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.

Evidence suggesting that ghrelin O-acyl transferase inhibitor acts at the hypothalamus to inhibit hypothalamo-pituitary-adrenocortical axis function in the rat

Production of n-octanoyl-modified ghrelin (GHREL), an active form of the peptide requires prohormone processing protease and GHREL O-acyltransferase (GOAT), as well as n-octanoic acid. Recently a selective GOAT antagonist (GO-CoA-Tat) was invented and this tool was used to study the possible role of endogenous GHREL in regulating HPA axis function in the rat. Administration of GOAT inhibitor (GOATi) resulted in a notable decrease in plasma ACTH, aldosterone and corticosterone concentrations at min 60 of experiment. Octanoic acid (OA) administration had no effect on levels of studied hormones. Plasma levels of unacylated and acylated GHREL remained unchanged for 60min after either GOATi or OA administration. Under experimental conditions applied, no significant changes were observed in the levels of GOAT mRNA in hypothalamus, pituitary, adrenal and stomach fundus. After GOATi injection hypothalamic CRH mRNA levels were elevated at 30 min and pituitary POMC mRNA levels at 60 min. Both GOATi and OA lowered basal, but not K(+)-stimulated CRH release by hypothalamic explants and had no effect on basal or CRH-stimulated ACTH release by pituitary slices. Neither GOATi nor OA affected corticosterone secretion by freshly isolated or cultured rat adrenocortical cells. Thus, results of our study suggest that in the rat endogenous GHREL exerts tonic stimulating effect on hypothalamic CRH release. This effect could be demonstrated by administering rats with selected inhibitor of ghrelin O-acyltransferase, the enzyme responsible for GHREL acylation, a process which is absolutely required for both GHSR-1a binding and its central endocrine activities.

Effects of neuropeptides B and W on the rat pituitary-adrenocortical axis: in vivo and in vitro studies

Neuropeptides (NP) B and W are hypothalamic peptides involved in the regulation of feeding and neuro-endocrine axes. Evidence has been provided that NPB and NPW act on both the central and the peripheral branches of the rat hypothalamic-pituitary-adrenocortical axis, and we carried out in vivo and in vitro studies to gain insight into this topic. Reverse transcription-polymerase chain reaction showed the expression of NPB, NPW and their receptors in both adrenal cortex (zonae glomerulosa and fasciculata-reticularis) and adrenal medulla, where immunocytochemistry also detected the presence of abundant NPB- and NPW-immunoreactivity. The acute subcutaneous administration of NPB (0.5 or 1.5 nmol/100 g) did not alter ACTH plasma concentration, while that of NPW (1.5 nmol/100 g) decreased it. Neither NPB nor NPW affected the blood level of aldosterone, while both peptides (0.5 nmol/100 g) raised that of corticosterone. NPB (10(-6) M) lowered ACTH-stimulated aldosterone secretion, and basal and ACTH-stimulated corticosterone production from adrenal quarters containing both cortical and medullary tissues. NPW (10(-6) M) enhanced basal aldosterone secretion from adrenal quarters, and the effect was suppressed by the beta-adrenoceptor antagonist l-alprenolol (10(-5) M). NPW did not affect corticosterone production. Collectively, our findings allow us to draw the following tentative conclusions: i) ACTH-independent extra-adrenal mechanism(s) are operative in vivo, by which NPB and NPW stimulate adrenal glucocorticoid, but not mineralocorticoid secretion; ii) in vitro the interaction of NPB with adrenal medulla activates unknown mechanism(s) hampering adrenocortical steroidogenic machinery; and iii) NPW stimulates in vitro aldosterone secretion by enhancing the release of medullary catecholamines, which in turn activate beta-adrenoceptors located on zona glomerulosa cells.

