Regulation of the rat liver sodium-dependent bile acid cotransporter gene by prolactin. Mediation of transcriptional activation by Stat5.

The intracellular mechanism(s) underlying the upregulation of the hepatic Na+/taurocholate cotransporting polypeptide (ntcp) by prolactin (PRL) are unknown. In this report, we demonstrate a time-dependent increase in nuclear translocation of phosphorylated liver Stat5 (a member of the ignal ransducers and ctivators of ranscription family) that correlated with suckling-induced increases in serum PRL levels. In electrophoretic mobility gel shift assays, nuclear Stat5 exhibited specific DNA-binding ability towards IFN-gamma-activated sequence (GAS)-like elements (GLEs; 5'TTC/A-PyNPu-G/TAA-3') located in the -937 to -904 bp region of the ntcp promoter. Transient cotransfections in HepG2 cells revealed that PRL inducibility (2.5-3-fold) required coexpression of the long form of the PRL receptor (PRLRL) and Stat5. Deletion analysis mapped the PRLinducible region to -1237 to -758 bp of the ntcp promoter. Linking this 0.5-kb region to a heterologous thymidine kinase (tk) promoter, or linking multimerized ntcp GLEs either upstream of the ntcp minimal promoter (-158 to +47 bp) or the heterologous promoter conferred dose-dependent PRL responsiveness. The short form of the PRL receptor failed to transactivate ntcp GLEs. These results indicate that PRL acts via the PRLRL to facilitate Stat5 binding to ntcp-GLEs and to transcriptionally regulate ntcp.

Characterization of prolactin-releasing factor in the rat posterior pituitary.

We previously reported that the rat posterior pituitary contains a potent PRL-releasing factor (PRF) which is distinct from oxytocin (OT), TRH, and angiotensin II (AII). The objectives of this study were 1) to examine whether posterior pituitary extracts stimulate PRL release in the presence of dopamine (DA), 2) to determine the chemical nature of PRF, and 3) to estimate its mol wt. Perifused anterior pituitary cells were used to assess PRF activity. Posterior pituitaries and medial basal hypothalamus (MBH) fragments were extracted with perchloric acid and lyophilized. Subsequent to various treatments, samples were reconstituted in the perifusion medium and introduced to the cells in short pulses. Fractions were collected and analyzed for hormone content by RIA. During a constant infusion of DA (50 nM), PRL secretion was inhibited by 75%, yet the posterior pituitary extract retained its ability to rapidly stimulate PRL release. Studies using proteolytic enzymes showed that posterior pituitary PRF was resistant to inactivation by trypsin, whereas the PRF activity of AII was abolished. Both chymotrypsin and proline-specific endopeptidase significantly reduced the PRF activity in the posterior pituitary. The PRL-releasing activity of TRH was not affected by chymotrypsin. Immunoreactive vasoactive intestinal polypeptide was undetectable in posterior pituitary extracts. Oxidation of posterior pituitary extracts with performic acid caused only a modest reduction of their PRF activity, while the ability of OT to stimulate PRL release as well as immunoreactive OT was abolished. Studies using ultrafiltration membranes showed that the PRF activity in the posterior pituitary was less than 5,000 mol wt. Furthermore, posterior pituitary PRF partitioned in nearly equal amounts across 1K membranes, as did AII and OT. In contrast, about 80% of the PRF activity in the MBH and all of the synthetic TRH passed through the 1K membranes. We conclude that 1) posterior pituitary PRF can stimulate PRL secretion from perifused anterior pituitary cells in the presence of physiological concentrations of DA; 2) PRF is a small peptide(s) of less than 5,000, and perhaps closer to 1,000, mol wt; 3) PRF is resistant to inactivation by trypsin and to oxidation by performic acid, but is hydrolyzed by both chymotrypsin and proline-specific endopeptidase; and 4) these data further distinguish posterior pituitary PRF from known PRL secretagogues.

The posterior pituitary contains a potent prolactin-releasing factor: in vivo studies.

