GHRH-eGFP neurons, and its differential regulation by gonadal factors in males and females. This information adds to our knowledge of processes that underpin the emergence of sex-specific GH secretory dynamics and hence biological activity of this pleiotropic hormone.

Aging and the growth hormone/insulin like growth factor-I axis

Growth hormone release and IGF-I synthesis decrease with increasing age. The regulation of the GH/IGF-I system is dependent on the integrity of the hypothalamus, pituitary and liver. During aging there are several changes which contribute to the decline in GH/IGF-I including changes in signal to the somatotrophs from growth hormone releasing hormone, somatostatin and other factors such as body composition, exercise, diet and sleep. All of these factors are discussed in detail within this review. The phenotypic similarities between aging and adult growth hormone deficiency syndrome combined with this decrease in GH/IGF-I with aging have prompted the question whether aging is a GH deficient state. The advent of recombinant growth hormone has led to a number of studies treating elderly patients with GH alone or in combination with sex steroids or exercise. The results of these studies would not back up the use of GH in elderly non-hypopituitary patients as they did not show efficacy, showed high rates of adverse events and there is also some evidence associating GH/IGF-I and risk of neoplasia. If GH therapy is to be used in this cohort of patients further long term efficacy and safety studies are required.

Somatotropic and gonadotropic axes linkages in infancy, childhood, and the puberty-adult transition

Integrative neuroendocrine control of the gonadotropic and somatotropic axes in childhood, puberty, and young adulthood proceeds via multiple convergent and divergent pathways in the human and experimental animal. Emerging ensemble concepts are required to embody independent, parallel, and interacting mechanisms that subserve physiological adaptations and pathological disruption of reproduction and growth. Significant advances in systems biology will be needed to address these challenges.

The impact of hormone physiology on clinical practice with reference to two papers spanning 40 years of endocrinology

Following the pioneering work of Roger Ekins in describing the methodology for radioimmunoassay of hormone concentrations in plasma a series of publications followed describing variation in plasma hormone concentrations in a number of diseases. Though fluctuations in hormonal concentrations had been suspected, it was not until Hunter and Rigal documented these for the GH axis that it became apparent that the preferred mode of signalling for many hormone systems and in particular the anterior-pituitary hormones was of a pulsatile nature.

Pubertal alterations in growth and body composition: IX. Altered spontaneous secretion and metabolic clearance of growth hormone in overweight youth

Deconvolution analysis was used to determine 12-hour spontaneous nocturnal growth hormone (GH) secretion and GH half-life in lean (body mass index, <85th percentile; n = 39) and overweight (body mass index, > or =85th percentile; n = 18) youth. The integrated GH concentration, GH burst mass, and half-life were lower (P < .05) in overweight than in lean youth. For each unit increase in percentage of body fat, integrated serum GH concentrations, secretory burst mass, and half-life declined by 83.6 microg/L per minute (r = -0.39, P < .01), 0.22 microg/L (r = -0.28, P < .05), and 0.2 minute (r = -0.38, P < .01), respectively. The effect of overweight on GH secretion was independent of pubertal status. Hierarchical regression models tested the hypothesis that altered GH secretion in youth is more related to total adiposity than abdominal visceral fat. When age, sex, fat-free mass, testosterone, and estradiol were held constant, the sequential addition of abdominal visceral fat did not increase R2 for any GH secretion variable. Sequential addition of percentage of body fat increased R2 (P < .05) for integrated GH concentration, total secretory rate, secretory burst mass, and pulsatile production rate. We conclude that serum GH concentrations are reduced in overweight youth primarily because of reduced GH burst mass with no change in the number of secretory events and secondarily to reduced GH half-life. Based on the model that GH-releasing hormone predominantly increases GH pulse amplitude whereas somatostatin primarily controls GH pulse frequency, these results suggest that overweight in youth diminishes GH-releasing hormone stimulation resulting in truncated GH bursts but does not alter the number of somatostatin withdrawal intervals so that GH burst frequency is conserved.

Growth hormone releasing hormone plus arginine stimulation testing in young adults treated in childhood with cranio-spinal radiation therapy

OBJECTIVE

Growth hormone deficiency (GHD) secondary to cranio-spinal radiation therapy (CSRT) is a complication seen in medulloblastoma survivors. The standard for diagnosis of adult GHD is a peak GH < 3 microg/l by the insulin tolerance test (ITT). However, insulin tolerance testing exposes patients to the risks of hypoglycaemia. Recent studies suggest that the GH releasing hormone + arginine (GHRH + ARG) test can identify GHD in cranially irradiated patients at longer time intervals after radiation. We evaluated the GHRH + ARG stimulation test compared to the ITT in young adults diagnosed with medulloblastoma during childhood.

PATIENTS

We evaluated 10 young adult patients (age range 17-26 years) who were treated with CSRT during childhood for medulloblastoma, and who had resultant childhood-onset GHD.

MEASUREMENTS

Subjects underwent GH provocative testing with the ITT and the GHRH + ARG test. IGF-I and IGFBP3 levels were also measured at baseline.

RESULTS

Insulin tolerance testing and GHRH + arginine stimulation were performed at a mean +/- SD 14 +/- 4.4 years after cranial radiation. All patients failed the ITT with median peak GH 0.40 microg/l (range < 0.05-2.2). GHRH + arginine gave higher peak GH levels with a mean of 7.9 +/- 5.7 microg/l (P = 0.003). Four patients had peak GH > 9 microg/l and were between 7.8 and 19.6 years from cranial radiation. There was no correlation of peak GH levels with time interval since CSRT. Thirty-three per cent of subjects had normal IGF-I; neither IGF-I nor IGFBP3 standard deviation scores (SDS) correlated with ITT results.

CONCLUSIONS

Using a GHRH + arginine cut-off for GHD of 9 microg/l, four patients would have been misclassified as GH sufficient, despite being > 7 years (with two patients being nearly 20 years) out from CSRT. These findings suggest that the pituitary GH-producing cells of young adults continue to maintain responsiveness to GHRH + arginine more than 5-10 years after cranial irradiation.

Somatostatin infusion withdrawal in the diagnosis of childhood growth hormone deficiency

OBJECTIVE

An evaluation of growth hormone (GH) testing for GH deficiency (GHD) in childhood is confounded by the lack of a world-wide consensus on the definition of GHD. Although a single GH test remains the most powerful biochemical tool in the evaluation of a child with growth failure, the test remains far from ideal. Withdrawal of somatostatin (SS) infusion is followed by a rebound rise of GH thought to be mediated by endogenous GH-releasing hormone (GHRH) function. This study was designed to compare the GH response to 90 min SS infusion in children with normal GH secretion versus children with GH deficiency.

METHODS

Ten children with GHD and 10 healthy controls (NC) have been evaluated for GH response to somatostatin infusion withdrawal (SSIW) and compared with response of two provocative tests, glucagon plus propranolol test and L-Dopa test. All children received constant infusion of somatostatin for 90 min (3 microg/kg per h, Stilamin, Serono, Aubonne, Switzerland). In order to determine GH, blood samples were obtained 90 min before the SS infusion and 0, 15, 30, 45, 60, 75, and 90 min after the cessation of infusion.

