Beta-adrenergic stimulation of adenosine-3',5'-monophosphate (c-AMP) accumulation and of prolactin and growth hormone secretion in rat anterior pituitary cell cultures

The beta-adrenergic agonist 1-isoproterenol (ISO) (10(-9)-10(-7) M) provoked a prompt and profound increase of intracellular c-AMP accumulation in monolayer cultures of rat anterior pituitary. In superfused reaggregate cell cultures ISO also stimulated c-AMP outflow. The effect was blocked by propranolol and the highly selective beta 2-receptor blocker ICI 118.551. Epinephrine (E), norepinephrine (NE) and the highly selective beta 2-agonist zinterol (ZIN) also stimulated c-AMP accumulation. The order of potency ZIN greater than or equal to ISO greater than E much greater than NE together with the high potency of ICI 118.551 suggests the beta-effect is mainly through the beta 2-receptor subtype. The same concentrations of ISO strongly stimulated growth hormone (GH) release and, as previously shown, prolactin (PRL) release from superfused reaggregate cell cultures, but not luteinizing hormone or thyroid stimulating hormone release. Stimulation of PRL and GH release from these cultures was also induced by the adenylyl cyclase activator forskolin. Since interference of beta-adrenergic effects on contaminating fibroblasts or endothelial cells could be reasonably excluded, the present data suggest that beta-adrenergic stimulation of c-AMP accumulation in anterior pituitary cells elicits GH and PRL release.     

Ontogeny of the in vitro growth hormone stimulatory effect of thyrotropin-releasing hormone in the rat

The ontogenic changes in the somatotroph's responsiveness to TRH were examined in enzymatically dissociated rat pituitary cells in primary monolayer culture. Exposure to TRH (10(-8) M) caused a significant increase in GH release in cultured pituitary cells from rats ranging in age from -1 day (20 days of gestational age) to 90 days. The magnitude of the response, expressed as a percent increment above control rat GH (rGH) release, rose progressively until it reached a maximum of 209 +/- 5% (mean +/- SE) on postnatal day 12. Thereafter, the response declined to values ranging from 10-30% above control rGH release. In cultured adenohypophyseal cells of rats on postnatal day 12, the effect of TRH was dose related; the effective concentration range was 10(-10)-10(-7) M, with an EC50 of 2.5 +/- 0.6 X 10(-9) M. TRH (10(-8) M) potentiated the GH stimulatory effect of a submaximally effective concentration of human GH-releasing factor-40 (hGRF-40; 10(-9) M) in cultured pituitary cells of developing rats, aged -1 to 30 days, and that of (Bu)2cAMP (5 X 10(-4) M) in cultured pituitary cells of rats aged -1 to 45 days. The rGH response to the combined addition of TRH with either hGRF-40 or (Bu)2cAMP was up to 2 times greater (P less than 0.05) than the sum of the individual responses. When the interaction of TRH (10(-8) M) with multiple concentrations of hGRF-40 (10(-10), 10(-9), and 10(-8) M) was tested in cultured pituitary cells of 4- to 36-day-old rats at 4-day intervals, synergism was least at the lowest and greatest at the highest concentration of hGRF-40; synergistic interaction decreased progressively after 20 days of age to undetectable levels by 36 days. In cultured anterior pituitary cells of 12-day-old rats, maximally stimulatory TRH (10(-7) M) potentiated the GH stimulatory effects of both hGRF-40 and (Bu)2cAMP at concentrations at the EC50 value or greater, with synergism being most pronounced at maximally effective concentrations. Whereas the GH response to the combined addition of maximal hGRF-40 (10(-7) M) and (Bu)2cAMP (1.5 X 10(-3) M) was not greater than that to maximal hGRF alone, TRH potentiated the responses to both secretagogues whether added separately or combined.(ABSTRACT TRUNCATED AT 400 WORDS)     

Growth hormone (GH) secretion in the pituitary-grafted male rat: in vivo effects of GH-releasing hormone and isoproterenol and in vitro release by individual somatotropes

