High concentrations of dopamine and epinephrine protect dopaminergic D2 receptors from inactivation by phenoxybenzamine on primary cultured rat lactotrophs.

The effect of a high concentration of catecholamines on phenoxybenzamine pretreatment was examined. The efficacy of the pretreatments was monitored by testing the inhibitory action of dopamine on prolactin release. Phenoxybenzamine is a beta-haloalkylamine which alkylates and irreversibly inactivates adrenergic alpha-receptors in smooth muscle. Dopaminergic D2 receptors share several common characteristics with the alpha-receptors. Primary cultured male rat pituitary cells were used. After phenoxybenzamine (0.1 mumol/l) pretreatment, the inhibitory action of dopamine on prolactin release was significantly reduced in a perifusion system. When the cells were pretreated with phenoxybenzamine in medium containing 0.1 or 1 mmol/l dopamine, the 0.1-mmol/l dopamine did not change the effect of phenoxybenzamine on inactivation of the receptors, but the 1-mmol/l dopamine eliminated the effect of phenoxybenzamine pretreatment. These observations were confirmed with a static monolayer culture system. The observations illustrate that a high concentration of dopamine forms a D2 receptor-dopamine complex and protects the D2 from inactivation by phenoxybenzamine. When the cells were pretreated with 0.1 mumol/l phenoxybenzamine in a medium containing 1 mmol/l epinephrine, the effect of the phenoxybenzamine was also eliminated, suggesting that a sufficient amount of D2 receptor-epinephrine complex was formed to protect the receptor from inactivation. The hormone release in response to a secretagogue depends on its affinity and intrinsic activity. It is, therefore, suggested that the intrinsic activity of epinephrine is much lower than that of dopamine on prolactin release, since the D2 receptor-epinephrine complex is as stable as the D2 receptor-dopamine complex, and the inhibitory action of epinephrine on prolactin release is less than 10% of that of dopamine.(ABSTRACT TRUNCATED AT 250 WORDS)     

A high concentration of dopamine preferentially permitted release of newly synthesized prolactin

We used continuous labelling ([3H]leucine) of cultured adenohypophysial cells to investigate the relationship between the storage and release of newly synthesized and stored prolactin in response to dopamine (1 mumol/l) and thyrotropin-releasing hormone (TRH) (0.1 mumol/l) challenge. Newly synthesized prolactin was identified by the tritium radiation activity incorporated in prolactin. A maximal dose of dopamine (1 mumol/l) could not completely block prolactin release from a primary culture of lactotrophs. During 3 h of continuous labelling under maximal dopaminergic inhibition, newly synthesized prolactin was released which was of a significantly higher specific activity than control groups. In contrast, TRH stimulation produced results consistent with previous observations of the release of predominantly old, stored hormone. However, the absolute amount of the newly synthesized prolactin was increased by the TRH administration, and the increased release of the newly synthesized prolactin could be accounted for by increased levels of synthesis. Our results are consistent with the concept of the existence of a regulated route and a dopamine-insensitive constitutive route of prolactin release which predominantly encompasses newly synthesized hormone. However, the possibility that cellular heterogeneity or that non-dopaminergic prolactin-release inhibiting factor(s) (PIF) is responsible for this observed release cannot be ruled out.     

Somatostatin partially impedes the stimulatory effects of thyrotrophin-releasing hormone and dibutyryl cyclic AMP on prolactin release: prolactin release through multiple routes.