Expression of neuropeptides B and W and their receptors in endocrine glands of the rat

Neuropeptides B and W (NPB and NPW) have been identified as endogenous ligands of the G protein-coupled receptors (GPR) 7 and 8, which in humans are expressed in the hypothalamus and probably involved in the regulation of energy homeostasis and feeding behavior. GPR8 is absent in the rat, where the GPR8-like receptor (GPR8-LR) has been described. Reverse transcription-polymerase chain reaction detected the expression of NPB, NPW, GPR7 and GPR8-LR mRNAs in the hypothalamus, anterior pituitary, thyroid and parathyroid glands, pancreatic islets, adrenal glands, ovary and testis of the rat. Immunocytochemistry demonstrated the presence of NPB and NPW immunoreactivities in these same glands. Radioimmune assay showed that the bolus intraperitoneal injection of 2 nmol/100 g NPB or NPW raised the plasma levels of parathyroid hormone, corticosterone and testosterone. NPB also increased the blood concentration of thyroxine, and NPW that of ACTH and estradiol. Taken together, these findings allow us to suggest that NPB and NPW play a role in the autocrine-paracrine functional regulation of the endocrine system in the rat.

Estradiol and resveratrol stimulating effect on osteocalcin, but not osteonectin and collagen-1alpha gene expression in primary culture of rat calvarial osteoblast-like cells

Evidence is available that some endocrine disruptors, acting as selective estrogen receptor modulators (SERMs), interfere with osteoblast differentiation and function. Therefore, we investigated whether 17beta-estradiol, bisphenol-A (BSP), silymarin, genistein, resveratrol, procymidone, linurone and benzophenone-3 (BP3) modulate differentiation of rat calvarial osteoblast-like (ROB) cells in primary in vitro culture. Disruptors were added at day 18 of culture and cells were harvested 48 h later. Real time-PCR revealed that estradiol and resveratrol enhanced osteocalcin mRNA expression in ROB cells, while other disruptors were ineffective. The expression of osteonectin and collagen-1alpha was not affected by any disruptor. Estradiol, resveratrol, genistein and BSP stimulated the proliferative activity of ROB cells. In contrast, procymidone and linurone inhibited the proliferative activity, and silymarin and BP3 were ineffective. The conclusion is drawn that i) only resveratrol is able, like estradiol, to stimulate the specialized functions of ROB cells, and ii) the proliferative activity of ROB cells is more sensitive to endocrine disruptors, some of which could probably act via a mechanism independent of their SERM 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 met-enkephalin on cell proliferation in different models of adrenocortical-cell growth

Met-enkephalin (met-Enk) is an opioid peptide that acts via three main subtypes of receptors referred to as mu (mu)-, delta (delta)- and zeta (zeta)-receptor. While the first two receptor subtypes mediate the classic opioid effects of met-Enk, zeta-receptors are reported to be involved in the non-opioid actions of the peptide, i.e. the inhibitory effect on the cell growth. Despite the fact that met-Enk is known to regulate the function of the hypothalamic-pituitary-adrenal axis acting on both its central and peripheral branches, none is known on the effects of met-Enk on adrenal growth. Hence, we have investigated the effects of met-Enk and its receptor agonists and antagonists on cell proliferation in three different models of rat adrenal growth: i) immature adrenal cortex, ii) regenerating adrenal cortex and iii) primary cultures of adrenocortical cells. In in vivo experiments, rats were given subcutaneous injections of 1 nmol/100 g of the peptides 28, 16 and 4 h before the sacrifice, and proliferative activity was assessed by counting the number of metaphase-arrested cells (after vincristine administration). In in vitro studies, cultured adrenocortical cells were exposed for 48 h to the peptides at a concentration of 10(-6) M, and proliferative activity was measured by the EZ4U method. The blockade of mu- and delta-receptors raised proliferative activity in immature adrenals and decreased it in regenerating glands, and the effects were reversed by mu- and delta-receptor agonists. Naltrexone-induced blockade of all met-Enk receptor subtypes decreased proliferative activity in immature adrenal and raised it in regenerating glands. The exposure to either mu- or delta-receptor agonists and antagonists evoked doubtful or no effects on the proliferative activity of cultured adrenocortical cells. In contrast, met-Enk exerted a marked antiproliferogenic effect that was reversed by naltrexone. Taken together, these findings allow us to draw the following conclusions: i) mu- and delta-receptor activation inhibits the growth of immature adrenals, stimulates adrenal regeneration, and does not affect proliferation of cultured adrenocortical cells; ii) zeta-receptors mediate the growth inhibitory effect of met-Enk on both regenerating adrenals and cultured adrenocortical cells, but unexpectedly their activation stimulates the growth of immature gland; and iii) the effects of mu- and delta-receptor activation in in vivo experiments are probably mediated by extra-adrenal indirect mechanisms.

