Evidence for a coupling of prolactin secretion and synthesis by rat pituitary cells in culture

The relationship between the release and the synthesis of prolactin by rat pituitary cells in culture was studied using a microtubule-disrupting drug, vinblastine. (1) Prolactin secretion was inhibited by vinblastine in short-term incubations. Vinblastine did not act via the dopamine pathway, since a potent anti-dopaminergic drug, fluphenazine, was unable to reverse the inhibiting action of the antimicrotubular agent. (2) Continuous treatment by vinblastine induced a progressive decrease of the rate of incorporation of [³H]leucine in prolactin. The half-inhibition time was about 2 days. This inhibition of prolactin synthesis was selective, since total protein synthesis remained unaffected. (3) Measurements of radioimmunoassayable prolactin showed that the inhibition of hormone release by vinblastine led to a transient increase of the intracellular content of prolactin. The phase of over-accumulation was followed by a progressive reduction of the total (cell + medium) prolactin. This result is in agreement with the observed inhibition of de novo synthesis of prolactin and indicates that a degradation process takes place in pituitary cells in culture. In conclusion, the use of vinblastine allows us to demonstrate that the rate of prolactin synthesis is dependent upon the secretory status of the cell.     

The effects of dopamine on prolactin mRNA levels in rat pituitary cells in culture.

Dopamine is known to be the prolactin-release inhibiting factor, but the effects of dopamine itself on regulation of prolactin messenger RNA have been little studied because of the instability of dopamine. We have compared the effects of dopamine and bromocriptine on the levels of prolactin mRNA and on the rates of synthesis, storage, and release of prolactin in primary cultured rat pituitary cells. The cells were incubated for 72 h with no secretagogue (control group) or in the presence of either dopamine (10 mumol/L) plus ascorbic acid (100 mumol/L) or bromocriptine (0.1 mumol/L). Prolactin mRNA was measured in cell extracts by means of slot blots, and newly synthesized prolactin was measured in similar incubations by the addition of [3H]leucine, followed by gel electrophoresis. The levels of total prolactin were measured by radioimmunoassay. Prolactin mRNA was reduced to 78 +/- 9% (mean +/- SEM) of control levels in bromocriptine-treated cells and to 59 +/- 7% in dopamine-treated cells, demonstrating that dopamine stabilized by ascorbic acid was able to reduce the levels of prolactin mRNA in rat pituitary cells in culture. Dopamine may act at sites in addition to the dopaminergic D2 receptor, since the level of prolactin mRNA was reduced more by a supramaximal dose of dopamine than by a supramaximal dose of bromocriptine. The results of the [3H]prolactin and prolactin measurements suggested that availability of mRNA was not a major factor in controlling the rate of prolactin synthesis.     

N-terminal prolactin-derived fragments, vasoinhibins, are proapoptoptic and antiproliferative in the anterior pituitary

The anterior pituitary is under a constant cell turnover modulated by gonadal steroids. In the rat, an increase in the rate of apoptosis occurs at proestrus whereas a peak of proliferation takes place at estrus. At proestrus, concomitant with the maximum rate of apoptosis, a peak in circulating levels of prolactin is observed. Prolactin can be cleaved to different N-terminal fragments, vasoinhibins, which are proapoptotic and antiproliferative factors for endothelial cells. It was reported that a 16 kDa vasoinhibin is produced in the rat anterior pituitary by cathepsin D. In the present study we investigated the anterior pituitary production of N-terminal prolactin-derived fragments along the estrous cycle and the involvement of estrogens in this process. In addition, we studied the effects of a recombinant vasoinhibin, 16 kDa prolactin, on anterior pituitary apoptosis and proliferation. We observed by Western Blot that N-terminal prolactin-derived fragments production in the anterior pituitary was higher at proestrus with respect to diestrus and that the content and release of these prolactin forms from anterior pituitary cells in culture were increased by estradiol. A recombinant preparation of 16 kDa prolactin induced apoptosis (determined by TUNEL assay and flow cytometry) of cultured anterior pituitary cells and lactotropes from ovariectomized rats only in the presence of estradiol, as previously reported for other proapoptotic factors in the anterior pituitary. In addition, 16 kDa prolactin decreased forskolin-induced proliferation (evaluated by BrdU incorporation) of rat total anterior pituitary cells and lactotropes in culture and decreased the proportion of cells in S-phase of the cell cycle (determined by flow cytometry). In conclusion, our study indicates that the anterior pituitary production of 16 kDa prolactin is variable along the estrous cycle and increased by estrogens. The antiproliferative and estradiol-dependent proapoptotic actions of this vasoinhibin may be involved in the control of anterior pituitary cell renewal.     

