Prolactin inhibits epidermal growth factor (EGF)-stimulated signaling events in mouse mammary epithelial cells by altering EGF receptor function.

We have previously shown that lactogenic hormones stimulate epidermal growth factor (EGF) mRNA accumulation in mouse mammary glands in vivo and in mouse mammary epithelial cells (NMuMG line). However, our in vitro studies indicate that the lactogenic hormone prolactin (PRL) completely inhibits EGF-stimulated DNA synthesis. PRL does not alter cholera toxin or insulin-like growth factor-1-stimulated cell growth, thus the inhibition appears to be specific for EGF. Our current studies are designed to evaluate the effects of PRL on EGF-stimulated signaling events in the NMuMG cell line. Cells treated with PRL for 30 min demonstrated a loss of high affinity EGF-binding ability. After long-term PRL treatment (18 h) there was a decrease in EGF receptor (R) number, as determined by [125I]EGF binding. PRL treatment (8 h) also decreased EGF-R mRNA levels. An EGF-stimulated increase in EGF-R mRNA observed 2-4 h after treatment was decreased when PRL was added to the cultures. Furthermore, levels of EGF-stimulated tyrosine phosphorylation of the EGF-R (170 kDa) and phospholipase C gamma (145 kDa) are dramatically decreased in cells treated with PRL. Also of great interest was a decrease in EGF-stimulated c-myc mRNA in PRL-treated cells. We conclude that PRL is acting to down-regulate the EGF-R, thus limiting EGF-stimulated cell signaling in mammary tissue.     

Gonadotropin-releasing hormone stimulates prolactin release from lactotrophs in photoperiodic species through a gonadotropin-independent mechanism

Previous studies have provided evidence for a paracrine interaction between pituitary gonadotrophs and lactotrophs. Here, we show that GnRH is able to stimulate prolactin (PRL) release in ovine primary pituitary cultures. This effect was observed during the breeding season (BS), but not during the nonbreeding season (NBS), and was abolished by the application of bromocriptine, a specific dopamine agonist. Interestingly, GnRH gained the ability to stimulate PRL release in NBS cultures following treatment with bromocriptine. In contrast, thyrotropin-releasing hormone, a potent secretagogue of PRL, stimulated PRL release during both the BS and NBS and significantly enhanced the PRL response to GnRH during the BS. These results provide evidence for a photoperiodically modulated functional interaction between the GnRH/gonadotropic and prolactin axes in the pituitary gland of a short day breeder. Moreover, the stimulation of PRL release by GnRH was shown not to be mediated by the gonadotropins, since immunocytochemical, Western blotting, and PCR studies failed to detect pituitary LH or FSH receptor protein and mRNA expressions. Similarly, no gonadotropin receptor expression was observed in the pituitary gland of the horse, a long day breeder. In contrast, S100 protein, a marker of folliculostellate cells, which are known to participate in paracrine mechanisms within this tissue, was detected throughout the pituitaries of both these seasonal breeders. Therefore, an alternative gonadotroph secretory product, a direct effect of GnRH on the lactotroph, or another cell type, such as the folliculostellate cell, may be involved in the PRL response to GnRH in these species.     

Effects of prolonged treatment with diltiazem on pituitary secretion of luteinizing hormone, follicle-stimulating hormone, thyrotropin and prolactin.

In previous studies it has been observed that acute administration or short-term treatment with calcium channel blockers can influence the secretion of some pituitary hormones. In this study, we have examined the effect of the long-term administration of diltiazem on luteinizing-hormone (LH), follicle-stimulating hormone (FSH), thyrotropin (TSH) and prolactin (PRL) levels under basal conditions and after gonadotropin-releasing hormone (GnRH)/thyrotropin-releasing-hormone (TRH) stimulation in 12 subjects affected by cardiovascular diseases who were treated with diltiazem (60 mg 3 times/day per os) for more than 6 months and in 12 healthy volunteers of the same age. The basal levels of the studied hormones were similar in the two groups. In both the treated patients and the control subjects, a statistically significant increase (p < 0.01) in LH, FSH, TSH and PRL levels was observed after GnRH/TRH administration. Comparing the respective areas under the LH, FSH, TSH and PRL response curves between the two groups did not present any statistically significant difference. These findings indicate that long-term therapy with diltiazem does not alter pituitary hormone secretion.     

