Expression of estrogen, estrogen related and androgen receptors in adrenal cortex of intact adult male and female rats.

INTRODUCTION: Adrenocortical activity in various species is sensitive to androgens and estrogens. They may affect adrenal cortex growth and functioning either via central pathways (CRH and ACTH) or directly, via specific receptors expressed in the cortex and/or by interfering with adrenocortical enzymes, among them those involved in steroidogenesis. Only limited data on expression of androgen and estrogen receptors in adrenal glands are available. Therefore the present study aimed to characterize, at the level of mRNA, expression of these receptors in specific components of adrenal cortex of intact adult male and female rats. MATERIAL AND METHODS: Studies were performed on adult male and female (estrus) Wistar rats. Total RNA was isolated from adrenal zona glomerulosa (ZG) and fasciculate/reticularis (ZF/R). Expression of genes were evaluated by means of Affymetrix® Rat Gene 1.1 ST Array Strip and QPCR. RESULTS: By means of Affymetrix® Rat Gene 1.1 ST Array we examined adrenocortical sex differences in the expression of nearly 30,000 genes. All data were analyzed in relation to the adrenals of the male rats. 32 genes were differentially expressed in ZG, and 233 genes in ZF/R. In the ZG expression levels of 24 genes were lower and 8 higher in female rats. The more distinct sex differences were observed in the ZF/R, in which expression levels of 146 genes were lower and 87 genes higher in female rats. Performed analyses did not reveal sex differences in the expression levels of both androgen (AR) and estrogen (ER) receptor genes in the adrenal cortex of male and female rats. Therefore matrix data were validated by QPCR. QPCR revealed higher expression levels of AR gene both in ZG and ZF/R of male than female rats. On the other hand, QPCR did not reveal sex-related differences in the expression levels of ERα, ERß and non-genomic GPR30 (GPER-1) receptor. Of those genes expression levels of ERα genes were the highest. In studied adrenal samples the relative expression of ERα mRNA was higher than ERß mRNA. In adrenals of adult male and female rats expression levels of estrogen-related receptors ERRα and ERRß were similar, and only in the ZF/R of female rats ERRγ expression levels were significantly higher than in males. We also analyzed expression profile of three isoforms of steroid 5α-reductase (Srd5a1, Srd5a2 and Srd5a3) and aromatase (Cyp19a1) and expression levels of all these genes were similar in ZG and ZF/R of male and female rats. CONCLUSIONS: In contrast to Affymetrix microarray data QPCR revealed higher expression levels of AR gene in adrenal glands of the male rats. In adrenals of both sexes expression levels of ERa, ERb, non-genomic GPR30 (GPER-1), ERR α and ERRß receptors were comparable. The obtained results suggest that acute steroidogenic effect of estrogens on corticosteroid secretion may be mediated by non-genomic GPR30.

Sex-related gene expression profiles in the adrenal cortex in the mature rat: microarray analysis with emphasis on genes involved in steroidogenesis.

Notable sex-related differences exist in mammalian adrenal cortex structure and function. In adult rats, the adrenal weight and the average volume of zona fasciculata cells of females are larger and secrete greater amounts of corticosterone than those of males. The molecular bases of these sex-related differences are poorly understood. In this study, to explore the molecular background of these differences, we defined zone- and sex-specific transcripts in adult male and female (estrous cycle phase) rats. Twelve-week-old rats of both genders were used and samples were taken from the zona glomerulosa (ZG) and zona fasciculata/reticularis (ZF/R) zones. Transcriptome identification was carried out using the Affymetrix(®) Rat Gene 1.1 ST Array. The microarray data were compared by fold change with significance according to moderated t-statistics. Subsequently, we performed functional annotation clustering using the Gene Ontology (GO) and Database for Annotation, Visualization and Integrated Discovery (DAVID). In the first step, we explored differentially expressed transcripts in the adrenal ZG and ZF/R. The number of differentially expressed transcripts was notably higher in the female than in the male rats (702 vs. 571). The differentially expressed genes which were significantly enriched included genes involved in steroid hormone metabolism, and their expression levels in the ZF/R of adult female rats were significantly higher compared with those in the male rats. In the female ZF/R, when compared with that of the males, prevailing numbers of genes linked to cell fraction, oxidation/reduction processes, response to nutrients and to extracellular stimuli or steroid hormone stimuli were downregulated. The microarray data for key genes involved directly in steroidogenesis were confirmed by qPCR. Thus, when compared with that of the males, in the female ZF/R, higher expression levels of genes involved directly in steroid hormone synthesis were accompanied by lower expression levels of genes regulating basal cell functions.