PMA-sensitive protein kinase C is not necessary in TRH-stimulated prolactin release from female rat primary pituitary cells.

In GH3 cells and other clonal rat pituitary tumor cells, TRH has been shown to mediate its effects on prolactin release via a rise of cytosolic Ca2+ and activation of protein kinase C. In this study, we examined the role of protein kinase C in TRH-stimulated prolactin release from female rat primary pituitary cell culture. Both TRH and PMA stimulated prolactin release in a dose-dependent manner. When present together at maximal concentrations, TRH and PMA produced an effect which was slightly less than additive. Pretreatment of rat pituitary cells with 10(-6) M PMA for 24 hrs completely down-regulated protein kinase C, since such PMA-pretreated cells did not release prolactin in response to a second dose of PMA. Interestingly, protein kinase C down-regulation had no effect on TRH-induced prolactin release from rat pituitary cells. In contrast, PMA-pretreated GH3 cells did not respond to a subsequent stimulation by either PMA or TRH. Pretreatment of rat pituitary cells with TRH (10(-7) M, 24 hrs) inhibited the subsequent response to TRH, but not PMA. Forskolin, an adenylate cyclase activator, stimulated prolactin release by itself and in a synergistic manner when incubated together with TRH or PMA. The synergistic effects of forskolin on prolactin release was greater in the presence of PMA than TRH. Down-regulation of protein kinase C by PMA pretreatment abolished the synergistic effect produced by PMA and forskolin but had no effect on those generated by TRH and forskolin. sn-1,2-Dioctanylglycerol (DOG) pretreatment attenuated the subsequent response to DOG and PMA but not TRH. The effect of TRH, but not PMA, on prolactin release required the presence of extracellular Ca2+. In conclusion, the mechanism by which TRH causes prolactin release from rat primary pituitary cells is different from that of GH3 cells; the former is a protein kinase C-independent process whereas the latter is at least partially dependent upon the activation of protein kinase C.     

Osmotic regulation of prolactin secretion. Possible role of chloride

The role of osmotic pressure in the exocytosis of prolactin from rat pituitary tumor (GH) cells in culture was investigated. Reducing the osmotic strength of the medium from 300 mosm to 150 mosm by removal of NaCl did not alter basal secretion of prolactin but inhibited secretion stimulated by thyrotropin-releasing hormone (TRH) and forskolin. Both basal and stimulated secretion of prolactin were inhibited by increasing the osmotic strength of the medium with NaCl (IC50 at approximately 500 mosm). The stimulated release of hormone from GH-cells was independent of sodium and unaffected by replacement of sodium ion with tetramethylammonium or choline, or by addition of 500 nM tetrodotoxin. Secretagogue-stimulated release was, however, dependent upon chloride. Exchange of medium chloride with benzoate or isethionate significantly inhibited the stimulated release of prolactin (IC50 at approximately 60 mM exchange) regardless of the secretagogue utilized (phorbol ester, forskolin, depolarization plus BAY K8644, or TRH). Exchange of medium chloride with either isethionate or benzoate reduced cell volume by 10% compared to 60% for sucrose and mannitol, suggesting that inhibition of secretion by isethionate exchange was not a result of increased intracellular osmotic pressure. Complete exchange of medium chloride with isethionate did not alter equilibrium [3H]methyl-TRH binding, resting internal [Ca2+], or the [Ca2+]i response to depolarization and TRH as measured with intracellularly trapped Fura 2. Chloride removal did not change resting internal pH and recovery from an acid load as measured by the intracellular pH-sensitive dye 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein. The stimulated secretion of prolactin was also inhibited by exchange of chloride with isethionate in normal pituitary cells in primary culture and the ability of normal cells to respond to the dopamine agonist bromocryptine was not affected by the exchange. These results suggest that exocytosis of prolactin from GH-cells and normal pituitary cells in culture is an osmotically driven process that is chloride-dependent. Stimulated release is more chloride-dependent than constitutive release. The inhibitory effect of isethionate substitution occurs after signal transduction and is distinct from the site of dopamine inhibition of prolactin release.     