Patterns of prolactin release were examined using stimulating and inhibiting agents. Primary cultured pituitary cells primed with oestrogens were used for perifusion experiments. TRH (100 nmol/l) increased the peak prolactin concentration to 360% of the basal concentration, while TRH, under inhibition by 1 nmol somatostatin/l, raised the peak prolactin concentration to 185% of the basal levels. When the somatostatin concentration was increased to 10, 100 and 1000 nmol/l, TRH still stimulated prolactin release to 128%, 121% and 140% respectively, indicating that concentrations of somatostatin of 10 nmol/l or higher did not further suppress the stimulatory effect of TRH. TRH (1 mumol/l) stimulated prolactin release under the influence of 0 (control), 1, 10, 100 and 1000 nmol dopamine/l (plus 0.1 mmol ascorbic acid/l) to 394, 394, 241, 73 and 68% of the basal concentration respectively, showing that the dopamine concentrations and peak prolactin concentrations induced by TRH have an inverse linear relationship in the range 1-100 nmol dopamine/l. The stimulatory effect of dibutyryl cyclic AMP (dbcAMP) on prolactin release was also tested. The relationship between dbcAMP and somatostatin was similar to that between TRH and somatostatin. When adenohypophyses of male rats were used for perifusion experiments, somatostatin (100 nmol/l) did not inhibit basal prolactin release from the fresh male pituitary in contrast with the primary cultured pituitary cells, but dopamine (1 mumol/l) effectively inhibited prolactin release. In conclusion, (1) oestrogen converts the somatostatin-insensitive route into a somatostatin-sensitive route for basal prolactin release, (2) TRH-induced prolactin release passes through both somatostatin-sensitive and -insensitive routes, (3) dopamine blocks both somatostatin-sensitive and -insensitive routes and (4) cAMP activates both somatostatin-sensitive and -insensitive routes.     

Differential inhibition of dopamine and bromocriptine on induced prolactin release: multiple sites for the inhibition of dopamine.

Effects of dopamine and bromocriptine on TRH- or dibutyryladenosine 3',5'-cyclic monophosphate (dbcAMP)-induced prolactin release from primary cultured rat pituitary cells were studied using a perifusion system. TRH (100 nmol/l) stimulated prolactin release from basal concentrations of 33.8 +/- 0.5 to 151.2 +/- 28.0 ng/ml (net increase) or 447% increase. Dopamine inhibited the basal release of prolactin throughout the experiment, but TRH (100 nmol/l) was still able to stimulate prolactin release under the influence of dopamine. The increment in prolactin release was inversely proportional to the dopamine concentration. When TRH (100 nmol/l) was introduced during a perifusion period with bromocriptine 1 nmol/l, the prolactin concentration was increased to 110.9% of basal levels. The stimulatory effect of TRH under the influence of bromocriptine (1 nmol/l) was significantly lower than that without bromocriptine (control), although the higher concentrations of bromocriptine (10 and 100 nmol/l) did not further reduce the peak concentration of TRH-induced prolactin release. During a perifusion period with a low concentration of dopamine (1 nmol/l plus 0.1 mmol/l ascorbic acid), introduction of dbcAMP (3 mmol/l) stimulated prolactin release to 48% of basal concentration. A higher concentration of dopamine further reduced the stimulatory effect of prolactin release. Bromocriptine impeded the stimulatory effect of dbcAMP (3 mmol/l) on prolactin release in a similar manner as dopamine. Since a higher concentration of bromocriptine (10 and 100 nmol/l) did not further inhibit the TRH-induced prolactin release whereas a higher concentration of dopamine did, it is concluded that dopamine acts through additional mechanism(s) other than the D2 receptor transduction system.     

Effects of metabolic inhibitors on hormone release, cyclic AMP levels, and oxygen consumption in rat pituitary cells in culture