Evaluation of TSH secretion after GnRh in patients with primary hypothyroidism

6 women (mean age 38 years) with high Thyroid Stimulating Hormone (TSH) serum levels because affected from primary hypothyroidism were studied. 6 healthy women (mean age 31 years) represented the control group. All subjects underwent evaluation of serum TSH, Follicle Stimulating Hormone (FSH), Luteinizing Hormone (LH), basally and 20, 30, 60, 120 minutes after administration of Gonadotropin Releasing Hormone (GnRH: 100 meg. IV). Seric FSH and LH show a large increase 30 minutes after GnRH either in healthy or in hypothyroid subjects. TSH is unresponsive to GnRH in normal condition, while shows a clear decrease (-78%) 30 minutes after GnRH in primary hypothyroidism. Rarely the hypothalamic releasing hormones possess an inhibitory effect on anteipophyseal secretions. Previously a GnRH inhibitory effect on prolactin (PRL) release from PRL secreting tumors in rat. The GnRH inhibitory effect on TSH release in pathological conditions such as primary hypothyroidism is difficult to explain: it may be that GnRH acts on Central Nervous System or at pituitary level: in the last case it could bind sites which are not quite different in the different glycoprotein secreting cells.     

Hormonal regulation of gonadotropin-releasing hormone receptors and messenger RNA activity in ovine pituitary culture

Previous studies demonstrate that gonadotroph responsiveness to GnRH, GnRH binding, and the apparent number of GnRH receptors are all increased by 17 beta-estradiol (E) or inhibin (IN) in ovine pituitary cultures. Progesterone (P) attenuates these effects. To explore differences between the effects of IN and E on GnRH binding, a detailed time-course study was performed. The results indicate that after 48 h, IN had a greater effect on binding of a GnRH agonist (5-fold increase) than E (3-fold increase), but was slower to act initially. A combined treatment of IN and E gave a partially additive effect at 48 h (6.5-fold increase). The mechanism of receptor regulation in this system is not known, but could involve synthesis, recycling, or modification of GnRH receptors. To investigate the contribution of altered receptor biosynthesis to the regulation of receptor levels, a functional Xenopus oocyte-based assay for GnRH receptor mRNA activity was employed. After 48 h of treatment, IN or E each led to a 7- to 8-fold increase in GnRH receptor mRNA activity. Treatment with both hormones led to a 19-fold increase. The increase in mRNA activity induced by either hormone was greatly attenuated by P. Modulation of GnRH receptor mRNA levels suggests that IN, E, and P regulate responsiveness to GnRH in the ovine pituitary at least in part by altering de novo synthesis of GnRH receptors. The differing time courses of action, as assayed by GnRH binding, and the additivity of effects at the mRNA level suggest that IN and E alter mRNA levels via different mechanisms.     

Differences in prolactin receptor (PRLR) in mouse and human fallopian tubes: evidence for multiple regulatory mechanisms controlling PRLR isoform expression in mice