Culture of human pituitary prolactin and growth hormone cells

Summary Fragments of pituitary tissue obtained from a total of 37 patients with either breast cancer, diabetic retinopathy, galactorrhea, or acromegaly were dissociated into single cell suspensions prior to cell culture. Release of human growth hormone (hGH) and human prolactin (hPRL) into the culture medium was measured by radioimmunoassay. During a 3-week culture period, prolactin cells released 9–13 times the intracellular levels of hPRL at the time of seeding, whereas hGH release from growth hormone cells was only 1–2 times that of their initial intracellular level during this same time. Both growth hormone and prolactin cells retained distinctive ultrastructural features during culture. The prolactin cells responded to TRH stimulation by elevated release of PRL into the medium. No evidence for mitotic division of prolactin cells in vitro was found.This work was supported by NCI Contract NO 1-CB-23863     

Cytoplasmic protein phosphorylation related to multihormonal regulation of prolactin in pituitary cells

The specialized functions of mammotropic cells from the anterior pituitary and of the pituitary tumor derived GH cell lines can be regulated by a large number of neurohormones and other substances. Although the biological responses to many of these regulatory signals are well documented, much less is known about the intracellular mechanisms involved in their action. Various “second messengers” are generated, which in turn regulate other intracellular activities like protein phosphorylation reactions. Thyrotropin-releasing hormone stimulates both prolactin synthesis and release by mammotrophs of the anterior pituitary, or by GH₄C₁ cells in culture. Thyrotropin-releasing hormone simultaneously enhances the phosphorylation of a small number of cytoplasmic proteins in GH₄C₁ cells, as revealed by two-dimensional polyacrylamide gel electrophoresis after ³²PO₄³⁻ labelling. On a pharmacological basis, two distinct subsets were identified among the seven phosphoproteins affected by thyrotropin-releasing hormone: set I, proteins 1–6, whose phosphorylation could be related to the regulation of prolactin synthesis; set II, proteins 7 and 8, whose phosphorylation was related to the modulation of prolactin release (Sobel A. and Tashjian A. H. Jr. (1983) J. Biol. Chem. 258, 10312–10324). Phosphorylation of all these proteins but protein 1 was alkali-resistant, indicating that it might take place on tyrosine residues. Protein 1, which could be visualized by silver-staining and whose phosphorylation resulted in a shift of its position on two-dimensional gels, was present also in normal rat pituitary cells in primary culture. Moreover, thyrotropin-releasing hormone induced its phosphorylation as in GH₄C₁ cells, thus indicating that this reaction is a normal regulatory process, not related to the tumoral origin of GH₄C₁ cells. This observation allowed us to study some physiologically important regulatory mechanisms which were lost in GH cells as, for example, the inhibition of prolactin synthesis and release by dopamine: in normal anterior pituitary cells in culture, dopamine also prevented the thyrotropin-releasing hormone induced phosphorylation of protein 1. This result is in good agreement with those obtained with GH₄C₁ cells, and extends them. The same technique allowed us to detect a protein with two-dimensional gel migration properties identical to those of protein 1 in certain tissues, like the adrenal medulla, but not in others, like the adrenal cortex. This tissue specificity might be related to the specific regulatory function of protein 1 in the cell.     

