Calcitonin expression in rat anterior pituitary gland is regulated by ovarian steroid hormones

Gonadotroph-derived calcitonin-like peptide (pit-CT) is a potent inhibitor of lactotroph function. We investigated the effect of ovarian hormones on pit-CT mRNA expression in the anterior pituitary (AP) gland of cycling female rats. Levels of mRNAs for pit-CT, CT receptor, prolactin (PRL), and beta-LH during 4-d estrous cycle were determined. In a second study, the effects of estrogens and progesterone on pit-CT and PRL mRNA levels were investigated. In a third group, the effect of estrogen or progesterone depletion on pit-CT mRNA expression was studied. In a fourth group, the effect of passive pit-CT immunization on PRL and LH mRNA expression was examined. Pit-CT mRNA levels varied during estrous cycle. They were highest in diestrus, but lowest in the evening of proestrus. CT-receptor mRNA levels displayed smaller fluctuations. Estrogen repletion caused a decline in pit-CT mRNA expression in ovariectomized rats, but progesterone produced a marked increase. ICI 182,780 prevented the decline of pit-CT mRNA levels during late proestrus-estrus, but RU 486 attenuated pit-CT mRNA levels. Passive CT immunization in diestrus altered PRL and LH mRNA expression, and advanced the estrus cycle. These results suggest that pit-CT mRNA expression is regulated by ovarian hormones, and depletion of pit-CT advances their estrous cycle.     

The enkephalin system in the rat anterior pituitary: regulation by gonadal steroid hormones and psychotropic drugs

The regulation of pituitary enkephalin system by gonadal steroid hormones and psychotropic drugs was studied. A distinct sex-related difference of (Met5)- and (Leu5)-enkephalin-like immunoreactivity (ME-LI and LE-LI, respectively) was found in the anterior lobe but not in the neurointermediate lobe. Levels of ME-LI and LE-LI in the anterior pituitary of male rats were 4.8- and 6.2-fold as much as those of female rats, respectively. Estradiol administration caused a marked decrease of ME-LI and LE-LI only in the anterior lobe of male rats whereas dihydrotestosterone treatment significantly increased the level of ME-LI in the anterior lobe of female rats. Castration of male rats decreased both ME-LI and LE-LI only in the anterior lobe, and the diminished levels of both peptides were partially restored by the administration of dihydrotestosterone. On the other hand, ovariectomy caused a significant increase in both ME-LI and LE-LI in the anterior lobe of female rats, and this increase was completely prevented by the administration of estradiol. These results indicate that the enkephalin system in rat anterior pituitary is regulated by circulating gonadal steroid hormones. The anterior pituitary levels of ME-LI and LE-LI were significantly reduced by the repeated administration of haloperidol or lithium chloride, whereas hypertonic NaCl loading elicited no effect. On the other hand, ME-LI and LE-LI levels in the neurointermediate lobe were significantly decreased by repeated administration of hypertonic NaCl solution or lithium chloride; both treatments caused a marked reduction of antidiuretic hormone level in the same lobe. These results suggest that the regulation of the enkephalin system in the anterior lobe may be mediated, at least in part, by the dopamine system, whereas the enkephalin system in the neurointermediate lobe may be regulated mainly through a mechanism similar to that regulating antidiuretic hormone release.     

Response of rat pituitary anterior lobe prodynorphin products to changes in gonadal steroid environment