The anterior pituitary-derived hormone prolactin (PRL) signals through the PRL receptor (PRLR) and is important for female reproductive function in mammals. In contrast to the extensive studies of PRLR expression and regulation in human and mouse ovary and uterus, the mechanisms controlling the regulation of PRLR isoform expression in the fallopian tube are poorly understood. Because dynamic interaction of hormonal signaling in gonadal tissue and the pituitary or in gonadal tissues themselves in mammals suggests endocrine or paracrine regulation of PRLR expression, we questioned whether differential regulation of PRLR isoforms by PRL ovarian-derived estrogen (E(2)) and progesterone (P(4)) exists in the fallopian tube and pituitary of prepubertal female mice. Western blot analysis showed distinct molecular separation of PRLR isoforms in mouse and human fallopian tubes, and cellular localization was found in mouse and human tubal epithelia but not in mouse tubal smooth muscle cells. These data support the concept of an isoform- and cell type-specific expression of PRLR in human and mouse fallopian tubes. Moreover, expression of the long form of PRLR decreased after PRL treatment and increased after blockage of endogenous PRL secretion by bromocriptine (an inhibitor of PRL secretion) in a time-dependent manner in mouse fallopian tube. The opposite regulation was observed in the pituitary. Treatment with exogenous E(2) or P(4) led to changes in PRLR expression in the fallopian tube similar to those of PRL treatment. However, E(2) and P(4) did not affect PRLR expression in the pituitary. Estrogen had no effect on the long form of PRLR expression, whereas P(4) regulated the long form of PRLR in the fallopian tube, as did PRL. Taken together, the data from our comparative study provide evidence that PRLR can be regulated by an interplay of two different mechanisms, PRL or ovarian steroid hormones independently or in combination in a tissue-specific manner. Furthermore, we found that ovarian steroid hormones selectively suppress the expression of PRLR isoforms in mouse fallopian tubes. These findings may contribute to our understanding of the mechanisms controlling PRLR isoform expression in the fallopian tube (in addition to ovary and uterus), with implications for female reproduction.     

Gonadotropin, prolactin and thyrotropin pituitary secretion after exogenous dehydroepiandrosterone-sulfate administration in normal women.

The effect of exogenous dehydroepiandrosterone-sulfate (DHAS) on luteinizing hormone (LH), follicle-stimulating hormone (FSH), prolactin (PRL) and thyroid-stimulating hormone (TSH) pituitary secretion was studied in 8 normal women during the early follicular phase. The plasma levels of these hormones were evaluated after gonadotropin-releasing hormone (GnRH)/thyrotropin-releasing hormone (TRH) stimulation performed after placebo or after 30 mg DHAS i.v. administration. The half-life of DHAS was also calculated on two subjects; two main components of decay were detected with half-times of 0.73-1.08 and 23.1-28.8 h. The results show an adequate response of all hormones to GnRH or TRH tests which was not significantly modified, in the case of LH, FSH and PRL, when performed in the presence of high levels of DHAS. However, the TSH response to TRH was significantly less suppressed (p less than 0.05) (39%) after DHAS administration than during repeated TRH stimulation without DHAS (51%). The data support the hypothesis that DHAS does not affect LH, FSH and PRL secretion, while TSH seemed to be partially influenced.     

Pituitary gonadotropins, hypothalamic gonadotropin-releasing hormone, and testicular traits of boars exposed to natural or supplemental lighting during pubertal development

Seventy crossbred boars were reared under natural (30 lux) or supplemental lighting (1000 lux) beginning at 4 wk of age. Boars received supplemental lighting from six 40-watt fluorescent bulbs between 0530 and 2030 h. Five boars from each treatment were killed at 67, 91, 119, 155, 182, 210, or 246 days of age. No differences (p greater than 0.05) in pituitary concentrations of luteinizing hormone (LH), follicle-stimulating hormone (FSH), and prolactin (PRL) were found between treatment groups at any age. Total pituitary content of LH, FSH and PRL increased as boars became older, but when expressed as hormone concentration, only PRL increased with age. Content of gonadotropin-releasing hormone (GnRH) in the pituitary stalk-median eminence, preoptic area, and hypothalamus proper was similar (p greater than 0.05) between treatments. When GnRH contents were totaled and combined for the treatment groups, it was found that GnRH content increased (p less than 0.05) as boars became older. No differences (p greater than 0.05) were observed in testicular volume percentage of seminiferous tubules and tubular diameter between lighting treatments. These data demonstrate that the supplemental lighting does not influence puberty in boars by altering hypothalamic content of GnRH or pituitary stores of LH, FSH, and PRL.     