Antisense Strategy Unravels a Dopamine Receptor Distinct from the D2 Subtype, Uncoupled with Adenylyl Cyclase, Inhibiting Prolactin Release from Rat Pituitary Cells

The antisense strategy was used to unravel the functional contribution of the mRNAs encoding dopamine (DA) receptors to the multiple transduction mechanisms operated by DA in rat pituitary cells. An antisense oligonucleotide was designed to recognize seven nucleotides upstream and 11 nucleotides downstream from the initiation translation codon of the mRNA that encodes the DA D2 receptor. Addition of the antisense oligonucleotide for 7 days to primary culture of rat pituitary cells resulted in a decreased expression of DA D2 receptor as shown by (a) the virtual disappearance of [³H]spiroperidol binding sites and (b) the marked reduction in the levels of both the long and the short splice variant of the D2 receptor mRNAs. After this treatment, the DA D2 receptor agonist bromocriptine lost its capability both to inhibit adenylyl cyclase activity and to reduce prolactin mRNA levels. On the contrary, the inhibition of prolactin release induced by bromocriptine was affected minimally by the antisense oligonucleotide treatment. These data indicate that (a) translation of the mRNA encoding DA D2 receptors results in receptors that are negatively coupled with adenylyl cyclase and functionally linked to inhibition of prolactin synthesis; and (b) the release of prolactin might be regulated, at least in part, by a DA receptor that is encoded by mRNA species distinct from those encoding the D2 receptor.     

Changes of cell morphology and prolactin secretion induced by 2-Br- alpha-ergocryptine, estradiol, and thyrotropin-releasing hormone in rat anterior pituitary cells in culture

The secretion of prolactin in cultured pituitary cells was studied in correlation with the cellular changes induced by stimulatory or inhibitory agents. The techniques used in this study were: radioimmunoassay, immunocytochemistry, scanning (SEM) as well as transmission (TEM) electron microscopy. Prolactin secretion was stimulated by 17 beta-estradiol (10 nM) as well as thyrotropin- releasing hormone (TRH) (3 nM) and inhibited by 2-Br-alpha-ergocryptine (CB-154) (1 muM). The total prolactin (release and cell content) increased between 2 and 8 d of estradiol treatment, indicating an increase of both synthesis and release of prolactin. This finding was in agreement with TEM observations because, in estradiol-treated prolactin cells, the Golgi saccules were distended and Golgi elements were increased, thus indicating increased synthetic activity of these cells. The addition of TRH over a 4-h period resulted in a significant degranulation of prolactin cells. In contrast, prolactin secretory granules became accumulated in the cells after CB-154 treatment for a period ranging from 4 to 24 h. In agreement, light microscope immunocytochemistry showed an increased reaction for prolactin after short-term (< 24 h) incubation with CB-154. Because prolactin cells represent approximately 70% of the glandular cell population as revealed by immunocytochemistry, it was then possible to observe the changes of cell surface by SEM. In most cells, estradiol and TRH led to an increase in the number and prominence of microvilli and blebs, whereas CB-154 treatment resulted in a slightly decreased number of microvilli and an increased occurrence of membrane foldings. This report thus provides morphological evidence for the stimulatory effects of estradiol and TRH, and the inhibitory effects of CB-154 on prolactin secretion in pituitary cells in primary culture. These data, moreover, show that acute changes in secretory activity of prolactin-secreting cells are accompanied by marked changes of their morphological characteristics.     

In vivo evidence for catecholaminergic inhibition of prolactin secretion in the teleostPoecilia latipinna

