Effects of 17 beta-estradiol on angiotensin II receptors and prolactin release in cultured pituitary cells

Angiotensin II (AII) binds to specific receptors in the lactotroph and stimulates PRL secretion from isolated rat pituitary cells. Since estrogens exert major regulatory actions on PRL secretion, the effects of estradiol (E2) on pituitary AII receptors and PRL responses were studied in vivo and in cultured rat anterior pituitary cells. In female rats, treatment with E2-containing Silastic capsules for 4 days caused a significant increase in PRA from 1.3 to 3 ng/ml X min and a 38% decrease in the binding of [125I]AII to anterior pituitary membrane-rich fractions (P less than 0.01). In vitro studies showed that treatment of cultured anterior pituitary cells with 1 nM E2 for 4 days caused a 57 +/- 6% decrease in AII receptor concentration with no change in binding affinity. Reduction of AII receptors by E2 in 4-day cultures was dose dependent and was demonstrable with E2 concentrations that occur in plasma during the estrous cycle (0.01-1 nM). The decrease in AII receptors in cells incubated with 1 nM E2 was near maximum after 24 h of culture, and results were similar when receptor concentrations were calculated per unit protein or per cell. Despite the substantial decrease in AII receptors, E2 treatment did not specifically decrease the responsiveness of the pituitary cells to AII stimulation. Thus, PRL responses to AII (10 nM) or TRH (100 nM) were unchanged after 1 day of E2 treatment and were increased after 4 days of treatment. These findings demonstrate that E2 has a direct inhibitory action on expression of pituitary AII receptors that is not accompanied by a decrease in AII-stimulated PRL secretion. In the rat pituitary, estrogen modulation of postreceptor events is the predominant determinant of lactotroph responsiveness during stimulation of PRL release by AII.     

Bradykinin parallels thyrotropin-releasing hormone actions on prolactin release from rat anterior pituitary cells

Bradykinin (BK), a nonapeptide, originally discovered in blood, is also present in neurons and fibers of the hypothalamus. We tested the putative releasing factor properties of BK on prolactin (PRL) release from anterior pituitary cells in vitro. BK stimulated the release of PRL in a dose-dependent manner, the threshold concentration being in the range. 0.1-1.0 nM. The release of PRL induced by BK at 1 nM concentration was about 2-fold, delayed and sustained over many minutes. Higher concentrations of BK stimulated PRL release in two phases. The shape of the BK-induced PRL release was superficially similar to that induced by thyrotropin-releasing hormone (TRH). 10 nM BK and 10 nM TRH induced about a 4-fold increase in PRL release within 5 min, followed by a gradual recovery to basal secretion. These results indicate that this peptide can act directly at the anterior pituitary gland to release PRL. Phorbol ester also promoted PRL release over the range of 1-10 nM, but the time course of the release was somewhat different.     

Dopamine inhibits prolactin release when cyclic adenosine 3',5'-monophosphate levels are elevated

We purified lactotrophs from pituitary tumors induced by estrogen in ovariectomized female Fischer 344 rats from 80% of the population before to more than 90% after purification through a continuous Percoll density gradient. The percentage of lactotrophs was evaluated by immunofluorescence. The patterns of PRL release stimulated by 100 nM TRH, 20 microM A23187 (a Ca++ ionophore), 50 nM 12-O-tetradecanoyl-phorbol-13-acetate (a C-kinase activator), or combinations of these agents, or inhibited by 10 microM dopamine were similar in perifused primary cultures of tumor lactotrophs to patterns in cultures of anterior pituitary cells from female retired breeders used previously. In particular, dopamine completely inhibited the release stimulated by forskolin. Intracellular cAMP concentrations and PRL accumulation in the medium were measured in monolayer cultures of purified tumor lactotrophs. In 9 separate experiments, forskolin (10 microM) increased intracellular cAMP concentrations more than 60-fold above control after 30 min of incubation. Preincubation (30 min) with dopamine (10 microM) reduced the cAMP accumulation caused by forskolin, but levels were still at least 20-fold above basal levels in most experiments. PRL release was stimulated 2-fold with forskolin alone, but there was no stimulation of PRL release by forskolin in the presence of dopamine even though cAMP levels were elevated above basal. Therefore, a decrease in cAMP levels is not necessary to inhibit PRL release, and dopamine must have a mechanism for inhibiting PRL release in addition to inhibiting adenylate cyclase.     

