GH Pulse Amplitude Research Articles

REGULATION OF THE GH-RECEPTOR (R) / BINDING PROTEIN (BP) BY GH PULSATILITY

GH secretion is pulsatile in man and in every mamalian species that has been so far studied. The magnitude of pulses, their frequency and their regularity vary. The R on it' part, undergoes cycles of internalization and recycling, which are in synchrony with the frequency of GH pulses. The present study correlated GH profiles with GH-R and GH-BP human and animal in the course of ontogenesis, effects of short stature, fasting, anorexia nervosa, obesity, diabetes, GH-therapy, acromegaly and cirrhosis. In short, slowly growing children GH-BP correlated negatively with mean GH-pulse amplitude and integrated concentration. GH pulsatility is high in newborns, fasting, anorexia nervosa, diabetes, acromegaly and cirrhosis. GH-BP is low in all these conditions. GH pulsatility is low, and GH-BP is high, in GH-therapy and obesity. Negative correlation of GH pulsatility with GH-BP exists across the mammalian class, with increasing pulsatility in rabbit < man < female rat < male rat < guinea pig, whereas GH-BP levels and liver membrane's GH-R decrease in the same order. Newborn rats have high GH pulsatility and low GH-R and GH-BP, whereas obese rats have low GH levels and high GH-receptors. It is concluded that the pattern of GH profiles is the major determinant of the GH-R / GH-BP, that the various physiological and pathological conditions regulate primarily the pattern of GH pulsatility, which, in turn, regulates the GH-R / GH-BP, and thereby exert the specific effects on target cells to promote or to suppress growth, or to express distinct metabolic actions.

Ontogenesis of the sexual dimorphism of growth hormone secretion by perifused rat hemipituitaries.

The aims of the present study were to investigate the sexual dimorphism and the role of sex steroids in GH secretion at the pituitary level, and to evaluate the ontogenesis of these effects. Towards these aims we used an in vitro perifusion system of hemipituitaries under a simulated milieu of hypothalamic factors: two 3-min pulses of GHRH at 3-hour intervals were separated by continuous flow of somatostatin. Rat GH was measured in 2.4-min fractions and analyzed by the pulse analysis program PULSAR. Pulses were similar in prepubertal male and female rats, but sexual dimorphism was evident in adults. In adult males, who had undergone neonatal gonadectomy, GH pulse amplitude and area under the curve (AUC) were lower compared to control. When gonadectomy had been performed at a prepubertal age, the pulse amplitude was still lower, but the AUC was not different from control. The gap between orchiectomy at neonatal and prepubertal age indicates the perinatal imprint, which induces an increase in AUC. Neonatal testosterone treatment of intact female rats had no effect on GH secretion by adult pituitaries. In neonatally gonadectomized female rats, under neonatal testosterone treatment, the pulse amplitude increased. A similar increase was observed after neonatal gonadectomy without testosterone treatment. We conclude that the sexual dimorphism of GH secretion is partially induced at the pituitary level and its response to the hypothalamic hormones. We assume that a neonatal imprint effect of testosterone in the male induces primarily an increase in AUC in response to GHRH. The imprint in females influences the GH pulse amplitude and AUC.

Synergistic interaction between insulin-like growth factors-I and -II in central regulation of pulsatile growth hormone secretion.

Insulin-like growth factor (IGF)-I and -II peptides, receptors, mRNAs, and binding proteins are widely distributed in the central nervous system (CNS), yet their physiological role in the brain remains largely unknown. While earlier in vivo studies in the rat suggested that IGF-I may participate in feedback regulation of GH secretion at a CNS level, the preparations used were only partially pure. The recent availability of purified recombinant IGF-I and -II peptides prompted us to reexamine the involvement of the IGFs in vivo in central regulation of pulsatile GH secretion. Five groups of free-moving adult male rats bearing chronic intracerebroventricular (icv) and intracardiac venous cannulae were icv administered IGF-I (in doses of 0.5, 2, 3, and 10 micrograms) or the acid-saline vehicle; an additional group received 1 microgram of the potent IGF-I analog, long R3 IGF-I. Spontaneous 6-h plasma GH secretory profiles were obtained from all groups. Vehicle-injected control animals exhibited the typical pulsatile pattern of GH secretion, with most peak GH values above 150 ng/ml and trough levels below 1.2 ng/ml. Central administration of IGF-I alone or long R3 IGF-I at all doses tested failed to alter the pulsatile pattern of GH release; there were no significant differences in GH peak amplitude, GH trough level, GH interpeak interval, or mean 6-h plasma GH level compared to those in vehicle-injected controls. In a second study, designed to determine the effects of central administration of IGF-I and IGF-II, in combination, icv injection of 1 microgram IGF-I and 1 microgram IGF-II resulted in a marked suppression in the amplitude of spontaneous GH secretory bursts approximately 3 h after injection; both GH pulse amplitude (43.5 +/- 5.6 vs. 130.6 +/- 14.6 ng/ml; P less than 0.001) and mean plasma GH level (16.3 +/- 1.9 vs. 35.2 +/- 1.8 ng/ml; P less than 0.001) were severely reduced 3-6 h after injection compared to those in vehicle-injected controls. These results demonstrate that IGF-I alone does not play a physiologically important role in feedback regulation of GH secretion at the level of the CNS. Our findings suggest a synergistic interaction between IGF-I and -II in the brain for central control of pulsatile GH secretion.

