Pituitary Somatotropes Research Articles

Differential Utilization of Transcription Activation Subdomains by Distinct Coactivators Regulates Pit-1 Basal and Ras Responsiveness

The POU-homeodomain transcription factor Pit-1 governs ontogeny and cell-specific gene expression of pituitary lactotropes, somatotropes, and thyrotropes. The splice isoform, Pit-1beta, inserts a 26-amino acid (AA) repressor at AA48 in the Pit-1 transcription activation domain (TAD). The Pit-1 TAD contains a basal regulatory subregion, R1 (AA1-45), and a basal and Ras-responsive region, R2 (AA46-80). To precisely map these activities, we generated GAL4-Pit-1/Pit-1betaTAD fusions and, in full-length HA-Pit-1, a series of substitution mutants of R2. Analysis in GH4 cells identified an activation domain at AA50-70, followed by an overlapping, dual-function, Ras-responsive-inhibitory domain, located from AA60-80. In contrast, GAL4-Pit-1betaTAD repressed both basal and Ras-mediated TAD activity. To determine the functional interplay between TAD subregions and the beta-domain, we inserted the beta-domain every 10 AA across the 80-AA Pit-1 TAD. Like wild-type Pit-1beta, each construct retained transcriptional activity in HeLa cells and repressed the Ras response in GH4 cells. However, beta-domain insertion at AA61 and 71 resulted in greater repression of Ras responsiveness, defining a critical R2 TAD spanning AA61-71 of Pit-1. Furthermore, Ras activation is augmented by steroid receptor coactivator 1, whereas cAMP response element binding protein-binding protein is not a Ras mediator in this system. In summary, the Pit-1/Pit-1beta TADs are composed of multiple, modular, and transferable subdomains, including a regulatory R1 domain, a basal activation region, a selective inhibitory-Ras-responsive segment, and a beta-specific repressor domain. These data provide novel insights into the mechanisms by which the Pit-1 TAD integrates DNA binding, protein partner interactions, and distinct signaling pathways to fine-tune Pit-1 activity.

A Single Base Difference between Pit-1 Binding Sites at the hGH Promoter and Locus Control Region Specifies Distinct Pit-1 Conformations and Functions

Activation of the human growth hormone (hGH-N) gene in pituitary somatotropes is mediated by a locus control region (LCR). This LCR is composed of DNase I-hypersensitive sites (HS) located -14.5 kb to -32 kb relative to the hGH-N promoter. HSI, at -14.5 kb, is the dominant determinant of hGH-N expression and is essential for establishment of a 32-kb domain of histone acetylation that encompasses the active hGH locus. This activity is conferred by three binding sites for the POU domain transcription factor Pit-1. These Pit-1 elements are sufficient to activate hGH-N expression in the mouse pituitary. In contrast, Pit-1 sites at the hGH-N promoter are consistently unable to mediate similar activity. In the present study, we demonstrate that the functional difference between the promoter-proximal and the HSI Pit-1 binding sites can be attributed in part to a single base difference. This base affects the conformation of the Pit-1/DNA complex, and reciprocal exchange of the divergent bases between the two sets of Pit-1 elements results in a partial reversal of their transgenic activities. These data support a model in which the Pit-1 binding sites in the hGH LCR allosterically program the bound Pit-1 complex for chromatin activating functions.

Locus Control Region Transcription Plays an Active Role in Long-Range Gene Activation

Activation of eukaryotic genes often relies on remote chromatin determinants. How these determinants function remains poorly understood. The hGH gene is activated by a 5'-remote locus control region (LCR). Pituitary-specific DNase I hypersensitive site I (HSI), the dominant hGH LCR element, is separated from the hGH-N promoter by a 14.5 kb span that encompasses the B-lymphocyte-specific CD79b gene. Here, we describe a domain of noncoding Pol II transcription in pituitary somatotropes that includes the hGH LCR and adjacent CD79b locus. This entire "LCR domain of transcription" is HSI [corrected] dependent and terminates 3' to CD79b, leaving a gap in transcription between this domain and the target hGH-N promoter. Insertion of a Pol II terminator within the LCR blocks CD79b transcription and represses hGH-N expression. These data document an essential role for LCR transcription in long-range control, link "bystander"CD79b transcription to this process, and support a unique model for locus activation.