Visinin-like peptide 1 in adrenal gland of the rat. Gene expression and its hormonal control.

VSNL1 encodes the calcium-sensor protein visinin-like 1 and was identified previously as an upregulated gene in a sample set of aldosterone-producing adenomas. Recently, by means of microarray studies we demonstrated high expression of Vsnl1 gene in rat adrenal zona glomerulosa (ZG). Only scanty data are available on the role of this gene in adrenal function as well as on regulation of its expression by factors affecting adrenal cortex structure and function. Therefore we performed relevant studies aimed at clarifying some of the above issues. By Affymetrix(®) Rat Gene 1.1 ST Array Strip, QPCR and immunohistochemistry we demonstrated that expression levels of Vsnl1 in the rat adrenal ZG are notably higher than in the fasciculata/reticularis zone. In QPCR assay this difference was approximately 10 times higher. Expression of this gene in the rat adrenal gland or adrenocortical cells was acutely down regulated by ACTH, while chronic administration of corticotrophin or dexamethasone did not change Vsnl1 mRNA levels. In enucleation-induced adrenocortical regeneration expression levels of both Vsnl1 and Cyp11b2 were notably lowered and positively correlated. Despite these findings, the physiological significance of adrenal Vsnl1 remains unclear, and requires further investigation.

Enucleation-induced rat adrenal gland regeneration: expression profile of selected genes involved in control of adrenocortical cell proliferation.

Enucleation-induced adrenal regeneration is a highly controlled process; however, only some elements involved in this process have been recognized. Therefore, we performed studies on regenerating rat adrenals. Microarray RNA analysis and QPCR revealed that enucleation resulted in a rapid elevation of expression of genes involved in response to wounding, defense response, and in immunological processes. Factors encoded by these genes obscure possible priming effects of various cytokines on initiation of regeneration. In regenerating adrenals we identified over 100 up- or downregulated genes involved in adrenocortical cell proliferation. The changes were most significant at days 2-3 after enucleation and their number decreased during regeneration. For example, expression analysis revealed a notable upregulation of the growth arrest gene, Gadd45, only 24 hours after surgery while expression of cyclin B1 and Cdk1 genes was notably elevated between days 1-8 of regeneration. These changes were accompanied by changes in expression levels of numerous growth factors and immediate-early transcription factors genes. Despite notable differences in mechanisms of adrenal and liver regeneration, in regenerating adrenals we identified genes, the expression of which is well recognized in regenerating liver. Thus, it seems legitimate to suggest that, in the rat, the general model of liver and adrenal regeneration demonstrate some degree of similarity.

Expression of selected genes involved in steroidogenesis in the course of enucleation-induced rat adrenal regeneration.

The enucleation-induced (EI) rapid proliferation of adrenocortical cells is followed by their differentiation, the degree of which may be characterized by the expression of genes directly and indirectly involved in steroid hormone biosynthesis. In this study, out of 30,000 transcripts of genes identified by means of Affymetrix Rat Gene 1.1 ST Array, we aimed to select genes (either up- or downregulated) involved in steroidogenesis in the course of enucleation-induced adrenal regeneration. On day 1, we found 32 genes with altered expression levels, 15 were upregulated and 17 were downregulated [i.e., 3ß-hydroxysteroid dehydrogenase (Hsd3ß), nuclear receptor subfamily 0, group B, member 1 (Nr0b1), cytochrome P450 aldosterone synthase (Cyp11b2) and sterol O-acyltransferase 1 (Soat1)]. On day 15, the expression of only 2 genes was increased and that of 3 was decreased. The investigated genes were clustered according to an hierarchical clustering algorithm and 4 clusters were obtained. Quantitative PCR (qPCR) confirmed the much lower mRNA expression levels of steroidogenic acute regulatory protein (StAR) during the regeneration process compared to the control, while the cholesterol side-chain cleavage enzyme (cholesterol desmolase; Cyp11a1) and Hsd3ß genes presented similar expression profiles throughout the entire regeneration process. Cyp11b2 mRNA levels remained very low during the whole regeneration period. Fatty acid binding protein 6 (Fabp6) was markedly upregulated, whereas hormone-sensitive lipase (Lipe) was downregulated. The expression of Soat1 was lowest on regeneration day 1 and, subsequently, its expression increased from there on, reaching levels higher than the control. Dosage-sensitive sex reversal, adrenal hypoplasia critical region, on chromosome X, gene 1 (Dax-1) mRNA levels were lowest on day 1 of the experiment; however, throughout the entire experimental period, there were no statistically significant differences observed. After the initial decrease in steroidogenic factor 1 (Sf-1) mRNA levels observed on the 1st day of the experiment, a marked upregulation in its expression was observed from there on. Data from the current study strongly suggest the role of Fabp6, Lipe and Soat1 in supplying substrates of regenerating adrenocortical cells for steroid synthesis. Our results indicate that during the first days of adrenal regeneration, intense synthesis of cholesterol may occur, which is then followed by its conversion into cholesteryl esters. Moreover, our data demonstrated that in enucleation-induced regeneration, the restoration of genes involved in glucocorticoid synthesis is notably shorter than that of those involved in aldosterone synthesis.