PKC and ERK are differentially involved in gonadotropin-releasing hormone-induced growth hormone gene expression in the goldfish pituitary

Gonadotropin-releasing hormone (GnRH) is produced by the hypothalamus and stimulates the synthesis and secretion of gonadotropin hormones. In addition, GnRH also stimulates the production and secretion of growth hormone (GH) in some fish species and in humans with certain clinical disorders. In the goldfish pituitary, GH secretion and gene expression are regulated by two endogenous forms of GnRH known as salmon GnRH and chicken GnRH-II. It is well established that PKC mediates GnRH-stimulated GH secretion in the goldfish pituitary. In contrast, the signal transduction of GnRH-induced GH gene expression has not been elucidated in any model system. In this study, we demonstrate, for the first time, the presence of novel and atypical PKC isoforms in the pituitary of a fish. Moreover, our results indicate that conventional PKC alpha is present selectively in GH-producing cells. Treatment of primary cultures of dispersed goldfish pituitary cells with PKC activators (phorbol ester or diacylglycerol analog) did not affect basal or GnRH-induced GH mRNA levels, and two different inhibitors of PKC (calphostin C and GF109203X) did not reduce the effects of GnRH on GH gene expression. Together, these results suggest that, in contrast to secretion, conventional and novel PKCs are not involved in GnRH-stimulated increases in GH mRNA levels in the goldfish pituitary. Instead, PD98059 inhibited GnRH-induced GH gene expression, suggesting that the ERK signaling pathway is involved. The results presented here provide novel insights into the functional specificity of GnRH-induced signaling and the regulation of GH gene expression.     

GnRH相关肽在大鼠垂体前叶的细胞学定位

本研究应用特异性抗GnRH相关肽(GAP)N端11个氨基酸的抗血清和六种垂体前叶激素的抗血清,通过免疫组织化学双重染色技术观察GAP在大鼠垂体前叶细胞的定位。结果发现,GAP样免疫反应性物质存在于LH细胞和FSH细胞,而未见于GH、PRL、TSH和ACTH细胞。本文首次证明GAP存在于正常大鼠垂体促性腺激素细胞,为GAP调节LH和FSH的分泌提供了形态学证据;也支持GAP的功能序列在其分子的N端,或GAP进一步裂解出N端片段而发挥作用。     

Development of gonadotropes may involve cyclic transdifferentiation of growth hormone cells

The cyclic rise in expression of anterior pituitary gonadotropins coincides with the appearance of cells sharing gonadotropic and somatotropic phenotypes. To learn more about possible factors that regulate the origin of this cell type, we studied the time of appearance of cells that co-expressed growth hormone (GH) and gonadotropins and estrogen receptors during the estrous cycle and compared this timing with known changes in regulatory hormones or their receptors. The first event in this cell population is an increase in expression of estrogen receptor (ER)beta by GH cells from estrus to metestrus suggesting that estrogen may mediate this early change. Expression of GH mRNA rises rapidly from metestrus to mid-cycle. The rise is seen first in GH cells and then in cells with luteinizing hormone (LH) antigens. These data suggest that, early in the cycle, cells bearing GH and growth hormone releasing hormone (GHRH) receptors begin to produce LH and gonadotropin releasing hormone (GnRH) receptors. Early in proestrus, there is an increase in cells with GH and follicle-stimulating hormone (FSH) suggesting that this set of multipotential cells develops later than GH-LH cells. This fits with earlier studies showing the later rise in expression of FSH mRNA. Collectively these data suggest that the anterior pituitary contains a subset of GH cells that have the capacity to respond to multiple releasing hormones and support more than one system.     

Regulation of aromatase mRNA and estradiol biosynthesis in rat ovarian granulosa and luteal cells by prolactin