The posterior pituitary contains a PRL-releasing factor (PRF), a small (less than 5000 mol wt) peptide which is distinct from known PRL secretagogues. The objectives of this study were to determine if posterior pituitary extracts specifically stimulate PRL release in vivo and to assess the relative contributions of oxytocin (OT), arginine vasopressin (AVP), and beta-endorphin (beta END) to the PRF activity of the extract. Rat posterior pituitaries or cerebellar tissue were extracted with 1.0 N acetic acid, boiled, and ultrafiltered through 5000 mol wt cutoff membranes. The eluates were treated with performic acid (which oxidizes disulfide bonds and methionine residues), lyophilized, and reconstituted in saline. Jugular blood was collected from conscious ovariectomized rats before and after intracarotid injection of test substances and was analyzed for PRL, LH, and GH by RIA. Injection of 0.3, 1.0, and 3.0, posterior pituitary equivalents increased plasma PRL levels by 2-, 8-, and 22-fold, respectively. PRL levels peaked within 5 min after the injection and returned to basal levels by 30 min. Plasma LH levels decreased slightly, and GH was unchanged. Cerebellar extracts did not affect plasma hormone levels. Injection of OT induced a 4-fold rise in plasma PRL levels. Oxidation of OT was well as AVP with performic acid abolished any PRL-releasing activity. Injection of beta END increased plasma PRL levels by 7-fold. Treatment of beta END with performic acid caused a 60% loss in its ability to release PRL. Pretreatment of rats with naloxone abolished the PRL-releasing effect of beta END, but did not alter the PRF activity of posterior pituitary extracts. We conclude that posterior pituitary extracts stimulate PRL release in vivo in the presence of an intact dopaminergic inhibition. This stimulation is rapid, dose dependent, and hormone specific. OT, AVP, and beta END do not contribute significantly to the PRF activity in the posterior pituitary extract.

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

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

Regulation of galanin gene expression in the rat anterior pituitary gland by the somatostatin analog SMS 201-995.

In addition to inducing pituitary tumors in rats, estrogen (E2) markedly increases galanin and PRL gene expression. We previously showed that galanin secretion from pituitary cells in vitro is inhibited by dopamine and somatostatin and stimulated by TRH. The objectives of these in vivo studies were to assess whether the long-acting somatostatin analog SMS 201-995 alters 1) immunoreactive galanin or PRL levels in the anterior pituitary, neurointermediate lobe, hypothalamus, or plasma, 2) pituitary galanin and PRL mRNA levels, and 3) the development of E2-induced pituitary tumors. Ovariectomized Fischer 344 rats were implanted with E2-filled or empty Silastic capsules and treated with or without SMS 201-995 (1.5 mg) via Alzet miniosmotic pumps. Two or 6 weeks later, immunoreactive galanin and PRL levels were determined by RIA. In ovariectomized rats, the somatostatin analog lowered the anterior pituitary content of galanin by 50%, but had no effect on PRL concentrations. E2 increased galanin and PRL levels in the anterior pituitary by 220- and 4-fold, respectively. Concomitant E2 and SMS 201-995 treatment further increased galanin and PRL in the anterior pituitary by 60-80%, but decreased plasma galanin and PRL levels. Likewise, the administration of SMS 201-995 for 2 and 6 weeks inhibited the E2-induced growth of the anterior pituitary. Galanin and PRL mRNA levels were quantified by solution hybridization. Galanin mRNA levels were reduced to undetectable levels in ovariectomized rats treated with SMS 201-995. Furthermore, a 10-fold increase in galanin mRNA levels seen in the presence of E2 was inhibited 80% by SMS 201-995. PRL mRNA levels in E2-treated rats were unchanged by SMS 201-995. We conclude that SMS 201-995 1) lowers plasma galanin and PRL levels in E2-treated rats, 2) elevates the anterior pituitary contents of galanin and PRL in E2-exposed rats, probably through decreased secretion of the hormones, and 3) reduces galanin mRNA levels in E2-treated and untreated ovariectomized rats. Overall, these results establish the differential regulation of galanin and PRL gene expression in vivo by SMS 201-995. Moreover, the data demonstrate that somatostatin receptor agonists may have therapeutic potential for some prolactinomas.

The human growth hormone-releasing hormone transgenic mouse as a model of modest obesity: differential changes in leptin receptor (OBR) gene expression in the anterior pituitary and hypothalamus after fasting and OBR localization in somatotrophs.