RESULTS

Growth hormone peak levels with SSIW were significantly lower in GH deficient children than in healthy children (2.5 +/- 1.2 ng/dL, vs 21.9 +/- 5.3 ng/dL, respectively, P < 0.01). No adverse effects were observed during or after somatostatin infusion.

CONCLUSION

In the present study, SSIW elicited a significant GH rise in healthy children but not in children with GH deficiency. Although further controlled studies using more data are necessary to expand these findings, the results suggested that children with GH deficiency can be reliably discriminated from healthy children by SSIW.

Somatostatin and somatostatin receptor physiology

Since the discovery of somatostatin (SST) over three decades ago, its ubiquitous distribution and manifold functions are still being documented. SST is synthesized in the hypothalamus and transported to the anterior pituitary gland where it tonicaly inhibits GH and TSH secretion as well as being responsible for GH pulsatile release. Several internal feedback loops, sleep, exercise, and chemical agents control and influence SST release. SST also impacts the function of a wide variety of cells and organ systems throughout the body. Knowledge of the structures of the SSTs has resulted in recognition of the essential four core conserved residues responsible for their actions. The SSTs act through six separate SST cell surface receptors (SSTRs), members of the family of G protein-coupled receptors. Receptor ligand binding (SST/SSTR) results in cellular activities specific for each receptor, or receptor combinations, and their tissue/cell localization. Understanding the structure/function relationship of the SSTs and their receptors, including the internalization of SST/SSTR complexes, has facilitated the development of a variety of novel pharmacologic agents for the diagnosis and treatment of neuroendocrine tumors and unfolding new applications.

Effect of withdrawal of somatostatin plus growth hormone (GH)-releasing hormone as a stimulus of GH secretion in Cushing's syndrome

OBJECTIVE

Somatostatin (SS) may not merely be inhibitory to GH secretion but, under appropriate temporal conditions, may act in a paradoxically positive manner to sensitize somatotroph responsiveness to GHRH. SS infusion withdrawal (SSIW) produces a rebound GH rise in humans and increases GHRH-induced GH release. Theoretically SSIW leaves the somatotroph cell in a situation of low endogenous SS. In Cushing's syndrome, GH secretion appears blunted to all stimuli. The mechanisms by which glucocorticoids impair GH secretion in Cushing's syndrome are unknown. There are no data evaluating GH responsiveness to SSIW plus GHRH in Cushing's syndrome patients. The aim of the present study was to evaluate the GH response to SSIW plus GHRH in a group of Cushing's syndrome patients, in order to further understand the deranged GH secretory mechanisms in Cushing's syndrome.

PATIENTS AND MEASUREMENTS

Eight female patients with Cushing's syndrome were studied. As a control group, eight normal subjects of similar age and sex were studied. Three tests were done. On one day, SS intravenous (i.v.) infusion (500 micro g for 0-90 min) was performed followed by placebo i.v. bolus at min 90 after SS withdrawal (SSIW). On another day, SS i.v. infusion (500 micro g for 0-90 min) was performed followed by GHRH (100 micro g) i.v. bolus at min 90 after SS withdrawal. On a third day, slow infusion of 150 mmol/l NaCl administration was performed followed by GHRH (100 micro g) i.v. bolus at min 90 after the start of the infusion. Blood samples were taken at appropriate intervals for determination of GH.

RESULTS

GHRH-induced GH secretion in normal subjects showed a mean peak of 15.4 +/- 2.1 micro g/l (conversion factor: 1 micro g/l = 1.2 mUI/l). Normal control subjects had a mean peak of 3.3 +/- 1.6 micro g/l after SSIW-induced GH secretion. When GHRH was administered after SSIW there was increased GH secretion with a mean peak of 23.7 +/- 4.2 micro g/l significantly greater than the response after SSIW alone (P < 0.05) and GHRH alone (P < 0.05). The patients with Cushing's syndrome had a blunted GH response after GHRH administration with a mean peak of 1.4 +/- 0.4. After SSIW, Cushing's syndrome patients had a mean peak of 1.0 +/- 0.5 micro g/l. When GHRH was administered after SSIW there was a similar GH response with a mean peak of 1.7 +/- 0.6 micro g/l, not statistically different than the response after SSIW alone (P = ns) and GHRH alone (P = ns). When we compare the response of normal subjects and Cushing's syndrome patients, after SSIW plus GHRH, it was decreased in Cushing's syndrome patients (P < 0.05), with a mean GH peak of 23.7 +/- 4.2 micro g/l and 1.7 +/- 0.6 micro g/l for normal subjects and Cushing's syndrome patients, respectively.

CONCLUSIONS

This study has demonstrated a significantly blunted peak GH response to somatostatin infusion withdrawal plus GHRH in Cushing's syndrome patients. In this theoretical situation of decreased somatostatinergic tone there is persistence of GH hyposecretion in Cushing's syndrome, suggesting the existence of a pituitary defect responsible for the decreased GH secretion in Cushing's syndrome.

Adult growth hormone deficiency in patients with fibromyalgia

Adult growth hormone (GH) deficiency is a well-described clinical syndrome with many features reminiscent of fibromyalgia. There is evidence that GH deficiency as defined in terms of a low insulin-like growth factor-1 (IGF-1) level occurs in approximately 30% of patients with fibromyalgia and is probably the cause of some morbidity. It seems most likely that impaired GH secretion in fibromyalgia is related to a physiologic dysregulation of the hypothalamic-pituitary-adrenal axis (HPA) with a resulting increase in hypothalamic somatostatin tone. It is postulated that impaired GH secretion is secondary to chronic physical and psychological stressors. It appears that impaired GH secretion is more common than clinically significant GH deficiency with low IGF-1 levels. The severe GH deficiency that occurs in a subset of patients with fibromyalgia is of clinical relevance because it is a treatable disorder with demonstrated benefits to patients.

Impaired growth hormone secretion in fibromyalgia patients: evidence for augmented hypothalamic somatostatin tone

OBJECTIVE

To determine whether female fibromyalgia (FM) patients exhibit a normal growth hormone (GH) response to an acute exercise stressor, and to assess the importance of somatostatin tone in the generation of this GH response.

METHODS

Twenty female FM patients were compared with 10 healthy female controls. All subjects exercised to volitional exhaustion on a treadmill. A standard metabolic cart was used to monitor pulse, blood pressure, electrocardiography, oxygen uptake, carbon dioxide output, anaerobic threshold, and maximal workload. Blood was drawn for GH and cortisol measurements 1 hour before exercise, immediately before exercise, immediately after exercise, and 1 hour after exercise. One month later, testing that was exactly similar was performed, except all subjects were given pyridostigmine bromide (Mestinon; 30 mg orally) 1 hour before exercise.

RESULTS

Compared with controls, FM patients failed to exhibit a GH or cortisol response to acute exercise (P = 0.003). After administration of pyridostigmine, 1 hour before exercise, the GH levels of FM patients increased 8-fold (P = 0.001), to a value comparable with that of controls. Pyridostigmine did not increase the cortisol response to exercise in FM patients. Pyridostigmine alone did not stimulate GH secretion in FM patients, nor did it improve exercise-induced GH secretion in controls. FM patients with normal insulin-like growth factor 1 (IGF-1) levels had an impaired GH response to exercise.