Regulation by PRL of aromatase (P450arom) mRNA and protein and estradiol (E) biosynthesis was examined in granulosa cells during early stages of luteinization in vitro and in vivo. PRL caused a dose-dependent (10-1000 ng/ml) decrease in P450arom mRNA and E biosynthesis (greater than 99%) in luteinized rat granulosa cells in vitro, even when the cells were cultured in the presence of insulin and hydrocortisone (hormones known to synergize with PRL to induce proteins in mammary tissue) or in the presence of forskolin (a nonhormonal stimulator of cAMP). PRL also prevented the marked increases in aromatase mRNA and E biosynthesis stimulated by FSH and forskolin in nonluteinized preovulatory granulosa cells in culture. These effects of PRL on granulosa cells in culture were specific for aromatase and were not observed for other proteins, such as cholesterol side-chain cleavage cytochrome P450 (P450scc) and alpha 2-macroglobulin. PRL also decreased P450arom mRNA and protein during the early stages of luteinization in vivo. PRL administered to rats beginning day 1 postovulation to mimic hormone release during pseudopregnancy reduced the progressive increase in P450arom mRNA occurring in corpora lutea on days 3-4 in ovulated rats not treated with PRL. CB 154, a dopamine agonist that inhibits pituitary release of PRL, caused P450arom mRNA and protein to decrease 50% if given to pregnant rats on days 8-10 of gestation, but increased P450arom mRNA and protein if given to pregnant rats on days 10-12 of gestation. These diverse effects of PRL in pregnancy suggest that placental factors may modify the response of luteal cells to PRL during gestation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Profiles of mRNA expression for prolactin,growth hormone,and somatolactin in Japanese eels,Anguilla japonica: The effect of salinity,silvering and seasonal change

For understanding the functions of the growth hormone (GH)/prolactin (PRL)/somatolactin (SL) family of hormones, we examined pituitary mRNA expression of these hormones in anguillid eels in relation to salinity difference, silvering, and seasonal change. Female Japanese eels (Anguilla japonica) were collected in the brackish Hamana Lake and its freshwater rivers from July to December. To clarify the effect of salinity, the habitat use history of the eels were determined using otolith microchemistry. Expression levels of mRNA of each hormone were determined using real time PCR. Although GH and PRL have been known to be osmoregulatory hormones, there were no consistent differences in expression levels of these hormones between different salinity habitats. In contrast, SL mRNA expression was higher in eels from freshwater rivers than from the brackish lake. GH mRNA expression clearly decreased during silvering, whereas PRL and SL mRNA expression did not change. We also showed that PRL mRNA and SL mRNA decreased in the brackish lake and PRL mRNA increased in freshwater rivers from autumn to early winter. These findings provide basic knowledge for a further understanding of the role of these hormones.     

Kisspeptin-10 stimulates the secretion of growth hormone and prolactin directly from cultured bovine anterior pituitary cells

Kisspeptins are peptide hormones encoded by the KiSS-1 gene, and act as the principal positive regulator of the reproductive axis by directly stimulating gonadotropin-releasing hormone (GnRH) neuron activity. We recently observed that kisspeptin-10 (the minimal kisspeptin sequence necessary for receptor activation) also has a direct stimulating effect on luteinizing hormone (LH) secretion in bovine anterior pituitary (AP) cells. In the present study, we evaluated the direct effect of kisspeptin-10 on the secretion of other pituitary hormones, growth hormone (GH) and prolactin (PRL), from bovine AP cells. The AP cells, which were prepared from 1- or 8-month-old male calves, were incubated for 2h with the peptides. Kisspeptin-10 at 100 nM (P<0.05), 1000 nM (P<0.01) and 10,000 nM (P<0.01), but not at 10 nM, significantly stimulated GH secretion from the AP cells of 1-month-old calves, while in 8-month-old calves it was significantly (P<0.05) stimulated at 1000 nM (P<0.01) and 10,000 nM (P<0.01), but not at 10nM and 100 nM. The response of GH to 100 nM (P<0.01), 1000 nM (P<0.05) and 10,000 nM (P<0.01) kisspeptin-10 in the AP cells of 1-month-old calves was significantly greater than in those of 8-month-old calves. All tested doses of kisspeptin-10 had no effect on PRL secretion from AP cells of 1-month-old calves. However, 1000 nM (P<0.05) and 10,000 nM (P<0.01), but not lower concentrations, of kisspeptin-10 significantly stimulated PRL secretion from the AP cells of 8-month-old calves. The present study is, as far as we know, the first to examine the direct actions of kisspeptin on the secretion of GH and PRL from the bovine pituitary gland. Further studies are necessary to evaluate the importance of multiple actions of kisspeptin on the pituitary of various animals in vivo.     