Summary Injections of L-dopa in freshwater (FW) fish reduced the size of the prolactin (PRL) cell nuclei, suggesting inhibition of PRL synthesis. A single injection of 6-hydroxydopamine (6-OHDA) in one-third seawater (1/3SW) fish reduced pituitary PRL content and increased PRL cell nuclear size at 6 h and 12 h, indicating stimulation of both synthesis and release of PRL. Two daily injections of 6-OHDA in 1/3SW fish led to PRL cell nuclear enlargement and elevated pituitary PRL content at 48 h after the second injection, indicating strong stimulation of PRL synthesis. Consideration of other parameters (plasma and body sodium levels, plasma osmotic pressure) suggests that the PRL cell responses to 6-OHDA were not mediated by internal osmotic changes. Pretreatment with 6-OHDA also appeared to accelerate the PRL cell activation induced by the transfer of fish from 1/3SW to FW.L-dopa opposed the enhancement of PRL release induced by a single injection of 6-OHDA. Injections of 3,4-dimethoxyphenylethylamine (DMPEA), a specific dopamine antagonist, caused short-term depletion of pituitary PRL, indicating enhanced PRL release.These results suggest that PRL secretion is subject to catecholaminergic inhibition, probably by dopamine. Considering these findings together with previous in vitro results (Wigham et al., 1975), it appears that the PRL cells are innervated by inhibitory catecholaminergic nerve fibres.Abbreviations DMPEA 3,4-dimethoxyphenylethylamine - L-dopa L-dihydroxyphenylalanine - FW freshwater - 6-OHDA 6-hydroxydopamine - PRL prolactin - 1/3SW one-third seawater     

Stereological and biochemical analysis of prolactin and growth hormone secreting rat pituitary cells in culture

Summary The secretion of prolactin is increased by treatment of prolactin producing rat pituitary cells with the hypothalamic tripeptide thyroliberin. To investigate the underlying mechanisms we used three closely related rat pituitary tumor cell strains (GH₁2C₁, GH₃ and GH₄C₁), which synthesize and spontaneously secrete prolactin and/or growth hormone. Growth hormone and prolactin released into the culture medium over a period of 24 h were measured by radioimmunoassay. Initial rates of synthesis were measured by immunoprecipitation of intracellular growth hormone and prolactin after incubation of cell cultures with ³H-leucine. The observed increase in prolactin synthesis and release was correlated with morphological effects of thyroliberin treatment. The volume density of Golgi complexes and the volume and surface densities of rough endoplasmic reticulum were compared in untreated cells and thyroliberin treated cells. As normal distribution could not be assumed, the non-parametric rank test of Wilcoxon was used whereby the densities calculated for each cell section were ranked. Alle three morphological parameters increased after thyroliberin treatment in cells secreting prolactin only (GH₄C₁), implying that the increase of prolactin secretion, at lest in part, is due to increased prolactin synthesis.     

An islet activating protein-sensitive G protein is involved in dopamine inhibition of angiotensin and thyrotropin-releasing hormone-stimulated inositol phosphate production in anterior pituitary cells

In primary culture of anterior pituitary cells, dopamine inhibited the angiotensin (AII)-stimulated inositol phosphate production by 28 +/- 2.5% (n = 14), with an EC50 of 660 +/- 228 nM (n = 8). This effect was blocked by (+)-butaclamol, a specific dopamine receptor antagonist. RU 24926, a D2 specific agonist, but not SKF 38393, a specific D1 agonist, inhibited AII-stimulated inositol phosphate production, suggesting that this dopamine effect is mediated through a dopamine receptor of the D2 subtype. Dopamine also partially inhibited (25%) inositol phosphate production stimulated by thyrotropin-releasing hormone (TRH). Our results suggest that the dopamine-mediated inhibition of hormonally stimulated inositol phosphate production is probably not mediated through the known inhibitory effects of dopamine on cAMP and Ca2+ intracellular concentrations. Although unknown, the mechanism by which dopamine inhibited the AII and TRH-stimulated inositol phosphate production implicates a GTP binding protein sensitive to the islet activating protein (IAP) since dopamine effects were blocked by this toxin. The alpha subunit of the GTP binding protein involved could be one of the three ADP-ribosylated proteins found in anterior pituitary cells in primary cultures, the alpha o (39 kDa), the alpha i (41 kDa), and an alpha subunit of 40 kDa. Indeed, we show here that this 40-kDa IAP substrate, already described in a few tissues, is present in anterior pituitary cells. The negative coupling between dopamine receptors and the AII or TRH inositol phosphate production systems, could be implicated in the dopamine inhibition of the AII- and TRH-stimulated prolactin release since such an inhibition is blocked by IAP. Our results suggest that the negative regulation of inositol phosphate production is one of the mechanisms by which dopamine controls hormonally stimulated prolactin release.     

