Background.Nicotinamide phosphoribosyltransferase (Nampt/visfatin/PBEF) acts both as an enzyme in the nicotinamide adenine dinucleotide (NAD) synthesis pathway as well as an extracellular hormone (eNampt).Among its effects, eNampt exerts potent pro-inflammatory effects.We have recently shown that, in rats, eNampt stimulates corticosterone secretion by acting through the pituitary rather than the hypothalamus.Objectives.To investigate the mechanism of action of eNampt on the secretion of adrenocorticotropic hormone (ACTH) and chemokine (C-C motif) ligand 2 (CCL2), which are cytokines secreted by pituitary neuroendocrine tumors. Materials and methods.The research was carried out on the AtT-20 murine cell line, primary rat pituitary cell culture, isolated pituitary corticotropes, and in vivo.The effects of the performed experiments were examined using the following methods: gene expression profiling using microarrays, quantitative polymerase chain reaction (qPCR) and enzyme-linked immunosorbent assay (ELISA).Results.The results suggest that eNampt stimulates ACTH secretion from rat corticotropes both directly and indirectly.Indirect action most likely occurs through interleukin (IL)-6 secreted by folliculostellate cells of the pituitary gland.In isolated ACTH cells of the rat pituitary gland, eNampt stimulates the expression of genes involved in the immune response.Among them, the protein encoded by the CCL2 gene seems to also be involved in the regulation of corticotropin-releasing hormone (CRH)-dependent metabolism.Unlike rat corticotropes, murine AtT-20 corticotropic cells do not react to either eNampt or Fk866 (the inhibitor of Nampt enzymatic action).Conclusions.The eNampt stimulates the secretion of ACTH from rat corticotropes indirectly and directly, likely by stimulating IL-6 secretion from folliculostellate cells of the pituitary gland.This effect was not observed in the AtT-20 corticotropic cell cancer cell line.
The effects of a prolonged (30-day) treatment with daily therapeutical doses of cyclosporin A (CAS) (20 mg/kg) on testicular Leydig cells were studied in adult rats. CSA administration provoked a significant decrease in both basal and human chorionic gonadotropin (hCG)-stimulated testosterone concentration in the peripheral blood without affecting the volume of the testes or the interstitial space. However, there was conspicuous atrophy of the Leydig cells, due mainly to a decrease in mitochondria and smooth endoplasmic reticulum, the organelles containing the enzymes of testosterone synthesis. Lipid droplets, in which cholesterol is stored, were notably increased. The nuclear volume and the surface area per cell of rough endoplasmic reticulum fell significantly in Leydig cells of CAS-treated animals. In light of these findings, it is concluded that CSA inhibits the growth and steroidogenic capacity of rat Leydig cells, probably by depressing their protein synthesis. Whether the mechanism underlying the action of CSA on Leydig cells is only indirect, by blockade of hypophyseal gonadotropin release, or also direct is unsettled and requires further investigation.
AbstractLeptin, the product of the oh gene, is a hormone mainly secreted by the adipose tissue, which acts through specific receptors (Ob-R) widely distributed in the body tissues Ob-Rs are present in the mammalian hypothalamo-pituitary-adrenal axis, and evidence indicates that leptin regulates adrenocortical secretion Moreover, leptin is known to act as a growth promoting factor in some tissues, including the endocrine ovary. We have investigated the effects of three subcutaneous injections of 2 nmol/100 g of native murine leptin[1–147] and of its biologically active fragment 116–130 on the secretory and proliferative activity of the regenerating rat adrenal cortex Leptin[1–147] increased plasma aldosterone concentration at day 8 and plasma corticosterone concentration (PBC) at day 5 of regeneration, without affecting mitotic index. In contrast, leptin[116–130] lowered PBC and mitotic index at both times of adrenal regeneration. In light of the fact that adrenal regeneration is at least in part dependent on the pituitary ACTH, we conclude that (i) native leptin moderately stimulates steroid secretion, acting directly on the adrenal cortex, through signaling mechanisms other than those involved in the ACTH action, (ii) native leptin is unable to enhance the proliferative activity of regenerating adrenals, which conceivably is maximally stimulated by ACTH; (iii) leptin[1–147] and leptin[116–130] differently interact with Ob-Rs or interact with different receptors; and (iv) leptin[116–130] inhibits the signaling pathways mediating both the secretagogue effect of native leptin and the proliferogenic effect of ACTH.
Evidence indicates that some regulatory peptides (endothelins, cholecystokinin and VIP) are involved in the control of thymus growth, and we have investigated whether galanin may be included in this group of peptides. In fact, galanin, a 29-amino acid peptide acting through three subtypes of G protein-coupled receptors (GalR1, GalR2 and GalR3), seems to play a role in the control of the immune system. Reverse transcription (RT)-polymerase chain reaction (PCR) allowed the detection of galanin, GalR1 and GalR3 mRNAs in the thymus cortex of immature (20-day-old) rats, while GalR2 expression was very weak or absent. Immature rats were given three subcutaneous injections (28, 16 and 4 h before sacrifice) of 2 nmol/100 g galanin and or the galanin-receptor antagonist (galanin-A) [D-Thr(6),D-Trp(8,9),15-ol]-galanin(1-15), and 0.1 mg/100 g vincristine 3 h before sacrifice. Thymuses were processed for light microscopy and the percentage of metaphase-arrested cells (mitotic index) was evaluated. Galanin-A increased the thymus mitotic index, while galanin was ineffective, thereby suggesting that endogenous galanin exerts a maximal tonic inhibitory effect on the proliferative activity of thymocytes in immature rats. Immature rat thymocytes were cultured in vitro for 12 h in the presence of 10(-6) M galanin and/or galanin-A. Hoechst 33342 and propidium iodide were added to the cultures, and the percentage of apoptotic and necrotic cells was determined under fluorescence microscope. Galanin increased apoptotic index, and the effect was prevented by galanin-A. Neither galanin nor galanin-A altered necrotic index. Collectively, our findings indicate that galanin, probably acting through GalR1 and GalR3, exerts antiproliferative and proapoptotic effects on immature rat thymocytes, which makes it likely that this peptide plays a role in the autocrine/paracrine functional regulation of immune system in the rat.
