Synthesis and release of acetylcholine by normal and tumoral pituitary corticotrophs

Incubation of cultured rat pituitary cell aggregates with [3H]choline ([3H]Chol) yielded a derivative that was identified as [3H]acetylcholine ([3H]ACh) by several criteria: 1) the [3H]Chol derivative with the highest retention time coeluted with a [14C]ACh standard in cation exchange and reverse phase HPLC; 2) cholinesterase treatment converted this derivative to a substance with the retention time of [3H]Chol; 3) two blockers of ACh production, hemicholinium and 4-[(1-naphthylvinyl)pyridinium], eliminated 3H-labeled material in the HPLC fractions with ACh retention time. Spontaneous [3H]ACh release was increased by depolarizing potassium concentrations, and both synthesis and release of ACh were increased by the glucocorticoid hormone dexamethasone. Double immunostaining of choline acetyltransferase (CAT) and, respectively, of ACTH, GH, PRL, TSH, S100, LH, and FSH in rat pituitary cells revealed that most of the CAT-immunoreactive cells were also ACTH immunoreactive. A small proportion (less than 10%) of the PRL-immunoreactive cells also showed CAT immunoreactivity, but all other cell types were negative. The immunocytochemical evidence for colocalization of CAT within the ACTH cell was strengthened by the finding of a significantly higher rate of [3H]ACh synthesis in a corticotroph-enriched cell population obtained by separating pituitary cells on a velocity sedimentation gradient. In addition, the mouse pituitary corticotropic cell line AtT20 contained CAT immunoreactivity, converted [3H]Chol to [3H]ACh, and released bioactive ACh-like material. In conclusion, the present data provide strong evidence that pituitary corticotrophs synthesize and release ACh, and that the activity of this intrapituitary cholinergic transmission system is under regulatory control.     

Veratridine and ouabain stimulate calcium-dependent prolactin release

We have investigated the effects of veratridine, a Na+ channel activator, and ouabain, an inhibitor of Na+-K+-ATPase, on short term (1-h) PRL release from primary cultures of rat anterior pituitary cells and from the rat anterior pituitary cell line GH4C1 in culture. Both compounds should increase intracellular Na+. Veratridine (20-500 microM) and ouabain (0.1-3 mM) stimulated PRL release from normal cells. The stimulation was inhibited by the omission of Ca++ from the release buffer or by preincubation with the calcium channel blocker D600 (20-500 microM), suggesting a role for Ca++ in the action of these compounds. Ouabain (1 mM), but not veratridine (200 microM), stimulated PRL release from GH4C1 cells, an effect that was also inhibited by calcium channel blockers. In the presence of the dopaminergic agonist bromocriptine (30 nM), the amount of stimulated release by veratridine (200 microM) and ouabain (1 mM) was reduced by 50%. The veratridine effect was only partially inhibited by preincubation of the cells with the Na+ channel blocker tetrodotoxin (1 and 10 microM), but the effect was inhibited completely when Na+ in the buffer was replaced by choline, suggesting that the action of veratridine requires extracellular Na+. The results of this study indicate that 1) ouabain- and veratridine-stimulated PRL release are largely dependent on Ca++; 2) veratridine appears to act through a tetrodotoxin-insensitive mechanism; and 3) stimulation of PRL release by these compounds is similar to that by 50 mM KCl and cAMP in its sensitivity to bromocriptine.     

