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.     

Human pancreatic tumor growth hormone (GH) - releasing factor and cyclic adenosine 3',5'- monophosphate evoke GH release from anterior pituitary cells: the effects of pertussis toxin, cholera toxin, forskolin, and cycloheximide

Both synthetic human pancreatic tumor GH-releasing factor (hpGRF) and prostaglandin E2 (PGE2) rapidly stimulate cellular cAMP accumulation in and GH release from primary cultures of rat anterior pituitary cells. SRIF inhibits both of these actins. A 1-h treatment with the protein synthesis inhibitor cycloheximide potentiates hpGRF-induced cAMP accumulation for hours and GH release for the first hour. This indicates that a rapidly turning over protein tonically mutes the degree of hpGRF-stimulated cAMP accumulation. Pretreatment of the cells with pertussis toxin amplifies hpGRF- and PGE2-stimulated cAMP levels and GH release; pertussis toxin also attenuates the ability of SRIF to affect these variables. This suggests that an inhibitory coupling protein contributes to these events. Finally, cholera toxin and forskolin are also potent stimulators of cAMP accumulation and GH release. We conclude that hpGRF-evoked GH release and the inhibitory action of SRIF are closely correlated with the cAMP-generating system.     

Somatostatin inhibits basal and vasoactive intestinal peptide-stimulated hormone release by different mechanisms in GH pituitary cells

Somatostatin (SRIF) inhibits both basal and vasoactive intestinal peptide (VIP)-stimulated hormone secretion by the GH4C1 clonal strain of rat pituitary tumor cells. We have previously shown that SRIF inhibits cAMP accumulation stimulated by VIP but does not alter basal cAMP levels in this cell line. To determine the importance of changes in cAMP accumulation in the mechanism of SRIF action, we have compared the effect of SRIF on hormone release stimulated by VIP and two other secretagogues which increase effective intracellular cAMP concentrations: forskolin and 8-Bromo-cAMP (8-Br-cAMP). VIP stimulated GH and PRL secretion to the same maximal extent (220% of control) with similar ED50 values (0.37 +/- 0.03 and 0.43 +/- 0.08 nM, mean +/- SE, respectively). SRIF (100 nM) reduced maximal VIP-stimulation of both GH and PRL release from 220 to 140% of control; however, it did not significantly change the ED50 values for VIP. The effect of SRIF on VIP-stimulated hormone release parallels its action on VIP-stimulated cAMP accumulation. Furthermore, the concentrations of SRIF required to produce half-maximal inhibition of VIP-stimulated GH and PRL release (0.8 +/- 0.2 nM and 0.7 +/- 0.1 nM, respectively) were similar to its potency to inhibit VIP-stimulated cAMP accumulation (1.2 +/- 0.1 nM). These data indicate that changes in cAMP levels mediate inhibition of VIP-stimulated hormone secretion by SRIF. Forskolin increased cAMP accumulation with an ED50 value of 2.4 +/- 0.5 microM. A maximal concentration of forskolin (100 microM) stimulated cAMP accumulation to a greater extent than 100 nM VIP (34 +/- 4-fold vs. 9 +/- 1-fold). Together, forskolin (100 microM) and VIP (100 nM) stimulated cAMP accumulation by more than 50-fold. However, PRL secretion in response to maximal concentrations of VIP or forskolin individually or together were the same (approximately 200% of control). These results support the conclusion that both compounds stimulate PRL secretion by a cAMP-mediated mechanism which can be fully activated by either one alone.(ABSTRACT TRUNCATED AT 400 WORDS)     

In vitro regulation of growth hormone (GH) release from ovine pituitary cells during fetal and neonatal development: effects of GH-releasing factor, somatostatin, and insulin-like growth factor I