Although the pituitary-grafted rat is a classic model of chronic PRL excess, the presence of somatotropes in grafted pituitary tissue indicates a potential for GH secretion. The current study was designed to investigate GH-releasing hormone (GRH)-induced GH secretion and beta-adrenergic inhibition of GH release in animals bearing ectopic pituitary tissue free from hypothalamic control. Positive findings with regard to these in vivo experiments led us to an initial determination of GH secretion by individual somatotropes from transplanted pituitary tissue. In litters of 10 30-day-old Fisher rats, 2 male animals received subcapsular renal grafts of 3 littermate pituitary glands each. Thirty-five days after grafting, 1 group received saline (SAL) followed by GRH, and the other received the beta-adrenergic agonist isoproterenol (ISO) followed by GRH. Blood samples were taken before and after SAL or ISO treatment, GRH was then infused, and sampling was continued. Plasma was assayed for GH and PRL, and the reverse hemolytic plaque assay was used to determine GH release by individual somatotropes from transplanted pituitary tissue. Plasma PRL was clearly elevated in pituitary-grafted compared to muscle-grafted animals, but there was no difference in either body weight gain or basal GH levels between the groups. As shown previously, ISO itself induced a brief release of GH due to its direct effect on the pituitary gland. The GH response to GRH was greater in pituitary-grafted animals than in muscle-grafted controls after both SAL and ISO. GRH-induced GH release was suppressed by ISO pretreatment in muscle-grafted animals, but not in pituitary-grafted animals. The reverse hemolytic plaque assay unequivocally showed that transplanted pituitary tissue was capable of tonic as well as GRH-stimulated GH release. These results demonstrate that despite similar basal GH levels, animals bearing pituitary grafts release significantly greater amounts of GH in response to GRH. The evidence for GH secretion by individual somatotropes from transplanted pituitary tissue directly shows the grafted tissue to be a source of GRH-stimulated GH. The lack of beta-adrenergic inhibition of GRH-induced GH release in pituitary-grafted animals is consistent with the hypothesis that beta-adrenergic inhibition of GRH-induced GH secretion is mediated by an effect on the hypothalamus.     

Combined effects of human growth hormone (GH)-releasing factor-44 (GRF) and somatostatin (SRIF) on post-SRIF rebound release of GH and prolactin: a model for GRF-SRIF modulation of secretion

Somatostatin (SRIF) and GRFs play key roles in regulating GH secretion. We previously presented a model of SRIF-cAMP interaction; SRIF blocks rat (r) GH release without preventing its accumulation in a potentially releasable pool. This phenomenon may represent a mechanism whereby tonic SRIF inhibition and its subsequent reduction or withdrawal can modulate the magnitude if not the initiation of rGH pulses. Herein we test that model using human GRF-44 (hGRF-44). Tritium-prelabeled rat anterior pituitary fragments were perifused until stored [3H]rGH and [3H]rPRL release rates were stable. SRIF (10 or 25 nM), with and without hGRF-44 (3 or 10 nM), was added in short (1-h hGRF-44) and long (3-h hGRF-44) protocols; SRIF was then withdrawn while hGRF-44 was continued. Release of stored prelabeled [3H]rGH and [3H]rPRL was assessed by immunoprecipitation. Effects on PRL release were followed for comparison. SRIF-induced inhibition of release was only partially reversed by hGRF-44. At these concentrations and so long as SRIF was present, hGRF-44 could not stimulate the rate of hormone release to values above pre-SRIF basal rates. On the other hand, the amplitude of post-SRIF rebound release was increased by prolonging exposure to SRIF alone, by including hGRF-44 with SRIF, by increasing the amount of hGRF-44 included with SRIF, by prolonging exposure to hGRF-44 plus SRIF, and by using a smaller concentration of SRIF during exposure to hGRF-44. Interaction of hGRF-44-SRIF effects generated peak rates of hormone release after SRIF withdrawal which exceeded the maximum rates achieved using hGRF-44 alone in this system. Lactotroph responses were much smaller, but qualitatively resembled somatotroph responses. We conclude that the interplay of simultaneous hGRF-44 and SRIF effects can regulate the amplitude of rGH pulses. Although GRF can initiate physiological GH release, and GRF antisera can block GH pulses, we suggest that the surge of release that follows reduction of SRIF-induced inhibitory tone in vitro represents a potential mechanism that could contribute to the initiation of some pulses of release. Finally, we also present a theoretical model of secretagogue interactions at the cellular level to explain our results. The model is compatible with either a homogeneous cell population in which each secretory cell has multiple capabilities or a heterogeneous cell population composed of cell subgroups with complementary secretory abilities.     