Calcitonin inhibits basal and thyrotropin-releasing hormone-induced release of prolactin from anterior pituitary cells: evidence for a selective action exerted proximal to secretagogue-induced increases in cytosolic Ca2+

Salmon calcitonin (sCT)-like peptide is present in the central nervous system and pituitary gland of the rat, and this peptide inhibits basal and TRH-stimulated PRL release from cultured rat anterior pituitary (AP) cells. The present studies were designed to examine further the inhibitory actions of sCT on basal and TRH-stimulated PRL release and investigated 1) the temporal dynamics of the responses, 2) the effects of sCT on PRL release induced by other secretogogues, and particularly those acting via elevations of cytosolic Ca2+, and 3) the selectivity of sCT action on basal and stimulated AP hormone release. The inhibition of basal PRL release by sCT (0.1-10 nM) was dose-dependent and was characterized by a rapid onset with a gradual recovery to normal rates of release after the period of sCT inhibition. The inhibitory effect of sCT on basal PRL release was reversed by treatment with either the Ca2+ ionophore A23187 or with the phorbol ester, phorbol myristate acetate (PMA). sCT infusion did not affect the basal release of GH, TSH, FSH, or LH by perifused AP cells. When administered in short pulses, TRH, at concentrations from 1-100 nM, elicited a dose-dependent increase in PRL release. When coadministered with short 10 nM TRH, sCT (1-100 nM) inhibited TRH-induced PRL release in a dose-dependent manner, with a maximal inhibition of 78% at a concentration of 10 nM, and an ED50 concentration of approximately 3 nM. During longer (30 min) pulses of TRH (100 nM), PRL release increased sharply over 4-fold within 2 min, followed within 12 min by a rapid decline to a level 1.5-2-fold higher than basal, and this level was maintained for the remainder of the stimulation period. sCT pretreatment inhibited the overall PRL response to TRH. In contrast to its inhibition of TRH-induced PRL release, sCT failed to prevent the stimulation of PRL release by either ionophore A23187, PMA, vasoactive intestinal peptide, or forskolin. In addition, sCT failed to block TRH-induced TSH release or GnRH-induced LH release.(ABSTRACT TRUNCATED AT 400 WORDS)     

Lactotrophs secreting small amounts of prolactin reveal great responsiveness to thyrotropin-releasing hormone: analysis by the sequential cell immunoblot assay.

The effects of TRH on PRL secretion from individual lactotrophs of female rats were investigated by using a sequential cell immunoblot assay. The same pituitary cells cultured on coverslips were first incubated to determine basal secretion of PRL and subsequently challenged by one of various concentrations of TRH. The PRL secreted from the single lactotrophs was absorbed on protein-blotting transfer membranes, immunostained, and quantified by microscopic image analysis. When no TRH was added to the medium used in the second incubation (controls), the amount of PRL secreted from individual lactotrophs was 93% of that secreted in the first incubation. Treatment with 3 x 10(-10)-10(-7) M TRH in the second incubation increased in a dose-dependent manner the proportion of lactotrophs whose PRL secretion was significantly greater than confidence limits for PRL secretion in the controls. However, the percentage of TRH-responsive lactotrophs remained less than 50% even at a maximally effective concentration of TRH. Proportions of the TRH-responsive lactotrophs were significantly greater in cells that secreted small amounts of PRL under basal conditions than in those that secreted large amounts. Furthermore, the small, but not the large, secretors showed a significant increase in mean absolute amounts of PRL secreted by 10(-7) M TRH, which represented no less than 45% of all PRL secreted from the lactotroph population by the TRH treatment. These results indicate that 1) there is a heterogeneity with respect to lactotroph responsiveness to TRH and that 2) a population of lactotrophs that secrete small amounts of PRL under basal conditions contains a much larger proportion of TRH-responsive lactotrophs than does a population of lactotrophs that secrete large amounts of PRL.     

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.     

Galanin secretion from anterior pituitary cells in vitro is regulated by dopamine, somatostatin, and thyrotropin-releasing hormone.