Tamoxifen attenuates pulsatile growth hormone secretion: mediation in part by somatostatin.

Tamoxifen, a partial competitive antagonist to the estrogen receptor, is a potent inhibitor of the proliferation of experimental mammary carcinoma in the rat and is widely used clinically in the treatment of breast cancer. Blockade of estrogen receptors present on neoplastic cells represents the classic mechanism of action of tamoxifen, but the drug has a variety of other actions that may contribute to its antiproliferative properties. While it is recognized that estrogens play an important role in modulating pulsatile GH release, the effect of antagonists to sex steroid receptors on GH secretory dynamics has not previously been described. In the present study we examined the effect of tamoxifen on pulsatile GH secretion in free-moving adult male and female rats. The drug, when administered in a manner previously shown to be associated with antineoplastic activity, caused a marked suppression of the amplitude of spontaneous GH secretory bursts and significantly reduced mean 6-h plasma GH levels in both sexes compared to those in their respective peanut oil-injected controls. Inhibition of spontaneous GH pulses persisted for up to 7 weeks after tamoxifen administration in both sexes. Immunoneutralization of endogenous somatostatin in tamoxifen-treated male rats completely restored both GH pulse amplitude (121.6 +/- 9.5 vs. 62.5 +/- 13.5 ng/ml in tamoxifen-treated rats given normal sheep serum; P less than 0.02) and mean 6-h plasma GH levels (53.3 +/- 6.6 vs. 17.9 +/- 3.6 ng/ml in normal sheep serum-treated rats; P less than 0.01) to levels observed in our peanut oil-injected controls. These results demonstrate that 1) tamoxifen has potent inhibitory effects on pulsatile GH secretion; and 2) the blunting of GH pulse amplitude by tamoxifen is mediated at least in part by increased release of endogenous somatostatin. These findings motivate further investigation of the clinical significance of tamoxifen-induced suppression of GH secretion in relation to the antineoplastic activity of this commonly used drug.

Spontaneous growth hormone secretion increases during puberty in normal girls and boys

To test the hypothesis that GH secretion increases during puberty, we measured GH levels in samples obtained every 20 min for 24 h from 132 normal children and adolescents. In both girls and boys, GH levels increased during puberty. The increase in mean levels was earlier in girls than boys, was most evident at night, and was due to increased pulse amplitude rather than a change in pulse frequency. The mean nighttime GH level in girls with bone ages (BA) greater than 12 to 14 yr were significantly greater than the mean level in girls with BA less than 8 yr (7.3 +/- 3.0 vs. 3.4 +/- 1.7 micrograms/L; P less than 0.01) and were greatest at breast stage 3 (7.9 +/- 2.5 micrograms/L). GH pulse amplitude increased significantly before pubertal onset in girls and was significantly greater at BA greater than 12 to 14 yr than at BA of 8 yr or less (13.9 +/- 6.0 vs. 7.9 +/- 4.8 micrograms/L; P less than 0.01) and greatest at breast stage 3 (15.0 +/- 6.3 micrograms/L). The pubertal increase in GH secretion was delayed in boys compared to girls, with the lowest mean 24-h GH and mean nighttime GH values in boys with BA greater than 8 to 11 yr. The mean nighttime GH level at BA greater than 11 to 13 yr in boys was significantly greater than that in the boys with BA greater than 8 to 11 yr (5.8 +/- 2.9 vs. 3.5 +/- 2.1 micrograms/L; P less than 0.05) and was greatest at a testicular volume of more than 10 to 15 mL (6.5 +/- 2.0 micrograms/L). The mean nighttime GH pulse amplitude in boys was significantly greater at BA greater than 11 to 13 yr than at BA greater than 8 to 11 yr (13.9 +/- 5.7vs. 7.3 + 2.6 micrograms/L, P less than 0.05) and was greatest at a testicular volume greater than 20 mL (15.8 +/- 12.0 micrograms/L). The mean nighttime GH levels correlated inversely with body mass index in both sexes, although the correlation achieved statistical significance only for the girls, being stronger in breast stage 3 to 5 girls (r = -0.57 P = 0.0007; n = 32) than in stage 1 and 2 girls (r = -0.38; P = 0.03; n = 32). These observations in normal adolescents emphasize the importance of interpreting spontaneous GH levels in short children in relation to normative data appropriate for sex, body mass, and bone age or pubertal stage.

Changes in growth hormone concentrations during puberty in adolescents with insulin dependent diabetes.