Growth hormone responsiveness in vivo and in vitro to growth hormone releasing factor in the spontaneously diabetic BB Wistar rat

In order to determine whether there is an abnormality in the pituitary responsiveness to GRF in the diabetic rat, we examined the in vivo and in vitro effects of hGRF-44 NH2 (hGRF) on growth hormone (GH) release in the spontaneously diabetic BB Wistar rat. Under pentobarbital anesthesia, hGRF was injected intravenously at a dose of 500 ng/kg in male diabetic BB Wistar rats (n = 11) and in male control Wistar rats matched for weight (n = 11). Basal serum GH concentrations were significantly lower in the diabetic group, (123 +/- 5 ng/ml, mean +/- SEM) than in the control group (362 +/- 15 ng/ml). However, the GH response to hGRF was significantly greater in the diabetic group (GH increment 873 +/- 153 ng/ml) than in the control group (268 +/- 91 ng/ml). The effect of hGRF was further tested in a perifusion system of freshly dispersed anterior pituitary cells of diabetic BB Wistar rats and control Wistar rats. Basal secretion rate of GH from cells of diabetic rats (0.85 +/- 0.06 microgram/2 pituitaries X 2 min) was lower than that from cells of control rats (1.60 +/- 0.18 micrograms/2 pituitaries X 2 min). The GH response to 2-min pulses of hGRF at concentrations of 1.56, 6.25, and 25 pM with and without somatostatin 10(-9) M was significantly greater in the diabetic group than in the control group. In conclusion, there is in the spontaneously diabetic rat an increased in vivo and in vitro GH responsiveness to exogenous hGRF suggesting an abnormality of GH regulation at the pituitary level.     

Plasma growth hormone (GH) response to intravenous GH-releasing factor (GRF) in adult rats: evidence for transient pituitary desensitization after GRF stimulation

The ability of human (h)GRF-(1-29)NH2 to stimulate GH secretion was studied in cannulated adult rats. In order to suppress endogenous GRF secretion and the inhibitory action of hypothalamic somatostatin (SRIF), rats were anesthetized with sodium pentobarbital. Intravenous administration of hGRF-(1-29)NH2 elicited a dose-dependent response of plasma GH, with 250 ng/kg being the smallest effective dose in male rats. In female rats, for each dose tested (250 to 70,000 ng/kg), the GH response represented only about 60% that of male rats. Repeated iv stimulations with hGRF-(1-29)NH2 at short time intervals (45 min) produced transient desensitization of pituitary responsiveness to GRF: a blunted GH response to the second and third stimulations was observed both in male and in female rats and for each dose tested. Similar blunted responses were also obtained with repeated injections of native hGRF-(1-44)NH2. The possibility that these blunted responses could be due to incomplete suppression of hypothalamic SRIF secretion by sodium pentobarbital was excluded by the use of rats that were passively immunized against SRIF; in these rats, it was shown that at least 65% of the inhibition of the GH response after the second GRF stimulation was unrelated to SRIF action. Similar transient desensitization to repeated hGRF-(1-29)NH2 stimulations was also observed in conscious rats that were passively immunized against SRIF. This occurrence of blunted responses was shown to be related to the length of the time interval between GRF stimulations, with longer intervals resulting in less or no desensitization. It appears thus that modulation of pituitary responsiveness to the action of GRF is mediated by at least two independent mechanisms in the rat: in addition to the inhibitory action imposed by hypothalamic SRIF, which induces periods of refractoriness to the action of GRF, it was shown in this study that in the pituitary level each GRF stimulation also induces a transient desensitization of somatotrophs for about 1 h. This period of refractoriness might not be due to excessive stimulation with GRF, since it was also observed with the lowest dose of hGRF-(1-29)NH2 that gave a significant release of GH. Finally, a sex difference was confirmed for the response of anesthetized adult rats to stimulation with hGRF-(1-29)NH2, reflecting a sex steroid-induced modification of pituitary responsiveness to GRF stimulation.     

The effect of age on somatostatin suppression of basal, growth hormone (GH)-releasing factor-stimulated, and dibutyryl adenosine 3',5'-monophosphate-stimulated GH release from rat pituitary cells in monolayer culture