CONCLUSION

Three new findings are reported: 1) FM patients have a reduced GH response to exercise, 2) pyridostigmine reverses this impaired response, and 3) defective GH secretion in FM can occur in patients with normal IGF-1 levels. Because pyridostigmine is known to reduce somatostatin tone, it is surmised that the defective GH response to exercise in FM patients probably results from increased levels of somatostatin, a hypothalamic hormone that inhibits GH secretion.

Effect of withdrawal of somatostatin plus GH-releasing hormone as a stimulus of GH secretion in obesity

OBJECTIVES

Somatostatin (SS) may not merely be inhibitory to GH secretion but, under appropriate temporal conditions, may act in a paradoxically positive manner to sensitize somatotroph responsiveness to GH-releasing hormone (GHRH). SS infusion withdrawal (SSIW) produces a rebound GH rise in humans and increases GHRH-induced GH release. Theoretically, SSIW leaves the somatotroph cell in a situation of low endogenous SS. In obesity, there is markedly decreased GH secretion. In both children and adults, the greater the body mass index (BMI), the lower the GH response to provocative stimuli. It has been postulated that increased hypothalamic somatostatin secretion is the main mechanism responsible for the blunted GH secretion of obesity. There are no data evaluating GH responsiveness to SSIW plus GHRH in obese adults. The aim of the present study was to evaluate the GH response to SSIW plus GHRH in a group of control subjects and a group of obese patients.

PATIENTS AND MEASUREMENTS

Seven obese patients (six female, one male) with a BMI of 36.1 +/- 7.7 kg/m2 were studied. As a control group, seven normal subjects (six female, one male) with a BMI of 20.3 +/- 0.9 kg/m2 were also studied. Two tests were performed. On one day, somatostatin (SS) i.v. infusion (500 microg from 0-90 min) was performed followed by a placebo i.v. bolus 90 min after SS withdrawal (SSIW). On another day, SS i.v. infusion (500 microg from 0-90 min) was performed followed by a GHRH (100 microg) i.v. bolus 90 min after SS withdrawal. A second group of seven obese patients (six female, one male) with a BMI of 32.2 +/- 2.3 kg/m2 were studied. As a second control group, seven normal healthy subjects (six female, one male) with a BMI of 20.1 +/- 0.6 kg/m2 were also studied. On one day, saline infusion was performed followed by a placebo i.v. bolus at 90 min. On another day, saline infusion was performed followed by a GHRH (100 microg) i.v. bolus at 90 min. Blood samples were taken at appropriate intervals for determination of GH. Serum GH was measured by chemiluminescent immunometric assay. Statistical analysis was performed by Wilcoxon and Mann-Whitney tests.

RESULTS

GHRH-induced GH secretion in normal subjects showed a mean peak of 15.8 +/- 2.1 microg/l. Normal control subjects had a mean peak of 3.1 +/- 1.5 microg/l after SSIW-induced GH secretion. When GHRH was administered after SSIW there was an increased GH secretion with a mean peak of 23.3 +/- 4.4 microg/l, significantly greater than the response after SSIW alone (P < 0.05) and GHRH alone (P < 0.05). GHRH-induced GH secretion in obese patients was decreased with a mean peak of 3.9 +/- 1.5 microg/l. In obese patients, GH secretion after SSIW was markedly decreased with a mean peak of 1.0 +/- 0.4 microg/l. When GHRH was administered after SSIW, an increase in GH secretion was observed with a mean peak of 4.3 +/- 0.9 microg/l, significantly greater than SSIW alone (P < 0.05) but not GHRH alone (P = NS), and significantly less than in normal subjects (P < 0.05).

CONCLUSIONS

This study demonstrates a significantly blunted peak GH response to somatostatin infusion withdrawal plus GHRH in obese patients compared to normal subjects. In this theoretical situation of decreased somatostatinergic tone, there is persistence of GH hyposecretion in obesity, suggesting the existence of multiple defects responsible for decreased GH secretion in obesity. We also found that in obese patients, in contrast to normal subjects, SSIW did not increase GHRH-induced GH secretion.

Growth hormone effects in intestinal adaptation after massive bowel resection in the suckling rat

BACKGROUND

Massive small bowel resection provokes intestinal malabsorption that leads to diminished growth in the suckling rat. Growth hormone is one of the several factors that can enhance the adaptive response of the intestines in the adult rat; however, whether it also enhances postresection intestinal adaptation in the suckling rat, thus reducing the adverse effects of resection on growth, is still unclear.

METHODS

Seventy-four 30-day-old suckling Wistar rats underwent 80% midgut bowel resection, laparotomy (sham operation), or no surgery. They were treated with either growth hormone or saline for 15 days and studied 15 or 45 days after surgery. Body weight was monitored and samples of bone and intestinal mucosa were obtained at the end of the study period for analysis.

RESULTS

Resected rats lost body and bone weight regardless of growth hormone administration. Bowel resection provoked significant increases in the proliferation and size of the intestinal mucosa. Growth hormone significantly, but just barely, increased crypt height and mucosal mass at day 15 after surgery, but not at day 45. Lengthening of the intestines was the main effect of growth hormone.

CONCLUSIONS

The relatively small adaptive response of intestines to growth hormone is insufficient to promote body growth after intestinal resection in the suckling rat. This response is lower than that in older rats and may reflect an age-related differential response to growth hormone.

Growth hormone (GH) secretion in patients with an inactivating defect of the GH-releasing hormone (GHRH) receptor is pulsatile: evidence for a role for non-GHRH inputs into the generation of GH pulses

GH secretion is regulated by the interaction of GHRH and somatostatin and is released in 10-20 pulses in each 24-h cycle. The exact roles in pulse generation played by somatostatin, GHRH, and the recently isolated GH-releasing peptide, Ghrelin, are not fully elucidated. To investigate the GHRH-mediated GH secretion in human, we investigated pulsatile, entropic, and 24-h rhythmic GH secretion in two young adults (male, 24 yr; female, 23 yr) from a Moroccan family with a novel inactivating defect of the GHRH receptor gene. Data were compared with values in age- and gender-matched controls. Plasma GH concentration were measured by a sensitive immunofluorometric assay, with a detection limit of 0.01 mU/L. All plasma GH concentrations in the female patient were measurable; in the male patient 30 of 145 samples were at or below the detection limit. GH secretion was pulsatile, with 21 and 23 secretory episodes/24 h in the male and female patients, respectively. The fraction of basal to total GH secretion was raised in both patients by 0.18 and 0.15, respectively. The total 24-h GH production rate was greatly diminished; in the male patient it was 6.9 mU/L (normal values for his age, 26--63 mU/L), and in the female patient it was 4.2 mU/L (normal values for her age, 96--390 mU/L). The nyctohemeral plasma GH rhythm was preserved (P < 0.001), with normal acrophases (0430 and 0218 h in the male and female, respectively). Approximate entropy was greatly elevated in both subjects (0.82 in the male and 1.17 in the female; upper normal values for age and gender, 0.24 and 0.59, respectively). Intravenous injection of 50 microg GHRH failed to increase the plasma GH concentration in both patients, but 100 microg GH-releasing peptide-2 elicited a definite increase (male patient, 0.13 to 1.74 mU/L; female patient, 0.29 to 0.87 mU/L). Both patients had a partial empty sella on magnetic resonance imaging scanning. In summary, the present studies in two patients with a profound loss of function mutation of the GHRH receptor favor the view that in the human the timing of GH pulses is primarily supervised by intermittent somatostatin withdrawal, and the amplitude of GH pulses is driven by GHRH. In addition, we infer that effectual GHRH input controls the GH cell mass and the orderliness of the secretory process.