Examination of the direct effects of metabolic factors on somatotrope function in a non-human primate model, Papio anubis

In humans, circulating GH levels are increased in catabolic states and suppressed in obesity. In both extremes, normalization of the metabolic environment normalizes GH release, leading to the conclusion that changes in metabolic hormones and/or metabolites promote changes in GH synthesis and release. Metabolic regulation of GH secretion can be mediated centrally by modulation of hypothalamic GHRH and somatostatin input to the pituitary and/or by direct regulation of pituitary somatotrope function. Although data are available showing glucocorticoids, free fatty acids (FFA), IGF-I, and insulin have direct effects on rat somatotrope function, little information is available regarding the direct pituitary effects of these metabolic factors in primates. Therefore, this study examined the effects of glucocorticoids (dexamethasone (0.1-100 nM) and hydrocortisone (10 nM)), FFA (oleic and linoleic acid, 100 and 400 microM each), IGF-I (0.5-50 nM), and insulin (0.5-50 nM) on GH release and GH, GHRH-receptor (GHRH-R) and ghrelin-receptor (GHS-R) mRNA levels, in primary pituitary cell cultures of baboons (Papio anubis) after 24 h treatment. A commercial ELISA kit was used to determine the amount of GH released into the media, while quantitative real-time reverse transcription-PCR was used to determine mRNA levels. To design species-specific primers for baboon GH, GHRH-R, GHS-R, insulin receptor (INSR), IGF-I receptor (IGF-IR), pituitary-specific transcription factor-1 (Pit-1), and cyclophilin A (used as a housekeeping gene) cDNA, sequence data for each baboon transcript were obtained and this data were submitted to Genbank. Glucocorticoids, FFA, insulin and IGF-I treatment did not significantly alter the expression of Pit-1, a transcription factor essential for normal somatotrope development and function. However, as previously reported in the rat, glucocorticoids increased, while FFA, IGF-I and insulin decreased GH release in baboon pituitary cell cultures, where changes in GH release were reflected by comparable changes in GH mRNA levels. In addition, glucocorticoids increased, while FFA, IGF-I and insulin decreased the expression of the GH stimulatory receptors, GHRH-R and GHS-R, without significantly altering cyclophilin A mRNA levels. A role of insulin/INSR pathway, independent of IGF-I, in regulating pituitary function is supported by the fact that (1) IGF-I and insulin significantly suppressed somatotrope function at doses (0.5 and 5 nM respectively) not anticipated to activate their respective receptors, and (2) the baboon pituitary expresses INSR mRNA at levels comparable to or greater than that of tissues commonly considered as insulin sensitive (i.e. liver, skeletal muscle, and fat). Taken together, these results demonstrate that metabolic factors can directly modulate primate somatotrope function through regulating GH synthesis and release, as well as mediating the expression of receptors important in central (GHRH) and systemic (ghrelin) regulation of GH secretion.

Molecular basis of neuroendocrine cell type‐specific expression of the chromogranin B gene: crucial role of the transcription factors CREB, AP‐2, Egr‐1 and Sp1

The molecular basis of neuroendocrine-specific expression of chromogranin B gene (Chgb) has remained elusive. Utilizing wild-type and mutant Chgb promoter/luciferase reporter constructs, this study established a crucial role for the cAMP response element (CRE) box at -102/-95 bp in endocrine [rat pheochromocytoma (chromaffin) cell line (PC12) and rat pituitary somatotrope cell line (GC)] and neuronal [rat dorsal root ganglion/mouse neuroblastoma hybrid cell line (F-11), cortical and hippocampal primary neurons] cells. Additionally, G/C-rich domains at -134/-127, -125/-117 and -115/-110 bp played especially important roles for endocrine-specific expression of the Chgb gene. Co-transfection of expression plasmids for CREB, activator protein-2 (transcription factor) (AP-2), early growth response protein (transcription factor) (Egr-1) or specificity protein 1 (transcription factor) (Sp1) with the Chgb promoter constructs trans-activated expression of the Chgb gene. Nuclear extracts from either PC12 or F-11 cells formed specific complexes with the Chgb (-110/-87 bp) (CRE) oligonucleotide, which were either supershifted or disrupted by anti-CREB antibodies. In addition PC12 nuclear extracts also formed a specific complex with a Chgb (-140/-104-bp) oligonucleotide containing three G/C-rich regions, which was dose-dependently disrupted by anti-AP-2, anti-Egr-1 or anti-Sp1 antibodies; indeed, any one of these three antibodies completely abolished the complex, suggesting that all three factors bind the region simultaneously, at least in vitro. Chromatin immunoprecipitation assays documented the binding of the transcription factors CREB, AP-2, Egr-1 and Sp1 to the chromosomal Chgb gene promoter in vivo in PC12 cells within the context of chromatin. We conclude that the neuroendocrine-specific expression of Chgb is mediated by the CRE and G/C boxes in cis and the transcription factors CREB, AP-2, Egr-1 and Sp1 in trans.