To document the changes in pulsatile growth hormone secretion in diabetic adolescents during puberty, and to investigate their relationship to both metabolic control and stature. Auxological parameters, overnight growth hormone secretion, fasting IGF-I, hourly glucose and metabolic control were assessed in a group of adolescents with diabetes. Fifty-two diabetic adolescents (28 males and 24 females) at different pubertal stages and with varying degrees of metabolic control were studied. Ten of those with poor diabetic control were studied on two occasions. Height and weight measurements, pubertal staging, growth velocity data and bone age estimation were obtained on all the patients. Overnight growth hormone profiles (Pulsar program analysis), glycosylated haemoglobin and fasting IGF-I were performed on all the subjects. Hourly overnight glucose measurements were also obtained on the ten subjects who had two overnight growth hormone studies. For the whole diabetic growth, GH area under curve (AUC) was maximal in late puberty (pubertal stage 4), and was paralleled by maximal GH peak amplitude. No relationship between GH-AUC and metabolic control was demonstrated. No difference in GH parameters was demonstrated between the male and female subgroups. The relationship between growth hormone secretory parameters and stature was not significant. However, GH-AUC was significantly correlated with growth velocity in the males but not the females. The pattern of GH secretion in adolescents with diabetes parallels that seen in normal adolescents during puberty, with increases in GH concentration associated with increased GH pulse amplitude. The degree of metabolic control had no effect on this pattern and there was no relationship between GH secretory parameters and stature.

Short-term adult exposure to estradiol feminizes the male pattern of spontaneous and growth hormone-releasing factor-stimulated growth hormone secretion in the rat

Experimental evidence indicates that the neonatal gonadal steroid environment is an important determinant of the sexual dimorphism of GH secretion and body growth. However, the influence of the sex steroids in GH control during adult life and their mechanism/site of action are largely unknown. In the present study we examined the effects of adult gonadectomy (GNX) and short term adult exposure to 17 beta-estradiol (E2) on both spontaneous and GRF-stimulated GH release in free-moving adult male rats. The rate of body weight gain was also monitored. GNX (3 weeks postoperatively) resulted in a 2-fold reduction in GH pulse amplitude compared to that in sham-operated control rats, but did not significantly alter the GH nadir or the interpeak interval. Exposure to E2 (sc implants) for 4 days markedly disrupted the spontaneous GH secretory profile of both sham-operated and GNX rats; E2-treated animals exhibited a striking elevation (4- to 20-fold) of GH trough levels and a significant decrease in GH interpeak interval, remarkably similar to the typical female rat GH secretory profile. The augmentation in both GH nadir and GH pulse frequency was evident as early as 12 h after a single sc injection of E2 valerate. In sham and GNX rats bearing control implants, the GH response to 1 micrograms rat GRF-(1-29)NH2, iv, was significantly greater when GRF was administered at peak (1100 h) than at trough (1300 h) times of GH secretion; the latter is known to be due to antagonism by the cyclical increased release of endogenous somatostatin (SRIF) in the male rat. Treatment with E2 abolished this time-dependent difference in both groups and produced a regular pattern of GH responsiveness to GRF similar to that typically observed in the female rat, thus suggesting that E2 has altered the pattern of hypothalamic SRIF secretion from a cyclic to a more continuous mode of release. Chronic exposure to E2 for 2 weeks resulted in an almost 6-fold inhibition of the rate of body weight gain in sham-operated male rats to levels comparable to those in normal adult female rats. Taken together, these results demonstrate that short term exposure to E2 during adult life can profoundly feminize the male pattern of spontaneous and GRF-stimulated GH secretion, as well as rate of somatic growth.(ABSTRACT TRUNCATED AT 400 WORDS)

Short-term adult exposure to estradiol feminizes the male pattern of spontaneous and growth hormone-releasing factor-stimulated growth hormone secretion in the rat.

Experimental evidence indicates that the neonatal gonadal steroid environment is an important determinant of the sexual dimorphism of GH secretion and body growth. However, the influence of the sex steroids in GH control during adult life and their mechanism/site of action are largely unknown. In the present study we examined the effects of adult gonadectomy (GNX) and short term adult exposure to 17 beta-estradiol (E2) on both spontaneous and GRF-stimulated GH release in free-moving adult male rats. The rate of body weight gain was also monitored. GNX (3 weeks postoperatively) resulted in a 2-fold reduction in GH pulse amplitude compared to that in sham-operated control rats, but did not significantly alter the GH nadir or the interpeak interval. Exposure to E2 (sc implants) for 4 days markedly disrupted the spontaneous GH secretory profile of both sham-operated and GNX rats; E2-treated animals exhibited a striking elevation (4- to 20-fold) of GH trough levels and a significant decrease in GH interpeak interval, remarkably similar to the typical female rat GH secretory profile. The augmentation in both GH nadir and GH pulse frequency was evident as early as 12 h after a single sc injection of E2 valerate. In sham and GNX rats bearing control implants, the GH response to 1 micrograms rat GRF-(1-29)NH2, iv, was significantly greater when GRF was administered at peak (1100 h) than at trough (1300 h) times of GH secretion; the latter is known to be due to antagonism by the cyclical increased release of endogenous somatostatin (SRIF) in the male rat. Treatment with E2 abolished this time-dependent difference in both groups and produced a regular pattern of GH responsiveness to GRF similar to that typically observed in the female rat, thus suggesting that E2 has altered the pattern of hypothalamic SRIF secretion from a cyclic to a more continuous mode of release. Chronic exposure to E2 for 2 weeks resulted in an almost 6-fold inhibition of the rate of body weight gain in sham-operated male rats to levels comparable to those in normal adult female rats. Taken together, these results demonstrate that short term exposure to E2 during adult life can profoundly feminize the male pattern of spontaneous and GRF-stimulated GH secretion, as well as rate of somatic growth.(ABSTRACT TRUNCATED AT 400 WORDS)