Using a monolayer approach, we have examined the acute (3 h) effects of GRF, somatostatin (SRIF), and insulin-like growth factor I (IGF-I) on GH release from pituitary cells of male and female 70-, 100-, and 130-day-old fetuses and newborn lambs and of prepubertal male lambs. GRF stimulated basal GH release in a dose-dependent (10(-12)-10(-8) M) manner at each stage in development. There was no linear relationship between maximal response and increasing age of the donor animals. The ED50 values for GRF were similar in all groups, except in the pituitaries from male and female 130-day-old fetuses, where the ED50 values were significantly higher. SRIF elicited a dose-related (10(-10)-10(-6) M) inhibition of basal GH secretion at each stage of fetal life and in the prepubertal period; although the response was lower in the youngest fetal pituitaries, there was no significant change in maximal response during the fetal or prepubertal period. No effect of SRIF on basal GH secretion was observed in newborn lambs. However, SRIF (10(-7) M) was able to block GRF (10(-8) M)-stimulated GH release in 100- and 130-day-old fetal and prepubertal as well as newborn lamb pituitary cells. Plasma IGF-I concentrations increased from 15.0 +/- 0.7 (mean +/- SE) and 13.8 +/- 0.9 ng/ml for male and female animals, respectively, at 70 days gestation to 55.8 +/- 3.2 and 51.8 +/- 11.1 ng/ml at the time of birth. The increase was much more pronounced in prepubertal lambs, especially in male animals, where IGF-I levels reached 300.8 +/- 37.7 ng/ml. IGF-I (100 ng/ml) had no effect on basal GH release in 70- and 100-day-old fetal, newborn, and prepubertal lamb pituitary cultures, but significantly inhibited basal GH secretion from 130-day-old fetal cells. This dose of IGF-I had no effect on GRF (10(-9) M)-stimulated GH release at 70 days gestation. It significantly inhibited this effect at 100 days and in prepubertal lamb cells. In 130-day-old fetal and newborn lamb pituitary cultures, IGF-I completely blocked the GH response to GRF.(ABSTRACT TRUNCATED AT 400 WORDS)     

Impaired suppression of growth hormone release by somatostatin in cultured adenohypophyseal cells of spontaneously diabetic BB/W rats

The effects of the diabetic state on the somatotroph's responsiveness to the secretagogues GRF and (Bu)2-cAMP and to the inhibitor somatostatin (SRIF) were evaluated in enzymatically dissociated rat adenohypophyseal cells in primary monolayer culture. Primary cultures were prepared from pituitary tissue of spontaneously diabetic BB/W rats 23-51 days after the onset of hyperglycemia and glycosuria and of age-matched diabetes-resistant control rats. Dose-related stimulation of GH release by GRF and (Bu)2cAMP did not differ significantly in the two preparations. There was no evidence of abnormal sensitivity to TRH in cultured somatotrophs of diabetic rats. Dose-related suppression of (Bu)2cAMP (0.5 mM)-stimulated GH release by 0.01-10 nM SRIF, on the other hand, was significantly affected by diabetes, as indicated by a parallel shift of the dose-response curve to the right and an increase in the IC50 value from 76 +/- 2 to 204 +/- 5 pM (mean +/- SEM; n = 3; P less than 0.001). Maximal suppression by 10 nM SRIF was identical in the two preparations. The degree to which the cultured cells' responsiveness to SRIF was reduced was unrelated to the duration and severity of the diabetic state. Hypothalamic SRIF content did not differ significantly between diabetic and diabetes-resistant rats (186 +/- 12 vs. 178 +/- 10 ng/mg protein). Nevertheless, the SRIF concentration may be elevated in hypophysealportal blood of diabetic rats; we, therefore, examined the effect of prolonged exposure of the cell cultures to SRIF or SMS 201-995 on the subsequent suppression of (Bu)2cAMP-stimulated GH release by SRIF. Addition of either SRIF (10 nM) or SMS 201-995 (5.5 nM) to the culture medium for 4 days significantly increased the IC50 values for SRIF to values similar to those obtained in cultured cells of diabetic rats. We conclude that the somatotrophs of diabetic rats are relatively resistant to SRIF. Since prolonged exposure to SRIF in vitro produced similar resistance, the desensitization in diabetic rats may be due to elevated concentrations of SRIF in hypophyseal-portal blood. This impaired responsiveness to SRIF may contribute to aberrant GH secretion in diabetes.     