Cortistatin mimics somatostatin by inducing a dual, dose-dependent stimulatory and inhibitory effect on growth hormone secretion in somatotropes

Cortistatin is a recently discovered neuropeptide that is structurally related to somatostatin, the classic inhibitor of growth hormone (GH) release. Cortistatin binds with high affinity to all five somatostatin receptors (sst1-5), and, like somatostatin, cortistatin inhibits in vivo GH release in man and rats. In this report, we compared the in vitro actions of cortistatin and somatostatin using primary pig pituitary cell cultures. In this species, we have previously reported that somatostatin not only inhibits GH-releasing hormone (GHRH)-stimulated GH release at high doses, but also stimulates basal GH release at low (pM) doses, a dual response that is markedly dependent on the subpopulation of pituitary somatotropes examined. Results reported herein demonstrate that cortistatin closely mimics the dose-dependent inhibitory and stimulatory effects of somatostatin on GH secretion. As cortistatin, unlike somatostatin, binds to the human receptor for ghrelin/GH secretagogs (GHS-R), we also investigated whether cortistatin stimulates GH release through this receptor by using a synthetic, short form of cortistatin, cortistatin-8 (CST8), which lacks the sst-binding capacity of full-length cortistatin but retains its GHS-R-binding capacity. Interestingly, CST8 stimulated GH release only at low doses (10(-15) M), and did not reduce GH secretion stimulated by GHRH, ghrelin, or low-dose, full-length cortistatin, yet it counteracted that induced by a nonpeptidyl GHS, L-163 255. Taken together, our results indicate that the dual, inhibitory and stimulatory effects of cortistatin on GH release closely parallel those of somatostatin and are probably mediated by the same receptor(s) and signaling pathway(s) for both peptides. Furthermore, they suggest that the pathway(s) activated by cortistatin (and somatostatin) to stimulate GH release are not initiated by GHS-R activation.

Effect of nutrient restriction on the somatotropes and substance P-immunoreactive cells in the pituitary of the female ovine fetus

The maternal environment affects fetal development and may influence the physiology of the adult. Fetal growth hormone (GH) is increased by maternal undernutrition but the mechanisms responsible are unknown. This study determined the effect of maternal undernutrition on the development of fetal pituitary somatotropes in the female. Ewes were grouped randomly into control (fed 100% of requirements) or nutrient restricted (fed 50%) from Days 28 to 78 of gestation. At Day 78, the ewes were killed and fetuses collected (Day 78 NR (nutrient restricted): n = 6; Day 78 C (control): n = 6). Remaining ewes were realimented to 100% of nutritional requirements and were killed at Day 135 (Day 135 NR (nutrient restricted): n = 6; Day 135 C (control): n = 6). Somatotropes were visualized immunocytochemically and the size, mean density, total percentage and proportion colocalized with substance P were determined for each group. Nutrient restriction increased ( p < 0.01) the density of pituitary cells in Day 78 fetuses but this difference was no longer apparent by Day 135 after realimentation. The density and proportion of somatotropes were not different between treatment groups at Day 78 but were significantly ( p < 0.05) lower in the nutrient restricted Day 135 fetuses as compared to the Day 135 control animals. Somatotropes from restricted fetuses were significantly ( p < 0.001) larger at Day 78. Nutrient restriction increased the density ( p < 0.001) and percentage ( p < 0.05) of substance P-immunoreactive cells Day 135 fetuses. Similarly, the proportion of somatotropes that expressed substance P was significantly ( p < 0.05) increased by nutrient restriction in the Day 135 fetuses. Although nearly two thirds of substance P-immunoreactive cells co-expressed GH, there was no significant effect of treatment on this co-expression. Additional studies are required to determine if other components of the neuroendocrine GH axis are affected by this nutritional insult, if the alterations that we have observed, particularly in the tachykinin system, persist into adulthood and, importantly, what are the long-term consequences of an altered GH axis.