Prolactin (PRL)-releasing peptide stimulates PRL secretion from human fetal pituitary cultures and growth hormone release from cultured pituitary adenomas

The hypothalamic peptide PRL-releasing peptide (PrRP) has recently been cloned and identified as a ligand of an orphan pituitary receptor that stimulates in vitro PRL secretion. PrRP also induces PRL release in rats in vivo, especially in normal cycling females. However, no information on the effects of PrRP in the human is available. To elucidate the role of PrRP in regulating human anterior pituitary hormones, we used human PrRP-31 in primary cultures of human pituitary tissues, including fetal (20--27 weeks gestation) and normal adult pituitaries, as well as PRL- and GH-secreting adenomas. PrRP increased PRL secretion from human fetal pituitary cultures in a dose-dependent manner by up to 35% (maximal effect achieved with 10 nM), whereas TRH was slightly more potent for PRL release. Coincubation with estradiol resulted in enhanced fetal PRL response to PrRP, and GH release was only increased in the presence of estradiol. Although PRL secretion from PRL-cell adenomas was not affected by PrRP, PrRP induced PRL release from cultures of a GH-cell adenoma that cosecreted PRL. PrRP enhanced GH release in several GH-secreting adenomas studied by 25--27%, including GH stimulation in a mixed PRL-GH-cell tumor. These results show for the first time direct in vitro effects of PrRP-31 on human pituitary cells. PrRP is less potent than TRH in releasing PRL from human fetal lactotrophs and is unable to release PRL from PRL-cell adenomas in culture, but stimulated GH from several somatotroph adenomas. Thus, PrRP may participate in regulating GH, in addition to PRL, in the human pituitary.     

Regulation of growth hormone and prolactin gene expression and secretion by chimeric somatostatin-dopamine molecules

Dopamine (DA) regulates both prolactin (PRL) secretion and gene expression, whereas somatostatin (SRIF) inhibits GH secretion with unclear effects on GH gene expression. We therefore tested the effects of SRIF analogs and chimeric SRIF/DA compounds BIM 23A760 and BIM 23A761 on GH and PRL secretion and gene expression in primary rat pituitary cultures and pituitary tumor GH(3) and MMQ cells. Chimeric SRIF/DA molecules suppressed GH release with a similar efficacy to SRIF receptor subtype 2 agonists in rat pituitary and GH(3) cells. After 24 h, BIM 23A760 and BIM 23A761 did not exert additive effects on GH secretion, and after 48 h were less effective than the combination of respective mono-receptor agonists in GH(3) cells. Real-time PCR did not reveal changes in GH mRNA levels after treatment with SRIF analogs and SRIF/DA molecules. SRIF/DA compounds suppressed PRL and PRL mRNA in rat pituitary and MMQ cells with a similar efficacy to D(2)-DA receptor agonist. In GH(3) cells, they suppressed PRL and PRL mRNA levels with a similar efficacy to SRIF receptor subtype 2 agonists. SRIF/DA molecules did not exhibit additive effects on PRL secretion and mRNA levels as compared with cotreatment with mono-receptor ligands. The results show that SRIF analogs and SRIF/DA molecules inhibit GH and PRL secretion and suppress PRL but not GH gene expression.     

The interrelationship between the effects of insulin-like growth factor I and somatostatin on growth hormone secretion by normal rat pituitary cells: the role of glucocorticoids