Angiogenesis in the course of enucleation-induced adrenal regeneration--expression of selected genes and proteins involved in development of capillaries.

Enucleation-induced rapid proliferation of adrenocortical cells and restoration of adrenals structure requires formation of new blood vessels. The performed studies aimed to select from around 30,000 transcripts, identified by means of Affymetrix(®) Rat Gene 1.1 ST Array, the genes involved in angiogenesis in the course of enucleation-induced adrenal regeneration and to characterize their expression levels in regenerating gland between days 1 and 15 after surgery. At day 1 of regeneration almost 2000 genes showed more than 2-fold up/down-regulation. At days 1-3 after surgery the highest expression demonstrated genes involved in the development of inflammation and blood clot formation. From around 2000 genes we selected genes involved in angiogenesis. During the regeneration 62 genes involved in angiogenesis were identified as up- or down-regulated. Some data were also validated by QPCR. Levels of Vegfa and Kdr (Vegfr-2) mRNAs were very low at day 1 of regeneration and remained unchanged thereafter. The highest expression of Figf gene was found at day 5 while that of Vwf gene at days 1 and 2 after surgery. Levels of Thy1 mRNA increased notably between days 2 and 5 of the experiment. In comparison to control rats, Mc2r (ACTH receptor) expression was lowered at day 1 of the experiment and remained unchanged thereafter. This suggests that enucleation-induced adrenal neoangiogenesis does not require elevated expression of ACTH receptor. Results of our studies strongly suggest that enucleation-induced adrenal regeneration is an angiogenesis-dependent process. Moreover, immunohistochemistry suggests that regenerating adrenal parenchymal cells release numerous angiogenic factors which paracrinally may regulate formation of new vessels.

Ghrelin and obestatin inhibit enucleation-induced adrenocortical proliferation in the rat.

Studies involving the role of ghrelin (GHREL) in regulating the proliferative activity of various cell types have obtained variable results depending primarily on the experimental model applied. It was recently reported that neither GHREL nor obestatin (OBS) affected the proliferative activity of cultured rat adrenocortical cells. In view of the conflicting results, we investigated the effects of GHREL and OBS on the proliferative activity of rat adrenocortical cells in a model of bilateral enucleation-induced adrenocortical regeneration in the rat. Rats were sacrificed 5 or 8 days after surgery. Twenty-four hours before being sacrificed, the appropriate groups were infused with 3 nmol GHREL or OBS/100 g. The mitotic index was assessed using the stachmokinetic method with vincristine. In comparison with intact rats, expression levels of ppGHREL, BAX, JUN-B and JUN-C genes were notably higher in regenerating adrenals, and neither GHREL nor OBS infusion affected these levels. Expression levels of the GHS-R, GPR39v2 and FOS genes were affected neither by adrenal enucleation nor GHREL or OBS infusion. Expression of only two studied genes, GPR39v1 and EGR1, was regulated by OBS. In the regenerating adrenal glands, GPR39v1 and EGR1 mRNA levels were higher than the levels in intact animals. GHREL infusion had no effect while OBS infusion notably stimulated GPR39v1 mRNA levels in the regenerating adrenal gland and evoked an opposite effect on EGR1 mRNA. OBS administration resulted in a potent decrease in the mitotic index of the studied cells, an effect found at both days 5 and 8 of the experiment. GHREL exerted a similar effect only at day 5 of adrenocortical regeneration. Neither GHREL nor OBS had an effect on blood aldosterone concentrations. GHREL infusion lowered plasma corticosterone concentration at day 5 but not 8 of the experiment, while OBS administration was ineffective. Thus, this study is the first to demonstrate that, in vivo, both GHREL and OBS inhibit the growth of the regenerating adrenal cortex. Moreover, the data suggest that the effect of OBS might be, at least in part, mediated by the EGR1 pathway known to be critical in cell proliferation.