Suppression of the Pituitary-Gonadal Axis in Children with Central Precocious Puberty: Effects on Growth, Growth Hormone, Insulin-Like Growth Factor-I, and Prolactin Secretion*

To assess further the relationship between gonadal sex steroids and PRL, GH, and insulin-like growth factor-I (IGF-I) secretion and to help clarify the mechanism underlying the pubertal growth spurt, we studied 11 children (10 girls) with central precocious puberty before and during gonadal suppression with the GnRH agonist (GnRH-a) leuprolide acetate. Nocturnal sampling for plasma levels of GH and PRL, GH response to GH-releasing factor-(1-44), and plasma IGF-I levels were determined before and 3-6 months after pituitary-gonadal suppression. Treatment caused a significant decrease in the LH and FSH responses to GnRH (P less than 0.01) and the plasma concentration of estradiol (P less than 0.05). The patients' mean height velocity SD score for chronological age, initially 3.8 +/- 1.9, decreased significantly to 0.9 +/- 0.9 with treatment (P less than 0.005). Nocturnal GH secretion (mean GH concentration, sum of GH pulse areas, sum of GH pulse amplitudes, and GH pulse frequency) and mean IGF-I levels (1.38 +/- 0.6 vs. 1.72 +/- 0.34 U/mL) were not significantly altered by treatment. However, the mean peak GH response to GH-releasing factor-(1-44) was 29.2 +/- 6.8 micrograms/L before treatment and declined significantly to 17.7 +/- 3.4 micrograms/L after gonadal suppression (P less than 0.05). PRL secretion was similar before and after GnRH-a-induced suppression. These results indicate that the decrease in height velocity noted during GnRH-a treatment occurred independently of changes in nocturnal GH secretion and IGF-I levels. These data are consistent with the premise that sex steroids can modulate growth by a direct action on skeletal growth.

Spontaneous Growth Hormone Secretion Increases during Puberty in Normal Girls and Boys*

To test the hypothesis that GH secretion increases during puberty, we measured GH levels in samples obtained every 20 min for 24 h from 132 normal children and adolescents. In both girls and boys, GH levels increased during puberty. The increase in mean levels was earlier in girls than boys, was most evident at night, and was due to increased pulse amplitude rather than a change in pulse frequency. The mean nighttime GH level in girls with bone ages (BA) greater than 12 to 14 yr were significantly greater than the mean level in girls with BA less than 8 yr (7.3 +/- 3.0 vs. 3.4 +/- 1.7 micrograms/L; P less than 0.01) and were greatest at breast stage 3 (7.9 +/- 2.5 micrograms/L). GH pulse amplitude increased significantly before pubertal onset in girls and was significantly greater at BA greater than 12 to 14 yr than at BA of 8 yr or less (13.9 +/- 6.0 vs. 7.9 +/- 4.8 micrograms/L; P less than 0.01) and greatest at breast stage 3 (15.0 +/- 6.3 micrograms/L). The pubertal increase in GH secretion was delayed in boys compared to girls, with the lowest mean 24-h GH and mean nighttime GH values in boys with BA greater than 8 to 11 yr. The mean nighttime GH level at BA greater than 11 to 13 yr in boys was significantly greater than that in the boys with BA greater than 8 to 11 yr (5.8 +/- 2.9 vs. 3.5 +/- 2.1 micrograms/L; P less than 0.05) and was greatest at a testicular volume of more than 10 to 15 mL (6.5 +/- 2.0 micrograms/L). The mean nighttime GH pulse amplitude in boys was significantly greater at BA greater than 11 to 13 yr than at BA greater than 8 to 11 yr (13.9 +/- 5.7vs. 7.3 + 2.6 micrograms/L, P less than 0.05) and was greatest at a testicular volume greater than 20 mL (15.8 +/- 12.0 micrograms/L). The mean nighttime GH levels correlated inversely with body mass index in both sexes, although the correlation achieved statistical significance only for the girls, being stronger in breast stage 3 to 5 girls (r = -0.57 P = 0.0007; n = 32) than in stage 1 and 2 girls (r = -0.38; P = 0.03; n = 32). These observations in normal adolescents emphasize the importance of interpreting spontaneous GH levels in short children in relation to normative data appropriate for sex, body mass, and bone age or pubertal stage.