Pharmacokinetic and pharmacodynamic modeling of NN703, a growth hormone secretagogue, after a single po dose to human volunteers

The objective of this study was to describe the pharmacokinetics and pharmacodynamics of NN703, a growth hormone (GH)-releasing secretagogue, after po administration to healthy human male subjects. The study was designed as a randomized, placebo-controlled, double-blind, dose-escalating, single-dose trial of NN703 covering eight dose levels. Each of the dose levels had 6 subjects on active treatment and 2 subjects on placebo. NN703 was administered po as a solution. Blood samples for serum concentrations of NN703 and GH were collected before dosing and up to 24 hours after dosing. Serum concentrations of NN703 were determined using a validated analytical method, based on solid-phase extraction and LC/MS/MS detection. A two-compartmental model with zero-order input was used to describe the pharmacokinetics of NN703. The parameters of the elimination phase were fitted simultaneously, whereas the parameters describing the absorption phase were allowed to vary between the dose levels. The pharmacodynamics of NN703 was described by use of an indirect-response model containing both a threshold value and a modulator for the development of tolerance. It was concluded that the absorption of NN703 after po administration was nonlinear; the bioavailability increased with the dose. The serum concentration of NN703 required for half-maximal stimulation of GH was determined to be 485 ng/ml. The proposed indirect-response model requiring a threshold concentration and development of tolerance provided a useful mean of quantifying the effects of NN703. Furthermore, the development of tolerance shown based on pharmacokinetic/pharmacodynamic modeling of single-dose data presented here has been confirmed following multiple dosing in healthy male subjects.

The relative roles of continuous growth hormone-releasing hormone (GHRH(1-29)NH2) and intermittent somatostatin(1-14)(SS) in growth hormone (GH) pulse generation: studies in normal and post cranial irradiated individuals

OBJECTIVES

Pulsatile GH release in humans is thought to involve the coordinated interaction of growth hormone-releasing hormone (GHRH) and somatostatin (SS). Disordered GH secretion is seen in most patients following high dose (> 30 Gy) cranial irradiation in childhood and could result from dysregulation of these hypothalamic hormones or reflect direct pituitary damage. We have used a peptide 'clamp' to assess the relative roles of continuous GHRH and intermittent SS in GH pulse generation in healthy volunteers and short-and long-term survivors of childhood brain tumours.

DESIGN

Randomized controlled study.

PATIENTS

12 adult male long-term survivors of childhood brain tumours (median age 17.0 years (15.2-19. 7); 12.2 years (5.8-14.0) postradiotherapy, > 30Gy whole brain irradiation) with 9 matched control volunteers and 6 short-term survivors of childhood brain tumours (median age 6.4 years (5.9-7. 7); 2.5 years (1.7-3.6) post radiotherapy, > 30Gy whole brain irradiation) with 6 matched controls (studies of spontaneous GH release alone).

MEASUREMENTS

Serum GH concentrations in 24 h spontaneous GH profiles and during three 'clamp' studies: continuous GHRH(1-29)NH2 (60 ng/kg/minutes, subcutaneous infusion, 24 h); intermittent SS(1-14) withdrawal (20microg/m2/hour, intravenous infusion, 3 h on/1 h off, 2-3 cycles over 8-12 h); intermittent SS and continuous GHRH combined (2-3 cycles over 8-12 h). Data were analysed by spectral analysis, 'peak' and 'trough' determination and serial array averaging.

RESULTS

In normal adults, discrete pulsatility was seen in all profiles of spontaneous GH secretion. Continuous GHRH amplified peak GH concentrations (median basal peak 21.1 mU/l vs. GHRH 62.0 mU/l, P = 0.008) whilst pulse timing remained unaffected. Rebound GH release following SS withdrawal alone was variable. Combining continuous GHRH with intermittent SS produced regular GH responses upon SS withdrawal (20.3 mU/l; range 2. 3-105.4). Heterogeneous patterns of spontaneous GH release were seen in the irradiated subjects. Spontaneous peak GH release was reduced in the children following irradiation (Irradiation 14.9 mU/l vs. Control 25.1 mU/l, P = 0.007). Peak GH concentrations were significantly amplified by GHRH in half of them. Adult long-term survivors had lower spontaneous GH concentrations and continuous GHRH amplified GH release in most subjects (Spontaneous 4.2 mU/l vs. GHRH 6.5 mU/l, P = 0.008) but peak concentrations remained far less than those of controls. Combining intermittent SS with continuous GHRH regularized GH release in many patients but the GH responses remained attenuated (4.6 mU/l; 2.5-17.5).

CONCLUSION

GH pulsatility can be generated in normal volunteers by the combination of continuous GHRH and intermittent SS and provides indirect evidence for a role for GHRH in GH synthesis and replenishment of stored GH pools at times of high SS tone. Patterns of GH release in short-and long-term survivors of childhood brain tumours are heterogeneous suggesting that combined hypothalamic deficiencies of GHRH and SS occur following high dose radiotherapy. The attenuated GH release seen in long-term survivors compared to controls suggests that GH secretory dysfunction does not simply reflect reduced GHRH and SS secretion, and that trophic effects or pituitary damage may be important with time.

A sexually dimorphic pattern of growth hormone secretion in the elderly

In rodents, the sexually dimorphic pattern of pulsatile GH secretion is an important determinant of growth, liver enzyme function and insulin-like growth factor I (IGF-I) expression. Whether this difference is present in humans at different ages is unclear. We studied GH secretory patterns in the elderly by constructing 24-h serum GH profiles in 45 male and 38 female (age, 59.4-73.0 yr) volunteers and related patterns to IGF-I, IGF-binding protein-3 (IGFBP-3), and GH-binding protein levels; body mass index; and waist/hip ratio. Serum GH concentrations were measured in samples drawn at 20-min intervals and analyzed using a sensitive chemiluminescent assay (Nichols Institute Diagnostics: sensitivity, 0.036 mU/L). The 24-h serum GH profiles were analyzed using a concentration distribution method to determine GH peak and trough levels, spectral analysis, and assessment of serial irregularity by approximate entropy (ApEn). There was a highly significant difference in mean 24-h serum GH concentrations in females compared to males (males, 0.88 mU/L; females, 1.31 mU/L; P = 0.009) as a result of significantly higher trough GH levels (males, 0.04 mU/L; females, 0.16 mU/L; P < 0.001). Peak values were not significantly different. Serum IGF-I levels were significantly higher in males (males, 162.4 ng/mL; females, 87.8 ng/ mL; P < 0.001). Peak GH values were related to serum IGF-I levels (males: r = 0.39; P = 0.009; females: r = 0.5; P = 0.002), whereas trough GH levels were not. IGFBP-3 levels were similar and related to GH peaks only in males (r = 0.32; P = 0.03). GH was secreted with a dominant periodicity of 200 min in males and 280 min in females (P < 0.025). The proportion of time taken up by regular oscillatory activity was less in females (females, 11.1%; males, 14.7%; P = 0.01). GH secretion assessed by ApEn was more disordered in females (males, 0.60; females, 0.81; P < 0.001), and increasing disorder was associated with lower IGF-I levels. Body mass index was negatively related to GH in both sexes. In males, trough values were the major determinant (r = -0.31; P = 0.04), whereas in females, the peak value was the major determinant (r = 0.35; P = 0.04). Trough GH levels were inversely related in both sexes to waist/hip ratio (males: r = -0.40; P = 0.006; females: r = -0.44; P = 0.006) and to increasing secretory disorder (ApEn; r = -0.46; P < 0.001). These data demonstrate a sexually dimorphic pattern of GH secretion in the elderly.