Lactotrophs, somatotrophs, and thyrotrophs have been shown to contain immunoreactive galanin. Furthermore, estrogen stimulates galanin mRNA and peptide levels in the rat anterior pituitary, particularly within lactotrophs. To determine whether galanin is released from the anterior pituitary in a regulated manner, we used cultured pituitary cells from male and ovariectomized Fischer 344 rats implanted with estrogen-containing capsules. Anterior pituitary cells (5 x 10(5) cells/well) were challenged (0.5-3 h) with hypothalamic factors known to regulate anterior pituitary hormone secretion, and medium galanin levels were measured by RIA. In female pituitary cells, galanin secretion was inhibited by dopamine (10 and 100 nM) and stimulated by TRH (20 and 100 nM). Although galanin release was significantly lower in male pituitary cells, dopamine and TRH inhibited and stimulated galanin secretion, respectively. Medium galanin levels were also significantly reduced by somatostatin (5 nM) in both female and male cells. The pattern of PRL release in response to dopamine, TRH, and somatostatin was similar to that observed for galanin, regardless of the sex of the pituitary donor. Although galanin has been localized in somatotrophs, 5 nM GH-releasing hormone (GRF) failed to alter galanin release in male as well as female pituitary cells; GH secretion was significantly increased by GRF. LHRH (5 nM) and CRF (5 nM) failed to alter galanin release in vitro. We conclude that in estrogen-exposed pituitary cells obtained from male and ovariectomized Fischer 344 rats: 1) galanin secretion is inhibited by dopamine and somatostatin, and stimulated by TRH; 2) GRF, LHRH, and CRF do not regulate galanin release in these cells; and 3) the profile of the regulated pathway for galanin release suggests that the primary location of galanin is the lactotroph, probably within secretory granules.     

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.     

Pharmacological characterization of the angiotensin receptor negatively coupled with adenylate cyclase in rat anterior pituitary gland

Angiotensin II (AII) inhibited anterior pituitary adenylate cyclase. Whereas GTP was necessary to fully express the AII inhibitory effect, Na+ was not required. The magnitude of inhibition (42 +/- 6%) permitted a pharmacological characterization of the AII receptor involved in adenylate cyclase inhibition. Angiotensin I (AI) was less potent than AII, and deletion of aminoacids in the N-terminal position resulted in a progressive reduction of the Ki (peptide concentration producing half-maximal inhibition). The Ki values were 3 +/- 0.9, 10, and 700 nM for AII, angiotensin III (AIII), and des-Asp, des-Arg-AII, respectively. Sarcosine in position 1 [( Sar, Phe]AII) increased the potency of inhibition (Ki = 0.12 +/- 0.12 nM). Different antagonists of the AII receptors appeared to be partial agonists. There was a very close correlation (r = 0.98) between the respective potencies of a series of AII analogs to inhibit adenylate cyclase and the potencies of these analogs to elicit PRL or ACTH release or to bind to AII-binding sites. Dopamine and AII inhibition of anterior pituitary adenylate cyclase were not additive. This suggests that both receptors are on the same cell and likely on lactotrophs. This hypothesis agrees with the observation that vasoactive intestinal peptide stimulation of adenylate cyclase was inhibited by AII, whereas corticotropin-releasing factor stimulation was unaffected. Although dopamine and AII inhibited the same adenylate cyclase, they had opposing effects on PRL release (inhibition and stimulation, respectively). The possible significance of this observation is related to a model implying that PRL release can be elicited through either a Ca+2 or a cAMP pathway.     

Corticotropin-releasing activity of the renin-angiotensin system peptides in rat and in man

In this study we investigated in the rat the binding and corticotropin-releasing factor (CRF) activity of various constituents of the renin-angiotensin system and the possible angiotensin II receptor changes following procedures known to alter plasma renin activity. We investigated also the CRF activity of angiotensin II in vitro and in vivo in humans. The CRF activity of peptides was studied by their ability to stimulate ACTH release from pituitary cells. Deleting amino acids from the N-terminus of angiotensin II resulted in decreased CRF activity; while the ED50 for angiotensin II was 2 nM, it increased to about 10 nM for the (2-8)-heptapeptide. Angiotensin I had a weak CRF activity, whereas the substrate angiotensinogen had no stimulatory effect even at a concentration of 100 nM. There was a strong correlation between the activation and binding properties of all peptides tested. Dietary salt load or depletion as well as dexamethasone treatment did not affect the number nor the affinity of pituitary angiotensin II receptors. Angiotensin II had a CRF activity on human pituitary cells in vitro. However, peripherally injected agiotensin II at a pressive dose of 7 ng/kg/min did not produce any ACTH release in normal male volunteers. These data suggest that angiotensin II may play a modulatory role in the physiological regulation of ACTH secretion, but this role might be attributed to the endogenous brain angiotensin II as it is not closely dependent on the angiotensin II plasma levels.     