Neuromedin-U inhibits unilateral adrenalectomy-induced compensatory adrenal growth in the rat.

Neuromedin-U (NMU) is a brain-gut peptide, which has been previously found to stimulate hypothalamic-pituitary-adrenal axis in the rat and to control the growth of the rat adrenal cortex. The present study aimed to investigate the possible involvement of NMU in the regulation of unilateral adrenalectomy-induced compensatory adrenal growth, a phenomenon known to be neurally mediated. The right adrenal gland of mature female rats was removed, the contralateral gland was then analyzed at 24 and 72h following surgery. Groups of rats were given 3 subcutaneous injections (24, 16 and 8h before decapitation) of NMU8 (1.5 or 3.0 nmol/100g/per injection). Three hours before sacrifice all rats received an intraperitoneal injection of 0.1mg/100g body weight of vincristin. By means of RT-PCR the presence of NMUR1 mRNA was detected in adrenal cortex of both intact and hemiadrenalectomized rats. As expected, unilateral adrenalectomy-induced an increase in adrenal weight, associated with increased plasma ACTH, aldosterone and corticosterone levels. The administration of NMU to hemiadrenalectomized rats did not significantly affect these parameters. NMU administration, however, notably inhibited the unilateral adrenalectomy-induced adrenocortical cell proliferation in both zona glomerulosa and zona fasciculata, as assessed by the metaphase index and the number of parenchymal cell nuclei per unit area of the tissue. When compared to hemiadrenalectomized animals receiving saline, a significant decrease of blood corticosterone levels was observed after 24h in rats treated with the highest dose of NMU. Since these effects were independent on changes in blood ACTH, they could reflect an interaction of NMU with the neural system innervating the adrenal gland.

Neuromedin U enhances proliferation of ACTH-stimulated adrenocortical cells in the rat.

Neuromedin U (NMU) is a brain-gut peptide involved in the regulation of the hypothalamic-pituitary-adrenal axis and adrenocortical cell proliferation. In this study, we investigated the effects of NMU8 (three subcutaneous injections of 6.0 nmol/100 g, 24, 16 and 8 h before autopsy) on the adrenal glands of rats treated for 2 or 4 days with a low (2 microg/100 g body weight/24 h) or a high (8 microg) dose of adrenocorticotropic hormone (ACTH). As revealed by RT-PCR, ACTH treatment did not prevent expression of NMUR1 in rat adrenal cortex. At day 4 of ACTH administration, the weight of adrenals was lower than at day 2. NMU8 administration prevented ACTH-induced increases of adrenal weight at day 2 of the experiment. ACTH plasma concentrations were increased in all ACTH-administered rats. NMU8 administration increased ACTH plasma concentration at day 2 of the lower ACTH dose-treated group while it reduced the ACTH plasma level at day 4 in the higher ACTH dose-administered rats. In all groups of ACTH-treated rats, NMU8 changed neither aldosterone nor corticosterone plasma concentrations. In the zona glomerulosa (ZG), NMU8 increased metaphase index at days 2 and 4 in the lower ACTH dose-treated group and had no statistically significant effect in rats treated with the higher ACTH dose. In the zona fasciculata (ZF), NMU8 administration increased metaphase index at day 2 in the lower ACTH dose-treated group but reduced metaphase index at day 4 in the higher dose ACTH-administered rats. NMU8 reduced the number of cells per unit area both in ZG and ZF at day 2 in the higher ACTH dose-treated rats. In the remaining groups NMU8 did not produce statistically significant changes in the number of cells per unit area. Thus, our findings demonstrate that exogenous NMU may stimulate proliferation primarily of the cortical ZG cells in rats administered with ACTH, although at high doses of exogenous corticotropin an opposite effect occurred.