We reported previously an increase in leptin receptor (OBR) gene expression in the anterior pituitary of human GH-releasing hormone (hGHRH) transgenic mice. The primary goal of this study was to investigate the possible mechanisms regulating OBR expression in these mice. Compared with normal sibling controls, hGHRH transgenic mice had significantly greater amounts of abdominal fat, higher levels of leptin messenger RNA (mRNA), and a 2-fold increase in plasma leptin concentrations. Despite normal plasma glucose levels, hGHRH transgenic mice had 4.5-fold elevated levels of plasma insulin. Using a ribonuclease protection assay, we measured the mRNA levels of the OBR long form (OBR(L)) in the anterior pituitary and hypothalamus after 48 h of fasting. In the anterior pituitary, food deprivation induced dramatic increases in OBR(L) mRNA levels in both normal and transgenic mice. In contrast, in the hypothalamus, fasting resulted in a significant decrease in OBR(L) gene expression in normal mice, and no changes were detected in hGHRH transgenic mice. Using dual in situ hybridization, OBR(L) mRNA was detected in somatotrophs. Moreover, the number of OBR(L)-positive pituitary cells as well as the percentage of OBR(L)-positive cells that express GH mRNA were increased in transgenic mice. In conclusion, 1) the modest obesity in hGHRH transgenic mice is associated with increases in leptin synthesis and secretion as well as insulin secretion; 2) GH and/or GHRH as well as leptin and insulin may differentially contribute to the changes in OBR(L) gene expression in the anterior pituitary and the hypothalamus; 3) the response of OBR(L) gene expression in the hypothalamus to fasting is absent in the modestly obese hGHRH transgenic mice; and 4) somatotrophs are target cells for leptin, and the increase in OBR(L) gene expression in the pituitary of hGHRH transgenic mice is due at least in part to the increase in the number of cells expressing OBR(L).

Upregulation of leptin receptor gene expression in the anterior pituitary of human growth hormone-releasing hormone transgenic mice.

The recently cloned leptin receptor (OB-R) is expressed in many tissues, including the anterior pituitary. It is not known whether OB-R gene expression is regulated by pituitary hormones. In the present study, we detected the long isoform of OB-R (OB-R(L)) in the anterior pituitary of normal mice using RT-PCR, but were unable to detect the short isoform (OB-R(S)). In human growth hormone-releasing hormone (hGHRH) transgenic mice, we discovered a significant increase in OB-R(L) mRNA levels in the anterior pituitary as compared to controls, and OB-R(S) gene expression was detectable. In contrast to the pituitary, there were no significant changes in OB-R gene expression for either isoform in the hypothalamus of hGHRH mice. The dramatic increase in the gene expression of OB-R(L) in the anterior pituitary of hGHRH transgenic mice was confirmed by RNase protection assay. This is the first study to demonstrate that OB-R gene expression in the anterior pituitary gland is increased by GH and/or GHRH.

The rat posterior pituitary contains a potent prolactin-releasing factor: studies with perifused anterior pituitary cells.

UNLABELLED: We previously reported that removal of the posterior pituitary abolished the suckling-induced rise in plasma PRL. This suggested that the posterior pituitary contains a PRL-releasing factor (PRF). Using perifused anterior pituitary cells, the objectives of this study were 1) to examine whether the posterior pituitary contains PRF activity as compared to the medial basal hypothalamus (MBH), and 2) to determine to what extent substances known to be present in the posterior pituitary and/or MBH contribute to this activity. Anterior pituitary cells, attached to Cytodex beads, were perifused with medium 199. Tissues were extracted with acid, lyophilized, and reconstituted in medium 199. Tissue extracts and synthetic compounds were introduced to the cells in short pulses. Fractions were collected and analyzed for PRL, LH, and GH by RIA. Posterior pituitary extracts contained a potent substance(s) which stimulated PRL release in a concentration-dependent manner, but did not alter LH secretion. As little as 1% of the extract increased PRL release. In contrast, the MBH extract contained significantly less PRF activity but was capable of stimulating and inhibiting LH and GH release, respectively. Cerebellar extracts did not alter PRL secretion. Of more than 25 neuroactive substances tested in the perifusion system, oxytocin, TRH, and angiotensin II (A II) appeared as likely candidates for PRF. Therefore, the specific receptor antagonists d(CH2)5Tyr(Me) ornithine vasotocin (for oxytocin), chlordiazepoxide (for TRH), or saralasin (for A II) were infused together with the posterior pituitary extract. These antagonists completely abolished the PRL-releasing activities of their respective peptides but failed to reduce the PRF activity of the posterior pituitary. In contrast, PRF activity in the MBH was nearly eliminated by the TRH antagonist. CONCLUSIONS: 1) The rat posterior pituitary contains a potent PRF capable of inducing a rapid, hormone-specific, concentration-dependent stimulation of PRL release from perifused anterior pituitary cells. 2) The MBH contains significantly less PRF activity, which is largely attributable to TRH. 3) Although the chemical identity of PRF is yet unknown, the PRF activity in the posterior pituitary is not accounted for by oxytocin, TRH, or A II.

An estrogen receptor binding site within the human galanin gene.