The total content of rat pituitary anterior lobe (AL) immunoreactive (ir) dynorphin A (ir-Dyn A) and ir-dynorphin B (Dyn B) increased in male rats between 15 and 58 days of age, but there was little alteration in the concentration of ir-Dyn A or B expressed relative to protein content. Adult rats (90 days of age) had lower concentrations of these peptide immunoreactivities in the AL. Castration of 58-day-old male rats produced a testosterone-reversible loss of ir-Dyn A and B by 50-60% 3 days after surgery. Thereafter, the levels of these peptides gradually increased to 2.5 times the levels found in control animals at 1 month after castration. These effects of castration on AL dynorphin were not seen in 15-day-old rats and were much less marked in adults. Similar changes were seen in the levels of other prodynorphin products, alpha- and beta-neo-endorphin (ir-alpha-nEnd and ir-beta-nEnd), and ir-[Leu5]enkephalin (ir-LE). Administration of testosterone (100 micrograms/100 g BW) to castrated rats for 2 days largely prevented the drop in the levels of AL ir-Dyn A and B. Ovariectomy produced an increase in the levels of ir-Dyn A, Dyn B, alpha-nEnd, beta-nEnd, and LE 2 weeks after surgery, but, in contrast to castration, no significant decrease was seen 3 days after ovariectomy. These changes in AL content of dynorphin-related peptides after castration or ovariectomy directly reflect those previously reported for AL content of LH. The mechanisms regulating storage (and perhaps secretion) of AL peptides derived from prodynorphin may be similar to those regulating storage and secretion of LH and FSH in rat AL. AL ir-LE could potentially arise from proenkephalin A or prodynorphin (proenkephalin B). Ir-LE levels in AL were approximately 10 times higher than the levels of ir-[Met5]-enkephalinyl-Arg-Gly-Leu (ME-RGL) in male rat AL, and changes in ir-LE content after castration were very similar to those observed in other prodynorphin-derived peptides, but different from the effects of castration on ir-ME-RGL. It is possible that prodynorphin is a major source of AL ir-LE.     

Estrogen regulation of kallikrein gene expression in the rat anterior pituitary

Using a rat pancreatic kallikrein cDNA probe (pcXP39), previously shown to hybridize to kallikrein mRNA in a variety of tissues, we have explored the control of kallikrein gene expression in rat anterior pituitary. Intact female rats have substantially higher levels of AP kallikrein mRNA than intact males; male levels are unaffected by castration, whereas female levels fall markedly postovariectomy. Administration of estradiol benzoate to intact male or ovariectomized female rats causes an increase in anterior pituitary levels of kallikrein mRNA. Since the pattern of responsiveness parallels that of PRL, we have studied GH3 cells grown in the presence and absence of estradiol; in neither instance was kallikrein mRNA above detection limits. Parallel changes were seen on Northern blots and by hybridization histochemistry; on emulsion autoradiography of pituitary sections, scattered positive cells were seen, but precise definition was not possible. We conclude that whereas in the submaxillary gland kallikrein gene expression appears androgen dependent and in the kidney is postulated to be mineralocorticoid regulated, in the anterior pituitary expression of the gene is under estrogen control; and that the local role(s) of pituitary kallikrein, whether precursor processing, control of blood flow, or other effects, would, in turn, appear to be modulated by estrogen in vivo.     

The posttranslational processing of prodynorphin in the rat anterior pituitary

The posttranslational processing of prodynorphin (Pro-Dyn) is not well understood. The rat anterior pituitary is an interesting tissue which merits examination to address this issue since it is known that Dyn immunoreactivity is stored as high mol wt (HMW) intermediates and not as free products such as dynorphin-A-(1-17) (Dyn-A17) or dynorphin-B-(1-13) (Dyn-B). The aim of our study is to characterize the Pro-Dyn products in the rat anterior pituitary quantitatively as well as qualitatively by keeping a close account of each of the possible domains that are known to compose the protein structure. This was achieved by a convergence of tools: designing RIA with antibodies to each of these domains, including antibodies to Dyn-A17, Dyn-B, alpha-neo-endorphin, bridge peptide, and Pro-Dyn carboxyl-terminal peptide (C-peptide), and using these antisera with gel filtration chromatography, reverse phase HPLC, immunoaffinity, and immunoprecipitation techniques. Our data indicate the presence of at least six distinct molecules which are classified as HMW intermediates (greater than 3.5K). By gel filtration chromatography they have apparent mol wt of 16,000, 10,000, 8,000, 6,000, 4,000, and 3,500, respectively. Each of these structures is characterized by multiple immunoreactivities to account for the observed mass. Based on the relative content of each structure we present a scheme for the posttranslational processing pathway of Pro-Dyn in the rat anterior pituitary. We also analyze other tissues, spinal cord and hypothalamus, for their content of Pro-Dyn HMW intermediates. Our results indicate that these tissues store Pro-Dyn HMW molecules of similar sizes and immunoreactive properties, suggesting that Pro-Dyn may be processed in a similar manner, at least in the initial phases, across tissues.     