Angiotensin peptides stimulate phosphoinositide breakdown and prolactin release in anterior pituitary cells in culture

We investigated the effects of angiotensin peptides on the breakdown of specific membrane phospholipids, the inositol lipids, in anterior pituitary cells in culture, measuring the water-soluble products (inositol phosphates) produced during the cleavage of phosphoinositides by phospholipase C. Both angiotensin II and angiotensin I in the presence of 10 mM LiCl potently increased, in a concentration-dependent manner, total [3H]inositol phosphate and PRL release in cultured rat anterior pituitary cells. The release of LH, TSH, or GH was not significantly enhanced by the peptides. The effect on inositol phosphate accumulation was significant at 0.01 nM, and maximal stimulation (approximately 5-fold increase) occurred at 10 nM, with an ED50 of about 0.3 nM. The stimulatory effects of both angiotensin II and angiotensin I were antagonized by the receptor antagonists saralasin and Sar1,Ile8-angiotensin II. Moreover, 1 microM captopril, an inhibitor of angiotensin-converting enzyme, antagonized the effects of 0.1 and 1 nM angiotensin I, suggesting that the effect of angiotensin I on phosphoinositide breakdown and PRL release is dependent on prior conversion of angiotensin I to angiotensin II. The effect of angiotensin II was very rapid. Fractionation of the water-soluble inositol phosphates showed that angiotensin II significantly increased inositol bisphosphate and inositol triphosphate at 10 sec, whereas inositol monophosphate was increased only after 40 sec. These data indicate that in the pituitary, and presumably in the lactotroph, the binding of angiotensin II to specific membrane receptors provokes increased polyphosphoinositide hydrolysis, leading to increased production of intracellular messengers, i.e. inositol triphosphate and 1,2-diacylglycerol, responsible for the stimulation of PRL release.     

Thyrotropin-releasing hormone rapidly stimulates a biphasic secretion of prolactin and growth hormone in GH4C1 rat pituitary tumor cells

The characteristics of TRH-induced acute PRL and GH secretion were studied in GH4C1 cells, a clonal rat anterior pituitary tumor cell line which secretes PRL and GH. The experiments were carried out both in a flow system in which microcarrier (Cytodex)-attached cells were perifused at a constant rate and in a conventional static culture system. In both systems, cells responded to TRH in a qualitatively similar manner. TRH significantly stimulated PRL and GH secretion within 5 sec without a detectable lag period. The secretion rate was highest during the initial 1 min, declined sharply thereafter despite the continuous presence of TRH, and plateaued at a lower level. The maximum dose of TRH caused 250-700% of basal secretion during the early period (approximately 8 min; first phase) and about 150% of basal secretion thereafter (second phase). The sustained lower secretion (second phase) was maintained as long as cells were exposed to TRH (up to 2.5 h), and the secretion rate returned to the basal level within 30 min of removal of TRH from the medium. The half-maximal doses for the first and second phase secretion were 2-3 and 0.5-1 nM, respectively, in both the perifusion and static culture systems. Over a 2-day period, TRH stimulated PRL synthesis and inhibited GH synthesis. The dose-response curves for these long term effects on hormone synthesis were similar to the dose-response curves for the first phase of release. [N3-methyl-His2]TRH gave similar results, but was more potent than TRH. [N3-methyl-His2]TRH stimulated first phase release with an ED50 of 0.4-0.8 nM, second phase release with an ED50 of 0.1-0.2 nM, and hormone synthesis with an ED50 of 0.7-0.8 nM. Preincubation of the cells with Ca+2-free medium significantly depressed both first and second phase secretion. Preexposure of the cells to cycloheximide (10 micrograms/ml) had little effect on the first phase of secretion, but reduced second phase secretion. The acute effects of TRH on GH and PRL were identical, except that the secretory response tended to be greater for PRL. We conclude that 1) TRH causes hormone secretion very rapidly in a biphasic manner; 2) the first phase of secretion consists primarily of the release of stored hormone, whereas the second phase includes the release of newly synthesized hormone; 3) the dose-response curve of second phase secretion is shifted to the left compared with that of first phase secretion; and 4) both phases of secretion are at least partially dependent on extracellular Ca+2.     