Effects of neuropeptides B and W on the secretion and growth of rat adrenocortical cells

Neuropeptide-B (NPB) and neuropeptide-W (NPW) are recently discovered endogenous ligands of the GPR7- and GPR8-receptors (R), which in humans are expressed in the hypothalamus and probably involved in the regulation of energy homeostasis and neuroendocrine axes. GPR8-Rs are absent in rodents, where the GPR8-like-R has been described. Reverse transcription-polymerase chain reaction detected the expression of NPB, NPW, GPR7-R and GPR8-like-R mRNAs in rat adrenocortical cells (both freshly-dispersed and 4-day-cultured cells). NPB did not acutely (60-min exposure) alter basal aldosterone secretion from freshly dispersed zona glomerulosa cells, while NPW raised it. Both NPB and NPW enhanced ACTH-stimulated aldosterone secretion and did not affect either basal or ACTH-stimulated corticosterone production by dispersed zona fasciculata/reticularis (ZF/R) cells. The prolonged (4-day) exposure to NPW, but not NPB, raised corticosterone secretion from cultured ZF/R cells, and both neuropeptides increased the proliferation rate of cultured cells. Taken together, our findings indicate that NPB and NPW affect rat adrenocortical function, so they may be included in that large family of peptides involved in the autocrine-paracrine stimulation of secretion and growth of adrenal cortex.

Effects of leptin and leptin fragments on steroid secretion and proliferative activity of regenerating rat adrenal cortex

Leptin, an adipose tissue-secreted hormone, acts via several isoforms of specific receptors (Ob-Rs), which may variously interact with the native leptin molecule and its fragments. Evidence has been provided that leptin affects rat adrenal functions, but the results were rather conflicting depending on the experimental condition examined (e.g. regenerating vs. mature or immature adrenal gland). Hence, we investigated the effects of three subcutaneous injections of murine leptin(1-147) and several leptin fragments (3 nmol/100 g body weight; 28, 16 and 4 h before the sacrifice) on the secretory activity and growth of regenerating rat adrenal cortex. The following leptin fragments were tested: murine leptin(116-130), and human leptin fragments 150-167, 138-167, 93-105, 22-56 and [Tyr]26-39. Leptin(1-147) enhanced plasma concentration of both aldosterone and corticosterone. The blood level of aldosterone was raised by leptin(116-130), leptin(138-167) and leptin(93-105), and that of corticosterone by leptin(93-105) and Tyr-leptin(26-39). Metaphase index (stachmokinetic method with vincristine) was unaffected by leptin(1-147), and lowered by leptin(116-130), leptin(150-167) and leptin(138-167). Collectively, our findings allow us to conclude that leptin and leptin fragments enhance the secretory activity and inhibit the growth of regenerating rat adrenal cortex, the biological activity of leptin being located in the C-terminal segment of its molecule.

Effects of leptin and leptin fragments on steroid secretion of freshly dispersed rat adrenocortical cells

The biological actions of leptin on target tissues are mediated via several isoforms of receptors (Ob-Rs), which may differently interact with native leptin and its fragments. Based on the presence in the rat adrenals of at least two Ob-R isoforms and the conflicting findings on the effect of leptin on adrenocortical secretion, we investigated the effects of the native leptin and several leptin fragments (10(-8) and 10(-6)M) on aldosterone and corticosterone secretion from freshly dispersed rat zona glomerulosa (ZG) and zona fasciculata-reticularis (ZF/R) cells. Reverse transcription (RT)-polymerase chain reaction (PCR) showed the expression of Ob-Ra and Ob-Rb mRNAs in both ZG and ZF/R cells. Native murine leptin (1-147) enhanced aldosterone and corticosterone secretion from dispersed ZG and ZF/R cells, and similar effects were elicited by murine leptin fragment 116-130, and human leptin fragments 138-167, 150-167 and [Tyr] 26-39. Human leptin fragment 93-105 was ineffective, while fragment 22-56 decreased corticosterone output without affecting aldosterone secretion. Taken together, our findings indicate that in rat adrenocortical cells leptin and leptin fragments may differently interact with Ob-Rs or interact with different Ob-R isoforms. Moreover, they suggest that (1) the direct adrenocortical secretagogue effect of leptin mainly depends on the C-terminal sequence 116-166; and (2) the N-terminal sequence is not needed for leptin to activate Ob-Rs positively coupled to steroidogenesis, but is possibly responsible for a direct inhibitory effect on glucocorticoid secretion.