The effect of short-term cortisol changes on growth hormone responses to the pyridostigmine-growth-hormone-releasing-hormone test in healthy adults and patients with suspected growth hormone deficiency

BACKGROUND AND AIMS

The interaction between cortisol and growth hormone (GH)-levels may significantly influence GH-responses to a stimulation test. In order to systematically analyse the interaction in a paired design, it is necessary to use a test, which has been proven safe and reliable such as the pyridostigmine-growth-hormone-releasing-hormone (PD-GHRH) test. Three groups of subjects with a different GH-secretory capacity were included.

STUDY A

Eight healthy adults were tested seven times, once with placebo throughout the examination and six times with the PD-GHRH test following no glucocorticoid pretreatment, pretreatment with hydrocortisone (HC) (30 mg/day and 80 mg/day for 1 and 3 days) or pretreatment with 15 mg prednisolone for 1 day. HC (80 mg/day for 1 day) in combination with PD significantly stimulated GH-levels compared to PD alone, 18.9 mU/l +/- 6.1 vs 3.0 mU/l +/- 0.8 (P < 0.05). However, peak GH-responses to PD in combination with GHRH were reduced during HC (80 mg/day for 1 day) compared to no glucocorticoid pretreatment in all healthy adults. Conventional HC therapy (30 mg/day for 1 and 3 days) did not significantly affect peak GH-responses.

STUDY B

16 patients with suspected GH-deficiency (GHD) (seven with known ACTH-deficiency and nine with an intact pituitary-adrenal axis) were tested five times with the PD-GHRH test following no pretreatment or pretreatment with HC (30 mg/day and 80 mg/day for 1 and 3 days). Peak GH-responses were not significantly affected by conventional HC therapy (30 mg/day for 1 and 3 days). However, peak GH-responses to PD in combination with GHRH were reduced during HC (80 mg/day for 1 day) compared to no glucocorticoid pretreatment in all patients. Short-term hypocortisolism did not significantly affect peak GH-responses.

CONCLUSION

The GH-responses to a PD-GHRH test were reduced in all individuals during acute stress-appropriate cortisol levels and the percentage reduction in GH-levels was independent of the GH-secretory capacity. Clinically, we found that peak GH-responses were not significantly affected by a short break in conventional HC therapy nor by conventional HC therapy itself. However, our results also demonstrated that a GH-stimulation test should not be performed on patients, suffering from acute stress.

Behavioural rhythmicity in transgenic growth hormone mice: trade-offs, energetics, and sleep–wake cycles

Transgenic mice with extra rat growth hormone (GH) genes (TRrGH mice) are behaviourally lethargic and sleep 3.4 h/d longer than normal on standard diets. We tested the hypothesis that the doubling of the growth rate of TRrGH mice reduced the energy available for behaviour. Provision of sucrose supplements ad libitum normalized the durations of activity and sleep. Our results support a new allocative theory suggesting that sleep serves as an umbrella function for a suite of synergistic anabolic functions (e.g., growth, immunity, repair). Relegating these to the period of sleep in a secure nest allows full dedication of waking resources to niche interfacing (resource acquisition, risk avoidance and environmental stress resistance). Energy stress in TRrGH mice may arise via specific diversion of energy from waking functions via GH-induced insulin resistance. GH is normally secreted during sleep, but any causal relationship remains unresolved. We examined the circadian and ultradian behaviour of TRrGH mice to determine how a chronically elevated GH level impacts sleep. Remarkably, even the major hormonal distortion in TRrGH mice had little impact on the timing of ultradian or circadian rhythms. Increased sleeping of TRrGH mice on normal diets was due to an increased likelihood and duration of sleep at permitted times. GH did, however, appear to increase the depth of sleep.

Different effects of somatostatin on in vitro growth hormone release in two porcine breeds with different growth rates

A perifusion system of anterior pituitary (AP) tissue was used to investigate the temporal interaction of growth hormone-releasing factor (GRF) and somatostatin (SRIF) in the control of GH secretion in two pig breeds, Göttingen Miniature Pig (GMP), a small obese breed, and German Landrace (GLR), a conventional lean breed. AP tissue pieces derived from sexually mature ovariectomized animals were perifused (6 replicates per treatment) and fractions were collected at 10 min intervals. Basal GH release (ng.ml-1.mg-1 AP) in GLR was twice that of GMP (P < 0.001). Exposure to 10 min pulses of 1 nM GRF repeated 3 times at 2 h intervals resulted in rapid stimulatory GH responses (area under the curve) which became attenuated (P < 0.05) over time in GMP but not in GLR. Surprisingly, during and following the exposure of AP tissue from GMP to 10-, 20-, or 40-min pulses of 10 nM SRIF alone, GH release was markedly stimulated (P < 0.05), while AP tissue from GLR only showed a weak rebound GH release after SRIF pulses. With AP tissue from GLR low concentrations (0.1 nM SRIF) amplified GRF-induced GH release, whereas 1 nM or 10 nM SRIF inhibited GRF-induced GH release. However, concomitant exposure of AP tissue from GMP to 0.1, 1 or 10 nM SRIF during a GRF pulse markedly enhanced the GH response (P < 0.05), compared to 1 nM GRF alone, except for 1 nM SRIF which inhibited the GH response to the first GRF pulse. Thus the presence of SRIF, and not only its withdrawal, is an important factor in setting the timing and duration of GH pulses in both breeds. In GLR the concentration of SRIF is more important than the duration and/or type of SRIF pulse. In contrast, in GMP type and/or duration of SRIF pulses seem to be crucial to optimize pulsatile GH release and even determine peak height of GH pulses caused by GRF. These findings indicate clear breed differences in the role of SRIF and in the control of GH release by the interplay of GRF and SRIF. The "paradoxical' effect of SRIF suggests that the role of SRIF is much more complex than that of a mere inhibitor and whose real role could be a modulator either of GH pulse and/or GRF action on GH release.

