Estrogen stimulates both prolactin and growth hormone mRNAs expression in the MtT/F4 transplantable pituitary tumor

The effects of 17 beta-estradiol (E2) on MtT/F4 pituitary tumor growth and on prolactin (PRL) and growth hormone mRNA expression were analyzed in F344 female rats. E2 (10 mg) stimulated pituitary PRL cell hyperplasia and PRL mRNA, but inhibited growth of the transplantable tumors. The expression of both PRL and growth hormone mRNA levels was increased in the MtT/F4 tumors. The effects of E2 on increasing PRL mRNA levels were more marked in the pituitary compared with the tumors. These results indicate that estrogens stimulate proliferation and PRL expression in the pituitary while inhibiting cell proliferation in the MtT/F4 tumor. E2 also stimulated both growth hormone and PRL mRNA expression in the MtT/F4 transplantable tumor.     

Conversion of growth hormone-secreting cells into prolactin-secreting cells and its promotion by insulin and insulin-like growth factor-1 in vitro

The newly established rat pituitary cell line, MtT/S, has pituitary somatotroph (growth hormone-producing cell)-like characteristics, i.e., the cells produce growth hormone (GH), possess GH-immunopositive secretory granules, and respond to GH-releasing hormone. When MtT/S cells were cultured in regular medium no prolactin (PRL) cells were observed and PRL was not detected, by radioimmunoassay or Western blot analysis, in the medium or the cells. However, GH production and the GH cell population decreased markedly when the cells were incubated with insulin or insulin-like growth factor-1 (IGF-1). After stimulation with insulin or IGF-1 there was a 2-day lag period, then some PRL was detected in the medium; after 5 days a number of PRL cells appeared. Double immunocytochemistry indicated clearly that no cell contained both PRL and GH. These results show that insulin and IGF-1 stimulate conversion of MtT/S cell line GH cells to PRL cells. This suggests that the MtT/S cell line is an excellent model system which shows the GH-cell/PRL-cell lineage.     

Concentration of native prolactin and prolactin binding sites in hepatic subcellular fractions from hyperprolactinemic rats

Lactogen binding and prolactin content were measured in hepatic subcellular fractions from tumor-bearing rats (TBR; MtT/F4, MtT/W5, MtT/W10) with elevated prolactin and growth hormone levels and from control animals. Specific binding of 125I-oPRL to Golgi fractions from tumor-bearing animals was 2.5 to 7 fold greater than that from controls. Binding to plasmalemma was 6-fold greater in tumor-bearing rats. The specific binding of 125I-labelled bGH and insulin showed less marked differences between TBR and controls. Subcellular fractions were extracted with HCl to determine hormonal content. The content of prolactin and growth hormone in Golgi fractions from TBR was at least 20-fold that in fractions from controls. Rat prolactin extracted from Golgi heavy elements was 50% as effective as native material in binding to lactogen receptors as judged by radioreceptor assay. These studies demonstrate that the chronic elevation of prolactin was associated with an increase of receptors not only in the intracellular compartment but on the cell surface as well. Furthermore, they demonstrate that native prolactin is internalized and accumulated in rat liver Golgi fractions.     

Characterization of functional receptors for somatostatin in rat pituitary cells in culture.