Growth Hormone-Binding Protein Activity Is Inversely Related to 24-Hour Growth Hormone Release in Normal Boys*

To investigate the physiological relationship between serum GH-binding proteins and 24-h GH release, we compared the 24-h GH pulse attributes in serum samples obtained at 20-min intervals to the serum GH-binding protein activity (GH-BP) from 38 normal boys between 7 5/12 and 18 4/12 yr of age. GH-BP was determined in a serum sample from each study (containing less than 1.0 micrograms/L GH) using a standardized GH-BP assay. GH-BP results are expressed as the percentage of [125I]human GH bound to the high affinity GH-BP complex (peak II) per 160 microL serum. There were significant inverse relationships between the high affinity (receptor-related) GH-BP and several characteristics of 24-h GH release. Specifically, GH-BP was significantly (P less than 0.005 for all), but negatively, correlated with mean 24-h GH concentration (r = -0.62), sum of the GH pulse amplitudes (r = -0.57), sum of the GH pulse areas (r = -0.55), interpulse mean GH concentration (r = -0.53), and number of GH pulses per 24 h (r = -0.53). In addition, GH-BP correlated positively with the mean time interval between pulses (r = 0.59). There was also a significant positive correlation (r = 0.75; P less than 0.001) between GH-BP and the subject's age-adjusted body mass index SD score (BMI-SDS). Each characteristic of 24-h GH release correlating inversely with GH-BP also correlated inversely with BMI-SDS (P less than 0.01 for all comparisons). GH-BP did not, however, correlate with plasma insulin-like growth factor-I levels, serum testosterone concentrations, or height SDS. Binding to the low affinity GH-BP (peak I) did not correlate significantly with any of the examined GH pulse attributes, BMI-SDS, or the degree of binding to the high affinity GH-BP (peak II). We conclude that an inverse relationship exists between the high affinity serum GH-BP and 24-h GH release in boys under normal physiological conditions. We speculate that abnormalities in this relationship probably also exist and may underlie some disorders of growth.

Growth hormone secretion patterns in relation to LH and estradiol secretion throughout normal female puberty

Pulsatile growth hormone secretion patterns were studied in relation to luteinizing hormone and estradiol release in 33 healthy (pre)pubertal girls. Plasma GH was determined every 10 min, plasma LH and E2 every hour. Night-time GH release was always higher than daytime GH release. During daytime, all GH secretion parameters, except for the basal GH level, increased significantly from the prepubertal stage to stage B4 before (m-) the menarche (p = 0.05) and decreased thereafter (p = 0.05). During night-time, mean GH level and the fraction of GH in pulses also tended to increase from stage B1 to stage B4m-. The number of high pulses (greater than 8 micrograms/l) during day and night together tended to increase until stage B4m- and decreased after the menarche (p = 0.05). Height velocity did not correlate with the number of high pulses (Kendall tau = 0.14, p = 0.14). From stage B1 to B4m- high correlations were observed between E2 levels and GH secretion parameters, particularly during the day (tau = 0.59-0.71, p less than or equal to 0.01). The correlations between LH levels and GH secretion were high as well (tau = 0.50-0.81, p less than or equal to 0.01), but equal during day and night. It is concluded that during puberty 1. spontaneous GH release in girls increases 2-3 fold until the menarche and decreases thereafter, primarily as the result of an increasing and decreasing GH pulse amplitude; 2. diurnally increasing estradiol levels correlated with increasing GH secretion.

Mechanisms of Impaired Growth Hormone Secretion in Genetically Obese Zucker Rats: Roles of Growth Hormone-Releasing Factor and Somatostatin*