Growth hormone and ghrelin receptor genes are differentially expressed between genetically lean and fat selection lines of sheep

The objective of this study was to determine whether differences in mRNA levels of key pituitary genes that regulate GH production, pituitary development, and growth were present and/or associated with divergent body composition phenotypes observed between sheep from genetically divergent lean and fat selection lines. Real-time PCR transcription profiles for pituitary specific transcription factor 1, prophet of pit1, GH, GH receptor, GH secretagogue receptor, GHRH receptor, leptin receptor, and somatostatin receptors 1 and 2 were determined in pituitary tissue. There was a difference in the amount of both GH (P < 0.001) and GH secretagogue receptor (P < 0.001) mRNA between the selection lines (5 females and 5 males per line; 20 wk of age); the lean line had greater abundance than the fat line, irrespective of which endogenous control gene was used. The results obtained for GHRH receptor were equivocal but suggestive; there were greater GHRH receptor mRNA levels (P < 0.001) in the lean line using beta-2-microglobulin as the endogenous control but not when hypoxanthine phosphoribosyltransferase and glyceraldehyde-3-phosphate dehydrogenase were used. No difference in pituitary specific transcription factor 1, prophet of pit1, GH receptor, leptin receptor, or somatostatin receptors 1 and 2 mRNA concentration was observed between the lines. The greater abundance of GH mRNA in the pituitary somatotropes from genetically lean animals appears to be associated with increased levels of GH secretagogue receptor mRNA and possibly GHRH receptor mRNA. This suggests that the difference in GH secretion between the lines may be due to differences in the afferent signals, such as ghrelin and/or GHRH, arising from the hypothalamus, or as a result of differential pituitary sensitivity to these hormones.

Differential Regulation of GHRH-Receptor and GHS-Receptor Expression by Long-Term In Vitro Treatment of Ovine Pituitary Cells with GHRP-2 and GHRH

GH secretion is regulated by GHRH and somatostatin via actions on their specific receptors in pituitary somatotropes. Ghrelin and synthetic analogs, GHRPs, also stimulate GH release via GHS-receptors (GHS-R). To examine the long-term effect of GHRH and/or GHRP on somatotropes, primary cultured ovine somatotropes were treated with GHRH (10(-9) and 10(-8) M) and GHRP-2 (10(-8) and 10(-7) M) for up to 2 d. After treatment, culture medium was collected for GH assay, and total RNA was extracted for RT-PCR analysis. To evaluate cell cultures used in this report, somatotrope-enriched pituitary cells were challenged by 6 h GHRH and dexamethasone (DEX) treatment. As expected, GHRH significantly decreased, whereas DEX increased, the levels of GHRHR mRNA. Combined low doses of GHRH (10(-9) M) and GHRP-2 (10(-8) M) treatment for 24 h increased accumulated GH secretion, significantly more than that induced by high doses of GHRH (10(-8) M) and GHRP-2 (10(-7) M). While levels of GHRH-R mRNA increased, GHS-R mRNA levels were decreased by low doses of GHRH and GHRP-2 for 24 h. High doses of GHRH and/or GHRP-2 for 2 d did not increase GH secretion in the second day of treatment and reduced the level of GHRH-R mRNA. High doses of GHRP-2 treatment decreased the levels of both GHRH-R and GHS-R mRNA. Low doses of GHRH and/or GHRP-2 for 2 d increased the level of GHS-R mRNA without changing GHRH-R mRNA levels. Such treatment also increased ghrelin- (10(-9) M) or ghrelin/GHRH (10(-9) M)-induced GH secretion. These results suggest that low doses of GHRP-2 and GHRH prime somatotropes for stimulation by GHRH and ghrelin.