Both insulin-like growth factor I (IGF-I) and somatostatin (SRIH) have been shown to directly inhibit GH release and the total GH content of cultured pituitary cells. In the present study we evaluated the interrelationship between the effects of a recombinant human IGF-I analog ([Thr59]IGF-I) and SRIH on GH release by cultured normal rat pituitary cells together with the effects of glucocorticoids. In all experiments anterior pituitary cells were preincubated for 24 h without or with IGF-I, SRIH, and/or dexamethasone. Thereafter, 24-h incubations without or with IGF-I, dexamethasone, SRIH, and GHRH were performed. Both IGF-I and SRIH inhibited basal and GHRH-stimulated GH release in a dose-dependent manner; the maximal inhibitory concentrations were 5 nM IGF-I and 10 nM SRIH. These concentrations inhibited basal and GHRH-stimulated GH release by 23% and 40% (IGF-I) and 80% and 85% (SRIH), respectively. The combination of IGF-I and low concentrations of SRIH exerted an additive inhibitory effect on GHRH-stimulated GH release; IGF-I (1 nM) and SRIH (10 pM) together inhibited GH release by 50%, while the maximal inhibitory concentrations of 5 nM IGF-I and 10 nM SRIH virtually completely inhibited GH release (by 93%). Preincubation with 5 and 100 nM dexamethasone attenuated the sensitivity of somatotrophs to SRIH and completely abolished the inhibitory effects of IGF-I. This effect of dexamethasone could be reversed by coincubation with the glucocorticoid receptor antagonist RU 38486. High concentrations of 5-10 nM of the recombinant human IGF-I analog stimulated PRL cell content (5 and 10 nM) and release (10 nM), while a purified IGF-I preparation extracted from human blood exerted a parallel inhibitory effect on GH and PRL release. We conclude that 1) IGF-I and SRIH exert an additive direct inhibitory effect on basal and GHRH-stimulated GH secretion by normal cultured pituitary cells; 2) glucocorticoids directly attenuate the sensitivity of somatotrophs to SRIH, but completely prevent the inhibitory effects of IGF-I on GH secretion; and 3) in contrast to a purified IGF-I preparation extracted from human blood (which inhibits GH and PRL release) high concentrations of the recombinant IGF-I preparation (which inhibit GH release) stimulate PRL production.     

Stimulation of growth hormone and prolactin release from rat pituitary cell aggregates by bombesin- and ranatensin-like peptides is potentiated by estradiol, 5 alpha-dihydrotestosterone, and dexamethasone

The effect of the bombesin-like peptides, gastrin-releasing peptide (GRP) and neuromedin-C (NMC), and the ranatensin-like peptides, neuromedin-B (NMB), neuromedin-B30 (NMB30), and neuromedin-B32 (NMB32), on pituitary GH and PRL release was studied in perifused anterior pituitary aggregate cell cultures from 9- to 12-week-old male rats cultured in serum-free defined medium supplemented with 0.05 nM T3 and 4 nM dexamethasone (DEX). All peptides stimulated PRL and GH release. GRP and NMC stimulated hormone release in a concentration-dependent manner between 0.1-10 nM. NMB was slightly more potent than NMB30 and NMB32, but was significantly less potent than GRP and NMC. The magnitude of the PRL response to GRP and NMC inversely correlated with that of the GH response. Cultures with relatively low PRL response levels displayed high GH responses, whereas the opposite was found in cultures with high PRL response levels. The stimulatory actions of GRP, NMC, and NMB were blocked by the bombesin receptor antagonist Leu13 psi (CH2NH) Leu14-bombesin, supporting the specificity of the findings. Addition of 1 nM estradiol (E2) to the culture medium provoked an impressive (4- to 10-fold) increase in the magnitude of the GH response to NMC without changing the EC50 value (0.5 nM). In contrast, E2 significantly decreased the stimulation of GH release by rat GH-releasing factor. In the E2-treated aggregates 3 nM NMC stimulated GH release to a comparable extent as 0.1 nM GRF. 5 alpha-Dihydrotesterone (10 and 100 nM) and DEX (80 nM) also enhanced the GH response to NMC, but to a much smaller extent than E2. E2 had also a stimulatory effect on the PRL response to NMC, particularly in cultures with a low intrinsic PRL response. The PRL response to NMC was decreased by DEX and slightly augmented by 5 alpha-dihydrotestosterone. It is concluded that bombesin- and ranatensin-like peptides have a stimulatory effect on GH and PRL release at the pituitary level. Since their action on GH release is strongly potentiated by E2 and much less so by glucocorticoids, these peptides clearly distinguish their activity and specificity from that of the protagonist releasing factor GH-releasing factor, suggesting a role in sex-related differences in GH release or in the control of GH secretion during sexual maturation.     