Endogenous growth hormone (GH)-releasing hormone is required for GH responses to pharmacological stimuli

The roles of hypothalamic growth hormone-releasing hormone (GHRH) and of somatostatin (SRIF) in pharmacologically stimulated growth hormone (GH) secretion in humans are unclear. GH responses could result either from GHRH release or from acute decline in SRIF secretion. To assess directly the role of endogenous GHRH in human GH secretion, we have used a competitive GHRH antagonist, (N-Ac-Tyr1,D-Arg2)GHRH(1-29)NH2 (GHRH-Ant), which we have previously shown is able to block the GH response to GHRH. We first tested whether an acute decline in SRIF, independent of GHRH action, would release GH. Pretreatment with GHRH-Ant abolished the GH response to exogenous GHRH (0.33 microgram/kg i.v.) but did not modify the GH rise after termination of an SRIF infusion. We then investigated the role of endogenous GHRH in the GH responses to pharmacologic stimuli of GH release. The GH responses to arginine (30 g i.v. over 30 min), L-dopa (0.5 g orally), insulin hypoglycemia (0.1 U/Kg i.v.), clonidine (0.25 mg orally), or pyridostigmine (60 mg orally) were measured in healthy young men after pretreatment with either saline of GHRH-Ant 400 microgram/kg i.v. In every case, GH release was significantly suppressed by GHRH-Ant. We conclude that endogenous GHRH is required for the GH response to each of these pharmacologic stimuli. Acute release of hypothalamic GHRH may be a common mechanism by which these compounds mediate GH secretion.

Relationship between hypophyseal portal GHRH and somatostatin and peripheral GH levels in the conscious sheep

The mechanisms involved in the genesis of pulsatile GH secretion are not well understood. Recently, methods for hypophyseal portal blood collection in conscious sheep became available. Using this method, GHRH and SRIH secretion into hypophyseal portal blood (HPB) and GH release from the pituitary gland were simultaneous assessed and the relationship between GHRH and SRIH changes in HPB and GH in peripheral blood was investigated. In 23 rams (9-11 month old, 35-45 kg bw), 126 hours of HPB were analysed. Fifty-four spontaneous GH peaks were detected. The majority of GH peaks (48.1%) was associated with an increased portal GHRH and a fall in somatostatin concentrations. A simultaneous increase in GHRH and somatostatin levels was observed in 18.5% of GH peaks while 12.9% of peaks occurred with a fall in SRIH and no modification in GHRH concentrations. Finally, 5/54 (9.3%) GH peaks occurred without any modification in portal GHRH and SRIH release. Our data indicate that the GHRH/SRIH interplay is complex. The occurrence of spontaneous GH peaks may be due not only to a coordinate increase in GHRH and reduction in SRIH release similar to male rat, but also to other patterns of GHRH/SRIH secretion.

Radiation and neuroregulatory control of growth hormone secretion

OBJECTIVE

Cranial irradiation frequently results in growth hormone (GH) deficiency. Patients with radiation-induced GH deficiency usually remain responsive to exogenous growth hormone releasing hormone, implying radiation damages the hypothalamus rather than the pituitary. Little is known about the effect of cranial irradiation on the neuroendocrine control of GH secretion. This study was to determine the effect of cranial irradiation on somatostatin tone.

DESIGN

Somatostatin tone was examined by manipulating cholinergic tone in young adults with radiation-induced GH deficiency and a control population. Each individual underwent three separate studies: the GH response to 100 micrograms GHRH-(1-29)-NH2 was assessed alone, and 60 minutes after pyridostigmine or pirenzepine.

PATIENTS

Eight young male adults with radiation induced GH deficiency following treatment in childhood for a brain tumour or acute lymphoblastic leukaemia, and ten healthy adult men were studied.

MEASUREMENTS

Serum growth hormone was measured at 15-minute intervals throughout each of the three study periods.

RESULTS

One of 10 controls and four of eight irradiated subjects had a peak GH level to GHRH analogue of less than 20 mU/l. After pretreatment with pyridostigmine, all subjects except one irradiated subject had a peak GH level of greater than 20 mU/l. Pretreatment with pyridostigmine and pirenzepine significantly modified the GH response to GHRH analogue within both groups (P < 0.0005). Pretreatment with pyridostigmine significantly enhanced the GH response to GHRH analogue (median (range) area under the curve, 9029 (1956-20940) mU/l/min in controls vs 1970 (628-3608) mU/l/min in the irradiated group) compared with GHRH analogue alone (1953 (512-16140) mU/l/min in control group vs 997 (266-3488) mU/l/min in the irradiated group). Pretreatment with pirenzepine significantly attenuated the GH response to GHRH analogue (552 (64-1274) mU/l/min in controls vs 305 (134-2726) mU/l/min in irradiated group). Between the groups there was no significant difference in GH area under the curve (AUC) after GHRH analogue alone. There was a significantly (P = 0.0014) greater increment of GH secretion after pyridostigmine and GHRH analogue compared with GHRH analogue alone (difference in AUC of pyridostigmine+GHRH analogue and GHRH analogue alone 6348 (696-12856) mU/l controls vs 542 (120-1340) mU/l in the irradiated group) and significantly (P = 0.033) greater suppression of GH secretion after pirenzepine and GHRH analogue compared with GHRH analogue alone (difference in AUC of GHRH analogue alone and pirenzepine+GHRH analogue 1644 (222-15205) mU/l in controls vs 479 (469-1623) mU/l in the irradiated group) in the control population compared with those who had received cranial irradiation in childhood.

CONCLUSIONS

These data suggest that cranial irradiation reduces but does not abolish somatostatin (SRIH) tone and also reduces endogenous GHRH secretion. Although SRIH tone is reduced, it can be increased by cholinergic manipulation and is therefore not irreversibly fixed. This has possible implications if GHRH analogues were used to treat children with radiation induced GH deficiency.

The effects of recombinant human insulin-like growth factor I on growth hormone secretion in adolescents with insulin dependent diabetes mellitus

OBJECTIVE

It has been proposed that low IGF-I levels and reduced IGF-I bioactivity may lead to elevated GH levels in adolescents with insulin dependent diabetes (IDDM). We have therefore studied the effects of human recombinant insulin-like growth factor I (rhIGF-I) administration on GH levels and GH secretion in adolescents with IDDM.

PATIENTS

Nine late pubertal adolescents (four male and five female) with IDDM.

DESIGN

A double-blind placebo controlled study of rhIGF-I administered subcutaneously in a dose of 40 micrograms/kg body weight at 1800 h.

MEASUREMENTS

IGF-I and GH concentrations were measured at regular intervals throughout the study. Twenty-two hour GH secretory rates were calculated by deconvolution analysis. Overnight GH profiles were analysed by distribution analysis, and Fourier transformations were performed on both overnight GH concentrations and GH secretory rates.

RESULTS

Mean IGF-I levels over the 22-hour study period were significantly elevated following rhIGF-I administration (350 +/- 26 vs 205 +/- 21 micrograms/l (mean +/- SEM), P < 0.01). Mean 22-hour GH levels were reduced following rhIGF-I administration (19.4 +/- 4.0 compared with 33.6 +/- 5.8 mU/l; P = 0.01). Distribution analysis demonstrated that the reduction in GH levels was due to changes in the proportion of values at both high and low concentrations. Deconvolution analysis also revealed a significant overall reduction in GH secretory rate following IGF-I administration (1.81 +/- 0.30 vs 2.98 +/- 0.47 mU/min, P = 0.01) which was still apparent during the final 5.5 hours of the study period (1.51 +/- 0.30 vs 2.76 +/- 0.61 mU/min, P = 0.02). The dominant periodicity of GH secretory episodes as determined by Fourier transformation was between 120 and 180 minutes after both IGF-I and placebo.