Basal and dopamine-inhibited prolactin secretion by rat anterior pituitary cells: effects of culture conditions

Culture conditions for rat pituitary cells were investigated which would result in high PRL synthesis and secretion with maintenance of dopamine-mediated inhibition of PRL secretion. From five commercially available media, RPMI resulted in the highest PRL content and secretion, but no inhibition of PRL secretion by dopamine was observed. MEM with Earle's salts fulfilled best our requirements for culturing functional PRL-secreting cells. PRL secretion was not affected by variations in the concentration of fetal calf serum, but was positively correlated with increasing horse serum concentrations. TRH-induced PRL release increased with increasing serum concentrations and was positively correlated with the concentration of 17 beta-estradiol in the culture medium (P less than 0.0025). An increase in the sodium bicarbonate concentration from 0.85 to 3.0 g/l resulted in a 4-fold stimulation of PRL synthesis and in a 27-fold stimulation of PRL secretion. However, at bicarbonate concentrations above 2.6 g/l, inhibition of PRL secretion by 500 nM dopamine was lost. The addition of 20 mM Hepes to the culture medium decreased basal PRL secretion by 48 +/- 13% (P less than 0.01), while dopamine inhibition of PRL secretion was reduced from 49 +/- 10% to 24 +/- 8% (P less than 0.05). When an increasing number of pituitary cells was cultured in a constant volume, PRL secretion expressed per cell increased up to 0.3-0.4 X 10(6) cells/dish/2 ml. With higher cell concentrations of up to 1 X 10(6) cells/dish, PRL secretion per cell diminished significantly, which indicates a direct negative feedback of high medium PRL on the PRL-secreting pituitary cells. In this culture system dopamine inhibited PRL secretion over a 4 h period in a dose-dependent manner (IC50 20 nM), while no paradoxical stimulation of PRL secretion was observed with low dopamine concentrations. However, a 25% stimulation (P less than 0.05) of PRL secretion by 0.1 nM dopamine could be obtained by addition of 0.01% ascorbic acid, which by itself decreased basal PRL secretion by 49% (P less than 0.01). Thus, tissue culture conditions that result in high PRL production are not necessarily the best choice, since dopamine-mediated inhibition of PRL secretion is another important parameter for the functioning of lactotrophs in culture. The best compromise is MEM with 2.2 g/l of sodium bicarbonate, without Hepes buffer and supplemented with 10% FCS.     

Effect of the circulating renin-angiotensin system on prolactin release in humans

We recently reported that renin, angiotensinogen, and angiotensin-converting enzyme were present in normal human pituitary lactotroph cells and PRL-secreting adenomas. Angiotensin-II and -III have also been shown to modulate PRL release in vitro. The present study was designed to determine whether angiotensin modulates PRL secretion in vivo. In 36 hypertensive patients with widely varying renin levels, active renin and basal PRL levels did not correlate. In 10 normal volunteers, both a sustained infusion of angiotensin-II and a graded infusion of angiotensin-III induced a 2- to 3-fold increase in aldosterone levels, but had no effect on PRL secretion. Administration of the angiotensin-converting enzyme inhibitor captopril had no effect on PRL circadian rhythm in 10 normal subjects or on PRL concentrations in 11 patients with PRL-secreting adenomas. Cross-over administration of placebo and captopril did not affect the peak PRL level measured after TRH treatment in 10 hypertensive men (placebo, 43.1 +/- 5.4; captopril, 40.0 +/- 6.2 micrograms/L; P = NS) or the rise in PRL induced by doperidone in 6 normal women (placebo, 129.5 +/- 16.2; captopril, 150.0 +/- 35.7 micrograms/L; P = NS). Further, administration of enalapril for 30 days to 6 hypertensive patients did not alter basal PRL concentrations or the peak concentrations induced by TRH. These data indicate that in humans the circulating renin-angiotensin system does not interact with diurnal PRL release or with the response to TRH or domperidone.     