Opiate modulation of the anterior pituitary hormone response during suckling in the rat

We have investigated the influence of endogenous opiates on hormone responses during suckling in the rat. In complementary experiments, opiate receptors were blocked by naloxone (NAL) or endogenous opiate release from the pituitary was inhibited by dexamethasone (DEX). Serial blood samples from unanesthetized suckled rats were then assayed for plasma PRL, beta-endorphin-like immunoreactivity (beta-END-LI), TSH, and GH levels. Identical studies were also done in saline-treated (control) suckled rats and in unsuckled rats exposed to control objects. Whereas suckling caused a rise in plasma PRL, beta-END-LI, and GH, introduction of plastic control objects did not elevate hormone levels. NAL blocked the GH rise and depressed TSH levels, but did not significantly inhibit the PRL or beta-END-LI response. DEX prevented the beta-END-LI rise and blocked the GH rise, but did not inhibit TSH. DEX enhanced PRL release during suckling. These results demonstrate that 1) the responses of beta-END-LI, PRL, and GH are not an artifact of the sampling procedure; 2) PRL release during suckling is independent of beta-END-LI release by the pituitary; and 3) suckling stimulates the release of ACTH, beta-END, and beta-lipotropin from the anterior pituitary. Our results are consistent with both a role of pituitary beta-END in the control of GH and a role of corticosterone in the control of PRL during suckling.     

Growth hormone and prolactin secretion in cultured somatomammotroph cells

A somatomammotropic cell line (P0) derived from adult rat pituitaries has been maintained in culture for 2 yr. Secretion of GH and PRL by this cell line has been studied in response to hypophysiotropic peptides known to affect the release of both hormones as well as agents that affect second messenger systems in an attempt to characterize the stimulus-secretion mechanisms used by these cells. GH and PRL release during short term (4 h) incubations of P0 cells and primary cultures of dispersed rat pituitary cells was initially measured in response to GRF, TRH, vasoactive intestinal peptide (VIP), and SRIF. In P0 cells, the minimal effective dose of each of the hypophysiotropic peptides was comparable with respect to GH and PRL secretion. The effects of TRH and VIP were similar to those in freshly dispersed cells with respect to PRL release, whereas those of GRF and SRIF were less potent with respect to GH release. The stimulation of GH and PRL release in P0 cells by adenylate cyclase-related agents ((Bu)2 cAMP and forskolin) was comparable to that for GH secretion in mature somatotrophs but much greater than that of PRL release in mature lactotrophs. Stimulation of GH and PRL release in P0 cells by protein kinase C-related agents (diacylglycerol and phorbol ester) was also similar to that observed for GH release from mature pituitary cells, whereas minimal or undetectable effects were observed on PRL release from mature cells. The results indicate that the P0 somatomammotropic cell line possesses receptors, second messenger systems, and secretory characteristics of both somatotrophs and lactotrophs, although where differences exist, there is more resemblance to somatotrophs. They also demonstrate that the responses to each of the agents studied are bihormonal and appear to be regulated by a common mechanism.     

Novel ghrelin analogs with improved affinity for the GH secretagogue receptor stimulate GH and prolactin release from human pituitary cells