GH4C1 cells are a clonal strain of rat pituitary tumor cells which synthesize and secrete prolactin and growth hormone. Somatostatin, a hypothalamic tetradecapeptide, inhibits the release of growth hormone and, under certain circumstances, also prolactin from normal pituitary cells. We have prepared [125I-Tyr1]somatostatin (approximately 2200 C1/mmol) and have shown that this ligand binds to a limited number of high affinity sites on GH4C1 cells. Half-maximal binding of somatostatin occurred at a concentration of 6 x 10(-10) M. A maximum of 0.11 pmol of [125I-Tyr1]somatostatin was bound per mg of cell protein, equivalent to 13,000 receptor sites per cell. The rate constant for binding (kon) was 8 x 10(7) M(-1) min(-1). The rate constant for dissociation (koff) was determined by direct measurement to be 0.02 min(-1) both in the presence and absence of excess nonradioactive somatostatin. Binding of [125I-Tyr1]somatostatin was not inhibited by 10(-7) M thyrotropin-releasing hormones. Substance P, neurotensin, luteinizing hormone-releasing hormone, calcitonin, adrenocorticotropin, or insulin. Of seven nonpituitary cell lines tested, none had specific receptors for somatostatin. Somatostatin was shown to inhibit prolactin and growth hormone production by CH4C1 cells. The dose-response characteristics for binding and the biological actions of somatostatin were essentially coincident. Furthermore, among several clonal pituitary cell strains tested, only those which had receptors for somatostatin showed a biological response to the hormone. We conclude that the characterized somatostatin receptor is necessary for the biological actions of somatostatin on GH4C1 cells.     

Production of both prolactin and growth hormone by clonal strains of rat pituitary tumor cells. Differential effects of hydrocortisone and tissue extracts

Several established clonal strains of rat pituitary cells which produce growth hormone in culture have been shown to secrete a second protein hormone, prolactin. Prolactin was measured immunologically in culture medium and within cells by complement fixation. Rates of prolactin production varied from 6.6 to 12 µg/mg cell protein per 24 hr in four different cell strains. In these cultures ratios of production of prolactin to growth hormone varied from 1.0 to 4.1. A fifth clonal strain produced growth hormone but no detectable prolactin. Intracellular prolactin was equivalent to the amount secreted into medium in a period of about 1–2 hr. Both cycloheximide and puromycin suppressed prolactin production by at least 94%. Hydrocortisone (3 x 10^-6 M), which stimulated the production of growth hormone 4- to 8-fold in most of the cell strains, reduced the rate of prolactin production to less than 25% of that in control cultures. Conversely, addition of simple acid extracts of several tissues, including hypothalamus, to the medium of all strains increased the rate of production of prolactin six to nine times and decreased growth hormone production by about 50%. We conclude that multifunctional rat pituitary cells in culture show unusual promise for further studies of the control of expression of organ-specific activities in mammalian cells.     

Effects of retinoic acid on estrogen- and thyroid hormone-induced growth in a newly established rat pituitary tumor cell line.

In order to elucidate the complex mechanism(s) of action of steroid hormones, thyroid hormone and retinoic acid in pituitary mammotrophs, a clonal cell line (G3) was isolated from the rat pituitary tumor MtT/F84. G3 cells were found to secrete prolactin constitutively and to contain receptors for estrogen, glucocorticoid, progesterone and thyroid hormone. Stimulation of G3 cells with thyroid hormone resulted in a modest but significant increase in estrogen and progesterone receptor levels, however, retinoic acid treatment had no effect. Simultaneous addition of thyroid hormone and estrogen showed an additive effect on progesterone receptor levels in G3 cells. Thyroid hormone as well as estrogen enhanced the growth of G3 cells. Interestingly, retinoic acid was also found to enhance their growth but its enhancement was less potent than thyroid hormone and estrogen. Low concentrations of estradiol and thyroid hormone showed additive effects, but G3 cells stimulated with high concentrations of thyroid hormone failed to elicit an additive effect with estrogen, suggesting the presence of a common pathway in the growth-stimulatory actions of these hormones. In addition, exposure of G3 cells to retinoic acid completely abolished the effects of estrogen or thyroid hormone in terms of cell growth. These results suggest that there are complex interactions in the signalling pathways for estrogen, thyroid hormone and retinoic acid action in G3 cells.     

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.     

Differential control of alveolar and ductal development in grafts of monodispersed rat mammary epithelium.