GH secretion is markedly blunted in obesity; however, the mechanism(s) mediating this response remains to be elucidated. In the present study we examined the involvement of the two hypothalamic GH-regulatory hormones, GH-releasing factor (GRF) and somatostatin (SRIF), using the genetically obese male Zucker rat. Spontaneous GH, insulin, and glucose secretory profiles obtained from free moving, chronically cannulated rats revealed a marked suppression in amplitude and duration of GH pulses in obese Zucker rats compared to their lean littermates (mean 6-h plasma GH level, 3.9 +/- 0.4 vs. 21.5 +/- 3.8 ng/ml; P less than 0.001). Obese rats also exhibited significant hyperinsulinemia in the presence of normoglycemia. The plasma GH response to an iv bolus of 1 microgram rat GRF-(1-29)NH2, administered during peak and trough periods of the GH rhythm, was significantly attenuated in obese rats at peak (137.4 +/- 26.1 vs. 266.9 +/- 40.7 ng/ml; P less than 0.02), although not at trough, times. Passive immunization of obese rats with a specific antiserum to SRIF failed to restore the amplitude of GH pulses to normal values; the mean 6-h plasma GH level of obese rats given SRIF antiserum was not significantly different from that of obese rats administered normal sheep serum. Both pituitary wet weight and pituitary GH content and concentration were reduced in the obese group. Measurement of hypothalamic GRF immunoreactivity revealed a significant (P less than 0.05) reduction in the mediobasal hypothalamic GRF content in obese rats (503.2 +/- 60.1 pg/fragment) compared to that in lean controls (678.1 +/- 50.2 pg/fragment), although no significant difference was observed in hypothalamic SRIF concentration. Peripheral SRIF immunoreactive levels were significantly (P less than 0.01) elevated in both the pancreas and stomach of obese rats. These results demonstrate that the genetically obese Zucker rat exhibits 1) marked impairment in both spontaneous and GRF-induced GH release, which cannot be reversed by SRIF immunoneutralization, 2) significant reduction in pituitary GH concentration, 3) depressed hypothalamic GRF content, and 4) elevated gastric and pancreatic, but not hypothalamic, SRIF levels. The findings suggest that the defect in pituitary GH secretion observed in the genetically obese Zucker rat is due, at least partially, to insufficient stimulation by hypothalamic GRF, and that SRIF does not play a significant role.

Growth Hormone-Releasing Hormone Messenger Ribonucleic Acid in the Hypothalamus of the Adult Male Rat Is Increased by Testosterone*

Since intact adult male rats have higher GH pulse amplitude than do castrated animals and since GH-releasing hormone (GHRH) secretion is predominantly responsible for the production of these GH pulses, we hypothesized that testosterone stimulates GHRH synthesis in neurons of the hypothalamus. To test this hypothesis, we compared GHRH mRNA content in individual neurons of the arcuate (ARC) and ventromedial (VMH) nuclei among groups of intact (n = 3), castrated (n = 5), and castrated testosterone-replaced (n = 5) adult male rats. Cellular GHRH mRNA content was measured by using semiquantitative in situ hybridization with an 35S-labeled cRNA probe complementary to the coding sequence of rat GHRH mRNA. Castration resulted in an approximately 35% decline in GHRH mRNA signal relative to that in intact animals in both the ARC (P less than 0.005) and VMH (P less than 0.005). Replacement with testosterone at the time of castration completely prevented the decline in both areas. Testosterone can exert effects either through activation of the androgen receptor directly or through aromatization to estradiol; therefore, we also examined the effects on GHRH mRNA of replacement with 17 beta-estradiol (n = 5) or dihydrotestosterone (DHT), a nonaromatizable androgen (n = 4). Estradiol had no effect on the castration-induced decline in GHRH mRNA in either the ARC or VMH. In contrast, DHT partially prevented the postcastration decline in GHRH in the ARC (P less than 0.005), while having no statistically significant effect on GHRH mRNA in the VMH. These results clearly indicate that testosterone stimulates expression of GHRH mRNA in neurons of the hypothalamus. Furthermore, the failure of estradiol to substitute for testosterone and the ability of DHT to substantially support GHRH mRNA suggest that testosterone exerts its effects on GHRH gene expression predominantly through direct activation of the androgen receptor.

Effects of Free Fatty Acids on Luteinizing Hormone and Growth Hormone Secretion in Ovariectomized Lambs*

The effects of FFA on circulating LH and GH concentrations in ovariectomized ewe lambs were investigated. Lambs (n = 14) were weaned at 2.5 months, ovariectomized at 6.5 months, and used at 8.5 months of age. From weaning until day 0 of the experiment, lambs were fed to maintain body weights (23 kg). On day 0, serum FFA concentrations and mean serum LH concentrations and number and amplitude of LH pulses, as assessed in blood samples collected every 12 min for 4 h, were 6.4 +/- 0.6 mg/100 ml, 0.57 +/- 0.08 ng/ml, 0.45 +/- 0.09 pulses/h, and 0.73 +/- 0.11 ng/ml, respectively. Double the maintenance feeding, beginning day 1, increased (P less than 0.01) body weights by 16% and LH pulse frequency by 82%, but had no effect (P greater than 0.1) on FFA concentrations, mean LH concentrations, or LH pulse amplitude by day 14. On day 14, lambs were infused with lipid (n = 9; 95.8 mg/min) or 0.9% saline solution (n = 5) for 8 h. Blood samples were collected at 12-min intervals for 12 h, beginning 4 h before infusions. FFA levels increased (P less than 0.01) in lipid-infused animals to 27.6 +/- 2.9 mg/100 ml by 4 h of infusion. Mean LH concentrations and LH pulse frequency and amplitude were unaffected (P greater than 0.1) by treatment. In contrast, mean GH concentrations and GH pulse frequency, which were similar (P greater than 0.1) between groups before infusion (14.0 +/- 0.8 ng/ml and 0.36 +/- 0.07 pulses/h, respectively) were decreased by FFA treatment by 51% (P less than 0.01) and 81% (P less than 0.006), respectively. GH pulse amplitude was highly variable and unaffected (P greater than 0.1) by treatment. In summary, elevated FFA levels appear to inhibit the release of GH, but not LH, in the ovariectomized ewe lamb.