OBJECTIVE: Ghrelin, a recently identified 28-amino acid peptide is a potent GH secretagogue (GHS) produced predominantly by the stomach. Ghrelin stimulates GH secretion through binding to the GHS receptor in the hypothalamus and pituitary. In addition to the GH-releasing action, ghrelin has been found to be a powerful orexigenic factor. To assess the direct in vitro effects of ghrelin on human pituitary hormone secretion we have produced a panel of novel ghrelin analogs (molecular weight, 3323-3384; human native ghrelin, 3371) with enhanced affinity for the human GHS receptor (IC(50) 0.38-1.09 nM; human ghrelin, 1.2-2.2 nM). METHODS: The peptidic analogs were tested for their effect on GH secretion using dispersed human fetal pituitaries (21 to 23 weeks of gestation) and cultured GH- and prolactin (PRL)-secreting adenomas. The expression of the GHS receptor in normal (fetal and adult) human pituitary tissues, GH- and PRL-cell adenomas was established using RT-PCR. RESULTS: The effects of ghrelin, its analogs and GH-releasing hormone (GHRH) alone or in combination on GH and PRL secretion were compared at various concentrations. The ghrelin analogs stimulated GH release by 35-60% from human fetal pituitary cells (1-10 nM; P<0.05) and by 50-75% from cultured pituitary adenomas (10 nM; P<0.05). This releasing effect was dose-dependent, achieving maximal stimulation with analog concentrations at 100 nM. Human ghrelin was less potent as compared with its analogs in stimulating human GH, in keeping with the improved binding affinity of the analogs for the GHS-1a receptor. The ghrelin analogs and GHRH had comparable effects on GH secretion from both normal and adenomatous cells, and in combination produced an additive stimulatory effect on GH (150%; P<0.0001). In contrast, ghrelin and its analogs induced a comparable increase in PRL release ranging between 25 and 40% (P<0.05) from fetal cells and 30 and 70% (P<0.001) from cultured PRL-cell and mixed GH-PRL adenomas. CONCLUSIONS: Our results have demonstrated for the first time that ghrelin analogs with enhanced affinity for the GHS receptor are potent stimulators of GH secretion from human pituitary cells, and thus may possess potential clinical therapeutic benefits.     

Angiotensin II is retained in gonadotrophs of pituitary cell aggregates cultured in serum-free medium but does not mimic the effects of exogenous angiotensins and luteinizing-hormone-releasing hormone on growth hormone release.

Angiotensin II (AII)-like immunoreactivity (LIR) was detected by immunostaining in 7.5 +/- 1.1% of cells obtained by redispersion of pituitary cell aggregates from 15- to 20-day-old female rats, cultured for 5-7 days in serum-free medium supplemented with thyroid hormone and dexamethasone. Also, renin-LIR was retained in these cultures. As shown by double immunostaining of paraffin-embedded sections of the aggregates, this AII-LIR was localized only in gonadotrophs. AII-LIR was detected at least up to 5 weeks in culture. On reversed-phase, high-performance liquid chromatography (HPLC), this AII-LIR co-migrated with authentic AII. In perifused aggregate cell cultures of 15- to 20-day-old female rat pituitary maintained in serum-free medium supplemented with dexamethasone (DEX) and triiodothyronine (T3), AII stimulated GH release. AI and AIII had a similar effect. To evaluate the possible involvement of endogenous AII in the local regulation of GH release, gonadotrophs were stimulated with luteinizing hormone-releasing hormone (LHRH). LHRH displayed a transient inhibitory effect on GH release, which was followed by a rebound of GH release after withdrawal of the peptide. Treatment of aggregates with pertussis toxin reversed this inhibitory effect into a significant stimulation of GH release. In aggregates cultured in serum-supplemented medium, LHRH provoked a significant stimulation of GH release which was still followed by a post-stimulus rebound release. In hemipituitaries from 5-day-old rats, a significant stimulatory effect of LHRH on GH release was found without rebound secretion. To evaluate the possible involvement of endogenous AII in the effects of LHRH on GH release, the influence of (Sar1,Ala8)AII, a peptide AII receptor antagonist, and of DUP753, a non-peptide AII receptor blocker was tested in various in vitro conditions. The effect of LHRH on GH release in aggregates cultured either in serum-free medium supplemented with DEX and T3 or in serum-supplemented medium was not affected by (Sar1,Ala8)AII, not even after enhancing the LHRH-induced GH release by treatment of the aggregates with pertussis toxin. A hundred times lower concentration of (Sar1,Ala8)AII, however, abolished the AII-induced changes in GH release. Also DUP753 (10 microM) failed to block LHRH-induced GH release in aggregates. (Sar1,Ala8)AII also failed to block the effect of LHRH on GH release from hemipituitaries. It is concluded that LHRH has inhibitory and stimulatory effects on GH release in cultured pituitary cell aggregates.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effects of the gp130 cytokines ciliary neurotropic factor (CNTF) and interleukin-11 on pituitary cells: CNTF receptors on human pituitary adenomas and stimulation of prolactin and GH secretion in normal rat anterior pituitary aggregate cultures