The metabolic inhibitors antimycin A (2 mumol/l), dinitrophenol (0.5 mmol/l), and iodoacetate (6 mmol/l) were tested for their effects on hormone release, cAMP levels, and oxygen consumption in clonal strains of rat pituitary cells (GH3 cells). Basal release of growth hormone (GH) and prolactin (PRL) was reduced by all three inhibitors, and thyrotropin-releasing hormone (TRH) (1 mumol/l) and K+ (50 mmol/l) stimulated hormone release were blocked. Trifluoperazine, a calmodulin antagonist, inhibited basal GH and PRL release at concentrations up to 30 mumol/l and stimulated above 50 mumol/l. The stimulatory effect of 80 mumol/l trifluoperazine on basal hormone release was eliminated by antimycin A, dinitrophenol, and iodoacetate, whereas the inhibitory effect of antimycin A, dinitrophenol and iodoacetate on basal hormone was not affected by 30 mumol/l trifluoperazine. None of the inhibitors had any effect on the level of cellular cAMP (i.e. intracellular plus extracellular). Oxygen consumption of GH3 cells was blocked by antimycin A, reduced by 25% by iodoacetate and increased by about 100% by dinitrophenol. In contrast, hormone secretion stimulated by TRH and K+ was not accompanied by any measurable alteration in oxygen consumption. Trifluoperazine (greater than or equal to 80 mumol/l) reduced the basal oxygen consumption and blocked the stimulatory effect of dinitrophenol on oxygen consumption. In conclusion, inhibition of the energy generation of GH and PRL-producing cells severely affects the action of secretagogues, although stimulated hormone secretion may not be accompanied by any measurable increase in oxygen consumption. The cellular energy supporting hormone secretion is mostly generated via oxidative phosphorylation.     

Inhibition of prolactin secretion by low-dose dopamine infusion in patients with hyperprolactinaemia

Dopamine inhibits the secretion of prolactin from the pituitary. We have examined the relation between plasma dopamine and serum prolactin in 12 patients with hyperprolactinaemia during the infusion of dopamine at low doses (0.01, 0.1 and 1 microgram/kg/min). Plasma dopamine levels were raised from less than 100 pg/ml at the lowest rate of infusion to more than 20 000 pg/ml at the highest. Suppression of prolactin secretion was seen in some patients even at the lowest rate of infusion (0.01 microgram/kg/min); marked suppression of prolactin secretion (60%; 17--83%) was found at the intermediate dose (0.1 microgram/kg/min) in 11 of the 12 subjects with little further decrease in serum prolactin (70%; 50--87%) in those in whom the rate of dopamine infusion was increased ten-fold. One patient with the highest serum prolactin (82 500 mu/l) showed no decrease in prolactin either at the lowest or intermediate rates of dopamine infusion. Serum prolactin levels returned to values similar to or greater than basal on cessation of dopamine infusion. Infusion of dopamine at doses much lower than previously used in man exposes the pituitary to a concentration of dopamine sufficient to suppress prolactin secretion. These observations have important implications in understanding the pathophysiology of prolactin secretion from the pituitary gland and for future investigations of the control of hormone release by dopamine.     

Involvement of dopamine D1 receptors in the control of growth hormone secretion in the rat

The effects of dopamine on GH release were investigated both in vivo in freely moving intact rats and in rats with a mediobasal hypothalamic lesion, and in vitro in a perifusion system using dispersed male rat pituitary cells kept in primary culture. In vivo, dopamine (5 mg/kg body weight) induced a rapid and very transient increase in plasma GH levels in lesioned but not in intact rats. This increase was markedly inhibited by a prior injection of the D1 antagonist SCH 23390 (0.5 mg/kg) but not of the D2 antagonist domperidone (0.5 mg/kg). The D1 agonist SKF 38393 induced a dose-dependent stimulation of GH release in lesioned rats, and the effect obtained with a dose of 5 mg/kg was abolished by pretreatment with SCH 23390 (0.5 mg/kg). In vitro, dopamine (0.1 mumol/l) and SKF 38393 (0.1 mumol/l) provoked a rapid and reversible release of GH from superfused rat pituitary cells; this effect was markedly inhibited by simultaneous superfusion of SCH 23390 (1 mumol/l). These findings indicate that dopamine can stimulate basal GH release at the pituitary level and that this stimulation is mediated by D1 but not by D2 receptors. They also support the hypothesis that unidentified hypothalamic neurohormones may modulate this effect.     