Multicellular secretory alveolar units (AU) develop in grafts of monodispersed mammary cells in intact recipient rats co-grafted with mammotropic hormone-secreting pituitary tumor (MtT). The cumulative evidence is consistent with a postulated clonal origin of these structures. Small numbers of multicellular structures of a second type, mammary ductal units (DU), were found in mammary cell grafts in intact Wistar/Furth recipients co-grafted with MtT W10 but not in intact F344 recipients co-grafted with MtT F4. Studies in (Wistar/Furth x F344) F1 hybrid recipients grafted with mammary cells from either parent strain demonstrated that this difference in DU formation is dependent on the strain of grafted MtT, and is not a genetic characteristic of the rat strain. DU formation is stimulated and AU formation is inhibited by elevation of mammotropic hormones from MtT coupled with glucocorticoid deficiency induced by adrenalectomy. cortisol treatment reverses this effect. Finally, in mammary glands in situ in intact rats, the total numbers of AU-forming clonogens decrease during 6 weeks after MtT transplantation. In contrast, during the same period, elevated mammotropins from grafted MtT coupled with glucocorticoid deficiency from adrenalectomy cause an increase in the total number of cells that are capable of AU formation when transplanted to intact recipients co-grafted with MtT. Thus, the same hormonal combination that stimulates DU formation in mammary cell grafts and has previously been shown to promote cancer in mammary glands in situ also stimulates an increase in the glandular content of assayable AU-forming cells in situ.     

Epidermal growth factor and thyrotropin-releasing hormone act similarly on a clonal pituitary cell strain. Modulation of hormone production and inhbition of cell proliferation

GH(4)C(1) cells are a clonal strain of rat pituitary cells that synthesize and secrete prolactin and growth hormone. Chronic treatment (longer than 24 h) of GH(4)C(1) cells with epidermal growth factor (EGF) (10(-8) M) decreased by 30-40 percent both the rate of cell proliferation and the plateau density reached by cultures. Inhibition of cell proliferation was accompanied by a change in cellular morphology from a spherical appearance to an elongated flattened shape and by a 40-60 percent increase in cell volume. These actions of EGF were qualitatively similar to those of the hypothalamic tripeptide thyrotropin-releasing hormone (TRH) (10(-7) M) which decreased the rate of cell proliferation by 10-20 percent and caused a 15 percent increase in cell volume. The presence of supramaximal concentrations of both EGF (10(-8)M) and TRH (10(-7)M) resulted in greater effects on cell volume and cell multiplication than either peptide alone. EGF also altered hormone production by GH(4)C(1) cells in the same manner as TRH. Treatment of cultures with 10(-8) M EGF for 2-6 d increased prolactin synthesis five- to ninefold compared to a two- to threefold stimulation by 10(-7) M TRH. Growth hormone production by the same cultures was inhibited 40 percent by EGF and 15 percent by TRH. The half- maximal effect of EGF to increase prolactin synthesis, decrease growth hormone production, and inhibit cell proliferation occurred at a concentration of 5 x 10 (-11) M. Insulin and multiplication stimulating activity, two other growth factors tested, did not alter cell proliferation, cell morphology, or hormone production by GH(4)C(1) cells, indicating the specificity of the EGF effect. Fibroblast growth factor, however, had effects similar to those of EGF and TRH. Of five pituitary cell strains tested, all but one responded to chronic EGF treatment with specifically altered hormone production. Acute chronic EGF treatment with specifically altered hormone production. Acute treatment (30 min) of GH(4)C(1) cells with 10(-8) M EGF caused a 30 percent enhancement of prolactin release compared to a greater than twofold increase caused by 10(-7) M TRH. Therefore, although EGF and TRH have qualitatively similar effects on GH(4)C(1) cells, their powers to affect hormone release acutely or hormone synthesis and cell proliferation chronically are distinct.     