The plasma pattern of growth hormone in conscious rats during late pregnancy

The plasma GH levels of female rats during late pregnancy were determined using an automatic method for repetitive blood sampling from conscious animals. The plasma GH patterns were analysed by a pulse analysis computer program (PULSAR). The mean plasma GH levels were about twofold higher in pregnant females on days 15, 18 and 22 of gestation than in age-matched non-pregnant females. The basal plasma GH levels were also increased, while there was no change in GH pulse amplitude or frequency. The augmentation of GH release was even more pronounced on day 20 of gestation, with a fourfold increase in mean plasma GH levels compared with those in non-pregnant females. This increase reflected an increase in both basal plasma GH levels and GH pulse amplitude, but there was no increase in pulse frequency. In female rats that delivered on day 22 of gestation, the basal and mean plasma GH levels increased during parturition. Pregnant females consistently responded to multiple i.v. infusions of 1 microgram human GH-releasing factor analogue (hGRF(1-29)-NH2) given at 45-min intervals on day 18 of gestation. Both basal and GRF analogue-stimulated plasma GH levels were undetectable after hypophysectomy of pregnant rats. The present study demonstrates an increase in basal plasma GH levels during late pregnancy and a marked increase in both basal plasma GH levels and GH pulse amplitude on day 20 of gestation. Furthermore, hypophysectomy of pregnant rats results in undetectable GH levels, indicating that the high levels of GH during pregnancy are derived from the pituitary.

Endogenous Growth Hormone (GH) Secretion in Male Rats Is Synchronized to Pulsatile GH Infusions Given at 3-Hour Intervals*

The feedback effects of GH on its own secretion were studied in conscious male rats receiving intermittent iv infusions of human GH. Male Sprague-Dawley rats (150-180 g) were implanted with double bore iv cannula. Infusions of human GH (hGH) or buffer were given for up to 32 h, while frequent microsamples (20 microliters) of blood were withdrawn simultaneously using an automatic blood-sampling system. The endogenous GH pulses became synchronized to pulsatile hGH infusions (2.1 U/kg.infusion) given at 3-h intervals. After two or more hGH infusions episodic GH release was present in most rats, and all endogenous pulses occurred concomitantly with the hGH infusions. After 24 h of hGH treatment the endogenous pulses were still synchronized to the every 3 h hGH infusions. In addition, the pulse amplitude was lower than that in vehicle-treated animals (74 +/- 12 vs. 215 +/- 35 ng/ml; P less than 0.01). At this time a complete (1.5-h) phase shift of the 3-hourly hGH infusions markedly suppressed endogenous GH pulses in all rats. In another experiment where the same daily dose of hGH was given in iv infusions every 1.5 h instead of every 3 h, the endogenous GH pulses were irregular, infrequent, and suppressed. Infusions at 3-h intervals of a lower dose of hGH (0.42 U/kg.infusion) did not affect the timing or amplitude of endogenous GH pulses compared to those in buffer-infused animals. The endogenous GH pulses were not synchronized between animals given 0.42 U/kg hGH or buffer at 3-h intervals. It is concluded that the endogenous GH pulses in male rats became synchronized to intermittent infusions of hGH at 3-h (but not 1.5-h) intervals. The fact that there were no endogenous pulses between the 3-hourly infusions suggests that the feedback effect of a GH pulse lasts for approximately 3 h. This mechanism may be involved in the control of the GH secretory pattern in male rats.

Increased Growth Hormone Pulse Frequency in Acromegaly*

To investigate whether GH secretion in acromegaly is subject to regulatory control by the hypothalamic GH-releasing hormone (GHRH) we studied GH secretion in 22 patients with acromegaly. Parameters of pulsatile GH secretion were assessed using frequent blood sampling (every 20 or 10 min for 24 h). Acute GH responses to GHRH-44 (0.1, 0.33, and 1.0 micrograms/kg BW, iv) were measured, and GH secretion during therapy with the long-acting somatostatin analog SMS 201-995 (Sandoz) was assessed. The results were compared to those in normal volunteers. Spontaneous GH pulse frequency was greater in patients with acromegaly than in 6 control subjects (8.6 +/- 0.6 vs. 4.3 +/- 1.1 pulses/24 h), as estimated by the 20-min sampling frequency. The 10-min sampling frequency revealed 12.9 +/- 0.7 pulses/24 h in acromegalics. Spontaneous GH pulse amplitude and acute GH rises in response to GHRH did not differ between control and acromegalic subjects. A similar degree of nocturnal augmentation of GH secretion was observed in both groups, and it persisted during SMS 201-995 therapy in patients with acromegaly. These observations suggest that GH secretion in acromegaly remains under stimulatory control by GHRH, which may be released at an abnormally high rate.