Neuromedin-U stimulates enucleation-induced adrenocortical regeneration in the rat.

Neuromedin-U (NMU) is a brain-gut peptide, which has been previously found to stimulate hypothalamic-pituitary-adrenal axis in the rat. Enucleation-induced adrenal regeneration in rats with contralateral adrenalectomy is a well-established model of adrenal growth, that not only depends on the compensatory ACTH hypersecretion, but is also modulated by several regulatory peptides. Hence, we investigated whether NMU may be included in this group of bioactive molecules. Reverse transcription-polymerase chain reaction and immunocytochemistry showed that regenerating rat adrenocortical cells at days 5 and 8 after surgery express the NMU receptor NMUR1 as mRNA and protein. NMU8 administration to rats bearing regenerating adrenals markedly raised the plasma concentration of corticosterone and notably enhanced proliferative activity of adrenocortical cells. ACTH blood level was unchanged at day 5 and significantly decreased at day 8. The conclusion is drawn that NMU stimulates regeneration of rat adrenal cortex, via a mechanism independent of pituitary ACTH and involving the activation of NMUR1 located on adrenocortical cells.

Effects of neuromedin-U on immature rat adrenocortical cells: in vitro and in vivo studies.

Neuromedin U (NMU) is a brain-gut peptide, that in the peripheral organs and tissues acts via a G protein-coupled receptor, called NMUR1. Reverse transcription-polymerase chain reaction showed the expression of NMUR1 mRNA in either cortex and medulla or dispersed zona glomerulosa and zona fasciculata-reticularis cells of the immature rat adrenals. Accordingly, immunocytochemistry demonstrated the presence of NMUR1-like immunoreactivity in the cortex and medulla of immature adrenals. NMU8 administration to immature rats was found to raise aldosterone, but not corticosterone, plasma concentration, without altering adrenal growth. Conversely, the exposure to NMU8 markedly enhanced the proliferative activity of immature rat inner adrenocortical cells in primary in vitro culture, without significantly affecting their corticosterone secretion. Collectively, our findings suggest that adrenals of immature rats may be a target for circulating NMU. However, the physiological significance and relevance of the adrenal effects of NMU remain to be ascertained.

Expression of neuromedins S and U and their receptors in the hypothalamus and endocrine glands of the rat.

Neuromedin S (NMS) and neuromedin U (NMU) are regulatory peptides that share the C-terminal amino-acid sequence and act via common G protein-coupled receptors called NMUR1 and NMUR2. Semiquantitative real time-PCR showed that in the rat hypothalamus and testis NMS gene expression was markedly higher than that of the NMU gene, while the reverse occurred in the anterior pituitary and thyroid gland. Low expression of both genes was detected in the thymus, adrenal gland and ovary, whereas in the pancreatic islets only the expression of NMU mRNA was detected. In the rat hypothalamus the expression of the NMUR2 gene was strikingly higher than that of the NMUR1 gene; in contrast, in the testis and ovary the very low expression of NMUR2 contrasted with the relatively high expression of the NMUR1 gene. In the other glands examined only expression of the NMUR1 gene was found. The marked differences in the level of expression of NMU, NMS and their receptors in the hypothalamus and endocrine glands of the rat suggest that in this species such neuromedins may play different roles in the functional regulation of neuroendocrine axes.

Effects of some endocrine disruptors on the secretory and proliferative activity of the regenerating rat adrenal cortex.