Isolation and characterization of rat-mouse somatic cell hybrids secreting growth hormone and prolactin

Interspecific somatic cell hybrid clones have been isolated and characterized in order to study growth hormone (GH) and prolactin (PRL) gene expression. Rat pituitary tumor cells (GH3, 69 chromosomes) secreting rat GH and PRL were grown for 48 h together with nonhormone secreting, aminopterin-sensitive murine fibroblast cells (LMTK-, 55 chromosomes) and fused using polyethylene glycol. Resultant heterokaryons were selected in hypoxanthine-aminopterin-thymidine (HAT) medium and cloned. Five clones produced rat GH and PRL. Hormone-producing hybrids morphologically resembled the mouse parent fibroblast. Hybrids grew in monolayers and contained 80-142 chromosomes, and marker chromosomes for both rat (small submetacentric) and mouse (bi-armed and large true metacentric) were identified. The interspecific nature of the hybrids was further confirmed by the presence of both rat and mouse adenosine deaminase and superoxide dismutase isozymes. Using specific antisera and indirect immunoperoxidase staining, both hybrid clones and GH3 rat parental cells stained positively for rat GH and PRL, while the murine fibroblast parental cells were negative. Hormone production by the hybrids has been sustained for over twenty subcultures; secretion rates were initially 150 ng PRL and 321 ng GH/10(6) cells/24 h and are currently 100 ng PRL and 90 ng GH/10(6) cells/24 h. Parental GH3 rat cells secreted 720 ng PRL and 660 ng GH/10(6) cells/24 h. Exposure of hybrids to KCl (50 mM) resulted in acute stimulation of rat PRL, but not rat GH release, and long-term incubation with thyrotropin-releasing hormone (TRH, 80 nM) stimulated PRL secretion. Hormone-dependent modulation of PRL secretion was transferred to the hybrid cell thus enabling the model to be used in studying regulation of PRL gene expression.     

Acquisition of Lubrol insolubility, a common step for growth hormone and prolactin in the secretory pathway of neuroendocrine cells

Rat prolactin in the dense cores of secretory granules of the pituitary gland is a Lubrol-insoluble aggregate. In GH(4)C(1) cells, newly synthesized rat prolactin and growth hormone were soluble, but after 30 min about 40% converted to a Lubrol-insoluble form. Transport from the endoplasmic reticulum is necessary for conversion to Lubrol insolubility, since incubating cells with brefeldin A or at 15 degrees C reduced formation of insoluble rat (35)S-prolactin. Formation of Lubrol-insoluble aggregates has protein and cell specificity; newly synthesized human growth hormone expressed in AtT20 cells underwent a 40% conversion to Lubrol insolubility with time, but albumin did not, and human growth hormone expressed in COS cells underwent less than 10% conversion to Lubrol insolubility. del32-46 growth hormone, a naturally occurring form of growth hormone, and P89L growth hormone underwent conversion, although they were secreted more slowly, indicating that there is some tolerance in structural requirements for aggregation. An intracellular compartment with an acidic pH is not necessary for conversion to Lubrol insolubility, because incubation with chloroquine or bafilomycin slowed, but did not prevent, the conversion. GH(4)C(1) cells treated with estradiol, insulin, and epidermal growth factor accumulate more secretory granules and store more prolactin, but not more growth hormone, than untreated cells; Lubrol-insoluble aggregates of prolactin and growth hormone formed to the same extent in hormone-treated or untreated GH(4)C(1) cells, but prolactin was retained longer in hormone-treated cells. These findings indicate that aggregation alone is not sufficient to cause retention of secretory granule proteins, and there is an additional selective process.     

n-Butyrate effects thyroid hormone stimulation of prolactin production and mRNA levels in GH1 cells