CONCLUSIONS

In late pubertal adolescents with IDDM the rise in IGF-I levels following rhIGF-I administration in a subcutaneous dose of 40 micrograms/kg body weight leads to a significant reduction in GH levels and GH secretory rate. The reduction in GH secretion is due to changes in pulse amplitude rather than frequency. A reduction in GH secretion was apparent at the beginning and also towards the end of the 22-hour study period.

Suppression of growth hormone (GH) secretion by a selective GH-releasing hormone (GHRH) antagonist. Direct evidence for involvement of endogenous GHRH in the generation of GH pulses

To study the potential involvement of growth hormone-releasing hormone (GHRH) in the generation of growth hormone (GH) pulses in humans we have used a competitive antagonist to the GHRH receptor, (N-Ac-Tyr1,D-Arg2)GHRH(1-29)NH2(GHRH-Ant). Six healthy young men were given a bolus injection of GHRH-Ant 400 micrograms/kg body wt or vehicle at 2200 h and nocturnal GH concentrations were assessed by every 10-min blood sampling until 0800 h. Integrated total and pulsatile GH secretion were suppressed during GHRH-Ant treatment by 40 +/- 6 (SE) % and 75 +/- 5%, respectively. GHRH-Ant suppressed maximum (7.6 +/- 2.2 vs 1.8 +/- 0.5 micrograms/liter; P < 0.001) and mean (3.3 +/- 1.0 vs 1.1 +/- 0.2 micrograms/liter; P = 0.02) GH pulse amplitudes. There was no change in integrated nonpulsatile GH levels, pulse frequency, or interpulse GH concentration. GHRH-Ant 400 micrograms/kg also suppressed the GH responses to intravenous boluses of GHRH 0.33 micrograms/kg given 1, 6, 12, and 24 h later by 95, 81, 59, and 4%, respectively. In five healthy men, the responses to 10-fold larger GHRH boluses (3.3 micrograms/kg) were suppressed by 82 and 0%, 1 and 6 h after GHRH-Ant 400 micrograms/kg, respectively. These studies provide the first direct evidence that endogenous GHRH participates in the generation of spontaneous GH pulses in humans.

Growth response to growth hormone-releasing hormone(1-29)-NH2 compared with growth hormone

To assess the growth-promoting effect of different doses of growth hormone-releasing hormone(1-29)-NH2 (GHRH(1-29)-NH2) in GH deficiency (GHD) of hypothalamic origin, 43 prepubertal children aged between 4.3 and 18.9 years (mean 10.4 +/- 2.9 years) were randomly assigned to three treatment regimens: low-dose GHRH(1-29)-NH2 (LD group; n = 15), high-dose GHRH(1-29)-NH2 (HD group; n = 12) and GH (GH group; n = 16). The LD group received GHRH(1-29)-NH2 at 30 micrograms/kg/day s.c. in three daily doses, the HD group received 60 micrograms/kg/day s.c. in three daily doses and the GH group received GH, 0.1 IU/kg/day s.c. once daily. All children were treated for a period of 6 months. Evaluation included anthropometry, bone age, intravenous and subcutaneous GHRH(1-29)-NH2 tests and determination of insulin-like growth factor I (IGF-I) levels. An increase in height velocity of 2 cm/year or more was observed in all except two children. Height velocity during treatment was lowest in the LD group, but comparable in the HD and GH groups. An increase in height SDS for bone age occurred only in the GH-treated group. GH responses to intravenous GHRH(1-29)-NH2 showed a priming effect of the LD GHRH(1-29)-NH2 treatment, while a decrease in response occurred in the GH-treated group. Following a subcutaneous test dose of one-third of the daily dose of GHRH(1-29)-NH2, GH levels remained unchanged in both the LD and HD groups. There was accumulation of GHRH immunoreactivity over time in the HD group, but there was no correlation between measured GHRH and GH levels.(ABSTRACT TRUNCATED AT 250 WORDS)

Physiological levels of growth hormone fail to suppress growth hormone releasing hormone (1-29) NH2-stimulated growth hormone secretion in man

We studied 11 normal adult males. Six subjects (Study A) received a bolus of saline or of 50 mU biosynthetic human growth hormone (r-hGH) or a one hour iv infusion of r-hGH (80 mU/h) in random order. On each occasion this was followed by an iv bolus of GHRH (1-29) NH2 (100 micrograms) 90 minutes after the first event. Five subjects (Study B) received a bolus iv injection of saline or of 500 mU r-hGH followed by iv GHRH (1-29) NH2 (100 micrograms) 90 minutes later. There was no significant difference in the serum GH concentrations achieved following the 50 mU bolus or iv infusion of r-hGH (range 5.6-67.0 mU/l). Higher concentrations of GH (mean +/- SE, 238.4 +/- 21.3 mU/l) were achieved with the 500 mU bolus of r-hGH. The peak GH responses to iv GH-RH (1-29) NH2 were similar in all instances. The most important factor determining the response to exogenous GHRH (1-29) NH2 was the serum GH concentration at the time that the GHRH (1-29) NH2 was administered and the mode of r-hGH administration (iv bolus or iv infusion). These data demonstrate that within the range of physiological serum GH concentrations the mode of presentation of GH (bolus or infusion) and GH secretory status are the most important factors in determining GH responsivity to GHRH. Under these circumstances GH would appear not to participate in a rapid-acting short-loop negative feedback mechanism in man as the response to exogenous GHRH was not attenuated.

The frequency and amplitude of growth hormone secretory episodes as determined by deconvolution analysis are increased in adolescents with insulin dependent diabetes mellitus and are unaffected by short-term euglycaemia

OBJECTIVE

High overnight plasma growth hormone (GH) levels in insulin-dependent diabetes mellitus (IDDM) are reflected in both an increase in the GH pulse amplitude and elevated baseline GH concentrations. To determine whether these are a result of an increase in GH secretory episodes, we undertook deconvolution analysis of overnight GH profiles using previously determined half-life data.

DESIGN

Deconvolution of overnight GH profiles (2000-0800 h) was undertaken from normal and diabetic adolescents (either on their usual insulin regime (n = 15), during overnight euglycaemic clamp using a variable rate insulin infusion (n = 29), or during clamp plus 100 mg pirenzepine to suppress endogenous GH (n = 7)).

PATIENTS

Thirty-five normal and 29 diabetic adolescents of both sexes at all stages of puberty.

MEASUREMENTS

GH secretory rates were calculated from deconvolution analysis, and Fourier transformation was increased mean overnight GH secretion when analysed by sex and by puberty stage compared to normal subjects; overnight GH secretion median (range) of diabetic group 1.88 (0.56-3.81) mU/min; control group 0.62 (0.32-1.92) mU/min (P < 0.001). Fourier transform analysis of these secretory episodes showed greater pulse frequency in the diabetics with dominant pulse periodicity of 90 minutes compared with 135 minutes in normal subjects. During overnight euglycaemia, mean +/- SEM overnight GH secretory rates were comparable to subjects' usual regime night (1.82 +/- 0.33 vs 1.91 +/- 0.37 mU/min) and there was no change in the dominant pulse periodicity of 90 minutes. Pirenzepine administration in diabetic subjects significantly reduced overnight GH secretion from 1.57 +/- 0.19 to 0.71 +/- 0.80 mU/min (P < 0.001) showing a median (range) reduction of 63 (9.3-82.8)% when compared to the subjects' clamp night. However, dominant pulse periodicity was not altered by pirenzepine administration, and remained at 90 minutes.