The effects of some endocrine disruptors that possess estrogen-like activity on the secretion and growth of regenerating rat adrenal cortex have been investigated in ovariectomized (OVX) and sham-OVX rats. As reference groups, dexamethasone (Dx)-administered sham-OVX and 17beta-estradiol-administered OVX animals were used. Dx, estradiol and endocrine disruptors were subcutaneously injected daily at a dose of 3 nmoles/100 g for 10 consecutive days after surgery, and adrenal enucleation was performed on day 5 of the experiment. Dx and genistein significantly decreased corticosterone plasma concentration (as measured by RIA) in sham-OVX rats with regenerating adrenals, while other disruptors (eusolex, procymidone, linurone, resveratrol, bisphenol-A and and silymarin) were ineffective. Mitotic index (as assayed by the stachmokinetic method with vincristine) was not changed by either Dx or disruptors. Estradiol significantly increased and genistein significantly lowered corticosterone blood level in OVX rats; similar effects were induced in the mitotic index of regenerating adrenals, but the changes were not significant. Eusolex increased the mitotic index, without altering the level of circulating corticosterone. Collectively, our findings allow us to conclude that, of the endocrine disruptors tested, only genistein is able to suppress the secretory activity of regenerating adrenal cortex, this Dx-like effect being apparently unrelated to its estrogen-like activity, and only eusolex enhances the proliferation rate of regenerating adrenal, the effect being conceivably connected with its estrogen-like activity.

Arginin-vasopressin regulates proliferative activity of the regenerating rat adrenal cortex.

Enucleation-induced adrenal regeneration is a classic model to investigate adrenocortical proliferation in vivo, which is dependent not only on pituitary ACTH release, but also on various other neural and endocrine signals. Arginin-vasopressin (AVP), mainly acting via V1 receptors, regulates hypothalamic-hypophyseal-adrenal axis function, acting on both its central and peripheral branches. Here, we studied whether endogenous AVP system modulates rat adrenal regeneration. Reverse transcription-polymerase chain reaction (PCR) detected only the mRNAs of V1a and V1b receptors in normal and regenerating adrenals. The expression was very low, and semi-quantitative conventional and real-time PCR showed that it was down-regulated in regenerating adrenals in relation to the time elapsed from enucleation. AVP (three subcutaneous injections 28, 16 and 4 h before sacrifice) raised metaphase index at day 5, but not at day 8 of regeneration. Unexpectedly, both V1-receptor and V2-receptor antagonists increased metaphase index at days 5 and 8 of regeneration. Neither AVP nor AVP-receptor antagonists affected plasma levels of corticosterone in rats bearing regenerating adrenals. It is concluded that AVP, acting via V1 receptors located in adrenals, exerts a stimulating effects on adrenal regeneration. Due to the down-regulation of V1-receptor expression in regenerating adrenals, this effect is very weak and is easily overcome by a tonic inhibitory action of endogenous AVP systems probably involving extra-adrenal indirect mechanisms.

Effects of prolonged cholecystokinin administration on rat pituitary-adrenocortical axis: role of the CCK receptor subtypes 1 and 2.

Many lines of evidence indicate that cholecystokinin (CCK) and its receptors, named CCK1-R and CCK2-R, are expressed in the hypothalamo-pituitary-adrenal (HPA) axis, the function of which they acutely stimulate. However, the role of endogenous CCK system in the regulation of HPA axis is still unknown. To address this issue we investigated the effect of the prolonged (6-day) administration of CCK, CCK-R antagonists (CCK-RAs) and pentagastrin (PG), a CCK2-R agonist, on adult rat HPA axis. Semiquantitative reverse transcription-polymerase chain reaction showed that CCK treatment lowered the expression of CCK1-R and CCK2-R mRNAs in the pituitary, but not adrenal gland. ACTH plasma concentration was not affected by any treatment. Neither CCK nor PG administration induced significant changes in the blood levels of aldosterone and corticosterone. CCK1-RA, although being per se ineffective, in the presence of CCK raised plasma levels of aldosterone and corticosterone; conversely, CCK2-RA, either alone or in the presence of agonists, lowered the blood concentrations of the two hormones. CCK, but not PG, treatment decreased relative adrenal weight, and morphometry showed that CCK-induced adrenal atrophy was coupled to decreases in the volume of adrenocortical zones, which in turn mainly depended on the lowering in the volume and number of adrenocortical cells. PG administration raised and CCK2-RA per se decreased the volume and number of adrenocortical cells. Taken together, these findings allow us to draw the following main conclusions: i) the prolonged exposure to elevated CCK concentrations down-regulates CCK-R expression in the pituitary gland, which accounts for the lack of effect of CCK on ACTH secretion; ii) adrenal CCK1-Rs and CCK2-Rs inhibit and stimulate, respectively, corticosteroid secretion; and iii) endogenous CCK system plays a minor role in the physiological regulation of rat HPA axis, its main effect being the CCK2-R-mediated maintenance of adrenocortical-cell number.