The dynamics of arachidonic acid liberation and prolactin release: a comparison of thyrotropin-releasing hormone, angiotensin II, and neurotensin stimulation in perifused rat anterior pituitary cells

The dynamics of arachidonic acid (AA) liberation and PRL release were highly correlated in perifused rat anterior pituitary cells during stimulation by three different neuropeptides: TRH, angiotensin II (AII), and neurotensin (NT). After preincubation of these cells with 1 microCi [3H]AA, a 20-min perifusion with AII (100 nM), TRH (100 nM), or NT (1 microM) elicited a sharp initial increase in PRL release and [3H]AA efflux, which rapidly subsided (within 6 min) to less elevated levels of PRL release and AA liberation. The plateau responses were sustained throughout the remainder of the 20-min treatment period; after the cessation of neuropeptide perifusion, the responses rapidly returned to basal levels. AII and TRH elicited a greater initial stimulation of PRL release and AA liberation, whereas NT resulted in less pronounced initial responses and a greater plateau of sustained PRL release and AA liberation. Dopamine (DA; 500 nM) or calcium-depleted medium (containing 60 microM EGTA) evenly attenuated the stimulation of PRL release throughout exposure to the neuropeptides; however, the initial stimulation of AA efflux by AII and TRH was relatively resistant to inhibition by DA or calcium-depleted medium. In contrast, the stimulation of AA liberation by NT was abolished by DA or calcium-dependent medium. These results establish that the time course of AA liberation is complimentary to that of PRL release during stimulation by AII, TRH, and NT and support a possible role for AA liberation and metabolism as one of the mechanisms that participates in the regulation of PRL release. A lesser ability of NT to elicit functional and biochemical responses to intracellular calcium mobilization is postulated as an explanation for the observed differences among AII, TRH, and NT effects on PRL release and AA liberation.     

Estrogens directly down-regulate receptors for angiotensin II in anterior pituitary cell culture without decreasing target cell responsiveness

Chronic estradiol treatment in vivo has been shown to reduce the density of receptors for angiotensin II (ANG II) in the anterior pituitary lobe (AP). We studied whether estradiol is directly involved in the down-regulation of ANG II receptors, using AP cells in culture. Binding affinity and density of ANG II receptors were measured in disrupted AP cells with the radiolabeled antagonist [125I]Sar1, Ile8-ANG II ([125I]SARILE). Estradiol treatment (10 nM) for either 48 or 96 h caused a marked reduction (approximately 70%) in the density of receptors for ANG II in cultured AP cells, with no change in the dissociation constant of [125I]SARILE (Kd, 0.5 +/- (SE) 0.1 nM). In the AP, specific binding sites for ANG II are present in lactotrophs and ANG II has been shown to release prolactin (PRL). In AP cells treated with estradiol for 48 h, dose-response curves revealed that ANG II still increased PRL release (P less than 0.01). The average net PRL release (ANG II-stimulated minus basal) was greater in estradiol-treated cells than in controls, whereas the half-maximal stimulation dose (ED50) of ANG II was the same (0.07 +/- 0.04 nM). These results suggest that estrogens are directly involved in the modulation of ANG II receptors in the AP, causing marked receptor down-regulation without decreasing target cell responsiveness.     

Preparation of thyrotroph cells from adult male rat pituitary glands by centrifugal elutriation

To study the metabolism of thyrotrophs and dynamics of TSH secretion in vitro, it is desirable to have a highly enriched population of thyrotrophs. For that purpose, centrifugal elutriation, a recently developed cell isolation method based on the size and density of cells, was used to prepare thyrotrophs from a cell suspension of adult male rat pituitary cells. Trypsin-dispersed cells (4-8 X 10(7] were loaded into the elutriation rotor (Beckman, JE-6) operating at 2800 rpm. Twelve cell fractions were collected at variable rotor speed (2000-2800 rpm) and increasing medium flow rate (10-103 ml/min). Cell recovery was 77-98%. The viability of the cells after elutriation was 90-95% based on trypan blue exclusion. Each fraction was analyzed for TSH, GH, and PRL content and for TRH-stimulated TSH release by RIA. Thyrotrophs were found predominantly in fractions 8-11 (flow rate 38-75 ml/min) based on TSH RIA. The mean TSH concentration in these fractions was 56 +/- 13.6 (+/- SD) microU/10(3) cells compared with 7.6 +/- 3.8 microU/10(3) cells in the initial cell suspension, representing a 7- to 8-fold enrichment of the thyrotrophs. Incubation with 20 nM TRH for 3 h increased the TSH release of cells eluted in fractions 8-11 by 3- to 5-fold; there was no significant increase in TSH release in fractions 3-6. Centrifugal elutriation may be used to prepare a uniform highly enriched thyrotroph fraction with excellent recovery from a suspension of rat pituitary cells. This technique should be valuable for study of the metabolism of thyrotrophs.     