Using cultured GH1 cells, a growth hormone and prolactin-producing rat pituitary cell line, we have shown that n-butyrate and other short chain carboxylic acids stimulate histone acetylation and elicit a reduction of thyroid hormone nuclear receptor which is inversely related to the extent of acetylation (Samuels, H. H., Stanley, F., Casanova, J., and Shao, T. C. (1980) J. Biol. Chem. 255, 2499-2508). In this study, we compared the n-butyrate and propionate modulation of receptor levels to regulation of the growth hormone and prolactin response by 3,5,3'-triiodo-L-thyronine (L-T3). n-Butyrate (0.1-10 mM) did not stimulate growth hormone production. L-T3 stimulated the growth hormone response 4- to 5-fold and n-butyrate (0.5-1 mM) increased L-T3 stimulation of growth hormone production 1.5- to 2-fold compared to L-T3 alone. L-T3 stimulation of growth hormone production at higher n-butyrate concentrations decreased in parallel with the n-butyrate-mediated reduction of receptor levels. In contrast with the growth hormone response, n-butyrate (0.5 mM) increased basal prolactin production about 5-fold. Prolactin production, which is inhibited 25 to 50% by L-T3, was stimulated between 20- and 70-fold by L-T3 + n-butyrate (0.5-1 mM) and this decreased at higher n-butyrate levels. Prolactin mRNA and growth hormone mRNA levels paralleled the changes in prolactin and growth hormone production rates. These effects of L-T3, n-butyrate, or L-T3 + n-butyrate appeared unrelated to changes in cAMP levels or global changes in DNA methylation of the growth hormone or prolactin genes. Propionate elicited the same effects as n-butyrate but at a 5- to 10-fold higher concentration consistent with their relative effect on stimulating acetylation of chromatin proteins. These results suggest that prolactin gene expression is under partial regulatory repression which is reversed by a carboxylic acid-mediated postsynthetic modification event which allows for stimulation of the prolactin gene by thyroid hormone.     

Non-thyrotropic pituitary cells in culture convert T4 to T3.

Although intrapituitary conversion of T4 to T3 has been shown in rat pituitary homogenates, this deiodination has not been demonstrated in non-thyrotropic pituitary cells. GH3 cells, which produce growth hormone and prolactin, were used to demonstrate formation of T3 from T4 in monolayer culture. During a 1 hr incubation, the amount of T3 generated increased with increasing T4 substrate concentrations, reaching a plateau after 0.9 μM T₄. When dithiothreitol was added to the medium, production of T3 doubled at all concentrations of T4. T3 production in the presence of 2 μM T4 increased from .23 nM after 0.5 hr incubation to .8 nM after 3 hr incubation. Deiodination by this nonthyrotropic rat pituitary tumor cell is markedly enhanced by a thiol-protective agent.     

Direct up-regulation of estrogen receptor by triiodothyronine in rat pituitary tumor MtT/F84.

To investigate a possible effect of triiodothyronine (T3) on the regulation of estrogen receptor, estrogen dependent rat pituitary tumor, MtT/F84, was studied in rats which received surgical thyroidectomy (Tx) or were given propylthiouracil (PTU) and were supplemented with T3. In T3 loaded rats, the grafted tumor showed high estrogen receptor levels (160-200% of control), whereas low estrogen receptor levels (20-35% of control) were observed in the tumors grown in Tx and PTU treated rats. A single injection of T3 to Tx rats with MtT/F84 increased the estrogen receptor level in a time dependent manner and reached the maximal level at 6 h. In primary culture of MtT/F84 cells, T3 increased the specific 3H-estrogen binding to tumor cells in a dose dependent manner (165% of control by 10(-7)M T3) and also in a time dependent (maximum at 12 h) manner. These data suggest that T3 directly up-regulates the estrogen receptor level in MtT/F84 cells.     

The mechanisms by which vasoactive intestinal peptide (VIP) and thyrotropin releasing hormone (TRH) stimulate prolactin release from pituitary cells

The effect of vasoactive intestinal peptide (VIP) on prolactin (PRL) secretion from pituitary cells is reviewed and compared to the effect of thyrotropin releasing hormone (TRH). These two peptides induced different secretion profiles from parafused lactotrophs in culture. TRH was found to increase PRL secretion within 4 s and induced a biphasic secretion pattern, while VIP induced a monophasic secretion pattern after a lag time of 45–60 s.The secretion profiles are compared to changes in adenylate cyclase activity, production of inositol polyphosphates, changes in intracellular calcium concentrations and changes in electrophysiological properties of the cell membrane.Abbreviations AC adenylate cyclase - DG diacyglycerol - GH growth hormone - GTP guanosine trisphosphate - G_i GTP binding proteins that mediate inhibition of adenylate cyclase and that are pertussis toxin sensitive - G_s GTP binding protein that mediates stimulation of adenylate cyclase - GH cells clonal rat pituitary tumor cells producing PRL and/or growth hormone - GH₃ GH₄C₁ and GH₄B6 subclones of GH cells - PKA protein kinase A - PKC protein kinase C - PLC phospholipase C - PRL prolactin - TPA 12-O-tetradecanoyl phorbol 13-acetate - TRH thyrotropin releasing hormone - VIP vasoactive intestinal peptide     