Oestrogen Replacement in vivo Rescues the Dysfunction of Pituitary Somatotropes in Ovariectomised Aromatase Knockout Mice

The mechanism of regulation of growth hormone (GH) secretion by oestrogens and androgens is still controversial. Available data on the action of oestrogens on GH expression and secretion in somatotropes is poorly understood. We previously reported that the aromatase knockout (ArKO) mouse with oestrogen deficiency and excessive androgen levels had dysfunctional somatotropes. In order to clarify the influence of androgen and oestrogen, we investigated the in vivo treatment of ovariectomised (OVX) ArKO mice with exogenous oestradiol (E₂) on the mRNA expression of GH, GH-secretagogue receptor (GHS-R), GH-releasing hormone receptor (GHRH-R), pituitary-specific transcription factor (Pit-1), and somatostatin receptors (sst1–5) in pituitary glands. Circulating plasma GH levels were also evaluated. The results showed that ArKO/OVX mice have a low expression of pituitary GH, GHRH-R, GHS-R and Pit-1, and significantly reduced GH levels. Treatment of female ArKO/OVX (E₂-deficient without excessive androgen) mice with E₂ for 21 days enhanced expression of pituitary GHRH-R and Pit-1 to 151 and 168%, respectively, of that in mice without treatment. E₂ treatment increased GH expression and plasma levels in ArKO/OVX mice to levels comparable with those in wild-type female mice. We conclude therefore that long-term E₂ replacement rescues the dysfunction of somatotropes in ArKO/OVX mice through increases in expression of GH, GHRH-R, and Pit-1 in the pituitary somatotropes, whereas the level of androgen in this oestrogen-deficient female mouse does not significantly influence the function of somatotropes.

Median Eminence Dopaminergic Nerve Terminals: A Novel Target in Autoimmune Polyendocrine Syndrome?

Autoantibodies to adenohypophyseal endocrine cells or to vasopressin neurohypophyseal neurons have long been known. Conversely, autoimmune targeting of further hypothalamic-hypophyseal structures, such as the blood-brain barrier-deprived median eminence, has been little studied. We studied a case of autoimmune polyendocrine syndrome type I with GH secretory deficiency, a distinctly rare event in autoimmune polyendocrine syndrome type I. We used rat and bovine tissue substrates to study autoantibodies against hypothalamic-hypophyseal nerve structures and endocrine cells. In the study case, circulating autoantibodies selectively decorated median eminence dopaminergic nerve terminals, as well as pituitary gonadotropes, but not GHRH nerve terminals or pituitary somatotropes. Such autoantibodies appeared de novo in parallel with the onset of GH secretory deficiency, whereas no median eminence labeling was found in patients suffering of idiopathic GH deficiency (n = 7) or in healthy controls (n = 23). The pathophysiological significance of our patient's autoantibodies remains to be confirmed. Nonetheless, the heterogeneous neuroendocrine structures of the median eminence are pointed out as potential immune targets, relevant to autoimmune polyendocrinopathy, as well as to a wide range of other conditions.

The estrogen receptor (ER) α, but not ER β, gene is expressed in hypothalamic growth hormone-releasing hormone neurons of the adult female rat

Growth hormone (GH) synthesis and release from pituitary somatotropes is controlled by the opposing actions of the hypothalamic neuropeptides, GH-releasing hormone (GHRH) in the arcuate nucleus (ARC), and somatostatin in the periventricular nucleus (PeV) and ARC. There is a striking sex difference in the pattern of GH secretion in rats. We have previously demonstrated in male rats that 70% of GHRH neurons in the ARC contain the estrogen receptor α (ER α) gene, whereas less than 5% of somatostatin neurons in the ARC and PeV expressed the ER α or ER β gene. In addition, it has been reported that the PeV somatostatin neurons of neither sex possess ER immunoreactivity. However, there is no available data about colocalization of ERs and GHRH and/or somatostatin in the ARC of female rats. In this study, we used in situ hybridization in the adult female rat brain to determine whether GHRH neurons and/or somatostatin neurons in the ARC coexpress the ER α or ER β gene. In the ARC, ER α mRNA was seen in the ventrolateral region where GHRH mRNA signals were also observed, and in the dorsomedial region where somatostatin mRNA signals were also observed. From studies using adjacent sections through these areas, the distribution of these cells appeared to overlap in part with that of cells containing ER α mRNA. On the other hand, few positive cells for ER β mRNA were observed in the ARC. The double-label in situ hybridization studies showed that in the ARC, 73.4% of GHRH neurons contain ER α mRNA, whereas less than 5% of somatostatin neurons express the ER α gene. These results indicated that the majority of the GHRH neurons in ARC have ER α, but not ER β, and few somatostatin neurons in ARC have ER α or ER β in either adult female or male rats, suggesting that colocalization with ERs in GHRH and/or somatostatin neurons is not an important determinant of the gender specific pattern of GH secretion.