CONCLUSION

In patients with insulin-dependent diabetes mellitus there is an increase in both the amplitude and frequency of pulsatile GH secretion compared to normal subjects, which is not affected by maintenance of overnight normoglycaemia. The anticholinergic drug pirenzepine appears to suppress the amplitude of GH pulse secretion but has no effect on frequency.

Effects of the new somatostatin analogue (BIM 23014) on blood glucose homeostasis in normal men

Changes in blood glucose homeostasis induced by the new somatostatin analogue BIM 23014 (BIM) were studied. Eight normal men (study 1) received either vehicle or 1000, 2000 and 3000 micrograms BIM as a 24 h s.c. infusion. Blood glucose, plasma insulin, C-peptide, glucagon and growth hormone (GH) were measured before treatment and then hourly for 24 h. In five normal men (study 2) an oral glucose tolerance test (OGTT) was performed during vehicle infusion and then on days 1 and 7 of a continuous s.c. infusion of 2000 micrograms BIM daily for 7 days. The same biological parameters as in study 1 were measured before OGTT and then twice-hourly for 5 h. Dose-dependent and transient glucose intolerance was observed in the first half of study 1. Except for glucagon, BIM significantly (P < 0.01) reduced plasma insulin, C-peptide and GH levels. In study 2 BIM infusion induced glucose intolerance and a drop in plasma insulin and C-peptide on day 1 which disappeared on day 7 of infusion. Higher on day 7 than on day 1, plasma GH secretion was significantly (P < 0.01) reduced throughout BIM infusion. In contrast plasma glucagon levels were not modified at any time. Side-effects were abdominal cramps and diarrhoea which were observed in most subjects when increasing BIM daily dose. In conclusion, BIM infusion induced transient changes in glucose homeostasis and insulin secretion in normal men. By contrast, plasma GH levels remained reduced throughout the treatment. BIM appears to be a useful tool to selectively inhibit GH secretion.

The pulsatile GH secretion in acromegaly: hypothalamic or pituitary origin?

OBJECTIVE

We studied the effects of different modes of octreotide therapy on the pulsatile pattern of GH release in an attempt to define better its regulation by growth hormone-releasing hormone (GHRH) and somatostatin and its effects on IGF-I plasma levels in acromegaly.

DESIGN

In six acromegalic patients not cured by previous treatment we compared the 24-hour GH secretion profiles under basal conditions with subcutaneous (s.c.) bolus injections of 100 micrograms octreotide every 8 hours and with continuous s.c. infusions of the same daily dose. Blood samples were taken every 10 minutes over 24 hours followed by a GHRH test (100 micrograms GHRH i.v.) with blood sampling every 15 minutes for another 2 hours. After a 4-week interval all patients were treated either by the bolus or continuous mode of octreotide application in a randomized cross-over design. On day 4 of treatment blood sampling and GHRH test were repeated. Octreotide treatment was withdrawn for another 4 weeks; all patients then received the alternate application mode and were measured under similar conditions.

MEASUREMENTS

Serum GH and plasma IGF-I concentrations were analysed by serial array averaging. IGF-I levels were measured in two different assays with and without previous protein extraction. For GH pulse detection three different algorithms (Cluster, Pulsar, Desade) were applied.

RESULTS

With both treatments, the initially elevated basal 24-hour mean serum GH concentrations (58.0 +/- 9.7 mU/l mean +/- SEM) decreased significantly (bolus: 11.5 +/- 4.9 mU/l, P < 0.001 vs basal; continuous infusion: 7.6 +/- 1.9 mU/l, P < 0.001 vs basal) after 4 days. GH suppression was significantly more pronounced following continuous infusion than bolus (P < 0.05). IGF-I plasma concentrations were lowered significantly (P < 0.05) with both forms of treatment which did not differ between themselves. Bolus and continuous infusion treatment significantly inhibited (P < 0.05) the amplitudes of pulsatile GH release, but did not change the pulse frequency. In two of the patients, GHRH stimulation did not increase GH serum levels suggesting a constitutive activation of adenylyl cyclase.

CONCLUSION

Continuous subcutaneous octreotide treatment in acromegaly suppresses mean GH levels better than bolus injection. The number of GH pulses remains unaffected by both modes of treatment providing evidence against a somatostatinergic mechanism of pulsatile GH secretion in these patients. The unchanged frequency of pulsatile GH release in the patients unresponsive to exogenous GHRH indicates that this pattern might be independent of hypothalamic GHRH and somatostatin and suggests a pituitary-derived mechanism for GH pulse generation in acromegaly.

Rate of change (modulation) of serum growth hormone concentrations is a more important factor in determining growth rate than duration of exposure

OBJECTIVE

To determine whether duration of exposure to GH and/or rate of change of serum GH concentration are important factors in determining the growth rate of short children.

DESIGN

An analysis of parameters of occupancy percentage and rate of change of serum GH concentration was performed as part of a prospective study investigating the relationship between growth and GH in childhood.

PATIENTS

Sixty-four short prepubertal children (48 male, 16 female) aged between 4.7 and 11.9 years were studied. Thirty-one children were growing with a height velocity standard deviation score between 0 and -0.8 and were defined as short normal. Thirty-three children were growing with a height velocity standard deviation score less than -0.8 and were defined as short slowly growing.

MEASUREMENTS

Twenty-four hour serum GH concentration profiles were constructed by withdrawing samples at 20-minute intervals. Analysis of occupancy percentage was performed on each data array by determining cumulative distributions and plotting these as linear probits against log serum GH concentration. Estimates of peak (OC95), intermediate (OC50) and trough (OC5) occupancies were calculated. A first-order derivative of the concentration-time data array was determined for each profile as a measure of rate changes.

RESULTS

First-order derivative values were significantly greater in the short normal group than in the short slowly growing children (short normal median 1.41 mU/l/min; short slowly growing median 0.72 mU/l/min; P less than 0.001). OC95 values were significantly higher in the short normal group (median 19.31 mU/l) than the short slowly growing group (median 7.69 mU/l) (P less than 0.001). There was no difference in OC50 values. OC5 values were lower in short normal children (median 0.20 mU/l) than in the short slowly growing children (0.55 mU/l) (P less than 0.003). The most important factor in determining growth rate was the rate of change in serum GH concentration (FOD). Occupancy percentage played no part in the relationship. The regression equation was Height velocity SDS = 1.16 (In FOD) - 1.03; r = 0.75; P less than 0.001

CONCLUSIONS

These data suggest that the pattern of presentation of GH in the circulation is an important factor in determining target organ response. Although occupancy percentages at differing serum GH concentrations differ between short slowly growing and short normal children, it is the rate of change of the hormone in the circulation which appears to be the more important 'signal' in terms of modulating growth.