To test the hypothesis that relative resistance of the somatotroph to somatostatin (SRIF) contributes to elevated circulating levels of GH in the newborn rat, we examined the effects of SRIF (0.1, 0.33, and 1 nM) on basal, human pancreatic GH-releasing factor-40 (hpGRF-40; 1 nM)-stimulated, and (Bu)2cAMP (0.5 mM)-stimulated GH release from pituitary cells of 2-day-old, 15-day-old, and adult Sprague-Dawley rats in monolayer culture. The effect of SRIF on basal GH release varied markedly with age. SRIF, in the doses studied, did not inhibit basal GH release (nanograms of GH per 10(5) cells/3 h) from pituitary cultures of 2-day-old rats. In those of 15-day-old rats, only the two higher doses of SRIF (0.33 and 1 nM) suppressed GH release. By contrast, in pituitary cell cultures of adult male and female rats, all doses of SRIF significantly inhibited basal GH release (P less than 0.001). Similarly, the degree of SRIF suppression of both hpGRF-40- and (Bu)2cAMP-stimulated GH release differed among the age groups. In pituitary cultures of 2-day-old rats, SRIF did not significantly inhibit stimulated GH release. In 15-day-old rat pituitary cells, SRIF inhibited GH release, but did not eradicate the stimulatory effect of hpGRF-40 or (Bu)2cAMP. By contrast, in pituitary cell cultures of adult male and female rats, SRIF completely abolished the stimulatory effect of both hpGRF-40 and (Bu)2cAMP. When expressed as a percentage of the control (or stimulated) value, GH release at each SRIF dose varied markedly with age (P less than 0.001). Furthermore, a similar age-associated trend was evident when, in a separate series of experiments (n = 37), we examined the suppressive effect of a single concentration of SRIF (0.33 nM) on (Bu)2cAMP (0.5 mM)-stimulated GH release in cultured pituitary cells of rats ranging in age from -1 (day 20 of gestation) to 78 days. The degree of suppression increased progressively with advancing age; GH release decreased from 82 +/- 2% (+/- SE) of stimulated values in cultured cells of perinatal rats to 20 +/- 1% of stimulated values in cultured cells of 78-day-old rats. There was a significant negative correlation between age and SRIF-inhibited GH release (r = -0.89; P less than 0.001).(ABSTRACT TRUNCATED AT 400 WORDS)     

Bombesin stimulates prolactin and growth hormone release by pituitary cells in culture

Bombesin (BBS) has been previously shown to stimulate the secretion of PRL and GH in steroid-primed rats. To determine whether these effects were mediated by the central nervous system or were due to direct action on the pituitary gland, we studied the interaction of BBS with GH4C1 cells, a clonal strain of rat pituitary cells which synthesizes and secretes PRL and GH. The addition of 100 nM BBS to GH4C1 cells for 60 min increased PRL release to 140 +/- 3% of the control value (mean +/- SE) and GH release to 133 +/- 5% of the control value. Stimulation of hormone secretion was observed within 15 min of treatment with 100 nM BBS and continued for at least 2 h. Half-maximal stimulation of PRL release occurred with 0.5 nM BBS, and a maximal effect was observed with 10 nM peptide. The BBS analogs ranatensin, litorin, and [Tyr4]BBS, each at a concentration of 100 nM, caused the same stimulation of PRL release as maximal concentrations of BBS itself. BBS stimulated hormone release selectively in two of five different clonal pituitary cell strains examined. Pretreatment of GH4C1 cells with 1 nM estradiol and/or 100 nM insulin resulted in more powerful stimulation of PRL release by both TRH and BBS. When epidermal growth factor and vasoactive intestinal peptide were added simultaneously with BBS, PRL release was greater than in the presence of either peptide alone. In contrast, the stimulatory effects of TRH and BBS were not additive. Somatostatin inhibited both basal and stimulated PRL release. Thus, low concentrations of BBS can directly stimulate PRL and GH release by a clonal pituitary cell strain in culture. These results suggest that BBS may stimulate PRL and GH secretion in vivo by direct action on the pituitary gland.     

Neuropeptide Y stimulates growth hormone and gonadotropin release from the goldfish pituitary in vitro

The effects of neuropeptide Y (NPY) on release of growth hormone (GH) and gonadotropin (GTH) from the goldfish pituitary in vitro were investigated. Exposure of perifused pituitary fragments, taken from female goldfish at late stages of gonadal recrudescence, to 5-min pulses of human NPY resulted in a rapid dose-dependent stimulation of GH and GTH release, with half-maximal effective dosages of 0.51 +/- 0.24 and 2.37 +/- 1.05 nM for GH and GTH, respectively. Repeated treatments with pulses of NPY (10 nM for GH, 5 nM for GTH) at 55-min intervals did not significantly alter the responsiveness of pituitary fragments to NPY; however, prior exposure of pituitary fragments to pulses of higher doses of NPY (50 nM GH, 10 nM for GTH) significantly reduced the subsequent hormone responses. When given at 85-min intervals repeated treatment with NPY did not blunt hormone responses to the second and third stimulations at these higher dosages. These results indicate that NPY acts at the pituitary level to stimulate GH and GTH secretion in female goldfish. The GTH response and, to a lesser extent, the GH response become desensitized to further stimulation by NPY in dose- and time-dependent manners. NPY should be considered as one element in the multifactorial systems regulating the GH and GTH secretion in goldfish.     