Two of the most potent cytokines regulating anterior pituitary cell function are leukemia inhibitory factor (LIF) and interleukin (IL)-6, which belong to the cytokine family using the common gp130 signal transducer. Recently, the expression and action of two other members of this family, IL-11 and ciliary neurotrophic factor (CNTF), on different cell lines has also been demonstrated. We studied the expression of the specific receptor subunits for CNTF in mammotropic, non-functioning and somatotropic tumors and the action of CNTF and IL-11 in the regulation of hormone secretion in these and normal pituitary cells. The mRNA for the alpha chain specific for the CNTF receptor was detected by Northern blot in tumors secreting prolactin (PRL) and GH and in non-functioning tumors. We found that both IL-11 and CNTF exerted a similar stimulatory effect on GH mRNA expression in somatotropic monolayer cell cultures from acromegalic tumors, but these cytokines had no significant influence on GH secretion. CNTF stimulates prolactin secretion in lactotropic monolayer cell cultures from patients with prolactinoma. In monolayer cell cultures from normal rat anterior pituitary, IL-11 and CNTF had no significant effect on the release of either GH or PRL, or on GH mRNA. However, when the cells were cultured in aggregate cultures, in which the three-dimensional structure of the cells is reconstituted, both cytokines, in doses at which they had no effect on monolayer cultures, significantly stimulated both PRL and GH secretion. These data show that IL-11 and CNTF may act as regulatory factors in anterior pituitary cells, in which the three-dimensional structure of the gland is of critical importance.     

Somatostatin analogs: correlation between receptor binding affinity and biological potency in GH pituitary cells

Somatostatin (SRIF) is a hypothalamic tetradecapeptide which acts on several different types of pituitary cells to inhibit hormone release both in vivo and in vitro. We have previously shown that the GH4C1 clonal strain of rat pituitary tumor cells contains a single class of specific high-affinity SRIF receptors and that SRIF is a potent inhibitor of GH and PRL release by these cells. In this study, we have determined the relationship between the apparent binding affinity and biological potency of 19 SRIF analogs in GH4C1 cells. Receptor binding and biological activity were assayed under identical conditions. A good correlation (r = 0.96) was observed over a 10,000-fold range between the receptor binding affinities and biological potencies of SRIF analogs. Modifications at the C- and N-terminal regions of the SRIF molecule had minimal effects on binding to the receptor or potency to inhibit PRL release. However, substitution of residues 6 through 10 or reduction of the disulfide bond resulted in a 100-fold or greater decrease in both activities. The N-terminal extended SRIF analogs, SRIF-28, [D-Trp22]SRIF-28, and SRIF-25, were all somewhat less potent than SRIF. These results strongly support the involvement of the characterized SRIF receptor in initiating the biological actions of SRIF in GH4C1 cells and define the structural features of the SRIF molecule required for both receptor binding and activation.     

Evidence for the presence of gastrin-releasing peptide immunoreactivity in rat anterior pituitary corticotrophs and lactotrophs, AtT20 cells, and GH3 cells: failure to demonstrate participation in local control of hormone release.