Regulation of galanin gene expression in the anterior pituitary (AP) is positively influenced by estrogen in rodents and undetermined in humans. The objective of this study was to investigate the mechanism behind estrogen induction of galanin by identifying any putative estrogen receptor (ER) binding sequences within the human galanin promoter that may function as estrogen response elements (ERE). Two regions, gERE1 and gERE2, were identified in the galanin 5'-flanking sequence with similarity to the full 13-base ERE consensus previously defined in the vitellogenin gene (vERE). Both sequences were tested in mobility shift assays for the ability to bind nuclear proteins isolated from rat AP tissue or MtTW-10 pituitary tumors. Only the distal sequence at -527 (gERE1) yielded an ERE-specific DNA/protein complex distinguished by mobility and cross-competition with vERE. The gel mobility pattern of the DNA/protein complex was comparable between the pituitary tissue and tumor extracts. However, DNA/protein affinity estimations demonstrated a greater affinity of pituitary proteins for gERE1 over the vERE sequence. Evidence that the human ER (hER) does recognize the gERE1 sequence in the human galanin gene was provided by electrophoretic mobility shift assays (EMSAs) with Sf9 extracts enriched in recombinant hER. In addition, antibodies specific for the hER recognized the gERE1/protein complex in supershift experiments. Enhancer activity by gERE1 was detected in transient transfections of the rat GH3 pituitary cell line, resulting in a 4-fold induction of expression driven by the heterologous thymidine kinase promoter in the presence of estrogen. Evidence for ER regulation of the gERE1 enhancer was demonstrated by: 1) inhibition of enhancement using the specific ER antagonist ICI 164,384; and 2) enhancement in HeLa cells that was dependent upon coexpression with hER. Enhancement by gERE1 was half the magnitude as that from the vERE element and may reflect a difference in affinity or composition of the ER complex between the two sequences. These data demonstrate the presence of a functional ERE sequence within the human galanin gene that could potentially function as a regulatory element for estrogen action in the AP.

The vasopressin-associated glycopeptide is not a prolactin-releasing factor: studies with lactating Brattleboro rats.

We have recently reported that the posterior pituitary contains PRL-releasing factor (PRF), a small (less than 5000 mol wt) peptide which induces a rapid, hormone-specific, and concentration-dependent stimulation of PRL secretion. Although the identity of posterior pituitary PRF is yet unknown, it is distinct from known PRL secretagogues. Recently, the vasopressin-associated glycopeptide (VAG), which is concentrated in the posterior pituitary, was suggested as a PRF. To investigate whether VAG functions as a PRF, we used Brattleboro rats, which are deficient in arginine vasopressin (AVP), AVP-associated neurophysin, and VAG. Homozygous (DI) and heterozygous (HZ) lactating Brattleboro rats were used. The water consumption of pregnant DI rats (greater than 300 ml/day) was 6-fold higher than that of HZ rats. To correct their water imbalance, DI rats were implanted with osmotic minipumps containing the vasopressin analog 1-desamino-8-D-arginine vasopressin. On days 7-8 of lactation, pups were separated for 6 h, and blood was collected from the dams via a jugular cannula. Upon introduction of the pups, plasma PRL levels increased 100-fold in both DI and HZ rats and remained elevated for the duration of suckling. The suckling-induced rises in plasma oxytocin in DI and HZ rats were also superimposable. The weight gains of the pups of DI and HZ mothers were similar. PRF activity was determined using perifused anterior pituitary cells. Posterior pituitaries from DI and HZ rats contained equivalent amounts of PRF activity. Moreover, purified rat VAG (1.5 and 6.0 micrograms) failed to stimulate PRL release from pituitary cells. The posterior pituitary content of immunoreactive AVP was 2500-fold higher in HZ rats, but the contents of dopamine and oxytocin were similar. It is concluded that VAG neither mediates the suckling-induced rise of plasma PRL, nor stimulates PRL secretion from perifused anterior pituitary cells. Furthermore, posterior pituitaries from DI and HZ rats contain equivalent amounts of PRF activity. Collectively, these data indicate that VAG is not the posterior pituitary PRF.

MtTW-10 pituitary tumor cells: galanin gene expression and peptide secretion.