Beta-adrenergic stimulation of growth hormone (GH) release in vivo, and subsequent inhibition of GH-releasing factor-induced GH secretion

In vivo and in vitro studies of beta-adrenergic influences on GH secretion have produced apparently conflicting data in which the in vivo effect seems to be inhibitory and the in vitro effect to be stimulatory. The present studies were designed to observe the in vivo effect of isoproterenol (ISO), a beta-adrenergic agonist, on 1) GH release during a brief interval after intraatrial infusion, and 2) GH release in response to GRF infused 10 min after ISO. ISO was found to stimulate GH release in both intact and hypothalamus-lesioned animals within 2 min after infusion, but GH returned to control levels within 10 min. ISO also profoundly inhibited the release of GH in response to GRF. Pretreatment of animals with somatostatin (SRIF) antiserum prevented the inhibitory action of ISO on GRF-induced GH release. No change in peripheral levels of SRIF was detected. Also, there was no suppression of GRF-induced GH release by ISO when the treatments were applied in vitro to dispersed perifused pituitary cells. These data show that beta-adrenergic systems can stimulate a rapid but brief release of GH in vivo, and that the subsequent inhibitory action on GRF-induced GH release might be by means of SRIF release.     

Growth hormone (GH)-releasing factor stimulates hypothalamic somatostatin release: an inhibitory feedback effect on GH secretion

GH-releasing factor (GRF) is a hypothalamic peptide that stimulates the secretion of pituitary GH. The possibility of feedback effects of GRF within the central nervous system was studied in conscious freely moving male rats with indwelling iv and intracerebroventricular (icv) cannulae. Animals were injected icv or iv with 10 ng-10 micrograms human (h) GRF(1-40)-OH (hGRF-40) or GRF(1-44)-NH2 (hGRF-44), and blood samples were obtained every 10-20 min from 1000-1400 h. GH secretion was pulsatile, with major secretory peaks at around 1200 h in most control animals. When 10 ng hGRF-40 were injected icv at 1100 h, immediately before the expected onset of the spontaneous GH secretory burst, GH secretion was suppressed during the following 2-h period. An iv injection of 10 ng hGRF-40 was without effect. In contrast, when 1 microgram hGRF-40 was injected icv or iv, plasma GH levels peaked at 20 and 10 min, respectively, and returned toward baseline shortly thereafter. The spontaneous GH secretory pulse after 1 microgram hGRF-40 (icv or iv) was suppressed in proportion to the magnitude of the GH secretory response to GRF (r = 0.78, p less than 0.01), and the prolongation of the interval between the injection of GRF and the subsequent spontaneous GH surge was directly related to the GH response to GRF (r = 0.85, p less than 0.001). The icv or iv injection of a larger dose of either hGRF-40 or hGRF-44 (10 micrograms) at 1100 h also resulted in marked and comparable increases in plasma GH levels, with peaks at 20 min (icv) and 10 min (iv) after injection. No changes in behavior or plasma glucose were observed up to 3 h after icv injection of any of the doses of hGRF-40 or of hGRF-44. The suppressive effect of centrally administered hGRF-40 (10 ng) on GH secretion was blocked by the iv administration of a specific antisomatostatin serum immediately before the injection of hGRF. These results demonstrate a dual action of GRF on spontaneous GH secretion and indicate the presence of an inhibitory feedback system within the central nervous system for the regulation of GH secretion which is mediated by hypothalamic somatostatin.     

Growth hormone (GH) response to GH-releasing hormone by perifused pituitary cells from male, female, and testicular feminized rats

To determine whether a normal complement of androgen receptors is required to permit full expression of sex-related differences in pituitary GH secretion, we compared the GHRH-stimulated GH secretory responses of continuously perifused anterior pituitary cells from normal male, normal female, and androgen-resistant testicular feminized (Tfm) rats. In each experimental replicate, acutely dispersed pituitary cells were exposed to GHRH (0.03-100 nM) administered as 2.5-min pulses in random order at 30-min intervals. The eluate was collected in 5-min fractions for GH determination by RIA. Basal unstimulated secretion of GH by cells from male rats was greater than that by cells from female (P = 0.007) and Tfm (P = 0.03) rats; basal secretion by the other two groups was similar (P = 0.55). Linear concentration-response relationships between GHRH and GH release were defined for cells from male (P = 0.0002), female (P = 0.0001), and Tfm (P = 0.0002) rats. Overall GHRH-stimulated GH secretion by cells from male rats was greater (P less than 0.0001) than that by cells from female rats. Overall secretion by cells from Tfm rats was less (P less than 0.001) than that by cells from male rats but greater (P less than 0.001) than that by cells from female rats. For all experimental groups, body weight was strongly correlated with both basal (r2 = 0.42; P = 0.001) and GHRH-stimulated (r2 = 0.53; P = 0.0001) GH secretion by the dispersed pituitary cells. These data suggest that a deficiency of androgen receptors results in a diminution of the in vitro GH secretory capability of anterior pituitary cells to a level below that by cells from normal males, but not to the level in normal females. The intermediate position of cells from the Tfm rat may represent a partial masculinization or defeminization within this generally female phenotype.     