Inhibition of growth hormone and prolactin secretion by a serine proteinase inhibitor

The action of the tripeptide aldehyde t-butyloxycarbonyl-DPhe-Pro-Arg-H (boc-fPR-H), belonging to a family of serine proteinase inhibitors, on the release of immunoreactive prolactin (iPRL) and growth hormone (iGH) has been studied. In rat anterior pituitary cell cultures and pituitary quarters 1 mM boc-fPR-H inhibited basal iPRL and iGH release. Thyroliberin-induced iPRL release by cultured cells was also markedly inhibited with a concomitant accumulation of intra-cellular iPRL. During the short- and long-term exposure of cells to boc-fPR-H there no changes in total cell protein contents and in activities of some lysosomal marker enzymes. A wide scale of unchanged parameters characteristic for cellular metabolism indicated that the tripeptide aldehyde has no cytotoxic effect. The marked inhibition of basal as well as stimulated hormone release in the presence of the enzyme inhibitor might suggest that at least a portion of the hormones is released via a proteolytic enzyme-dependent process.     

The effect of clozapine on prolactin secretion at the level of the lactotroph

Clozapine is an antipsychotic drug which is unusual in that it has no dopamine receptor-blocking activity. Previous studies gave conflicting results whether administration of clozapine induces hyperprolactinemia. In the present study it was shown that a wide concentration range of clozapine does not interfere with dopamine-mediated inhibition of prolactin (PRL) secretion by normal cultured rat pituitary cells. This in contrast to other neuroleptics, like haloperidol and trifluoperazine. Clozapine does also not antagonize norepinephrine-mediated inhibition of PRL secretion. Clozapine exerts at micromolar concentrations a direct inhibitory action on PRL release by cultured normal rat pituitary cells. In cultured rat pituitary tumor cells, these high concentrations of clozapine directly inhibit PRL release as well as the DNA content of the cells, suggesting a direct antimitotic action. In this model clozapine was about 5-10 times less potent than trifluperazine. Clozapine and trifluoperazine exert an additive inhibitory action both on PRL release and on the DNA content of the pituitary tumor cells. It is concluded that clozapine does not interfere at the pituitary level with dopamine-mediated inhibition of PRL release. At micromolar concentrations clozapine may act on lactotrophs as a calmodulin-inhibitor. These observations suggest that the transient PRL-releasing effects which have been observed in both animal and human studies after clozapine administration are mediated via supra-pituitary actions of the drug.     

Calcitonin inhibits the rise of intracellular calcium induced by thyrotropin-releasing hormone in GH3 cells

Both human and salmon calcitonins markedly inhibit the TRH-stimulated rise in intracellular [Ca2+] in GH3 cells. Calcitonin also inhibits prolactin release from these cells. Both [Ala] salmon calcitonin and salmon calcitonin (1-23) peptide amide also inhibit this rise in [Ca2+] and also inhibit TRH-stimulated prolactin release from GH3 cells as well as from primary pituitary cell cultures. It is likely that calcitonin inhibits prolactin release in the pituitary by decreasing the extent of the rise of intracellular calcium concentration. Neither an intact disulfide bond at the amino terminus nor residues 24-32 of the carboxyl terminus of salmon calcitonin are required for this inhibition.     

Effect of extracellular matrix on prolactin secretion and mRNA accumulation in GH3 cells

The matrix upon which cells grow affects their morphology, growth rate, response to external stimuli, and protein synthesis. GH3 cells, a well-characterized rat pituitary tumor cell line, synthesize and secrete growth hormone and prolactin (Prl). These cells are rounded, attach loosely, and form clumps when plated on plastic. GH3 cells plated on an extracellular matrix (ECM) from bovine corneal endothelial cells become flattened and strongly adherent to the culture dish, and have an initial increased rate of proliferation. Cells cultured on plastic have a 48-hr lag period before the start of cell division; this can be shortened by increasing the concentration of serum in the medium. Since GH3 cells store little Prl, hormone release is a good index of Prl synthesis. Prl secretion from cells cultured on extracellular matrix is twice as great as from cells cultured on plastic. The increase in Prl secretion from cells grown on extracellular matrix paralleled by a concomitant increase in the accumulation of prolactin mRNA. Cells cultured on plastic secrete more Prl in response to TRH stimulation than do cells cultured on ECM. Cells grown on either surface were unresponsive to dopamine. Thus, culturing cells on ECM may change their morphology and affect the synthesis and regulation of specific cellular proteins and their mRNAs.     