Using antisera raised against the N-terminal (1-16) or the C-terminal part of the bombesin (BBN)-like peptide gastrin-releasing peptide (GRP) and against the C-terminus of pro-GRP, GRP- and pro-GRP-like immunoreactivity (IR) was detected by immunostaining in freshly dispersed rat anterior pituitary (AP) cells and in reaggregate AP cells cultured in serum-free medium. Depending on the antiserum used, 6.4 +/- 0.4% to 12.4 +/- 2.7% of freshly dispersed cells were immunoreactive. Solid phase preabsorption of the antisera with the respective antigens abolished the staining. GRP-IR was detectable by double immunostaining in a subpopulation of PRL cells and ACTH-containing cells. In contrast, only very few somatotrophs, gonadotrophs, and thyrotrophs were immunoreactive, and they were much smaller than the typical mature forms of these cell types. GRP- and pro-GRP-IR were also detected in the ACTH-secreting AtT20 cell line and in the PRL- and GH-secreting GH3 cell line. GRP- and pro-GRP-IR were present in AP cell aggregates maintained in culture for 4 weeks. The finding of both GRP- and pro-GRP-IR in a subpopulation of lactotrophs and corticotrophs and their persistence in culture under serum-free conditions strongly suggest that GRP-like peptides are produced in rat AP. Although the potent GRP receptor antagonist L 686,095-001C002 effectively blocks stimulation of GH and PRL release by exogenous BBN-like peptides, it failed to affect basal GH and PRL release from perifused reaggregate AP cell cultures as well as GH and/or PRL release stimulated by epinephrine, vasoactive intestinal peptide, TRH, GH-releasing factor, and angiotensin-II or PRL release inhibited by dopamine. Thus, the latter data do not support the hypothesis often suggested that peptides endogenously present in AP cells are involved in the paracrine regulation of AP hormone secretion.     

Stimulation and inhibition of prolactin release from rat pituitary lactotrophs by the cholinomimetic carbachol in vitro. Influence of hormonal environment and intercellular contacts

The prolactin (PRL) response of perifused rat pituitary tissue to the cholinomimetic agent carbachol (CARB) was studied under various in vitro conditions. Perifusion of freshly removed hemipituitaries from 14-day-old rats with CARB did not affect basal PRL release. When established in organ culture for 3 days in a serum-free chemically defined medium, there was a significant increase of PRL release in response to CARB. This PRL releasing activity of CARB depended on the hormonal environment of the culture medium: supplementation of the culture medium with triiodothyronine (T3) and the glucocorticoid dexamethasone (DEX) completely reversed the PRL releasing activity of CARB into an inhibition of PRL release. In dispersed pituitary cells from immature rats, cultured as three-dimensional reaggregates, a similar reciprocal responsiveness to CARB existed which was also determined by T3 and DEX. This reciprocal responsiveness to CARB was preserved in adult female rats but was shifted to a more prominent inhibition in adult male rats. Tumoral PRL secreting GH3 cells, cultured as aggregates, always responded in an inhibitory way, irrespective of the hormonal environment. The expression of the reciprocal responses, in particular of the inhibitory pathway to CARB was dependent on close cellular contacts, as the inhibitory response of normal and tumoral pituitary cells, cultured as isolated cells on Cytodex beads, was completely absent. The stimulatory response of normal lactotrophs, cultured as isolated cells was, although attenuated, still preserved. The present data suggest that there exists a reciprocal responsiveness of normal lactotrophs to cholinomimetics depending on the hormonal environment and close cellular associations. In contrast, only inhibitory PRL responses occur in GH3 tumoral lactotrophs, which are not dependent on thyroid and glucocorticoid hormones.     

Differential effects of ketoconazole on prolactin and growth hormone release by normal and tumoral rat anterior pituitary cells in vitro

The imidazole derivative ketoconazole (1-100 microM) was shown to stimulate the release of prolactin (PRL) from rat anterior pituitary cells in vitro. In contrast, this drug did not affect growth hormone (GH) release from the same cells. In addition, ketoconazole was found to have no effect on PRL or GH release from a tumoral pituitary cell clone (GH3). Treatment of normal pituitary cells with ketoconazole (10 microM) for more than 20 min abolished TRH-induced hormone release. TRH-stimulated release was both attenuated and delayed in the ketoconazole-treated tumoral cells. Ketoconazole (10 microM) did not affect the basal electrophysiological properties of GH3 cell membranes, although it did affect the TRH-induced response. The action of ketoconazole of the spontaneous release of PRL by normal cells and the TRH-stimulated release of PRL and GH is consistent with an interference with arachidonic acid metabolism.     