Dopamine stimulates release of thyrotrophin-releasing hormone from perfused intact rat hypothalamus via hypothalamic D2-receptors

We have studied the effect of dopamine together with agonist and antagonist drugs of different specificities on the release of TRH from the perfused, intact hypothalamus of the adult rat in vitro. Dopamine produced a dose-related stimulatory effect on TRH release with maximal effect being achieved at 1 mumol/l (increase over basal, 118 +/- 16.5 (S.E.M.) fmol TRH; P less than 0.001 vs basal). This effect was mimicked by the specific D2-agonist drugs bromocriptine (0.1 mumol/l) and LY 171555 (0.1 mumol/l) (increase over basal values, 137.5 +/- 13.75 fmol and 158.6 +/- 10.7 fmol respectively; P less than 0.001 vs basal), but not by the D1-agonist SKF 38393A. The stimulatory effect of dopamine (1 mumol/l) was blocked in a stereospecific manner by the active (D) but not by the inactive (L) isomers of the dopamine antagonist butaclamol. Similar blockade was achieved with the specific D2-antagonist domperidone (0.01 mumol/l) whereas the D1-antagonist SCH 23390 was only effective when used at a concentration 100 times greater. Lower concentrations (0.01 mumol/l) of this D1-antagonist did not block the stimulatory effect of dopamine. High-performance liquid chromatography characterization of the material secreted within the hypothalamus showed one single peak of immunoreactive material which coeluted with synthetic TRH. These data suggest that dopamine exerts a stimulatory role in the control of hypothalamic TRH release by acting at specific D2-receptors.     

Effects of H2-receptor antagonists on prolactin secretion: specificity and mediation of the response

The effects on prolactin secretion of histamine H2-receptor antagonists infused intracerebroventricularly were studied in urethane anaesthetized male rats. A dose of 1.6 mumol cimetidine stimulated basal prolactin secretion and did not affect the histamine-induced release, whereas 0.4 mumol cimetidine inhibited basal and histamine-stimulated prolactin secretion. 0.1 mumol cimetidine had no effect. The more potent H2-receptor antagonist ranitidine at doses of 0.1, 0.4, 1.6 mumol had no effect on basal prolactin secretion, whereas 0.4 and 1.6 mumol inhibited the histamine-stimulated secretion completely. SKF-92408, a compound resembling cimetidine in chemical structure but devoid of H2-receptor antagonist activity, stimulated basal prolactin secretion at a dose of 1.6 mumol, but had no effect on the histamine-induced release or at a dose of 0.4 mumol. The H2-receptor antagonists metiamide and oxmetidine (1.6 mumol) stimulated basal prolactin secretion and did not prevent the response to histamine. A dose of 0.4 or 1.6 mumol imidazole (the ring structure contained in cimetidine, SKF-92408, metiamide, and oxmetidine) had no effect on basal or histamine-stimulated prolactin secretion. The findings indicate that cimetidine stimulates prolactin secretion by a non-specific action when infused centrally at high doses. In contrast, when infused at lower doses cimetidine inhibits the basal and histamine-stimulated secretion by blockade of H2-receptors. The prolactin-stimulatory action of cimetidine was not due to an H2-agonist effect, since ranitidine did not prevent the response. Cimetidine did not stimulate prolactin secretion via an effect on the dopaminergic system, since the drug had no effect on the dopamine concentration in hypophysial portal blood or in hypothalamic tissue and since inhibition of the dopamine synthesis by alpha-methyl-p-tyrosine did not prevent the cimetidine-induced prolactin release.     