On the mechanism of 5-bromodeoxyuridine induction of prolactin synthesis in rat pituitary tumor cells

GH12C1, a clonal strain of rat pituitary tumor cells in culture (GH cells), does not produce detectable amounts of prolactin. 5-Bromodeoxyuridine (BrdUrd), the thymidine analogue, at sublethal concentrations (3-5 microgram/ml) induces prolactin synthesis in these cells. BrdUrd also induces prolactin synthesis in F1BGH12C1 cells, a BrdUrd resistant (BrdUrdr) substrain isolated from GH12C1 cells. The F1BGH12C1 strain is not drug dependent, but its resistance to BrdUrd is a stable phenotype. The significant features of the induction of prolactin synthesis in the BrdUrdr strain are the increased net synthesis of prolactin and the shortening of the lag period of prolactin induction. As BrdUrd concentration in the growth medium is increased, the rise in prolactin synthesis parallels the increased incorporation of BrdUrd into DNA. Prolactin synthesis is first detected when BrdUrd replaces 20-25% of the thymidine in DNA. BrdUrd can replace up to 75-80% of the thymidine within 2 d of treatment. Partial starvation of these cells under specified growth conditions does not affect the general growth pattern of the cells, general protein synthesis, and thymidine uptake, but does affect DNA synthesis. When cells are cultured under conditions in which DNA synthesis is preferentially inhibited, BrdUrd does not induce prolactin synthesis, suggestive of a DNA-mediated mechanism of action for the drug.     

Prolactin and growth hormone synthesis and thymidine incorporation in dissociated rat pituitary tumor cells

The effect of in vivo diethylstilbestrol (DES) treatment on the MtT/W15 transplantable pituitary tumor was examined in dissociated pituitary cells by measuring the rate of incorporation of [3H]thymidine into DNA and the synthesis of prolactin (PRL) and growth hormone (GH) as assessed by the rate of incorporation of [3H]leucine. MtT/W15 transplantable pituitary tumors from rats treated for 3 weeks with DES showed significant reduction in the extent of [3H]thymidine incorporation compared with tumor cells from untreated rats (2231 +/- 182 vs 172 +/- 17 dpm/10(5) cells; n = 3). In addition, tumor cells from DES-treated rats showed a significant increase in GH synthesis compared with tumor cells from untreated rats. In contrast to these findings, dissociated pituitary cells from non-tumor-bearing rats given 10 mg DES in Silastic tubing for 3 weeks showed a three-fold increase in PRL synthesis compared to cells from untreated control rats (29.3 +/- 1.5 vs 10.0 +/- 0.9% of total radioactivity in gel; n = 3. There was also a four-fold increase in the rate of [3H]thymidine incorporation after DES-treatment in non-tumor-bearing rats (695 +/- 114 vs 178 +/- 13.9 dpm/10(5) cells; n = 3). These results indicate that DES inhibits MtT/W15 pituitary tumor cell proliferation, while stimulating synthesis of GH.     