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.     

Adenosine inhibits prolactin and growth hormone secretion in a clonal pituitary cell line

Although purine nucleosides have been shown to regulate the secretion of several peptide and steroid hormones, effects on pituitary hormone release have not been reported. We show here that in the clonal GH4C1 pituitary cell line maximal concentrations of adenosine (greater than or equal to 50 microM) inhibited PRL and GH secretion by 40%. Adenosine deaminase abolished the inhibitory effect of adenosine but not that of SRIF or (-)N6(R-2-phenylisopropyl)adenosine (PIA), a nonhydrolyzable adenosine analog. Furthermore, this enzyme increased basal secretion by 50%, and analysis of the incubation medium by HPLC demonstrated that the cells secreted biologically effective concentrations of adenosine. These results indicate that adenosine produced in culture tonically inhibits hormone release. In other target cells, adenosine inhibition is mediated by two types of binding sites: an extracellular Ri-site requiring an intact ribose moiety or an intracellular P-site requiring an intact purine ring. Four lines of evidence indicate that in GH4C1 cells, adenosine acts at an Ri-site. PIA, an Ri-site-specific agonist, was a potent inhibitor of hormone release (ED50 = 30 nM). Theophylline, an Ri-site antagonist, competitively inhibited the action of PIA (Ki = 2.4 microM). 3) 2'5'-Dideoxyadenosine, a P-site-specific agonist, did not inhibit PRL release even at a concentration of 1 mM. 4) Dipyridamole, an adenosine uptake inhibitor, did not reduce adenosine inhibition. In addition to its effect on basal secretion, PIA inhibited stimulation of hormone release by vasoactive intestinal peptide and TRH. PIA also reduced vasoactive intestinal peptide-stimulated cAMP accumulation by 75%, consistent with its action to inhibit adenylate cyclase via Ri receptors in other targets. Since PIA inhibition of PRL release and cAMP accumulation was not additive with the effects of SRIF and carbamyl choline, these inhibitors may act via a common rate-limiting step. Our results demonstrate that adenosine activates an Ri-type of adenosine receptor in GH4C1 cells and that the production of adenosine under normal culture conditions causes autocrine inhibition of secretion.     

Somatostatin receptors in pituitary and development of somatostatin receptor subtype-selective analogs

Somatostatin receptor (SSTR) subtypes 1, 2, and 5 are expressed in the normal human pituitary. SSTR2 and SSTR5 are expressed in almost all growth hormone (GH) cell adenomas, and prolactin (PRL)-secreting tumors express SSTR5 more than SSTR2. SSTR4 is not detected in all pituitary adenoma subtypes, and SSTR1 and SSTR3 are expressed in about 50% of tumors. Human GH is regulated through ligand binding to both SSTR2 and SSTR5, but octreotide and lanreotide, the two clinically available somatostatin analogs, bind to human SSTR2 much better than to SSTR5. Novel SSTR2- and SSTR5-selective analogs with improved binding affinity for these receptor subtypes are highly potent in suppressing GH release from cultures of human fetal pituitaries or GH-cell adenomas. Only SSTR5-selective analogs suppress in vitro PRL secretion from cultured prolactinomas. A new SSTR2+5 bispecific analog with high affinity and selectivity for both SSTR2 and SSTR5, and a somatostatin analog with a unique broad receptor (SSTR1, 2, 3, and 5) binding profile, are both able to inhibit in vitro GH release in GH cell adenomas partially sensitive to octreotide. Recently, a somatostatindopamine hybrid molecule was introduced with potentially functional synergy on GH and PRL release. Using the expanding knowledge on SSTRs and their ligand activation, the development of novel pharmacologic concepts may open new opportunities for effective manipulation of this complex intracellular signaling system. These concepts may achieve better control of pituitary hormone hypersecretion, pituitary size, as well as antitumor effects in patients with SSTR-expressing tumors.