Presence of an adenylate cyclase dually regulated by somatostatin and human pancreatic growth hormone (GH)-releasing factor in GH-secreting cells

We have investigated the effects of SRIF and human pancreatic GH-releasing factor-44 (hpGRF-44) on adenylate cyclase (AC) activity of male rat anterior pituitaries (in which somatotrophs are present in large proportion) and of human GH-secreting pituitary adenomas (which are almost homogeneously constituted by somatotrophs). The adenoma's responsiveness to both agents in terms of secretion was previously demonstrated in in vitro experiments. SRIF inhibited in a dose-dependent fashion the GH release from monolayer cultures of the tumors. The inhibition ranged from 32-66% at the maximal effective concentration (10(-6) M). hpGRF-44 stimulated GH release in a dose-dependent fashion. The stimulation was 78-172% at 10(-7) M. SRIF and hpGRF-44 markedly affected AC activity in both systems. SRIF elicited a pronounced inhibition of the enzyme activity in a dose-dependent manner. The inhibition was about 40% in the rat and ranged from 16-49% in adenomas at the maximal effective concentration (10(-5) M SRIF). The inhibitory effect was GTP-dependent. hpGRF-44 markedly stimulated AC activity. The stimulation was dose dependent and GTP dependent. The stimulation was about 650% in the rat and 26-350% in adenomas at the maximal effective concentration (10(-6) M). These results suggest the presence of a dually regulated (by SRIF and hpGRF-44) AC in GH-secreting cells; an involvement of cAMP in the intracellular mechanisms transducing the signals of SRIF and hpGRF-44 in somatotrophs.     

Human pancreatic growth hormone-releasing factor-44 differentially stimulates release of stored and newly synthesized rat growth hormone in vitro

Effects of synthetic human pancreatic GH-releasing factor-44 (hpGRF-44) on synthesis and release of rat pituitary GH and PRL were examined in vitro in a static incubation system. A double label, specific immunoprecipitation protocol permitted simultaneous study of hormone synthesis as well as release of both stored and newly synthesized hormone. Synthetic hpGRF-44 (0.3 and 3.0 nM) stimulated the release of stored GH 240% beyond the basal level, while simultaneously stimulating the release of newly synthesized GH by 610%. Despite the stimulation of release, hpGRF-44 did not alter GH synthesis (102% of control value). A small but statistically significant increase in release of stored PRL occurred in response to hpGRF-44, while release of newly synthesized PRL and PRL synthesis were unaffected. In contrast, 1 mM (Bu)2cAMP stimulated the release of both newly synthesized and stored GH and PRL. We conclude that hpGRF-44 differentially stimulates GH release from separate intracellular compartments and that the lactotroph may also, under certain conditions, respond to this secretagogue.     

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.     

12-O-tetradecanoyl phorbol-13-acetate stimulates rat growth hormone (GH) release through different pathways from that of human pancreatic GH-releasing factor

The mechanism(s) of action of 12-O-tetradecanoyl phorbol-13-acetate (TPA) on rat (r) GH release was studied in primary rat pituitary cell cultures. TPA stimulated rGH release (3.2- to 4.1-fold above control value) and rTSH and rLH release (1.4- and 1.7-fold above control values, respectively), but not rPRL release. The ED50 of TPA on rGH secretion was 1.3 X 10(-9) M compared to 4.5 X 10(-11) M for human pancreatic GH-releasing factor [hpGRF-(1-44)]. If maximally effective doses of TPA or hpGRF-(1-44) were added to the cells, the magnitudes of the increase in rGH release were quite similar for both agents when the incubation period was less than 12 h. When (Bu)2cAMP was added simultaneously with various doses of TPA, (Bu)2cAMP increased rGH release beyond the maximal effect of TPA. There was an additive effect when hpGRF-(1-44) and TPA were used to stimulate rGH release. These results indicate that TPA enhances rGH release through a different pathway than hpGRF-(1-44). TPA failed to increase the formation of intra- and extracellular cAMP, whereas hpGRF-(1-44) increased both, suggesting that TPA stimulates rGH release through an cAMP-independent pathway(s). Protein kinase C has been postulated to be a receptor for TPA in human platelets. When phospholipase C, which activates protein kinase C via the formation of diacylglycerol, was added to the cells, rGH release was stimulated in a dose-dependent manner. This effect was not blocked by indomethacin. These results may suggest that activation of protein kinase C leads to rGH release. The observations are consistent with the hypothesis that TPA activates protein kinase C and causes the release of rGH in normal pituitary cells in culture. These findings indicate that the mechanism(s) of action of TPA on rGH release is different from that of hpGRF-(1-44).     