Differential gene expression in pituitary adenomas by oligonucleotide array analysis

OBJECTIVES: Microarray technology allows for the expression profile of many thousands of genes to be quantified at the same time, and has resulted in novel discoveries about the tumour biology of a number of cancers. We sought to do this in pituitary adenomas, the most common intracranial neoplasm. METHODS: Affymetrix GeneChip HG-U133A oligonucleotide arrays covering 14 500 well-characterised genes from the human genome were used to study pooled RNA for each of the four major pituitary adenoma subtypes. Individual gene-expression levels in the tumours were compared relative to the expression profile in normal pooled pituitary RNA. Three differentially expressed genes with potential importance in tumourigenesis were chosen for validation by real-time quantitative PCR on the original tumours and on an additional 26 adenomas. RESULTS: Bioinformatic analysis showed that 3906 genes and 351 expressed sequence tags were differentially expressed among all pituitary tumour subtypes. Lysosomal-associated protein transmembrane- 4-beta (LAPTM4B), a novel gene upregulated in hepatocellular carcinoma, was significantly over-expressed in adrenocorticotrophin (ACTH)-secreting adenomas and non-functioning pituitary adenomas (NFPAs). Bcl-2-associated athanogene (BAG1), an anti-apoptotic protein found at high levels in a number of human cancers, was significantly over-expressed in growth hormone-secreting and prolactin-secreting adenomas and NFPAs. The cyclin-dependent kinase inhibitor p18, in which murine gene deletion has been shown to produce pituitary ACTH cell hyperplasia and adenomas, was significantly under-expressed in ACTH-secreting adenomas. CONCLUSIONS: Expression array analysis of pituitary adenomas using the Affymetrix GeneChip HG-U133A arrays appears to be a valid method of identifying genes that may be important in tumour pathogenesis.     

Kallikrein gene expression in the rat anterior pituitary

The report of 'kallikrein-like' activity in the rat neuro-intermediate lobe (N-IL) and its possible involvement in pro-opiomelanocortin processing led us to explore the expression of the kallikrein gene(s) in the pituitary. Using 32P-labelled rat pancreatic kallikrein cDNA, we have shown positive hybridization for rat anterior pituitary poly(A)+ RNA, of identical size on Northern blots (approximately 1.0 kb) to rat kidney poly(A)+ RNA run in parallel. Prior adrenalectomy or ovariectomy decreased the level of kallikrein mRNA seen in the anterior pituitary; total RNA from rat N-IL showed no significant hybridization. On hybridization histochemistry the anterior pituitary was strongly positive, and the neural and intermediate lobes negative. The previously reported kallikrein-like activity in the N-IL is therefore probably due to a non-kallikrein kininogenase; in the anterior pituitary, kallikrein may have a physiological role in limited precursor proteolysis, but lack kininogen activity.     

Differential regulation of type II corticosteroid receptor messenger ribonucleic acid expression in the rat anterior pituitary and hippocampus

The present study was designed to characterize the regulation of the type II corticosteroid receptor (GR) mRNA in two tissues involved in the control of the hypothalamic-pituitary-adrenal axis. We have used a solution hybridization/S1 nuclease protection assay to quantitate GR mRNA levels in the rat hippocampus and anterior pituitary after CRF, dexamethasone (DEX), or corticosterone (CORT) treatment. In general, hippocampal GR mRNA levels increased after removal of endogenous corticosteroids by surgical adrenalectomy and decreased in response to glucocorticoid treatment. More specifically, in the hippocampus 1) GR mRNA expression was decreased when adrenalectomized (ADX) animals were replaced with a relatively low dose of CORT, but not with a low dose of DEX; 2) acutely, CRF was more effective than DEX in decreasing the levels of GR mRNA in intact animals; however, under the same paradigm in ADX animals, DEX decreased the level of GR mRNA, whereas CRF was ineffective; and 3) in contrast to the decrease in GR mRNA levels observed after acute and low doses of glucocorticoid treatment, chronic treatment with either DEX or CORT did not change the level of hippocampal GR mRNA. These results suggest that in the hippocampus the decrease in GR mRNA expression after CRF treatment is probably via the release of glucocorticoids, and that this tissue is more sensitive to endogenous glucocorticoids than DEX. Anterior pituitary GR mRNA was differentially regulated compared with that in the hippocampus. In marked contrast to Gr mRNA in the hippocampus, ADX did not alter anterior pituitary GR mRNA expression, and glucocorticoid treatment led to an increase in GR mRNA levels. In the anterior pituitary 1) glucocorticoid treatment led to an increase in GR mRNA expression, when replaced with a relatively low dose of DEX, but not when replaced with a low dose of CORT; 2) acutely, neither CRF nor DEX altered levels of GR mRNA in intact animals; however, under the same paradigm DEX increased levels in ADX animals; and 3) chronic DEX or CORT treatment of intact animals elevated levels of anterior pituitary GR mRNA. In summary, these data have demonstrated tissue-specific regulation of GR mRNA in the hippocampus and anterior pituitary, which is dependent on both the dose and length of treatment and, in addition, on the glucocorticoid itself.     