Pituitary Transcription Factor-1 Induces Transient Differentiation of Adult Hepatic Stem Cells into Prolactin-Producing Cells in Vivo

A subset of transcription factors function as pivotal regulators of cell differentiation pathways. Pituitary transcription factor-1 (Pit-1) is a tissue-specific homeodomain protein that specifies the development of pituitary somatotropes and lactotropes. In this study, adenovirus was used to deliver rat Pit-1 to mouse liver. Pit-1 expression was detected in the majority (50-80%) of hepatocyte nuclei after tail vein injection (2 x 10(9) plaque forming units). Pit-1 activated hepatic expression of the endogenous prolactin (PRL), GH, and TSHbeta genes along with several other markers of lactotrope progenitor cells. Focal clusters (0.2-0.5% of liver cells per tissue section) of periportal cells were positive for PRL by immunofluorescent staining. The PRL-producing cells also expressed proliferating cell nuclear antigen as well as the hepatic stem cell markers (c-Kit, Thy1, and cytokeratin 14). These data indicate that Pit-1 induces the transient differentiation of hepatic progenitor cells into PRL-producing cells, providing additional evidence that transcription factors can specify the differentiation pathway of adult stem cells.

Ghrelin Reduces Voltage-Gated Potassium Currents in GH&lt;SUB&gt;3&lt;/SUB&gt; Cells Via Cyclic GMP Pathways

Ghrelin is an endogenous growth hormone secretagogue (GHS) causing release of GH from pituitary somatotropes through the GHS receptor. Secretion of GH is linked directly to intracellular free Ca(2+) concentration ([Ca(2+)]i), which is determined by Ca(2+) influx and release from intracellular Ca(2+) storage sites. Ca(2+) influx is via voltage-gated Ca(2+) channels, which are activated by cell depolarization. Membrane potential is mainly determined by transmembrane K(+) channels. The present study investigates the in vitroeffect of ghrelin on membrane voltage-gated K(+) channels in the GH3 rat somatotrope cell line. Nystatin-perforated patch clamp recording was used to record K(+) currents under voltage-clamp conditions. In the presence of Co(2+) (1 mM, Ca(2+) channel blocker) and tetrodotoxin (1 microM, Na(+) channel blocker) in the bath solution, two types of voltage-gated K(+) currents were characterized on the basis of their biophysical kinetics and pharmacological properties. We observed that transient K(+) current (IA) represented a significant proportion of total K(+) currents in some cells, whereas delayed rectifier K(+) current (IK) existed in all cells. The application of ghrelin (10 nM) reversibly and significantly decreased the amplitude of both IA and IK currents to 48% and 64% of control, respectively. Application of apamin (1 microM, SK channel blocker) or charybdotoxin (1 microM, BK channel blocker) did not alter the K(+) current or the response to ghrelin. The ghrelin-induced reduction in K(+) currents was not affected by PKC and PKA inhibitors. KT5823, a specific PKG inhibitor, totally abolished the K+ current response to ghrelin. These results suggest that ghrelin-induced reduction of voltage-gated K(+) currents in GH3 cells is mediated through a PKG-dependent pathway. A decrease in voltage-gated K(+) currents may increase the frequency, duration, and amplitude of action potentials and contribute to GH secretion from somatotropes.

Estradiol and calcium affect the growth hormone producing cells in female middle-aged rats

The effects of multiple doses of estradiol dipropionate (EDP) or calcium glucoheptonate (Ca) on the growth and function of pituitary somatotropes (GH cells) were studied. Female middle-aged rats were receiving i.p. EDP (0.625 mg i.p./kg b.w), or Ca (11.4 mg/kg b.w) every day for two weeks. Blood samples were collected for hormone analyses and pituitaries dissected for histological and morphometric evaluation 24 h after the last injection. GH-producing cells were examined using the peroxidase-antiperoxidase (PAP) immuno-histochemical procedure. Both EDP- and Ca-treatment significantly decreased all morphometric parameters of GH cells (p<0.05) in comparison with the corresponding controls. Serum concentration of growth hormone (GH) in EDP- or Ca-treated groups was lower by 65% and 13% (p<0.05) respectively comparing to the controls. The difference between all morphometric parameters of EDP- and Ca-treated rats was statistically significant (p<0.05) in relation to the controls. These findings suggest that multiple EDP, or Ca application affects (directly or indirectly) the control of growth and secretory activity of GH cells in middle-aged female rats.