Transient dopamine withdrawal differentially potentiates thyrotropin releasing hormone-induced release of prolactin of various ages

Transient removal of dopamine (DA) potentiates the prolactin (PRL) releasing action of thyrotropin releasing hormone (TRH) in cultured lactotrophs. We have determined if this potentiating action on PRL release is related to the intracellular processing of PRL by studying this phenomenon in cells in which PRL was pulse-labeled at varying times. Anterior pituitaries from ovariectomized estradiol-treated rats were dispersed and cultured on plastic coverslips. Cells were incubated for 24 h in media containing 500 nM DA. Cells were exposed to three consecutive 20-min incubation periods. During the first period all cells were maintained in 500 nM DA, during the second period half of the cells were removed from DA inhibition and during the third period DA inhibition was restored and the cells challenged with 100 nM TRH. In experiments involving labeling of PRL, cells were incubated in leucine-free media containing 100 microCi/ml [3H] leucine for 1 h prior to treatment, for 1 h starting 5 h prior to treatment or for 16 h starting 24 h prior to treatment. Total PRL (by radioimmunoassay) and radiolabeled PRL (by liquid scintillation after electrophoretic isolation) were determined both in media and cells. The withdrawal of DA alone resulted in a 2-fold stimulation of total PRL release. The efficacy of TRH to release total PRL was also increased 2- to 4-fold after transient DA withdrawal. Whereas release of 1-hour-old labeled PRL was not affected by DA withdrawal, 5-hour-old and 8- to 24-hour-old [3H] PRLs were stimulated 2.6- and 2-fold, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thyrotropin-releasing hormone stimulates growth hormone release from the anterior pituitary of hypothyroid rats in vitro

We have examined the interaction of thyroid hormone and TRH on GH release from rat pituitary monolayer cultures and perifused rat pituitary fragments. TRH (10(-9) and 10(-8)M) consistently stimulated the release of TSH and PRL, but not GH, in pituitary cell cultures of euthyroid male rats. Basal and TRH-stimulated TSH secretion were significantly increased in cells from thyroidectomized rats cultured in medium supplemented with hypothyroid serum, and a dose-related stimulation of GH release by 10(-9)-10(-8) M TRH was observed. The minimum duration of hypothyroidism required to demonstrate the onset of this GH stimulatory effect of TRH was 4 weeks, a period significantly longer than that required to cause intracellular GH depletion, decreased basal secretion of GH, elevated serum TSH, or increased basal secretion of TSH by cultured cells. In vivo T4 replacement of hypothyroid rats (20 micrograms/kg, ip, daily for 4 days) restored serum TSH, intracellular GH, and basal secretion of GH and TSH to normal levels, but suppressed only slightly the stimulatory effect of TRH on GH release. The GH response to TRH was maintained for up to 10 days of T4 replacement. In vitro addition of T3 (10(-6) M) during the 4-day primary culture period significantly stimulated basal GH release, but did not affect the GH response to TRH. A GH stimulatory effect of TRH was also demonstrated in cultured adenohypophyseal cells from rats rendered hypothyroid by oral administration of methimazole for 6 weeks. TRH stimulated GH secretion in perifused [3H]leucine-prelabeled anterior pituitary fragments from euthyroid rats. A 15-min pulse of 10(-8) M TRH stimulated the release of both immunoprecipitable [3H]rat GH and [3H]rat PRL. The GH release response was markedly enhanced in pituitary fragments from hypothyroid rats, and this enhanced response was significantly suppressed by T4 replacement for 4 days. The PRL response to TRH was enhanced to a lesser extent by thyroidectomy and was not affected by T4 replacement. These data suggest the existence of TRH receptors on somatotrophs which are suppressed by normal amounts of thyroid hormones and may provide an explanation for the TRH-stimulated GH secretion observed clinically in primary hypothyroidism.     

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.