Effects of colchicine and 2-Br-alpha-ergocryptine-methane-sulfonate (CB 154) on the release of prolactin and growth hormone by functional pituitary tumor cells in culture

The effects of colchicine and 2-Br-α-ergocryptine-methane-sulfonate (CB 154) on the release of prolactin and growth hormone have been studied in a clonal strain of rat pituitary tumor cells (GH₃) in monolayer culture. These cultures produce both prolactin and growth hormone and release both proteins spontaneously into the medium without storing them in large amounts. Immunological methods were used to measure both intracellular and extracellular concentrations of the hormones. Colchicine (5 × 10^?6 M for 3 hours) caused a 2- to 3-fold increase in intracellular concentrations of prolactin and growth hormone but, under basal conditions, had little or no measurable effect on the amounts of hormone accumulated in the medium during the course of the standard three hour treatment period. This latter finding evidently is due to a lag in the onset of drug action. Colchicine had little or no effect on accumulation of extracellular prolactin during the first two hours of treatment whereas such accumulation was depressed by over 60% during the third hour of treatment. Previous studies have shown that treatment of GH₃ cells with thyrotropin releasing hormone (TRH) and hydrocortisone (HC) increases both intra and extracellular levels of prolactin and growth hormone, respectively. In cultures treated with TRH (5 × 10^?8 M), colchicine (5 × 10^?6 M for 3 hours) increased intracellular prolactin by about 70% and decreased extracellular hormone by 10%. In cultures treated with HC (3 × 1O^?6 M), colchicine increased intracellular growth hormone by more than 100% and decreased medium concentrations of the hormone by 15%. Colchicine did not significantly alter total hormone (intracellular + extracellular) accumulation, cellular uptake of ³H-amino acids, or total cell protein synthesis. The synthetic ergot alkaloid, CB 154, (3.3 × 10^?6 M for 3 hours) caused an 80% increase in intracellular, and a nearly 50% decrease in extracellular, prolactin without affecting the accumulation of growth hormone, the uptake of ³H-labeled amino acids, or overall protein synthesis in the cultures. Elevation of medium potassium concentration from a basal value of 5.3 mM to 3–5 × 10^?2 M (by addition of KCl) decreased intracellular levels of prolactin by 85% and growth hormone by 55%. These effects of high potassium were blocked by colchicine and by CB 154. We conclude that colchicine, after a lag period of two hours, acts to inhibit the release of prolactin and growth hormone from GH₃ cells. By the end of three hours of treatment, this inhibition is over 60% complete in the case of prolactin. The qualitatively different effects of colchicine and CB 154 on prolactin and growth hormone release suggest that these two secretory blocking agents probably act on GH₃ cells by different mechanisms.     

Contrasting effects of pituitary adenylate cyclase activating polypeptide (PACAP) on in vivo and in vitro prolactin and growth hormone release in male rats.