Chronic orchidectomy does not influence the sensitivity of the pituitary somatotropes to varying doses of GHRH administered intravenously to the adult male rhesus monkey

In the present study, the pituitary growth hormone (GH) response to graded doses of GH-releasing hormone (GHRH) was determined in intact (n = 3) and chronically orchidectomized (n = 3) adult rhesus monkeys (Mucaca mulatta). GHRH in doses of 0, 6.25, 12.5 and 25 μg/kg BW was infused through a teflon cannula implanted in the saphenous vein. Blood samples were collected 60 min before and 90 min after the injection of the neurohormone at 15 min intervals. All bleedings were carried out under ketamine hydrochloride anesthesia. The plasma levels of GH were determined by using AutoDELFIA time-resolved flouroimmunoassay, whereas plasma levels of testosterone and estradiol were determined using specific radioimmunoassay systems. The GH responses to GHRH were not significantly different between intact and chronically orchidectomized monkeys at any of the dose levels tested (p > 0.05). The administration of GHRH resulted in a significant (p < 0.05) stimulation of GH secretion at all the doses tested and in both the groups studied. In both intact and orchidectomized animals, the greatest response was observed at 6.25 μg/kg and no further increase was noted with the higher doses of GHRH. In conclusion, the present study suggests that chronic orchidectomy does not influence the sensitivity of the pituitary somatotropes to GHRH stimulation implying that the responsiveness of the pituitary somatotropes to GHRH is independent of testicular steroid modulation.

Homologous and heterologous regulation of pituitary receptors for ghrelin and growth hormone-releasing hormone.

Secretion of GH by pituitary somatotropes is primarily stimulated by the hypothalamic GHRH through the activation of a specific G protein-coupled receptor, GHRH receptor (GHRH-R). GH is also released in response to ghrelin, a peptide produced in the stomach, hypothalamus, and pituitary that activates somatotropes via a distinct G protein-coupled receptor, referred to as the GH secretagogue receptor (GHS-R). Here, we have analyzed the expression of both GHRH-R and GHS-R (by multiplex RT-PCR) in porcine pituitary cell cultures, after acute (4 h) treatment with GHRH or ghrelin as well as with other regulators of somatotropes (somatostatin, dexamethasone). Exposure of cultures to GHRH decreased GHRH-R mRNA content and also diminished GHS-R transcript levels. Likewise, ghrelin down-regulated both GHS-R and GHRH-R expression. Interestingly, administration of the activator of adenylate cyclase, forskolin, decreased GHRH-R mRNA levels but had no effect on GHS-R, thus suggesting a distinct contribution of the various intracellular signals operating in somatotropes to the regulation of the expression of these receptors. Accordingly, an atypical activator of adenylate cyclase in the pig somatotrope is low-dose (10(-13) m) somatostatin, which also suppressed GHRH-R mRNA levels without altering GHS-R expression. Finally, dexamethasone did not modify GHRH-R or GHS-R expression. In summary, our data show for the first time that ghrelin, as well as GHRH, mediates homologous and heterologous down-regulation of their own receptor synthesis. However, our results also indicate that the expression of porcine GHRH-R and GHS-R is regulated by distinct signals that may differ from those reported in other mammalian species.

Regulation of leptin mRNA and protein expression in pituitary somatotropes.

Leptin, the ob protein, regulates food intake and satiety and can be found in the anterior pituitary. Leptin antigens and mRNA were studied in the anterior pituitary (AP) cells of male and female rats to learn more about its regulation. Leptin antigens were found in over 40% of cells in diestrous or proestrous female rats and in male rats. Lower percentages of AP cells were seen in the estrous population (21 +/- 7%). During peak expression of antigens, co-expression of leptin and growth hormone (GH) was found in 27 +/- 4% of AP cells. Affinity cytochemistry studies detected 24 +/- 3% of AP cells with leptin proteins and growth hormone releasing hormone (GHRH) receptors. These data suggested that somatotropes were a significant source of leptin. To test regulatory factors, estrous and diestrous AP populations were treated with estrogen (100 pM) and/or GHRH (2 nM) to learn if either would increase leptin expression in GH cells. To rule out the possibility that the immunoreactive leptin was bound to receptors in somatotropes, leptin mRNA was also detected by non-radioactive in situ hybridization in this group of cells. In estrous female rats, 39 +/- 0.9% of AP cells expressed leptin mRNA, indicating that the potential for leptin production was greater than predicted from the immunolabeling. Estrogen and GHRH together (but not alone) increased percentages of cells with leptin protein (41 +/- 9%) or mRNA (57 +/- 5%). Estrogen and GHRH also increased the percentages of AP cells that co-express leptin mRNA and GH antigens from 20 +/- 2% of AP cells to 37 +/- 5%. Although the significance of leptin in GH cells is not understood, it is clearly increased after stimulation with GHRH and estrogen. Because GH cells also have leptin receptors, this AP leptin may be an autocrine or paracrine regulator of pituitary cell function.