The peptide galanin is synthesized within and secreted from specific cell types of the rat anterior pituitary gland. The small size of the rat anterior pituitary gland is somewhat limiting for studying the regulation of galanin gene expression and peptide synthesis/secretion. We examined the mammotropic rat pituitary tumor MtTW-10 as a possible model system to study galanin. The objectives of this study were to 1) determine if galanin is secreted from MtTW-10 cells in vitro in a regulated manner, 2) characterize the molecular forms of immunoreactive galanin secreted by MtTW-10 cells, and 3) assess whether galanin gene expression in MtTW-10 tumors is regulated by estradiol. MtTW-10 pituitary tumors were transplanted to female Wistar-Furth rats that were implanted with estradiol-filled capsules. Cells were harvested from the MtTW-10 tumors and cultured for 4 days. When examined by electron microscopy, the MtTW-10 cells maintained in culture were irregular in shape with microvilli on their surface and contained numerous large secretory granules. Immunoreactive galanin, PRL, and GH were secreted from the cells in a time-dependent fashion during static incubations. LH, ACTH, and TSH were undetectable in the culture medium. Somatostatin (10 and 100 nM) inhibited galanin, PRL, and GH release in a dose-dependent manner. In contrast, dopamine, TRH, LH-releasing hormone, CRH, and GH-releasing hormone at concentrations of 10-100 nM failed to alter hormone secretion. Only high concentrations of dopamine (1 microM) inhibited the secretion of galanin, PRL, and GH. HPLC fractionation of peptides secreted by MtTW-10 cells cultures showed that approximately 84% of the galanin immunoreactivity coeluted with synthetic rat galanin. In tumor-bearing rats, plasma levels of immunoreactive galanin were 10-fold higher after estradiol treatment than levels in ovariectomized controls. Galanin mRNA levels were increased 20-fold by estradiol in MtTW-10 tumors, as determined by solution hybridization, and peptide levels were elevated nearly 100-fold. We conclude that 1) galanin is secreted from MtTW-10 cells in vitro, and its secretion is inhibited by somatostatin; and 2) estradiol increases galanin gene expression and peptide secretion in MtTW-10 tumors in vivo. These data show that MtTW-10 tumors may be useful to study the regulation of pituitary galanin gene expression, peptide synthesis, and secretion.

Colocalization of galanin and prolactin within secretory granules of anterior pituitary cells in estrogen-treated Fischer 344 rats.

Galanin is localized within specific cell types of the rat anterior pituitary gland (AP). Immunocytochemical studies at the light microscope level have shown that lactotrophs, somatotrophs, and thyrotrophs contain galanin in the intact female rat, whereas lactotrophs in the male AP do not. We recently reported that galanin and PRL release from estrogen-treated male and female pituitary cells in culture are coregulated by dopamine, TRH, and somatostatin. This suggested that galanin is stored within secretory granules, conceivably with PRL. Using postembedding immunocytochemistry at the ultrastructural level, the objectives of this study were to: 1) determine the subcellular location of galanin in the AP; 2) elucidate if galanin and PRL are colocalized within the same secretory granules; and 3) compare the cellular localization of galanin in the male and female AP. Male and ovariectomized female (OVEX) Fischer 344 rats were implanted with estradiol-containing or empty Silastic capsules for 2 weeks. Postembedding immunogold labeling was performed using rabbit (for galanin) and guinea pig (for PRL) generated antisera. Two different sizes of colloidal gold spheres were used to localize the hormones in the same tissue section. Galanin was primarily localized in secretory granules of adenohypophyseal cells. Based upon immunocytochemical results and morphological criteria, galanin was contained in somatotrophs but not lactotrophs in the male and OVEX AP. The AP of estrogen-treated rats contained more specific immunogold labeling for galanin than untreated rats. The increased immunoreactivity for galanin was notably associated with lactotrophs. After exposure to estrogen, galanin and PRL were colocalized within the same secretory granules of the male and OVEX pituitary cells. We conclude: 1) galanin is localized within secretory granules of the rat AP; 2) galanin and PRL are colocalized within secretory granules of the male and OVEX AP after estrogen treatment; and 3) galanin is localized in similar cell types in the male and OVEX AP, before and after estrogen treatment. These data provide a morphological basis for the coregulation of galanin and PRL secretion by hypothalamic factors.

Galanin gene expression is increased in the anterior pituitary gland of the human growth hormone-releasing hormone transgenic mouse.