Prolonged orexin administration stimulates steroid-hormone secretion, acting directly on the rat adrenal gland

Orexins A and B are two hypothalamic peptides, that play a role in the central control of food intake. Orexins act via two subtypes of receptors: OX1R which is selective for orexin A, and OX2R which binds both orexins. Reverse transcription-polymerase chain reaction demonstrated the expression of both OX1R and OX2R gene in the adrenal cortex of adult female rats. The prolonged systemic administration of orexins A and B (20 ng/kg x day, for 7 days) affected neither adrenal weight and the morphology of adrenocortical zones (as evaluated by morphometric techniques) nor ACTH plasma concentration in rats. In contrast, the treatment with both orexins increased plasma concentration of both aldosterone and corticosterone. Taken together, these findings indicate that orexins exert a marked direct chronic secretagogue action on adrenocortical cells, acting through both OX1R and OX2R.

Effects of neurotensin and bombesin on the secretory and proliferative activity of regenerating rat adrenal cortex

Neurotensin (NT) and bombesin (BM)-like peptides are known to be involved in the regulation of the rat hypothalamo-pituitary-adrenal axis. By using selective NT- and BM-receptor antagonists (NT-A and BM-A, respectively) we investigated whether endogenous NT and BM-like peptides play a role in the control of rat adrenal secretion and growth during enucleation-induced regeneration. At day 5 of regeneration, NT-A did not affect the plasma concentrations of aldosteronc (PAC) and corticosterone (PBC), but at day 8, it raised both PAC and PBC over the respective baseline value; the simultaneous administration of NT abolished this effect of NT-A. BM-A did not alter PAC and PBC at day 5 of regeneration, while at day 8 it enhanced PBC, an effect reversed by BM. NT-A did not alter mitotic index, and BM-A lowered it at both day 5 and day 8 of regeneration, an effect suppressed by the simultaneous administration of BM. Collectively, these findings allow us to draw the following conclusions: 1) endogenous NT and BM-like peptides influence adrenocortical regeneration in rats; 2) NT exerts a tonic inhibitory action on both aldosterone and corticosterone secretion, without affecting cell-proliferation rate; and 3) BM-like peptides exert a tonic suppressive effect on corticosterone production, coupled with a clear-cut stimulating effect on cell proliferation.

Arginine-vasopressin and corticotropin-releasing hormone are sequentially involved in the endothelin-1-induced acute stimulation of rat pituitary-adrenocortical axis

The acute effect of endothelin-1 (ET-1) on the hypothalamo-pituitary-adrenal (HPA) axis has been investigated in the rat. The plasma concentrations of arginine-vasopressin (AVP), ACTH, aldosterone and corticosterone have been measured by RIA 30 and 60 min after ET-1 administration. ET-1 (2.0 nmol kg(-1) raised AVP plasma concentration at both 30 and 60 min. ET-1 did not alter the ACTH plasma level at 30 min, but markedly increased it at 60 min. ACTH response was unaffected by the simultaneous administration of AVP-receptor antagonists (AVP-As) Des-Gly-[Phaa1,D-Tyr(Et)2,Lys6,Arg8]-vasopressin or [Deamino-Pen1,Tyr(Me)2,Arg8]-vasopressin (20 nmol kg(-1), but abolished by the corticotropin-releasing hormone (CRH)-receptor antagonist alpha-helical-CRH(9-41) (alpha-CRH, 10 nmol kg(-1). ET-1 evoked significant rises in the blood levels of aldosterone and corticosterone at both 30 and 60 min. AVP-As abrogated the response at 30 min, while alpha-CRH was ineffective. Both AVP-As and alpha-CRH partially reversed adrenocortical secretory response at 60 min. Collectively, these findings confirm that systemically administered ET-1 stimulates rat HPA axis, and provide evidence that the mechanism underlying this effect may involve the sequential activation of AVP and CRH release.