Ghrelin, an endogenous ligand for the growth hormone-secretagogue receptor, is expressed in the human adrenal cortex.

Ghrelin is an endogenous ligand of the growth hormone secretagogue receptor (GHS-R), which was originally isolated from rat stomach. Ghrelin and GHS-R are also expressed in several peripheral tissues, including adrenal glands, and this prompted us to study ghrelin expression and ghrelin-binding site localization in the human adrenal cortex, and the possible effect of this peptide on corticosteroid-hormone secretion. Reverse transcription-polymerase chain reaction (RT-PCR) and radioimmune assay (RIA) showed sizeable expression of ghrelin mRNA and protein in six human adrenal cortexes. Autoradiography evidenced abundant [125I]ghrelin binding sites in the adrenal zona glomerulosa and outer zona fasciculata. However, ghrelin (10(-6) M) did not significantly affect either basal or agonist (ACTH and angiotensin-II)-stimulated early and late steps of steroid-hormone synthesis from adrenocortical slices (as measured by quantitative high pressure liquid chromatography). Since zona glomerulosa is the cambium layer involved in the growth maintenance of adrenal cortex, the present coupled RT-PCR, RIA and autoradiographic findings could suggest the involvement of ghrelin in the autocrine-paracrine regulation of human adrenal growth.

Exendin-4, a GLP-1 receptor agonist, stimulates pituitary-adrenocortical axis in the rat: Investigations into the mechanism(s) underlying Ex4 effect.

Exendin-4 (Ex4) is a potent and long-lasting agonist of glucagon-like peptide-1 (GLP-1), which has been previously found to stimulate pituitary-adrenal axis in the rat. Aim of the present study was to gain insight into the mechanism(s) involved in the Ex4-induced rise in the rat plasma concentrations of ACTH, aldosterone and corticosterone. Preliminary time- and dose-response studies showed that the maximum stimulating effect of Ex4 occurred within 1 or 2 h and at dose ranging from 0.5 to 2.0 nmol/100 g body weight. The GLP-1 receptor (GLP-1R) antagonist Ex(9-39) did not significantly affect ACTH, aldosterone and cortico-sterone responses to Ex4. Neither the administration of CRH and arginine vasopressin (AVP)-receptor antagonists nor adrenal demedullation prevented pituitary-adrenal axis responses to Ex4. The prolonged (4 or 6 days) suppression of the pituitary ACTH release by dexamethasone impaired corticosterone, but not aldosterone response to Ex4. The following conclusions are drawn: i) Ex4 stimulates rat pituitary-adrenal axis through receptors other than the classic GLP-1R; ii) neither CRH and AVP nor medullary catecholamines are involved in the Ex4-induced stimulation of ACTH release; iii) ACTH stimulation accounts for the rise in corticosterone plasma concentration; and iv) the aldosterone secretagogue effect of Ex4 occurs via a mechanism independent of the stimulation of either ACTH or medullary catecholamines.

Effects of preproglucagon-derived peptides and exendins on steroid-hormone secretion from dispersed adrenocortical cells of normal and streptozotocin-induced diabetic rats.

Many lines of evidence have shown that preproglucagon-derived peptides affect steroid secretion from dispersed adrenocortical cells, and that streptozotocin (STZ)-induced experimental diabetes alters adrenocortical-cell function. Hence, we compared the effects of glucagon, glucagon-like peptide (GLP)-1 and GLP-2 on basal and ACTH-stimulated secretion of dispersed adrenocortical cells from normal and STZ-induced diabetic rats. We also examined the effects of exendins (EX) 3 and 4, because EX4 is known to be a potent and long-lasting agonist of GLP-1 receptors. STZ-induced diabetes moderately enhances basal and ACTH-stimulated secretion from dispersed zona glomerulosa (ZG) cells, without significantly affecting corticosterone production from dispersed zona fasciculata-reticularis (ZF/R) cells. In normoglycemic rats, glucagon increased basal aldosterone and corticosterone secretion from ZG and ZF/R cells, GLP-2 raised both basal and ACTH-stimulated aldosterone secretion and ACTH-stimulated corticosterone output, and EX4 increased basal corticosterone secretion. In contrast, glucagon, GLP-2 and EX4 did not elicit secretory responses from adrenocortical cells of diabetic rats. GLP-1 and EX3 did not alter secretion of dispersed adrenocortical cells of either normal or STZ-treated rats. Taken together, our findings indicate that preproglucagon-derived peptides enhance steroid secretion from adrenocortical cells of normal, but not STZ-induced diabetic rats. It is suggested that the prolonged exposure to low concentrations of insulin causes unresponsiveness of adrenocortical cells to glucagon, GLP-2 and EX4, which may contribute to the hyporeninemic hypoaldosteronism and alterations in glucocorticoid metabolism occurring in experimental diabetes.