The peptide galanin is synthesized within and secreted from specific cells of the anterior pituitary gland. Previous studies showed that GH-releasing hormone (GHRH) stimulates galanin release from pituitary cells in vitro. In the present study we used human (h) GHRH transgenic mice to examine the effects of high circulating levels of GHRH on pituitary galanin gene expression in vivo. Moreover, the hGHRH transgenic mice develop pituitary tumors and, thus, may be used as a model of estrogen-independent pituitary adenoma formation. We examined male hGHRH transgenic mice and nontransgenic siblings at 2, 4, 6, 8, and 10 months of age. Transgenic mice were identified using the polymerase chain reaction. Body weights and plasma mGH levels were higher in transgenic mice at all ages. Total protein contents in the anterior pituitary glands of transgenic mice were significantly greater at each age. Galanin peptide contents in the anterior pituitary gland of hGHRH mice were normalized for differences in total protein content and were significantly elevated at all ages examined. At 10 months of age, anterior pituitary galanin peptide concentrations were increased 7-fold. Hypothalamic concentrations of galanin peptide were also increased in hGHRH transgenic mice, but were not greater than those in nontransgenic siblings until 4 months of age. In contrast, no significant differences in galanin peptide concentrations of the neurointermediate lobes were evident. Galanin mRNA concentrations in the anterior pituitary of 6-month-old transgenic mice were increased 4-fold. In conclusion, 1) galanin peptide concentrations in the anterior pituitary gland and hypothalamus are increased in hGHRH transgenic mice compared to those in nontransgenic siblings, whereas galanin peptide concentrations in the neurointermediate lobe are not different; 2) pituitary galanin mRNA concentrations are increased 4-fold in 6-month-old transgenic mice; and 3) the development of pituitary hyperplasia is correlated to the increase in galanin mRNA and peptide concentrations.

Function of galanin in the anterior pituitary of estrogen-treated Fischer 344 rats: autocrine and paracrine regulation of prolactin secretion.

Estrogen is a robust stimulator of galanin synthesis and secretion in the anterior pituitary. Galanin is colocalized in lactotrophs in the estrogen-treated anterior pituitary, and its roles in lactotroph function are still being elucidated. In the present studies, we quantified the phenotypes of estrogen-treated Fischer 344 rat anterior pituitary cells expressing the galanin gene by dual in situ hybridization. The total population of galanin-positive pituitary cells increased from undetectable levels to 16% of all cells after 2 weeks of estrogen treatment. More than 90% of the galanin-positive cells coexpressed PRL messenger RNA, and one-third of the lactotrophs expressed galanin messenger RNA. We hypothesized that galanin in the anterior pituitary may contribute to the heterogeneous secretion of PRL, and that one of the functions of galanin is to regulate PRL secretion in an autocrine/paracrine manner. To test this hypothesis, we performed the reverse hemolytic plaque assay combined with in situ hybridization to measure PRL secretion and galanin gene expression within the same individual cells. PRL secretion from galanin-positive lactotrophs was significantly greater than that from galanin-negative lactotrophs. Moreover, treatment with galanin antiserum significantly attenuated PRL secretion from galanin-positive cells, and treatment with galanin significantly enhanced PRL secretion from galanin-negative lactotrophs. In conclusion, these data provide direct evidence that galanin derived from the estrogen-treated anterior pituitary stimulates PRL secretion in both autocrine and paracrine manners.

Targeted overexpression of galanin in lactotrophs of transgenic mice induces hyperprolactinemia and pituitary hyperplasia.

We generated transgenic mice that carry 4.6 kb of the mouse galanin gene fused to 2.5 kb of the rat PRL promoter. In all transgenic lines that carried and transmitted the transgene, there were significant increases in galanin messenger RNA and peptide levels in the anterior pituitary in both male and female transgenic mice, and the elevation of galanin was restricted to the anterior lobe. Furthermore, galanin release from pituitary cells in vitro of both male and female transgenic mice was dramatically increased compared with that in control mice. At 2-4 months of age, pituitary PRL contents in female transgenic mice were increased compared with those in normal controls. Moreover, PRL messenger RNA levels were increased in female transgenic mice. However, plasma levels of PRL in female transgenic mice were not significantly higher until 6 months of age. By 11 months of age, cell numbers in the anterior pituitary were increased in female, but not male, transgenic mice. The percentage of lactotrophs in female transgenic mice as well as PRL gene expression per cell were significantly higher. No differences were detected in PRL content, gene expression, or release between normal and transgenic male mice. Six weeks of estrogen treatment significantly increased anterior pituitary weights and PRL secretion in male transgenic mice compared with that in normal male mice. In addition, anterior pituitary weights and PRL secretion were decreased in female transgenic mice compared with controls 6 weeks after ovariectomy. We conclude that overexpression of galanin in lactotrophs stimulates PRL synthesis and secretion and acts as a growth factor resulting in the formation of pituitary hyperplasia and hyperprolactinemia. Furthermore, estrogen appears critical for these galanin-mediated events.

An interactive physiological role of neuropeptide Y and galanin in pulsatile pituitary luteinizing hormone secretion.