Developmental regulation of leptin gene expression in rat brain and pituitary.

We have previously reported the expression of leptin mRNA and protein in adult rat brain and pituitary gland. We report here the presence of leptin and leptin receptor mRNA in neonatal female rat brain and pituitary using RT-PCR as well as leptin and leptin receptor immunoreactivity in neonatal rat brain. In addition, we describe age-related changes in leptin mRNA expression in female rat brain and pituitary from postnatal day 2 to 28, evaluated using semi-quantitative RT-PCR analysis. Age-related differences in leptin (ob) mRNA levels were tissue-dependent. The most striking developmental changes were noted in the pituitary and cerebral cortex. In the pituitary, ob mRNA levels were maximal during postnatal days 7-14 and fell sharply by postnatal day 22. In cortex, ob mRNA levels were low in neonatal pups (day 2-7) but increased significantly between postnatal days 14 and 28. Leptin mRNA was detectable at postnatal day 2 in hypothalamus and subcutaneous fat. No significant differences in the level of expression were observed between postnatal day 2 and 28. Serum leptin levels were highest at day 7-14 and decreased significantly by day 21-28, coincident with the fall in pituitary leptin expression. The high levels of leptin expression in the neonatal pituitary suggest that this gland may contribute to the circulating leptin levels during early postnatal development, when adipose deposits are minimal. These data indicate that regulation of leptin gene expression in the postnatal period is tissue-dependent, a finding, which suggests that local leptin expression may have important functional significance in the development of the brain-pituitary system.     

Effects of pituitary hormones on the cell-specific expression of the KAP gene.

The expression of kidney androgen-regulated protein (KAP) gene in mouse kidney is regulated in a multihormonal fashion. As determined by in situ hybridization analysis, epithelial cells of proximal convoluted tubules of cortical nephrons express KAP mRNA in response to androgenic stimulation while similar cells in the juxtamedullary S3 segment of the tubules express KAP mRNA under estrogenic and pituitary hormonal control. In situ hybridization analysis of kidney sections using hypophysectomized (hypox) mice resulted in a total absence of KAP mRNA suggesting the participation of a pituitary hormone(s) in the constitutive expression of KAP mRNA in S3 cells. Treatment of hypox mice with steroid hormones showed that androgens restored the ability of cortical tubule cells to synthesize KAP mRNA. Estrogen treatment, on the other hand, partially induced KAP gene expression only in S3 cells. These results indicated that the androgenic response of the gene is independent of pituitary function, while expression in S3 cells, although partially induced by the direct action of estrogens, is primarily regulated by a pituitary factor. In order to elucidate which hormone(s) is responsible for KAP gene expression in S3 cells, individual pituitary hormones were administered to hypox normal animals and to strains of mice genetically deficient in certain pituitary hormones. Surgically treated C57BL/6 female and male mice were implanted for 7 days with osmotic pumps containing individual pituitary hormones, after which the kidneys were analyzed by in situ hybridization. Mice injected with growth hormone (GH), corticotropin (ACTH), prolactin (PRL), or vehicle failed to express KAP mRNA. Mice treated with thyrotropin (TSH), follitropin (FSH), and lutropin (LH) exhibited high levels of KAP mRNA in S3 cells of females as well as in the renal cortex of male animals. Expression in the cortex in response to LH and FSH may be due to their gonadotropic effect on testosterone production. Similarly, contamination of TSH samples with small amounts of the gonadotropins may explain the cortical response to TSH. TSH produced the strongest response in S3 cells suggesting that it is responsible for the permissive effect of the pituitary on KAP gene expression. This conclusion was supported by studies performed with the dwarf mouse (dw/dw) which lacks PRL, GH, and TSH due to a mutation in the pit-1 gene. In situ hybridization analysis of dwarf mice kidney sections showed a complete lack of KAP gene expression. The possible participation of GH and PRL was eliminated on the basis of the hormone replacement studies.(ABSTRACT TRUNCATED AT 400 WORDS)     