Stimulation of somatostatin release in vitro by synthetic human growth hormone-releasing factor by a nondopaminergic mechanism

The effect of synthetic human GH-releasing factor (hGRF-40) on somatostatin (SRIF) release from the median eminence of the hypothalamus was evaluated in rats with use of an in vitro incubation system. hGRF-40 stimulated SRIF release in a dose-related manner. This effect was significant at concentrations varying from 10(-11)-10(-7) M, with a minimal effective dose of 10(-11) M. Maximal stimulation was observed at 10(-10) M. Pimozide was added in vitro at a concentration of 10(-6) M to block dopamine (DA) receptors, since DA is a known stimulator of SRIF release. Pimozide was without effect on SRIF release and did not alter the stimulatory effect of hGRF-40. To evaluate the possibility that DA and GRF may share a common pathway to stimulate SRIF release, median eminence fragments were simultaneously exposed to submaximal concentrations of both DA (6 X 10(-7) M) and hGRF-40 (10(-12) M). By themselves, each of these doses had little effect on SRIF release. When they were added together, a marked stimulation was noted, which was not, however, significantly greater than the sum of the responses to each agent alone. These results suggest that DA and GRF act by separate mechanisms to stimulate SRIF release. GRF may be physiologically involved in the regulation of SRIF release. Stimulation of SRIF release may be a mechanism by which GRF exerts a negative ultrashort-loop feedback to inhibit GH release.     

Human pancreatic growth hormone-releasing factor-40 (hpGRF-40) allows stimulation of GH release by TRH

The effects of synthetic hpGRF-40 on GH release from continuously perifused male rat anterior pituitary cells were studied. Pulses (2.5 min) of hpGRF-40 stimulated GH release in a log-linear dose response relationship: concentrations of 0.03, 0.1, 0.3, 1, 3, 10, 30 and 100 nM given in a random order elicited a GH response above baseline of 1.2 +/- 0.3, 2.4 +/- 0.4, 2.8 +/- 0.2, 4.3 +/- 0.2, 6.2 +/- 0.7, 7.0 +/- 1.0, 8.7 +/- 1.7, and 10.8 +/- 0.8 micrograms/10(7) cells (mean +/- SEM; n = 3; r = 0.93), respectively. During a 5-h hpGRF-40 infusion, GH stimulation peaked within 5 min and waned to near baseline by the end of the fifth h. The integrated GH responses to 0.03, 0.1 and 0.3 nM hpGRF-40 were 37.6 +/- 7.4, 52.9 +/- 8.5, and 66.15 +/- 8.2 micrograms/10(7) (mean +/- SEM; n = 3; r = 0.72), respectively. The interaction of TRH and hpGRF-40 in the control of GH secretion was studied to investigate the mechanism of the "paradoxical" TRH stimulation of GH release associated with GH excess states in humans. Dispersed cells were perifused with either 100 nM TRH for 0.5 h, 5 nM hpGRF-40 for 4 h, or 5 nM hpGRF-40 for 4 h, to which a 0.5 h pulse of TRH was added at 2 h. GH levels did not change significantly in the presence of TRH alone. When TRH was added to the ongoing hpGRF-40 perifusion, GH release increased from 1.4 +/- 0.06 to 4.0 +/- 1.0 micrograms/min.10(7) cells (n = 4; P = 0.03). Thus, dispersed pituitary cells are highly sensitive to very low concentrations of hpGRF-40 administered as both an acute pulse and as a tonic infusion. When the cells are exposed to a maximal concentration of hpGRF-40 (i.e. 5 nM), TRH becomes a secretagogue at the pituitary level, thus suggesting the site and mechanism of the "paradoxical" GH response to TRH observed in some acromegalics.     

Differential responsiveness of the somatotroph to growth hormone-releasing factor during early neonatal development in the rat