Actions of dopamine on prolactin secretion and cyclic AMP metabolism in ovine pituitary cells

Prolactin secretion from cultured sheep pituitary cells was inhibited by low concentrations of dopamine (0.1 nM-0.1 microM) with a half-maximal effect at 3 nM. At a maximally effective dose (0.1 microM) dopamine significantly inhibited prolactin secretion within 5 min. with an 80% inhibition of basal secretion over 2 h. Basal prolactin secretion was stimulated by the addition of methylisobutylxanthine (MIX) (0.3-1.0 mM) and 8-bromo-cyclic AMP (2 mM), but cholera toxin (3 micrograms/ml) and prostaglandin E2 (0.1-1.0 microM), which also raised cellular cyclic AMP levels, had no effect on prolactin release. The inhibition of prolactin release by dopamine (0.1 microM) was not affected by any of these compounds. Dopamine inhibited MIX-induced cyclic AMP accumulation over a similar concentration range to the inhibition of secretion, but had no effect on the changes in cyclic AMP concentration produced by cholera toxin and prostaglandin E2. Overall the results with sheep pituitary cells suggest that lowered cyclic AMP levels do not mediate the inhibitory effects of dopamine on basal prolactin secretion, but that changes in cellular cyclic AMP levels may alter the secretion of this hormone, and dopamine may affect pituitary cell cyclic AMP concentrations in some circumstances.     

Dopamine and somatostatin inhibit forskolin-stimulated prolactin and growth hormone secretion but not stimulated cyclic AMP levels in sheep anterior pituitary cell cultures

Forskolin, an activator of adenylate cyclase, has been used to investigate the effects of raising pituitary cell cyclic AMP concentrations on prolactin and growth hormone secretion and to examine the role of cyclic AMP in the inhibitory actions of dopamine and somatostatin. Incubation of cultured ovine pituitary cells with forskolin (0.1-10 microM; 30 min) produced a modest dose-related increase in prolactin release (120-140% of basal) but a much greater stimulation of growth hormone secretion (170-420% of basal). Cellular cyclic AMP concentrations were only increased in the presence of 1 and 10 microM forskolin (2-5.5 times basal). A study of the time course for forskolin (10 microM) action showed that stimulation of prolactin (1.5-fold) and growth hormone (4.7-fold) secretion occurred over 15 min; subsequently (15-60 min) the rate of prolactin secretion from forskolin-treated cells was equivalent to that measured in controls, while growth hormone release remained elevated. Cellular cyclic AMP concentrations were also rapidly stimulated by forskolin (10 microM); they reached a maximum (12 times control) within 15 min, and then declined (15-60 min) but remained elevated relative to those in untreated cells (4.9 times control at 60 min). Dopamine (0.1 microM) inhibited basal secretion of both prolactin and growth hormone. In the presence of forskolin (0.1-10 microM), dopamine (0.1 microM) inhibited prolactin secretion to below the basal level and considerably attenuated the stimulation of growth hormone secretion. Similarly, somatostatin suppressed both basal and forskolin-induced prolactin and growth hormone secretion. However, neither dopamine nor somatostatin significantly decreased the stimulatory effect of forskolin on cellular cyclic AMP accumulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of dopamine and morphine on immunoreactive somatostatin and LH-releasing hormone secretion from hypothalamic fragments in vitro

Dopamine and morphine modulate GH and LH release, probably at a hypothalamic locus. To investigate this in more detail, we studied the influence of these substances on somatostatin and LH-releasing hormone (LHRH) release from rat hypothalamic fragments in vitro. Hypothalamic fragments were incubated in Earle's medium. After 60 min of preincubation, medium from two 20-min incubations was collected and somatostatin and LHRH levels measured by radioimmunoassay. Dopamine (10 nmol/1-0.1 mmol/l) induced a progressive increase (r = 0.41; P less than 0.01) in basal somatostatin levels. K+ (30 mmol/l)-induced somatostatin release was also increased (r = 0.54; P less than 0.01) by increasing doses of dopamine. Metoclopramide (10 mumol/l) blocked the dopamine (1 mumol/l)-induced increase in somatostatin release. No significant relationship between dopamine and LHRH was found either basally or after K+ (30 mmol/l) stimulation. Basal somatostatin was negatively correlated (r = -0.63; P less than 0.01) with morphine concentrations. No significant correlation was found after K+ (30 mmol/l) depolarization. Basal LHRH release was not influenced by morphine, while K+ (30 mmol/l)-induced release was significantly lower than controls only at a concentration of 10 nmol/l. These results suggest that dopamine and morphine act at a hypothalamic level to modulate GH release through alterations in somatostatin secretion. Dopamine and morphine have no consistent effect on hypothalamic LHRH release.     