Catecholestrogens and release of anterior pituitary gland hormones. II. Prolactin

We investigated the effects of the peripheral administration of 17 beta-estradiol (E2), estrone (E1), and the catecholestrogens, 2-hydroxyestradiol (2-OHE2) and 2-hydroxyestrone, (2-OHE1), on anterior pituitary gland PRL release in the prepuberal rat. Steroids in oil were injected sc into 25-day-old female and 35- to 40-day-old male rats. The injection of E2, E1, or 2-OHE2, but not of 2-OHE, caused a surge in serum PRL levels in female rats 48 h later, during the afternoon hours. Only E1 induced a PRL surge 24 h after injection. In male rats, the injection of E1 or 2-OHE2, but not of 2-OHE1, elevated serum PRL levels on a chronic basis. The results suggest that 2-OHE1 plays no discernible role in PRL release in either sex, but that 2-OHE2 might play a role in the tonic release of PRL in the male and in the preovulatory release of PRL in the female.     

Tachykinins and their gene expression in the anterior pituitary of the siberian hamster-Effects of photoperiod, thyroid hormones, and analogs of hypothalamic hormones

The anterior pituitary gland of the Siberian hamster contains high concentrations of tachykinins compared to other laboratory rodents. In this investigation we studied the relative quantities of neurokinin A (NKA), neuropeptide gamma (NPG), and neuropeptide K (NPK) present in extracts of anterior pituitaries from this species. The anterior pituitary extracts, purified by HPLC, contained similar quantities of NKA and NPG, and lower quantities of NPK. The anterior pituitary gland of the Siberian hamster contained mRNA encoding β-preprotachykinin A, which is a precursor of substance P, NKA, and NPK. This fact proves that the anterior pituitary gland of the Siberian hamster has the ability to synthesize tachykinins. Animals exposed to short photoperiods had higher concentrations of tachykinins in the pituitary gland, and triiodothyronine markedly depressed the stores of these peptides in the anterior pituitary. In some groups of animals, the somatostatin analog octreotide induced a small, but significant decrease of the levels of NKA in the pituitary. The present results, together with previously published findings, indicate that thyroid hormones and estrogens are the most active endogenous substances to suppress the levels of anterior pituitary tachykinins in the Siberian hamster.     

Prostaglandin-induced release of anterior pituitary hormones: structure-activity relationships.

Prostaglandins (PG's) of the E, F, A, or B series were infused into a lateral ventricle of the brain of adult male rats, and the efficacy of each PG to stimulate the discharge of LH, prolactin, and TSH from the pituitary gland was determined. PGE2, PGF2alpha, and PGF2beta were found to be potent stimulators of LH release. The release was considerably less when PGE1, PGF1beta, PGA2, or PGB2 was infused. The basal release of LH was not altered by infusion of PGF1alpha, PGA1, PGB1, or the control solution. It is suggested that the cis double bond in the 5,6 position and the 11-hydroxyl group are essential for the LH releasing activity of PG's and that these functional groups may be of importance for activation of a receptor at the level of the brain. Prolactin secretion was stimulated 6 to 7-fold by the infusion of 5 mug of PGE2, but 20 mug had no stimulatory effect. PGF2beta caused a 3 to 4-fold increase in basal plasma prolactin concentration and was the only PG tested other than PGE2 that stimulated prolactin release. None of the PG's infused intraventricularly affected TSH secretion.