Pituitary adenylate cyclase activating polypeptide (PACAP) is produced by hypothalamic neurons which terminate within the median eminence suggesting that it may be a hypophysiotropic hormone. However, little endocrine activity has been ascribed to the peptide. Therefore we studied the effects of PACAP on prolactin (Prl) release from dispersed cultivated rat pituitary cells in vitro using conventional cultures as well as the reverse hemolytic plaque assay (RHPA). Furthermore the effects of the peptide on in vitro GH release were assessed. In addition, the activity of the peptide on in vivo release of Prl and GH was studied in hypothalamus-lesioned animals. PACAP dose dependently inhibited Prl release form dispersed pituitary cells in both, monolayer cell cultures and the RHPA, whereas GH secretion was not affected. In hypothalamus-lesioned rats which have high Prl levels due to the absence of hypothalamic dopamine, PACAP further stimulated Prl release. Serum GH increased more than 20 fold in response to the intravenous PACAP infusion. Thus in vitro (inhibition of Prl release, no effect on GH release) and in vivo (stimulation of both hormones) experiments yielded contradicting effects of PACAP on pituitary hormone release. We suggest that PACAP may stimulate the release of a paracrine, yet unknown factor which in the intact pituitary overrides the direct inhibitory action of PACAP on the lactotropes. The same or another paracrine factor may also enhance in vivo GH release. In cell culture the paracrine factor is diluted by the medium. Therefore the peptide never reaches effective concentrations which are present within the intact pituitary tissue.     

Cadmium Mimics Estrogen-Driven Cell Proliferation and Prolactin Secretion from Anterior Pituitary Cells

Cadmium (Cd) is a heavy metal of considerable occupational and environmental concern affecting wildlife and human health. Recent studies indicate that Cd, like other heavy metals, can mimic effects of 17β-estradiol (E2) involving E2 receptor (ER) activation. Lactotrophs, the most abundant cell type in anterior pituitary gland, are the main target of E2, which stimulates cell proliferation and increases prolactin secretion through ERα. The aim of this work was to examine whether Cd at nanomolar concentrations can induce cell proliferation and prolactin release in anterior pituitary cells in culture and whether these effects are mediated through ERs. Here we show that 10 nM Cd was able to stimulate lactotroph proliferation in anterior pituitary cell cultures from female Wistar rats and also in GH3 lactosomatotroph cell line. Proliferation of somatotrophs and gonadotrophs were not affected by Cd exposure. Cd promoted cell cycle progression by increasing cyclins D1, D3 and c-fos expression. Cd enhanced prolactin synthesis and secretion. Cd E2-like effects were blocked by the pure ERs antagonist ICI 182,780 supporting that Cd acts through ERs. Further, both Cd and E2 augmented full-length ERαexpression and its 46 kDa-splicing variant. In addition, when co-incubated Cd was shown to interact with E2 by inducing ERα mRNA expression which indicates an additive effect between them. This study shows for the first time that Cd at nanomolar concentration displays xenoestrogenic activities by inducing cell growth and stimulating prolactin secretion from anterior pituitary cells in an ERs-dependent manner. Cd acting as a potent xenoestrogen can play a key role in the aetiology of different pathologies of the anterior pituitary and in estrogen-responsive tissues which represent considerable risk to human health.     

Routing, processing and export of rat pituitary prolactin: identification of a 36 kDa disulphide-bridged oligomeric preprolactin

To gain an insight in the routing, processing and export of rat prolactin, rat pituitary cells were cultured in serum-free medium in the presence of cycloheximide, carbonyl cyanide m-chlorophenylhydrazone, Brefeldin A and monensin. The potential influence of these perturbants, whose well documented effects are the altering of protein synthesis and transport, was studied on rat prolactin molecular size isoforms appearing in cellular extracts and in culture medium. The outcome of the culture experiments as recorded in vertical SDS-PAGE, thiol gradient electrophoresis and sequential SDS-PAGE followed by prolactin specific immunoblotting and densitometry, was as follows: (1) at the cellular level we were able to characterize a novel 36 kDa protein as a disulphide-bridged oligomeric precursor prolactin, which is presumably rapidly transformed in the cis/medial Golgi; to designate monomeric rat prolactin as an early Golgi protein and t o advance evidence that the main processing of the glycosylated rat prolactin is a cis/medial Golgi event; (2) in release none of the perturbants disturbed the relative distribution of monomeric and glycosylated rat prolactin, the main molecular size isoforms currently secreted by untreated pituitary cells, or induced the appearance of transformed molecular size isoforms; (3) the secretion mode indicates that rat prolactin is released via the regulated pathway in the presence of the perturbants used.