Adrenomedullin stimulates proliferation and inhibits apoptosis of immature rat thymocytes cultured in vitro.

Adrenomedullin (AM) is a hypotensive peptide, which derives from the proteolytic cleavage of pro(p)AM, and acts through two subtypes of receptors, named L1-receptor (L1-R) and calcitonin receptor-like receptor (CRLR). CRLR functions as either a calcitonin gene-related peptide (CGRP) receptor or a selective AM receptor depending on which member of a family of receptor-activity-modifying proteins (RAMPs) is expressed: RAMP1 generates CGRP receptors, while RAMP2 and RAMP3 produce AM receptors. Reverse transcription (RT)-polymerase chain reaction (PCR) consistently allowed the detection of pAM and peptidyl-glycine alpha-amidating monooxygenase (the enzyme converting immature AM to the mature peptide) mRNAs in the thymus cortex of immature (10-day-old) rats. Accordingly, radioimmune assay (RIA) measured low but sizeable AM concentrations in this tissue. RT-PCR also demonstrated the presence of the specific mRNAs of L1-R, CRLR and RAMPs. AM (from 10(-9) to 10(-7)M) increased proliferation index and lowered apoptotic index of cultured immature rat thymocytes, and the effects were annulled by the AM receptor antagonist AM(22-52). In conclusion, our study demonstrated that (1) immature rat thymus cortex expresses AM and the AM receptors L1-R and CRLR/RAMP; and (2) AM, acting via AM(22-52)-sensitive receptors, exerts a potent growth promoting effect on immature rat thymus, by enhancing proliferation and lowering apoptotic death of thymocytes. Taken together, these findings could suggest that AM may play a role in the development of immunity.

Effects of adrenomedullin and its fragment 22-52 on basal and ACTH-stimulated secretion of cultured rat adrenocortical cells.

Adrenomedullin (ADM) and its receptors are expressed in the adrenal cortex, where ADM is currently known to inhibit agonist-stimulated aldosterone secretion from zona glomerulosa (ZG), without affecting either basal aldosterone release or the secretory activity of zona fasciculata-reticularis (ZF/R) cells. These functional findings have been obtained using freshly dispersed adrenocortical cells, but evidence has been provided that ADM is able to enhance basal aldosterone secretion from rat capsule-ZG preparations. Hence, we investigated the effect of ADM and ADM22-52, a putative antagonist of ADM receptors, on the secretory activity of rat adrenal cell cultured in vitro for 72 h. Cultures were exposed for 3 or 24 h to 10(-7) M ADM and/or ADM22-52, in the absence or the presence of 10(-8) M ACTH, and the concentration of aldosterone and corticosterone in the culture medium was measured by radioimmune assay. ADM and/or ADM22-52 raised basal aldosterone secretion at 3 h, but not 24 h exposure, and did not affect ACTH-stimulated aldosterone production. Corticosterone secretion was not changed at 3 h. In contrast, at 24 h exposure ADM22-52 alone or with ADM decreased basal corticosterone secretion; ADM evoked a small rise in ACTH-stimulated corticosterone production, and the effect was annulled by ADM22-52. These puzzling findings are interpreted in light of the fact that i) our cultures were actually a mixture of ZG, ZF/R and medullary chromaffin cells; ii) ADM stimulates adrenomedullary cells to release catecholamines, which are able to enhance aldosterone secretion from ZG cells; and iii) the prolonged exposure to ADM may modify, under in vitro culture conditions, ZF/R cells, switching their phenotype from an ADM-unresponsive to an ADM-responsive one. Our study casts doubts on the selectivity of ADM22-52 as ADM receptor antagonist, and stresses that great caution must be used in comparing adrenal-secretion findings obtained with different in vitro techniques.