The effects of human pancreatic GH-releasing factor-40 (hpGRF-40; 0.01-100 nM) and (Bu)2cAMP (0.015-1.5 mM) on GH release from primary monolayer cultures of pituitary cells were evaluated in rats of three age groups: postnatal days 2 and 12, and young adult males (3-4 months). Both hpGRF-40 and (Bu)2cAMP elicited a dose-related increase in GH release in cell cultures from each age group. However, the magnitude of the fractional increase over basal release was markedly age dependent. hpGRF-40-stimulated GH release (expressed as a percentage of control values) was greater in cultured cells of 2-day-old than of 12-day-old rats, which was, in turn, significantly greater than in cells of adult rats (P less than 0.001). Maximum hpGRF-40-stimulated GH release was 1058 +/- 50% of control values (+/- SE) in 2-day-old, 617 +/- 21% of control values in 12-day-old, and 405 +/- 6% of control values in adult pituitary cell cultures. The slopes of the dose-response curves differed significantly among the three age groups (P less than 0.001) and varied inversely with increasing age. GH release induced by (Bu)2cAMP was similarly age dependent; maximal stimulated release was 1073 +/- 20%, 414 +/- 4%, and 259 +/- 7% of control values in cultured cells of 2-day-old, 12-day-old, and adult rats, respectively (P less than 0.001 for age effect at each dose). As with hpGRF-40, the slopes of the dose-response curves for (Bu)2cAMP decreased with advancing age (P less than 0.001). Intracellular GH storage during culture, basal release of GH, and serum GH were also age dependent. Pooled serum GH was consistently elevated in 2-day-old rats (139 +/- 2 ng ml-1), became lower and more variable in 12-day-old rats (62 +/- 14 ng ml-1), and was even more variable in adult male rats (79 +/- 23 ng ml-1), owing to random sampling during spontaneous secretory pulses. These results indicate that the stimulatory effects of GRF and (Bu)2cAMP on GH secretion from cultured rat pituitaries vary with age; pituitary cells of newborn rats are relatively more sensitive to these secretagogues than those of adult rats. This increased responsiveness of the neonatal somatotroph to GRF may contribute to the elevation of the plasma GH concentration which is characteristic of the perinatal period in the rat.     

The interrelationship between the effects of somatostatin and human pancreatic growth hormone-releasing factor on growth hormone release by cultured pituitary tumor cells from patients with acromegaly

The effects of somatostatin (SRIF) and human pancreatic tumor GRF on GH release by cultured pituitary tumor cells obtained during transsphenoidal operation from 15 acromegalic patients were investigated. In a study of the sensitivity of pathological GH release to SRIF, 1-10 nM SRIF induced maximal inhibition of hormone release in 3 consecutive tumors. In 12 of 15 tumor cell cultures, 10 nM SRIF produced statistically significant inhibition of basal GH release by 39 +/- 3% (mean +/- SEM). In 2 of the 3 other tumors, SRIF inhibited GRF-stimulated GH release, while this was not investigated in the third tumor. A dose-response study of the effect of GRF on GH release by cultured pituitary tumor cells showed that doses of 0.1, 1, 10, and 100 nM induced similar maximal (35%) stimulation of hormone secretion. In four of five consecutive tumor cell suspensions, 1 and 10 nM GRF induced statistically significant GH stimulation by 18-300%. Preincubation of the tumor cells with 5 nM dexamethasone greatly increased the sensitivity and the maximal stimulation in response to GRF and made one tumor cell suspension, which did not react to GRF initially, sensitive to GRF. In the tumors of four patients, the interrelationship between the effects of SRIF and GRF on GH release were also studied. SRIF (10 nM) inhibited the stimulatory effects of GRF on GH release virtually completely. In conclusion, GH release by in vitro cell cultures of GH-secreting pituitary adenomas was inhibited by SRIF and stimulated by GRF. The interaction of GRF and SRIF on GH release by these pituitary tumor cells was similar to that in normal rat GH cells, as SRIF virtually completely overcame the GRF-induced GH release.     

Plasma growth hormone (GH) and somatomedin C response to continuous growth hormone-releasing factor (GRF) infusion in patients with GH deficiency

Pituitary growth hormone (GH) responses during a 10-h iv infusion of saline or human GH-releasing factor (hGRF-44) at 500 ng/kg/h, followed by an iv bolus injection of hGRF-44 at 2 micrograms/kg body weight, were studied in 10 patients with GH deficiency. During saline infusion in 4 patients, small plasma GH increase were observed in 2 patients. However, during hGRF infusion in 6 patients, up to 4 or 13 pulses of GH secretion were observed. The mean integrated GH pulse area during hGRF infusion was 22.5 +/- 5.2 (SE) ng/ml X h, which was greater than that obtained during saline infusion. Plasma somatomedin C levels did not increase after hGRF infusion. After saline or hGRF infusion all patients responded to an iv bolus injection of the peptide. These results indicate that hGRF infusion augments GH secretion by increasing the number and amplitude of GH pulses and that the infusion does not cause pituitary somatotrophs to lose their capacity to respond to hGRF subsequently.     