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.     

Release of stored, pre-labeled growth hormone and prolactin from perifused rat pituitary: effect of human pancreatic growth hormone-releasing factor-44

Human pancreatic growth hormone-releasing factor-44 (hpGRF-44) differentially stimulates release of stored and newly synthesized rGH without altering rGH synthesis over 3 h in static in vitro incubation; hpGRF-44 also stimulates release of stored, but not newly synthesized, rPRL. To study the time course of pre-labeled, stored hormone release without pharmacologically interrupting synthesis, the current experiments were performed in perifusion. Fifteen minute pulses of 0.1 to 10 nM hpGRF-44 stimulated stored [3H]rGH release (to 890% of base); 1.0 to 10 nM hpGRF-44 stimulated stored [3H]rPRL release (to 440% of base). Pulses of 0.1 to 1.0 mM (Bu) 2cAMP also stimulated release of [3H]rGH (to 570% of base) and [3H]rPRL (to 410% of base). However, peak [3H]rGH and [3H]rPRL responses to hpGRF-44 required 10 min, while peak responses to (Bu) 2cAMP required 25 min. Continuous hpGRF-44 stimulated an initial surge of stored [3H]rGH release which was not sustained; the diminishing release was not explained by hpGRF-44 degradation. Total radioimmunoassayable (RIA) hormone release roughly paralleled release of stored immunoprecipitable (IPn) hormone. Conclusions: in pituitary perifusion, hpGRF-44 stimulates release of both stored rGH and rPRL as shown in static incubation, but the response is biphasic: initial rapid release is followed by a progressively lesser response; and the response is both more acute and less well sustained than that resulting from exposure to (Bu) 2cAMP.     

Regulation of release of somatotropin from in vitro cultures of bovine and porcine pituitary cells

Bovine and human GH releasing factors (GHRF), in concentrations ranging from 10 pM to 10 nM, stimulated GH release from cultured bovine and porcine anterior pituitary cells. Agents that increase intracellular cAMP levels (e.g. isobutylmethylxanthine and 8-bromo-cAMP) also stimulated bovine and porcine GH release. Somatostatin, in doses ranging from 1-100 nM, inhibited both basal and GHRF-stimulated GH release from the bovine pituitary cultures, and 100 nM somatostatin inhibited GHRF-stimulated release of porcine GH. Addition of exogenous bovine GH suppressed basal, but not GHRF-stimulated, release of bovine GH. Human insulin-like growth factor I did not suppress basal or GHRF-stimulated release of bovine GH from bovine pituitary cells, although it has been confirmed in this report that insulin-like growth factor I suppresses stimulated release of GH from rat cells. Furthermore, the GH release peptides described by Momany et al. stimulated little or no GH release from bovine or porcine pituitary cell cultures, in contrast to their activity in rat cells. The results show that whereas some regulatory features of GH release from bovine, porcine, and rat pituitary cell cultures are similar, others differ significantly.     

Growth hormone (GH) secretion in the dwarf rat: release, clearance and responsiveness to GH-releasing factor and somatostatin

The new mutant GH-deficient dwarf (Dw) rat was used to study the effects of GH-releasing factor (GRF) or somatostatin (SRIF) on GH release. In anaesthetized adult Dw female rats, i.v. injections of GRF (0.031-2.0 micrograms) elicited a dose-dependent release of GH. Although the peak plasma GH responses to maximal GRF doses were much lower in adult Dw rats compared with normal rats of this strain (AS), the responses largely reflected their relative pituitary GH contents (140 +/- 17 micrograms vs 2.9 +/- 0.4 micrograms, AS vs Dw (means +/- S.E.M.), P less than 0.001). Except at 20 days of age, normal AS rats were more sensitive to GRF than Dw rats despite their larger body weight. Peak GH responses to injection of 31.25 ng GRF increased nine-fold in normal rats between 20 and 40 days, whereas the GH responses to this GRF dose diminished in Dw rats over this age range, and their pituitary GH content was only 2-5% of that of age-matched AS rats. Treatment with human GH (200 micrograms/day for 7 days) stimulated growth in 40-day-old Dw rats and slightly increased the GH response to a low dose of GRF. Basal GH levels in adult Dw animals were sevenfold lower than in AS rats (2.4 +/- 0.3 vs 17.6 +/- 3.3 micrograms/l P less than 0.001) and were further suppressed by i.v. infusion of SRIF (25 micrograms/h). As in normal rats, a rebound GH secretion occurred in Dw rats after stopping SRIF, which was blocked by injection of anti-GRF serum.(ABSTRACT TRUNCATED AT 250 WORDS)     