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.
Adrenomedullin (AM) is a hypotensive peptide, that acts via the calcitonin receptor-like receptor (CRLR), whose interaction with the subtypes 2 and 3 of a family of receptor activity-modifying proteins (RAMP) gives rise to two distinct AM receptors, named AM1 and AM2 receptors. AM derives from the post-translational proteolytic cleavage of pro(p)AM, the last step of which involves the conversion of the inactive AM to active AM by the peptidyl-glycine alpha-amidating monooxigenase (PAM). Compelling evidence suggests that AM, in addition to exerting its well-known regulatory action on blood pressure and water and electrolyte balance, also possesses a growth promoting effect in several normal and neoplastic tissues, including human prostate. Conventional reverse transcription (RT)-polymerase chain reaction (PCR) demonstrated the expression of pAM, PAM, CRLR and RAMP(1-3) mRNAs in both prostate hyperplasias (PH) and carcinomas (PC), and semiquantitative PCR showed that pAM, PAM and RAMP3 mRNA expression was higher in PCs than PHs. Radioimmunoassay measured higher concentrations of immunoreactive AM in PCs than PHs. The expression of pAM, CRLR and RAMP1,2 mRNAs was also detected in the PC-derived cell lines PC-3 and DU-145, RAMP3 expression being restricted to the latter line. AM did not affect the growth rate (duplication time) of PC-3 cells, but it did significantly increase that of DU-145 cells. The growth promoting effect of AM was found to ensue from both the rise in the proliferation rate and the lowering in the apoptosis rate of DU-145 cells. These effects of AM were counteracted by the AM receptor antagonists CGRP(8-37) and AM(22-52), the former antagonist, which is more selective for AM2 than AM1 receptors, being more effective than the latter one. Both antagonists were per se able to induce a slow, but significant decrease in the basal growth rate of DU-145 cells by inhibiting proliferation and enhancing apoptosis, again CGRP(8-37) being more effective than AM(22-52). Taken together, our findings allow us to suggest that: i) endogenous AM system plays an important autocrine-paracrine growth promoting action in the human prostate, being possibly involved in the development of the malignant phenotype of epithelial cells; and ii) the tumor promoting effect of AM in the human prostate is mainly mediated by the AM2 receptor (CRLR/RAMP3) subtype.
11beta-Hydroxysteroid dehydrogenase types 1 and 2 (11betaHSD1 and 11betaHSD2) are two isoenzymes that convert inactive glucocorticoids (e.g., cortisone) to their active forms (e.g., cortisol) and vice versa. Abundant evidence indicates that 11betaHSD2 is expressed as mRNA and protein in both adrenal cortex and adrenal tumors. In contrast, 11betaHSD1 has been investigated to a much lesser degree. We therefore studied and compared the expression and activity of the two isoenzymes in the human adrenal cortex (HAC) and cortisol-secreting adenomas (CSAs).Six HAC and six CSA specimens were studied. 11betaHSD1 and 11betaHSD2 gene expression was studied by conventional and semiquantitative reverse transcription-polymerase chain reaction. 11betaHSD1 and 11betaHSD2 activity was assayed by measuring the capacity of both microsomal fraction and tissue fragments to convert [3H]cortisone to [3H]cortisol and vice versa. Steroid hormones were separated and purified by high-performance liquid chromatography, and cortisol concentration was measured by radioimmunoassay.Semiquantitative reverse transcription-polymerase chain reaction and enzymatic assay demonstrated higher 11betaHSD1 expression and activity and lower 11betaHSD2 expression and activity in CSAs than in HACs. CSA slices secreted larger amounts of cortisol than did HAC specimens, and the cholesterol side-chain-cleaving enzyme inhibitor aminoglutethimide, by blocking the early step of steroid synthesis, reduced cortisol secretion by approximately 70%. Aminoglutethimide decreased [3H]cortisol production from [3H]cortisone and increased [3H]cortisone production from [3H]cortisol in both tissues, thereby annulling differences in 11betaHSD1 and 11betaHSD2 activity between HACs and CSAs.Collectively, our findings indicate that 1) both 11betaHSD isoenzymes are expressed as mRNA and proteins in the HAC and CSA, with 11betaHSD1 upregulated and 1betaHSD2 downregulated in CSAs; and 2) 11betaHSD1 and 11betaHSD2 activity is positively and negatively correlated with the intracellular concentration of steroid hormones. Hence, 11betaHSD isoenzymes could act as amplifiers of the secretagogue effect of agonists and could contribute to the elevated hormonal secretion of CSAs.
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.