Failure of dopamine and bromocriptine to affect prolactin release and cell growth in the dopamine receptor-deficient 235-1 clone

The 235-1 clone was recently derived from the 7315a transplantable pituitary tumor and continues to secrete rat prolactin. The cells have a prominent Golgi apparatus which can be stained immunocytochemically for prolactin, but there were no 600–900 nm granules which are characteristic of normal mammotrophs. In a perfused cell-column apparatus, prolactin release from the clone was unchanged by dopaminergic agonists, thyrotropin-releasing hormone and estradiol but stimulated by dibutyryl cyclic AMP. Cellular cyclic AMP content was also not changed by dopamine but was dramatically enhanced by prostaglandin E₁, indicating that at least one hormone-adenylate cyclase coupling mechanism was functional. In radioligand binding studies using the dopamine antagonist [³H]spiperone, no evidence of a dopamine receptor was obtained. The [³H]spiperone binding present was not stereoselective, and exceedingly high concentrations of other ligands were required to displace the binding. In addition, the induction of a prolactin-secreting hard tumor in rats by subcutaneous innoculation of the 235-1 cells failed to induce measurable dopamine receptors associated with the tumor cells.In order to address the possibility that there were functional dopamine receptors on these cells, but that they could not be resolved with either the cell column and cyclic AMP studies or the radioreceptor assay, the clone cells were incubated with 0.1–100 nM bromocriptine for up to 8 days. Bromocriptine had no effect on the growth rate or prolactin secretion of the 235-1 clone but inhibited prolactin release from anterior pituitary cells by over 73% in control studies.We conclude that the 235-1 clone does not express dopamine receptors and that the presence of dopamine receptors is obligatory for the typical inhibitory effects of bromocriptine on prolactin release and pituitary cell growth.     

Effect of thyrotropin-releasing hormone and dopamine on the in vitro secretion of prolactin by the bullfrog pituitary gland

Pituitary glands of bullfrogs (Rana catesbeiana) were incubated in medium containing thyrotropin-releasing hormone (TRH) and/or dopamine in order to see their effects on the release and synthesis of prolactin, which was measured by a homologous radioimmunoassay. Prolactin synthesis was measured by monitoring the incorporation of [3H]leucine into prolactin. TRH (0.1-10 ng/ml) stimulated the release of immunoassayable prolactin and newly synthesized [3H]prolactin into the medium in a dose-dependent manner; however, it was ineffective in increasing total prolactin (medium plus pituitary) and the incorporation of [3H]leucine into the total prolactin during the experimental period (20 hr). The TRH-induced elevation of prolactin release was suppressed by the addition of dopamine (5 X 10(-7) M) to the medium.     

Pituitary gonadotrophin-releasing hormone receptor up-regulation in vitro: dependence on calcium and microtubule function