Parallel stimulation of ACTH, beta-LPH + beta-endorphin and alpha-MSH release by alpha-adrenergic agents in rat anterior pituitary cells in culture

Characteristics of the alpha-adrenergic stimulation of ACTH, beta-endorphin + beta-LPH and alpha-MSH release were studied in rat anterior pituitary cells in primary culture. Parallel changes of ACTH, beta-endorphin + beta-LPH and alpha-MSh release were found under all stimulatory and inhibitory conditions by natural and synthetic catecholamine agonists and antagonists. (-)Epinephrine and (-)norepinephrine lead to a 8--10-fold stimulation of peptide release at ED50 values of 20 and 90 nM, respectively. The stereoselectivity of the alpha-adrenergic stimulatory action on peptide release is indicated by a 100-fold higher activity of (-)- than (+)norepinephrine while (-)epinephrine is 10 times more potent than the corresponding (+) stereoisomer. The involvement of a typical alpha-adrenergic mechanism in the control of release of ACTH, beta-endorphin and related peptides in rat anterior pituitary gland is indicated by the following order of potency of a series of catecholaminergic agents (ED50 values): (-)epinephrine (20 nM) greater than (-)norepinephrine (90 nm) greater than phenylephrine (400 nM) greater than isoproterenol (6000 nM). The stimulatory effect of (-)epinephrine or phenylephrine is completely reversed by low concentrations of the alpha-adrenergic antagonist phentolamine while the beta-adrenergic antagonist propranolol has no effect up to 10 muM. Beside providing an easily accessible pure population of post-synaptic alpha-adrenergic receptors having potential applications as a model for other less accessible alpha-adrenergic brain systems, the present data suggest the possibility of the direct involvement of a catecholamine in the physiological control of ACTH secretion in the rat anterior pituitary gland.     

Beta-adrenergic binding and secretory responses of the anterior pituitary

Our studies demonstrated that beta-adrenergic agonists stimulate the release of GH from rat anterior pituitary (AP) cells in vitro. Concentration-response experiments with beta-adrenergic agonists demonstrated that beta 2-adrenergic receptors mediated this phasic GH release, while having no apparent effect on PRL or LH release. The ACTH response to beta-adrenergic agonists was equivocal. Half-maximal stimulation of GH release occurred at 14 +/- 2 (+/-SE) nM isoproterenol, 160 +/- 30 nM epinephrine, and over 1 microM l-norepinephrine (n = 4). Direct binding studies in membrane particulates of rat AP confirmed receptors of the beta 2-subtype. Iodocyanopindolol binding to beta-adrenergic receptors of rat AP yielded a dissociation constant of 4.6 +/- 0.1 pM and a maximal capacity of 1.9 +/- 0.4 fmol/mg protein (n = 3). In contrast, porcine AP contained beta 1-adrenergic receptors. These results support the hypothesis that the endogenous beta 2-adrenergic agonist l-epinephrine may be a GH-releasing factor of physiological significance in the rat.     

Cysteamine effects on monoamines, dopamine-beta-hydroxylase and the hypothalamic-pituitary axis

Cysteamine (beta-mercaptoethylamine, MEA) is a naturally occurring sulfhydryl compound that depletes pituitary PRL, causes a reduction in brain and gut somatostatin (SRIF), and suppresses norepinephrine (NE) and epinephrine (EPI) synthesis by inhibition of dopamine-beta-hydroxylase (DBH). SRIF inhibits GH and TSH secretion, whereas, NE and EPI facilitate their release. The objectives of this investigation were to: (1) determine the dose-response and time course of DBH inhibition by MEA in vivo and in vitro, and correlate these findings with MEA tissue levels and (2) assess the function of SRIF and NE/EPI in regulation of episodic GH and TSH secretion using MEA. Animals were administered MEA (75-300 mg/kg, s.c.) and hypothalamic levels of dopamine (DA), NE, EPI, serotonin (5-HT) and MEA were measured by high-performance liquid chromatography (HPLC) and electrochemical detection. DBH activity was measured in vitro after exposure to MEA +/- N-ethylmaleimide (NEMI). Chronically cannulated rats were administered MEA (100 or 300 mg/Kg) and serial blood samples were removed in undisturbed animals, and after 30 min swimming stress. Cannulated rats with bilateral lesions of the ventromedial/arcuate nuclei (VMN/ARC) were administered MEA (150 mg/kg). MEA caused a dose-related decrease in NE/EPI nd in increase in DA at doses greater than or equal to 150 mg/kg. Tissue MEA was highest at 4 h (679 +/- 64 pM/mg tissue), but still measureable after 24 h. MEA inhibited DBH in vitro (95% inhibition at 10(-3) M); NEMI blocked inhibition. Stress-induced GH supression and corticosterone release were partially blocked by a low dose of MEA (100 mg/kg).(ABSTRACT TRUNCATED AT 250 WORDS)