Specific, Time-Dependent Actions of Low-Dose Ethinyl Estradiol Administration on the Episodic Release of Growth Hormone, Follicle-Stimulating Hormone, and Luteinizing Hormone in Prepubertal Girls with Turner's Syndrome *

To investigate the actions of acute and chronic low doses of ethinyl estradiol (EE) on the pulsatile characteristics of GH and gonadotropin release we studied seven girls with Turner's syndrome [mean age, 7.5 +/- 0.75 (+/- SE) yr] on 3 separate study days. At baseline (study I), blood was drawn every 20 min from 2000-0800 h for GH, LH, and FSH determinations. One month after study I the patients were started on 100 ng/kg EE, orally, daily, and an identical study was repeated 1 week (study II) and 5 weeks (study III) from the initiation of low dose EE therapy. A pulse detection algorithm, Cluster, was used to objectively analyze pulsatility profiles. There were consistent and significant increases in all seven patients after 5 weeks of low dose EE therapy in mean GH concentrations (study I, 7.0 +/- 1.1 micrograms/L; study III, 13.4 +/- 1.7; P = 0.008), mean area under the GH pulse (study I, 602 +/- 52 micrograms/L.min; study III, 1350 +/- 261; P = 0.026), and mean GH pulse amplitude (study I, 14.0 +/- 2.2 micrograms/L; study III, 32.8 +/- 6.0; P = 0.018); with no detectable changes in GH pulse frequency (study I, 5.3 +/- 0.6 pulses/12 h; study III, 5.3 +/- 0.4). These findings were not accompanied by any significant changes in plasma somatomedin-C or serum estradiol concentrations or urinary cytological maturation indexes. Conversely, the amount of radioimmunoassayable FSH activity was suppressed after low dose EE therapy, with a decrease in mean FSH concentrations (study I, 23.5 +/- 6.6 IU/L; study III, 5.9 +/- 1.2; P = 0.035) and mean pulse amplitude (study I, 28.6 +/- 8.6 IU/L; study III, 8.2 +/- 1.8; P = 0.038), with no detectable changes in FSH pulse frequency (study I, 7.6 +/- 0.6 pulses/12 h; study III, 7.3 +/- 0.6). Similar qualitative changes in LH pulsatility were observed after low dose estradiol administration. In conclusion, our results demonstrate that low dose EE therapy results in a significant augmentation of pulsatile GH activity, with reciprocal decreases in gonadotropin concentrations in girls with Turner's syndrome. Such observations indicate an exquisite sensitivity of gonadotrope and somatotrope function to low dose estrogen action in this prepubertal hypogonadal model.

Alterations in the pulsatile mode of growth hormone release in men and women with insulin-dependent diabetes mellitus.

The mechanisms responsible for the elevated levels of circulating GH observed in diabetes mellitus (DM) remain incompletely defined. To assess the episodic fluctuations in serum GH as a reflection of hypothalamic-pituitary activity, we accumulated GH concentration-time series in a total of 48 adult men and women with and without insulin-dependent DM by obtaining serum samples at 10-min intervals over 24 h. Significant pulses of GH release were subsequently identified and characterized by an objective, statistically based pulse detection algorithm (Cluster) and fixed circadian (24-h) periodicities of secretory activity, resolved using Fourier expansion time-series analysis. Compared to those in age-matched controls, integrated 24-h concentrations of GH were 2- to 3.5-fold higher in diabetic men (P = 0.002) and women (P = 0.0005). Both men and women with DM had over 50% more GH pulses per 24 h than their non-DM counterparts. In addition, maximal GH pulse amplitude was markedly elevated in the men and women with DM (P = 0.0019 and 0.0189, respectively). That the increase in maximal pulse amplitude was accounted for by greater baseline levels was documented by a higher interpulse valley mean GH concentration in the diabetics compared to the controls (P = 0.0437 and 0.0056, men and women, respectively) and the absence of any difference in incremental pulse amplitude for either sex (P greater than 0.05). DM men had larger GH pulse areas (P = 0.039) than control men, apparently accounted for by greater pulse width (P = 0.0037). Pulse areas in DM and non-DM women were indistinguishable. Time-series analysis revealed that the 24-h (circadian) rhythms of serum GH concentrations exhibited significantly increased amplitudes in the diabetic group as a whole (compared to the controls, P = 0.011). However, the times of maximal GH concentrations (acrophases) were not significantly different. As a group, serum insulin-like growth factor-I was lower in DM vs. non-DM individuals (P = 0.0014), although when separated by sex this difference did not reach statistical significance in women (P = 0.317). The present data confirm the higher circulating levels of GH previously reported to occur in individuals with poorly controlled DM. The altered frequency of GH pulses together with enhanced interpulse GH concentrations and an amplified circadian GH rhythm are compatible with hypothalamic dysfunction associated with dysregulation of somatostatin and/or GHRH secretion.(ABSTRACT TRUNCATED AT 400 WORDS)