Both neuropeptide Y (NPY) and galanin (GAL) systems have been implicated in the excitatory regulation of pulsatile LH secretion in the ovariectomized rat. The present studies were designed to examine the possible interaction of these two neuropeptides in controlling episodic LH release by testing the effects of central infusion of antibodies (Ab) to NPY and GAL, alone or in combination; additional studies tested the effects of central administration of an antisense oligodeoxynucleotide (ODN) to NPY and GAL messenger RNA. Rats were ovariectomized, implanted with a cannula in the third ventricle, and used in experiments 2 weeks later. Central infusion, via Alzet osmotic minipumps, of IgG purified from an NPY Ab produced a dose-related suppression of pulsatile LH secretion. Although an Ab dilution of 1:10 was ineffective, a maximal inhibitory effect was obtained using an NPY Ab dilution of 1:1, which decreased the mean levels, pulse frequency, and pulse amplitude of LH. These parameters of episodic LH secretion were also significantly reduced by central injection of antisense NPY ODN compared to those in vehicle- or missense ODN-treated controls. Similar dose-related inhibitory effects on the parameters of LH secretion were seen after central infusion of GAL Ab. Furthermore, infusion of a combination of NPY Ab and GAL Ab, each at the ineffective dilution of 1:10, resulted in a profound inhibition of LH secretion equivalent to the pattern seen with the maximally effective 1:1 Ab dilution. These results strengthen the idea of a physiological role for both NPY and GAL systems in the mechanism underlying the LHRH pulse generator activity and further suggest that these two excitatory neuropeptides act in concert to generate pulsatile LHRH release.

Galanin within the normal and hyperplastic anterior pituitary gland: localization, secretion, and functional analysis in normal and human growth hormone-releasing hormone transgenic mice.

Studies evaluating estrogen-induced anterior pituitary tumors revealed a strong direct correlation between expression of the peptide galanin and tumor growth. To evaluate further the potential roles of galanin in the hyperplastic pituitary, we used a model of estrogen-independent anterior pituitary tumor formation, the male human GH-releasing hormone (hGHRH) transgenic mouse. Pituitaries of hGHRH transgenic mice are characterized by a hyperplasia of somatotrophs and contain markedly elevated levels of galanin. We examined the population of galanin-producing pituitary cells in 4- to 6-month-old male hGHRH transgenic mice and their nontransgenic siblings. The percentage of galanin-containing pituitary cells was significantly increased within the anterior pituitaries of hGHRH transgenic mice. By using the cell immunoblot assay we found that the basal secretion of galanin and GH from individual pituitary cells of hGHRH transgenic mice was significantly greater than that from pituitary cells of nontransgenic mice. By modifying the cell immunoblot assay, we determined that somatotrophs from both hGHRH transgenic and normal mice that were positive for galanin immunoreactivity secreted significantly greater amounts of GH than those somatotrophs devoid of galanin immunoreactivity. Moreover, immunoneutralization of galanin significantly decreased GH secretion from pituitary cells obtained from hGHRH transgenic mice. Thus, we now show that the increased levels of galanin peptide within the hyperplastic pituitaries of hGHRH transgenic mice are due to an increase in the population of cells containing galanin, and that galanin participates in the augmented secretion of GH from hyperplastic proliferating pituitary cells.

Galanin: a novel intraovarian regulatory peptide.

Galanin is a 29-amino acid peptide that acts as a neuropeptide in many tissues. To date, galanin action and the hormonal regulation of galanin gene expression have not been described in the ovary of any species. To study possible ovarian expression and regulation of galanin, immature gonadotropin-primed rats were given hCG (10 IU), and their ovaries were collected 0, 4, 8, 12, and 20 h after hCG treatment for determination of galanin messenger RNA (mRNA) concentration by solution hybridization. Galanin mRNA levels progressively increased after hCG administration, peaking at 12 h (2.4-fold increase vs. 0 h), with a subsequent return to 0 h levels at 20 h. To determine a possible ovarian role for galanin, rats were killed 48 h after gonadotropin administration, their ovaries were removed, and granulosa cells were harvested. These cells and the ovarian tissue remaining after granulosa cell collection (i.e. "shells") were each cultured for 24 h with increasing concentrations of galanin (0, 10, 100, and 1000 nM) in the presence or absence of LH. The medium was examined for steroid production and metalloproteinase inhibitor activity. In granulosa cell cultures, galanin increased the levels of estradiol by 26% and had no effect on progesterone, but decreased metalloproteinase inhibitor activity by 61% in the conditioned medium. In the shell cultures, galanin increased estradiol, progesterone, and androstenedione in the medium, suggesting that galanin acts on cells other than granulosa cells or that galanin action requires a paracrine interaction between granulosa and thecal cells. Our data demonstrate that galanin message is increased by hCG, and that galanin acts to amplify ovarian steroidogenesis while decreasing metalloproteinase inhibitor activity. These findings establish that ovarian galanin mRNA is hormonally stimulated and that galanin acts as an intraovarian regulatory peptide.