Somatostatin inhibits vasoactive intestinal peptide-stimulated cyclic adenosine monophosphate accumulation in GH pituitary cells

Somatostatin (SRIF) has previously been shown to inhibit both basal and hormone-stimulated PRL secretion from GH4C1 cells, a clonal strain of rat pituitary tumor cells. In this study we examined the ability of SRIF to modulate cAMP accumulation in GH4C1 cells to determine whether such alterations mediate its biological effects. SRIF did not cause statistically significant changes in basal cAMP accumulation. Of six PRL secretagogues examined, only vasoactive intestinal peptide (VIP) increased cAMP accumulation significantly: TRH, bombesin, epidermal growth factor, insulin, and the tumor promoter, phorbol-12,13-dibutyrate were without effect. When SRIF was added simultaneously with VIP, it inhibited maximal VIP-stimulated cAMP accumulation (55 +/- 3%, mean +/- SE) without changing the ED50 for VIP (3.0 +/- 0.2 nM). Inhibition by SRIF was not due to altered kinetics of VIP stimulation, since the half-time for VIP-stimulated cAMP accumulation was 2 min both in the absence and presence of 100 nM SRIF. SRIF did not inhibit isobutylmethylxanthine-stimulated cAMP accumulation, and the presence of 0-10 mM isobutylmethylxanthine did not alter the inhibitory effect of SRIF on VIP-stimulated cAMP accumulation. Therefore, SRIF must act primarily to modulate VIP activation of adenylate cyclase activity. Inhibition of VIP-stimulated cAMP accumulation occurred at concentrations of SRIF (ID50 = 1.2 +/- 0.1 nM) close to the equilibrium dissociation constant for receptor binding (Kd = 0.6 +/- 0.2 nM). Furthermore, the potencies of a series of SRIF analogs to inhibit VIP-stimulated cAMP accumulation correlated with the apparent Kd of each peptide for binding to the SRIF receptor. In addition, SRIF did not reduce VIP-stimulated cAMP accumulation in GH(1)2C1 cells, which lack SRIF receptors. We conclude that SRIF inhibits VIP-stimulated cAMP accumulation by a receptor-mediated process that may be causally related to the ability of SRIF to inhibit VIP-dependent PRL secretion.     

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)     

Dihydropyridine-sensitive calcium channel activity related to prolactin, growth hormone, and luteinizing hormone release from anterior pituitary cells in culture: interactions with somatostatin, dopamine, and estrogens