Exogenous cyclic adenosine nucleotides increase gonadotrophin-releasing hormone (GnRH) receptors in intact cultured rat pituitary cells in a similar manner to that observed with GnRH itself. In this study the calcium and microtubule dependency of GnRH receptor up-regulation was examined in vitro. Treatment of pituitary cells in Ca2+ and serum-containing media with either GnRH (1 nmol/l), K+ (58 mmol/l) or dibutyryl cyclic AMP (dbcAMP; 1 mmol/l) for 7-10 h routinely resulted in a 50-100% increase in GnRH receptors. Incubation of pituitary cells with the calcium channel blocker verapamil, for 7 h, or the calcium chelator EGTA, for 10 h, had no effect on basal receptor levels but prevented the increase in GnRH receptors stimulated by either GnRH, K+ or dbcAMP. Luteinizing hormone release measured with the same stimulators over a 3-h period was prevented by both verapamil and EGTA. Calcium ionophore (A23187) increased GnRH receptors by 40-60% at low concentrations (10 and 100 nmol/l) while higher concentrations (10 and 100 mumol/l) reduced receptor levels. Luteinizing hormone release was not increased by receptor-stimulating concentrations of A23187, but was by higher concentrations (10 mumol/l). None of these pretreatments, for up to 10 h, impaired the subsequent LH response of the cells to increasing doses of GnRH. Vinblastine (1 mumol/l did not affect basal receptor levels but markedly reduced the increase in GnRH receptors stimulated by GnRH, K+ and dbcAMP. This concentration of vinblastine had no effect on LH release.(ABSTRACT TRUNCATED AT 250 WORDS)     

HUMAN FETAL HYPOTHALAMIC GnRH NEUROSECRETION: DOPAMINERGIC REGULATION IN VITRO

An in-vitro perifusion system was used to investigate GnRH release from fetal (21-23 weeks gestation) human hypothalami in response to dopamine (DA) and the DA receptor antagonist haloperidol. Administration of 1 mumol/l DA during five perifusions in which 1 mumol/l haloperidol was added to the medium failed to alter basal GnRH release. In contrast DA evoked a rapid and sustained 95.8 +/- 20.3% increase (P less than 0.01) in GnRH release during five matching perifusions with medium containing the alpha-adrenergic antagonist phentolamine. While exposure to 0.01 mumol/l DA failed to alter basal GnRH release during three perifusions, 0.1 mumol/l DA elicited a 145.7 +/- 65.2% increase (P less than 0.05) in GnRH release in three matching perifusions, indicating a dose-dependent effect. These studies demonstrate that DA can stimulate in-vitro release of GnRH from the mid-gestation fetal human hypothalamus by a DA receptor mediated mechanism.     

Effect of serotonin on basal and TRH-induced release of prolactin from rat pituitary glands in vitro

The effect of serotonin on the release of prolactin (PRL) was studied in vitro. Anterior hemipituitary glands from ovariectomized rats were incubated for 1 h in the presence of different doses of serotonin. Serotonin added into the culture medium caused a significant increase in basal PRL release. The effect was dose-related between 10 and 30 nmol/l serotonin, but responsiveness declined towards basal levels with higher concentrations. When studied as a function of incubation time, basal release of PRL was significantly increased up to 1 h but decreased thereafter. Serotonin also enhanced the release of prolactin induced by 30 nmol/l thyrotropin-releasing hormone (TRH), at all doses tested. A serotonin concentration of as little as 30 nmol/l was already effective. A significant response was seen at 15 min and further increases occurred during the following incubation periods. Serotonin (approximately EC50 4.6 X 10(-8) mol/l) was less potent than TRH (EC50 about 1.2 X 10(-8) mol/l) to increase basal PRL release. On the other hand, the indole amine appeared to act with similar potency in stimulating PRL release both basal and TRH-induced. In addition, the combined effect of the releasing agents was found to be additive. These results suggest that serotonin and TRH could act through separate mechanisms. Methysergide, a serotoninergic blocking agent, had no effect on the in vitro PRL release either basal or TRH-induced, but it completely blocked that evoked by serotonin suggesting that serotonin may interact with specific receptors on the lactotropes. These findings clearly demonstrate that serotonin may stimulate the release of PRL by acting directly at the pituitary gland level.     