Effect of guanine nucleotides on phospholipase C activity in permeabilized pituitary cells: possible involvement of an inhibitory GTP-binding protein

Cultured pituitary cells prelabeled with myo-[2-3H] inositol were permeabilized by ATP4-, exposed to guanine nucleotides and resealed by Mg2+. Addition of guanosine 5'-0-(3-thio triphosphate) (GTP gamma S) to permeabilized cells, or gonadotropin releasing hormone (GnRH) to resealed cells, resulted in enhanced phospholipase C activity as determined by [3H] inositol phosphate (Ins-P) production. The effect was not additive, but the combined effect was partially inhibited by guanosine 5'-0-(2-thiodiphosphate) (GDP beta S) or by neomycin. Surprisingly, addition of GDP beta S (100-600 microM) on its own resulted in a dose-related increase in [3H]Ins-P accumulation. Several nucleoside triphosphates stimulated phospholipase C activity in permeabilized pituitary cells with the following order: UTP greater than GTP gamma S greater than ATP greater than CTP. The stimulatory effect of UTP, ATP and CTP, but not GTP gamma S or GDP beta S, could also be demonstrated in normal pituitary cells suggesting a receptor-activated mechanism. GTP and GTP gamma S decreased the affinity of GnRH binding to pituitary membranes and stimulated LH secretion in permeabilized cells. These results suggest the existence of at least two G-proteins (stimulatory and inhibitory) which are involved in phospholipase C activation and GnRH action in pituitary cells.     

Stimulation of rat luteinizing hormone-beta messenger RNA levels by gonadotropin releasing hormone. Apparent role for protein kinase C

The ability of gonadotropin releasing hormone (GnRH) to elevate cellular levels of mRNA for beta-subunit of luteinizing hormone (LH) has been examined in monolayer cultures from rat pituitary. Low concentrations of GnRH (100 pM) induced a 6.8-fold increase in LH-beta mRNA, while higher concentrations of GnRH were less effective. The low concentrations of GnRH (100 pM) did not result in altered GnRH receptor levels (92 +/- 12% compared to controls) after 24 h treatment but did increase protein kinase C activity to 249 +/- 16%. The protein kinase C activator, phorbol 12-myristate 13-acetate, at concentrations (2-20 nM) which did not deplete protein kinase C, stimulated LH-beta mRNA levels 2-5-fold after 24 h. Higher concentrations of phorbol 12-myristate 13-acetate, which depleted protein kinase C activity, substantially reduced the ability of 100 pM GnRH to stimulate increases in LH-beta mRNA levels. As previously observed, protein kinase C-depleted cells exhibited normal LH release in response to GnRH stimulation. These studies demonstrate that low concentrations of GnRH may have an important role in regulation of gonadotropin biosynthesis. Furthermore, the results suggest that activation of protein kinase C is sufficient to stimulate increases in LH-beta mRNA levels and that protein kinase C is necessary for normal GnRH stimulation of LH-beta mRNA levels. Accordingly, we postulate that protein kinase C may mediate the action of GnRH on LH-beta mRNA levels.     

Inhibitory effects of cysteamine on neuroendocrine function

The action of cysteamine on anterior pituitary hormone secretion was studied in vivo using conscious, freely moving male rats and in vitro using anterior pituitary cells in monolayer culture. Administration of 500 micrograms cysteamine into the lateral cerebral ventricles of normal rats caused the complete inhibition of pulsatile GH secretion for a minimum of 6 h. This treatment also significantly decreased plasma concentrations of LH for at least 6 h in orchiectomized rat, TSH in short-term (0.5 month) thyroidectomized rats, and PRL in long-term (6 months) thyroidectomized rats. The in vivo stimulation of GH, LH, TSH and PRL with their respective releasing hormones 60 min after administration of cysteamine was not different from the response observed in rats pretreated with saline except for PRL where cysteamine pretreatment significantly inhibited the expected PRL increase. In vitro, 1 mM cysteamine decreased basal and TRH stimulated PRL release while not affecting basal or stimulated GH, LH, TSH and ACTH secretion. These data demonstrate the dramatic and wide-ranging effects of cysteamine on anterior pituitary hormone secretion. This action appears to be mediated through hypothalamic pathways for GH, LH and TSH and through a pituitary pathway for PRL.