In the present work, we determined the activity of voltage-dependent dihydropyridine (DHP)-sensitive Ca2+ channels related to PRL, GH, and LH secretion in primary cultures of pituitary cells from male or female rats. We investigated their modulation by 17 beta-estradiol (E2) and their involvement in dopamine (DA) and somatostatin (SRIF) inhibition of PRL and GH release. BAY-K-8644 (BAYK), a DHP agonist which increases the opening time of already activated channels, stimulated PRL and GH secretion in a dose-dependent manner. The effect was more pronounced on PRL than on GH release. BAYK-evoked hormone secretion was further amplified by simultaneous application of K+ (30 or 56 mM) to the cell cultures; in parallel, BAYK-induced 45Ca uptake by the cells was potentiated in the presence of depolarizing stimuli. In contrast, BAYK was unable to stimulate LH secretion from male pituitary cells, but it potentiated LHRH- as well as K+-induced LH release; it had only a weak effect on LH secretion from female cell cultures. Basal and BAYK-induced pituitary hormone release were blocked by the Ca2+ channel antagonist nitrendipine. Under no condition did BAYK affect the hydrolysis of phosphoinositides or cAMP formation. Pretreatment of female pituitary cell cultures with E2 (10(-9) M) for 72 h enhanced LH and PRL responses to BAYK, but was ineffective on GH secretion. DA (10(-7) M) inhibited basal and BAYK-induced PRL release from male or female pituitary cells treated or not treated with E2 (10(-9) M). SRIF (10(-9) and 10(-8) M) reversed BAYK-evoked GH release to the same extent in cell cultures derived from male or female animals. It was ineffective on BAYK-induced PRL secretion in the absence of E2, but antagonized it after E2 pretreatment. The effect was dependent upon the time of steroid treatment and was specific, since 17 alpha-estradiol was inactive. In addition, DA and SRIF decreased the 45Ca uptake induced by the calcium agonist. These data demonstrate that DHP-sensitive voltage-dependent calcium channels of the L type present on different pituitary cells are not equally susceptible to BAYK activation under steady state basal conditions, indicating that their spontaneous activity and/or distribution vary according to the cell type; their activity is modulated by sex steroids. In addition, these data suggest that Ca2+ channels represent a possible site of DA and SRIF inhibition of PRL and GH release, respectively, by gating calcium entry into the corresponding cells.     

17 beta-estradiol induces somatostatin (SRIF) inhibition of prolactin release and regulates SRIF receptors in rat anterior pituitary cells

The role of 17 beta-estradiol (E2) in the induction of an inhibitory effect of somatostatin (SRIF) on PRL release and in the regulation of SRIF receptors was analyzed in rat anterior pituitary cells. SRIF exerts a moderate inhibitory effect on basal PRL release from cultured pituitary cells prepared from normal rats. The inhibitory effect of SRIF was weakened when the cells were prepared from castrated rats, but was strengthened in cells from E2-treated rats. When cells from ovariectomized rats were cultured with charcoal-treated sera in the absence of E2, SRIF affected neither basal PRL release nor the increased PRL release elicited by TRH, (Bu)2cAMP, or vasoactive intestinal peptide. However, in cells cultured with E2 (10(-9) M) for more than 12 h, SRIF decreased basal as well as secretagogue-stimulated PRL release. Enhancement of both the sensitivity and magnitude of the inhibitory effect of SRIF appeared dependent upon the length of the preincubation and the E2 concentration. On the other hand, an inhibitory effect of SRIF on GH release was unaffected by castration, E2 administration in vivo, or E2 treatment in vitro. Dihydrotestosterone (10(-6) M) produced an effect similar to that of E2, but other steroids tested did not. Binding studies demonstrated that the specific binding of [125I-Tyr11]SRIF was saturable, with a Kd of 99 pM and a maximum binding capacity of 89.4 fmol/mg protein in pituitary membranes from control rats, and a Kd of 45 pM and a maximum binding capacity of 305.2 fmol/mg protein in membranes from rats primed with E2 for 4 weeks. Apparent Ki values for native SRIF in both membranes were similar. Treatment of pituitary cells with E2 for 8 days in vitro in culture produced a 2-fold increase in the number of binding sites. These results demonstrate that E2 acts on mammotrophs at the pituitary level, rendering them sensitive to SRIF, probably by increasing the number of SRIF receptor sites.     

Paradoxical enhancement of pituitary growth hormone (GH) responsiveness to GH-releasing factor in the face of high somatostatin tone