Characterization of monoclonal antibodies against ovine prolactin: suitability for use in immunocytochemical analysis of rat prolactin

The aim of this study was to identify a monoclonal antibody (MAb) suitable for use in the immunocytochemical localization of prolactin in rat tissues. We took advantage of the conservation of certain amino acid sequences in prolactin among species by examining the crossreactivity patterns of five MAb, originally generated to ovine prolactin, with rat prolactin by enzyme-linked immunoassay (ELISA), Western blot analysis, and immunocytochemistry. Two of five antibodies (17D9 and 6F11) showed reactivity with 100 ng of immobilized rat prolactin (NIH RP-3) by ELISA, 6F11 reacting more strongly than 17D9. Only 6F11 reacted with prolactin in lysates of GH4C1 rat pituitary tumor cells by Western blot analysis. When we examined the crossreactivity of the MAb with rat prolactin in monolayer cultures of GH4C1 cells by indirect immunofluorescence, we found that both 17D9 and 6F11 reacted strongly with the cultures. The distribution of staining with 17D9 or 6F11 was coincident with staining with a polyclonal antiserum to rat prolactin. Preabsorption of the antibodies with a 20-fold excess of purified rat prolactin abolished the staining of GH4C1 cell cultures with either antibody. Therefore, we have selected from a series of MAb raised to ovine prolactin two antibodies (17D9 and 6F11) that react specifically with rat prolactin in immunocytochemical studies, whereas 6F11 also reacts strongly with rat prolactin by ELISA and Western blot analysis.     

Increased peptidylarginine deiminase expression during induction of prolactin biosynthesis in a growth-hormone-producing rat pituitary cell line, MtT/S.

Insulin and type I insulin-like growth factor (IGF-I) suppressed growth hormone (GH) expression followed by the induction of prolactin (PRL) biosynthesis in MtT/S cells cultured with normal sera. Insulin also increased the peptidylarginine deiminase activity in a dose-dependent manner. The increase was detectable at 1 ng/ml and reached a maximum (about 16-fold higher than the control) at 1 micrograms/ml. IGF-I showed similar but less prominent effects. The enzyme activity started to increase by 15 hr after the addition of insulin (500 ng/ml), and reached a plateau level at 48 hr. There were concurrent increases in the enzyme mRNA level, enzyme biosynthesis, and enzyme protein contents detected by Northern blot hybridization, [35S]-amino-acid incorporation, and Western immunoblot analysis, respectively. Two-color immunofluorescence staining at 1 day after the insulin addition detected a small number of peptidylarginine-deiminase-positive cells (about 1% of the total cells) which were also GH-positive. The enzyme-positive cells increased to 12% on day 2 and to 24-26% on days 4-6. PRL-positive cells first appeared in the enzyme-positive cell population on day 2, and PRL-positive, enzyme-negative cells appeared later. These results suggest that peptidylarginine deiminase expression increases in association with the hormone switching in MtT/S cells. When the cells were cultured in a steroid-depleted medium, insulin failed to increase the enzyme activity. The insulin action could be specifically restored by estrogen, indicating estrogen-insulin synergism in regulation of the enzyme expression.     

Thyroid hormonal activity of the flame retardants tetrabromobisphenol A and tetrachlorobisphenol A

The thyroid hormonal-disrupting activity of the flame retardants tetrabromobisphenol A (TBBPA) and tetrachlorobisphenol A (TCBPA) was examined and compared with that of bisphenol A, a typical estrogenic xenobiotic. TBBPA and TCBPA, halogenated derivatives of bisphenol A, markedly inhibited the binding of triiodothyronine (T(3); 1 x 10(-10) M) to thyroid hormone receptor in the concentration range of 1 x 10(-6) to 1 x 10(-4) M, but bisphenol A did not. The thyroid hormonal activity of TBBPA and TCBPA was also examined using rat pituitary cell line GH3 cells, which grow and release growth hormone (GH) depending on thyroid hormone. TBBPA and TCBPA enhanced the proliferation of GH3 cells and stimulated their production of GH in the concentration range of 1 x 10(-6) to 1 x 10(-4) M, while bisphenol A was inactive. TBBPA, TCBPA, and bisphenol A did not show antagonistic action, i.e., these compounds did not inhibit the hormonal activity of T(3) to induce growth and GH production of GH3 cells. TBBPA and TCBPA, as well as bisphenol A, enhanced the proliferation of MtT/E-2 cells, whose growth is estrogen-dependent. These results suggest that TBBPA and TCBPA act as thyroid hormone agonists, as well as estrogens.