Effects of suramin on hormone release by cultured rat anterior pituitary cells

Suramin is a polyanionic compound which has been used in the treatment of trypanosomiasis and acquired immunodeficiency syndrome (AIDS), while preliminary success has been reported in the treatment of cancer. However, suramin also causes adrenal insufficiency. We have previously reported that suramin selectively inhibited corticotropin (ACTH)-stimulated corticosterone release by dispersed adrenal cells in a dose-dependent manner via a direct interaction with the ACTH molecule. The present study was undertaken in order to investigate the effect of suramin on hormone release by dispersed rat anterior pituitary cells. Suramin at a concentration of 100 microM inhibited both basal and secretagogue-stimulated ACTH release by cells cultured in minimal essential medium (MEM) only, while it had no effect on ACTH release by cells cultured in MEM + 10% fetal calf serum (FCS) or MEM + 0.1% bovine serum albumin (BSA). In addition, suramin also caused a parallel decrease of prolactin (PRL) and growth hormone (GH) release by cells cultured in MEM only, suggesting a toxic, rather than a selective effect of suramin on anterior pituitary cells cultured in MEM only. In addition, suramin potentiated the effect of thyrotropin-releasing hormone (TRH) on PRL release by cells cultured in MEM + 10% FCS and suppressed the inhibitory effect of dopamine (DA) on PRL release by cells cultured in MEM + 10% FCS and in MEM + 0.1% BSA. Comparable suppressive effects of suramin on growth hormone-releasing hormone (GHRH)-stimulated and somatostatin (SRIH)-inhibited GH release were found in cells cultured in MEM + 0.1% BSA but not in cells cultured in MEM + 10% FCS.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence that serotonin is involved in prolactin release by electrical stimulation of the medial basal hypothalamus in the rhesus monkey

The possibility that serotonin plays a role in prolactin secretion after electrical stimulation of the rhesus medial basal hypothalamus (MBH) was investigated. Prolactin responses to electrical stimulation and intravenous injection of 0.5 and 1.0 micrograms of thyrotropin-releasing hormone (TRH) were evaluated before and after administration of methysergide (MES), a serotonin receptor blocker (2 mg orally every 12 h for 48 h), and bromocriptine (CB-154), a dopamine agonist (2.5 mg orally every 12 h for 48 h). Both electrical stimulation and TRH caused prompt increases in serum prolactin. Prestimulation (basal) prolactin levels in both drug-treated groups were not significantly lower than basal levels in control groups. Pretreatment with MES significantly attenuated the electrically induced release of prolactin but had no effect on the TRH-induced release; CB-154 blocked prolactin release induced by both types of stimulation. The study reported here has provided evidence of a possible role for hypothalamic serotinin in releasing pituitary prolactin.     

Effects of trifluoperazine on prolactin release and cyclic AMP formation and degradation in GH4C1 pituitary cells

In GH4C1 cells, the calmodulin antagonist trifluoperazine (TFP) showed a dose-dependent, biphasic effect on the basal release of PRL. An inhibition of PRL release was observed with 15-50 mumol/l TFP, whereas a concentration of 100 mumol/l and above had a stimulatory effect. The increase in basal hormone release evoked by TRH (1 mumol/l) and high extracellular concentration of K+ (50 mmol/l) was eliminated by 30 mumol/l TFP. The stimulatory effect of 100 mumol/l TFP on basal hormone release was not affected by addition of TRH (1 mumol/l) or K+ (50 mmol/l). The Ca2+ antagonists Co2+ (5 mmol/l) and verapamil (100 mumol/l), and the Ca2+ chelator EgTA (4 mmol/l) abolished the stimulatory effect of TRH (1 mumol/l) and of K+ (50 mmol/l) on PRL release, whereas only Co2+ inhibited the stimulation caused by 100 mumol/l TFP. TFP (75 mumol/l) caused a transient increase in the concentration of cellular cAMP. Incubation of intact GH4C1 cells with TFP (75 mumol/l), had an inhibitory effect on both the low and the high affinity form of cAMP phosphodiesterase. Basal as well as TRH-stimulated adenyl cyclase activity were inhibited by TFP, and this effect was counteracted by addition of calmodulin.