Arginine Increases Growth Hormone Gene Expression in Rat Pituitary and GH3 Cells

The effect of arginine (Arg) and Ornitargin^® (OT) [a compound containing the aminoacids Arg, citrulline (Cit) and ornithine (Orn)] administration upon growth hormone (GH) gene expression was studied both in vivo and in vitro (hemipituitaries and GH3 cells) by Northern blot analysis. For in vivo studies, adult male Wistar rats were anesthetized, subjected to i.v. infusion of 200 µl of 150 mM NaCl (control group), Arg (15 or 150 mg) or OT (15 mg of Arg, 1 mg of Cit and 4 mg of Orn) at a rate of 20 µl/min, and killed 50 min thereafter. For the in vitro studies, hemipituitaries or GH3 cells were incubated in 1 ml of appropriate medium containing Arg (15 or 150 mg) or OT (15 mg of Arg, 1 mg of Cit and 4 mg of Orn) for 60 min. The pituitaries of the in vivo and in vitro studies and GH3 cells were subsequently processed for RNA extraction. Total RNA was subjected to electrophoresis in agarose (1%)/formaldehyde gel, transferred to a nylon membrane and subjected to hybridization with a rat GH ³²P-cDNA, and ³²P-18S rRNA probe to correct for the variability in RNA loading. After autoradiography of the membrane, the abundance of GH mRNA and 18S rRNA bands was quantified by densitometry. The in vivo study demonstrated that Arg and OT infusion induced a 2.3-fold increase in GH mRNA expression, which could result from the Arg-mediated inhibition of somatostatin release. In addition, in vitro Arg, but not OT, induced GH gene expression in hemipituitaries and GH3 cells, indicating that the aminoacid can act per se at the pituitary somatotrope level. In conclusion, our data show for the first time that arginine stimulates GH gene expression in parallel to its recognized GH-releasing activity.

Functional modification of pituitary somatotropes in the aromatase knockout mouse and the effect of estrogen replacement.

Available data on the influence of estradiol (E(2)) on GH levels remains controversial. A factor contributing to this uncertainty is a lack of knowledge of both E(2) action on somatotropes as well as the molecular mechanisms involved. In this study we investigated gene expression implicated in GH secretion in somatotropes derived from female aromatase knockout (ArKO) mice. In these mice E(2) production is blocked due to disruption of the Cyp19 gene encoding aromatase, the enzyme responsible for estrogen biosynthesis. The effect of E(2) replacement was also studied by in vivo treatment of mice with E(2) for 3 wk. It was demonstrated that somatotropes from ArKO mice had a low expression of GH, GH secretagogue receptor, GHRH receptor (GHRH-R), and pituitary-specific transcription factor (Pit-1). On the other hand, the somatotropes exhibited elevated expression of somatostatin receptors (sst1-5). Overall, these effects resulted in a reduction in GH secretion. E(2) replacement increased GHRH-R, Pit-1, and GH mRNA levels to 185%, 193%, and 157% and reduced the levels of sst1, sst2, sst4, and sst5 mRNA expression in ArKO mice, respectively. E(2) replacement did not affect the levels of pituitary estrogen (alpha and beta) and androgen receptor mRNA expression. It is concluded that the expression of important genes involved in GH synthesis in somatotropes of the female ArKO mouse are functionally down-regulated, and such a down-regulation is reversed to normal levels by E(2) replacement. The levels of GH secretagogue receptor, GHRH-R, and Pit-1 mRNA expression were also reduced, and sst1 and sst3 mRNA expression enhanced in aging ArKO and wild-type mice, resulting in a decrease in GH mRNA expression. It is suggested that aging is another important impact factor for the pituitary expression and regulation of GH mRNA in female mice.