Pituitary GH secretion is regulated by a delicate interplay between stimulatory (GRF) and inhibitory [somatostatin (SRIF)] hypothalamic hormones, although the nature of the GRF/SRIF interaction remains to be elucidated. In the present study, we documented a significant elevation of plasma SRIF-like immunoreactivity in 72-h fasted rats compared to that in fed controls (129.0 +/- 17.9 vs. 38.2 +/- 5.8 pg/ml; P less than 0.01) and used this model of high SRIF tone to further delineate the interrelation between GRF and SRIF in physiological regulation of pulsatile GH secretion. We examined pituitary GH responsiveness to GRF, both in vivo and in vitro, after 72-h exposure to nutritional deprivation and high SRIF secretion. In vivo, GRF-induced GH release was markedly enhanced in the face of high circulating SRIF; freely moving, starved rats released 4- to 8-fold more GH than fed controls in response to rat GRF iv. In vitro, both basal and human GRF-induced GH release were augmented 2- to 4-fold in perifused dispersed anterior pituitary cells of starved rats compared to those in fed controls, and this enhanced responsiveness persisted in the presence of 10(-9) M SRIF. These results demonstrate that SRIF not only inhibits GH secretion stimulated by GRF, but that under different temporal conditions SRIF may act in a paradoxically positive manner to sensitize pituitary GH responsiveness to GRF. Such a cooperative interaction of the two peptides may be necessary to optimize pulsatile GH release. Our findings provide support for the hypothesis that the temporal patterning of hypothalamic GRF/SRIF signals to pituitary somatotrophs may be the major determinant for pulsatile GH secretion and, ultimately, body growth.     

Human pancreatic growth hormone (GH)-releasing hormone stimulates GH synthesis and release in infant rats. An in vivo study

Administration of human pancreatic GH-releasing factor 1-40 (hpGRF-40) at doses of 1, 10, 20, 100, and 500 ng/100 g BW sc induced in 10-day-old rats a clear-cut rise in plasma GH 15-min post-injection, although the effect was not dose-related and peak GH levels were already present after the lowest GRF dose. In 25-day-old rats, hpGRF induced only a slight rise in plasma GH at the dose of 500 ng/100 g BW sc, whereas it was completely ineffective at the lower doses. In 5-day-old rats, hpGRF (20 ng/100 g BW sc twice daily), administered for 5 days, induced a marked rise in pituitary GH content and plasma GH levels determined 14 h after the last hpGRF injection. In these rats, at the end of treatment, a challenge hpGRF dose (20 ng/100 g BW) induced a rise in plasma GH significantly higher than in infant rats receiving only the challenge hpGRF dose. These data show that: 1) pituitary responsiveness to hpGRF is strikingly higher in infant than in post-weaning rats; 2) in infant rats, subacute administration of hpGRF stimulates GH synthesis and release.     

The effects of thyroid hormone deprivation in vivo and in vitro on growth hormone (GH) responses to human pancreatic (tumor) GH-releasing factor (1-40) by dispersed rat anterior pituitary cells

Anterior pituitary cells from euthyroid and hypothyroid male rats have been cultured as monolayers for 3 days with or without 5 nM T3 and stimulated with either human pancreatic GH-releasing factor 1-40 (hpGRF), TRH, or the Ca2+ channel ionophore A23187. Basal GH secretion was reduced in the hypothyroid cultures (P less than 0.001) and basal TSH secretion increased (P less than 0.001). Culture with T3 increased GH secretion and intracellular GH content in euthyroid and hypothyroid cultures but suppressed TSH secretion with no effect on intracellular TSH content in either euthyroid or hypothyroid cultures. hpGRF released more GH from euthyroid [3.52 +/- 0.2 (SE) micrograms/6 h X 10(5) cells] than hypothyroid cultures of (0.17 +/- 0.01 micrograms/6 h X 10(5) cells, P less than 0.001) without a change in ED50 (approximately 0.02 nM). The reduction in hpGRF-induced GH release remained significant when corrected for the reduced intracellular GH content in the hypothyroid cultures. hpGRF-induced GH release also declined relative to A23187-induced GH release in hypothyroid cultures. Culture with 5 nM T3 doubled maximum hpGRF-induced GH release in euthyroid cultures and increased maximum release 10-fold in hypothyroid cultures without altering the ED50 of hpGRF action. In contrast, T3 suppressed TRH-induced TSH release in euthyroid cultures but was without effect on TRH-induced TSH release in the hypothyroid cultures. T3 did not effect the ED50 of TRH action (2-5 nM). In summary, hypothyroid rat anterior pituitary cells in culture have a reduced maximal GH response to hpGRF, but the same ED50. hpGRF activity can be partially restored by physiological concentrations of T3 in vitro.