Pituitary hormone gene expression and secretion in human growth hormone-releasing hormone transgenic mice: focus on lactotroph function.

The human GH-releasing hormone (hGHRH) transgenic mouse has a hyperplastic anterior pituitary gland that eventually develops into an adenoma. We showed previously that the number of lactotrophs in the male hGHRH transgenic mouse is increased 2-fold, yet there is no concomitant increase in plasma levels of PRL. To further elucidate underlying changes in lactotroph function in the hGHRH transgenic mouse, the objectives of this study were to 1) examine the relative differences in PRL gene expression in transgenic mice and their siblings, 2) quantify PRL secretion at the level of the individual cell, 3) determine whether tyrosine hydroxylase gene expression and/or activity are altered in the hypothalamus of transgenic mice, and 4) assess dopamine receptor gene expression and functional sensitivity in lactotrophs of transgenic mice. Total PRL messenger RNA (mRNA) levels were increased nearly 5-fold in the hGHRH transgenic mouse, whereas the concentrations of PRL mRNA (PRL mRNA per microg total RNA) were unchanged. In contrast, total PRL contents were unchanged, whereas the concentrations of PRL (micrograms of PRL per mg total protein) were decreased 3-fold. Hypothalamic tyrosine hydroxylase steady state mRNA levels were not altered in the hGHRH transgenic mice, but hypothalamic tyrosine hydroxylase activity was increased 2-fold in transgenic mice. Dopamine D2 receptor mRNA concentrations in the anterior pituitary were increased 2.5-fold in hGHRH transgenic mice, and total pituitary D2 receptor mRNA levels were increased nearly 10-fold. Furthermore, the basal secretory capacity of lactotrophs from transgenic mice was increased significantly at the level of the single cell, and dopamine inhibited the secretion of PRL to a greater extent in hGHRH transgenic mice. Thus, although the total number of lactotrophs is increased 2-fold in hGHRH transgenic mice, the present data are consistent with the hypothesis that increased hypothalamic dopamine synthesis and release coupled with an increase in D2 dopamine receptor gene expression and functional sensitivity in the pituitary result in normal plasma levels of PRL.

PRL, placental lactogen, and GH induce NA(+)/taurocholate-cotransporting polypeptide gene expression by activating signal transducer and activator of transcription-5 in liver cells.

We investigated the transcriptional regulation of the Na(+)/taurocholate cotransporting polypeptide gene by PRL, placental lactogen, and GH. In primary hepatocytes, ovine PRL induced a dose-dependent phosphorylation and nuclear translocation of signal transducers and activators of transcription-5a and -5b, but not -1 or -3, whereas mouse placental lactogen I and rat GH activated -5a, -5b, and -1. In EMSAs, ovine PRL, mouse placental lactogen I, and rat GH increased the specific DNA binding of nuclear signal transducer and activator of transcription-5 to its consensus element in both transfected HepG2 cells and primary hepatocytes. PRL, placental lactogen I, and GH also increased Na(+)/taurocholate cotransporting polypeptide mRNA expression in hepatocytes from control and pregnant (mouse placental lactogen I) rats. Genistein, a phosphotyrosine kinase inhibitor, inhibited PRL-induced signal transducer and activator of transcription-5 activation and Na(+)/taurocholate-cotransporting polypeptide mRNA. In HepG2 cells transiently cotransfected with either the long form of the rat PRL receptor or rat GH receptor, signal transducer and activator of transcription-5a and a -5-responsive luciferase expression vector containing the Na(+)/taurocholate-cotransporting polypeptide promoter, mouse placental lactogen I, like ovine PRL, activated -5a via the long form of the rat PRL receptor; whereas rat GH activated -5a via rat GH receptor, leading to transactivation of the Na(+)/taurocholate-cotransporting polypeptide promoter. These data establish that PRL and placental lactogen I induce Na(+)/taurocholate-cotransporting polypeptide gene expression via signal transducer and activator of transcription-5 proteins in liver, and indicate that these hormones play an important role in regulating liver metabolic function.