Regulation of Proliferative Processes in Rat Adrenal Cortex by Transcriptional Factor PRH under Conditions of Developmental Exposure to Endocrine Disruptor DDT.

The effects of endocrine disrupters of transcriptional control of morphogenesis are poorly studied. Changes in the expression of transcriptional factor PRH and proliferation of adrenal cortical cells were analyzed in pubertal and postpubertal rats exposed prenatally and postnatally to low doses of endocrine disrupter DDT. In rats exposed to DDT, the expression of PRH and proliferation of adrenal cortical cells differed from those in control rats. Association between these parameters was weakened in the zona glomerulosa and zona reticularis and was absent in the zona fasciculata. These findings suggest that exposure to DDT in pre- and postnatal periods impairs the regulation of proliferative processes by transcriptional factor PRH in all zones of rat adrenal cortex, which can be a mechanism of the disruptive action of DDT.

Changes in Canonical ß-Catenin/Wnt Signaling Activation in the Adrenal Cortex of Rats Exposed to Endocrine Disruptor Dichlorodiphenyltrichloroethane (DDT) during Prenatal and Postnatal Ontogeny.

Prenatal and postnatal exposure to low doses of the endocrine disruptor dichlorodiphenyltrichloroethane (DDT) leads to delayed activation of the canonical ß-catenin/Wnt signaling in zona glomerulosa and zona reticularis of the adrenal cortex in rats, which changed the rate of their postnatal development. Suppression of the Wnt pathway in zona fasciculata promotes its regeneration after DDT-induced blood circulation disorders and cell death.

Adrenal cortex development and related disorders leading to adrenal insufficiency.

The adult human adrenal cortex produces steroid hormones that are crucial for life, supporting immune response, glucose homeostasis, salt balance and sexual maturation. It consists of three histologically distinct and functionally specialized zones. The fetal adrenal forms from mesodermal material and produces predominantly adrenal C19 steroids from its fetal zone, which involutes after birth. Transition to the adult cortex occurs immediately after birth for the formation of the zona glomerulosa and fasciculata for aldosterone and cortisol production and continues through infancy until the zona reticularis for adrenal androgen production is formed with adrenarche. The development of this indispensable organ is complex and not fully understood. This article gives an overview of recent knowledge gained of adrenal biology from two perspectives: one, from basic science studying adrenal development, zonation and homeostasis; and two, from adrenal disorders identified in persons manifesting with various isolated or syndromic forms of primary adrenal insufficiency.

ß-Catenin and FGFR2 regulate postnatal rosette-based adrenocortical morphogenesis.

Rosettes are widely used in epithelial morphogenesis during embryonic development and organogenesis. However, their role in postnatal development and adult tissue maintenance remains largely unknown. Here, we show zona glomerulosa cells in the adult adrenal cortex organize into rosettes through adherens junction-mediated constriction, and that rosette formation underlies the maturation of adrenal glomerular structure postnatally. Using genetic mouse models, we show loss of ß-catenin results in disrupted adherens junctions, reduced rosette number, and dysmorphic glomeruli, whereas ß-catenin stabilization leads to increased adherens junction abundance, more rosettes, and glomerular expansion. Furthermore, we uncover numerous known regulators of epithelial morphogenesis enriched in ß-catenin-stabilized adrenals. Among these genes, we show Fgfr2 is required for adrenal rosette formation by regulating adherens junction abundance and aggregation. Together, our data provide an example of rosette-mediated postnatal tissue morphogenesis and a framework for studying the role of rosettes in adult zona glomerulosa tissue maintenance and function.

Development of adrenal cortex zonation.

The human adult adrenal cortex is composed of the zona glomerulosa (zG), zona fasciculata (zF), and zona reticularis (zR), which are responsible for production of mineralocorticoids, glucocorticoids, and adrenal androgens, respectively. The final completion of cortical zonation in humans does not occur until puberty with the establishment of the zR and its production of adrenal androgens; a process called adrenarche. The maintenance of the adrenal cortex involves the centripetal displacement and differentiation of peripheral Sonic hedgehog-positive progenitors cells into zG cells that later transition to zF cells and subsequently zR cells.

Development of functional zonation in the rat adrenal cortex.

In an attempt to elucidate the mechanism(s) through which the functional adrenal cortex is established, we analyzed immunohistochemically the expression of various markers for the adrenocortical zones, i.e. the zona glomerulosa (zG), the zona fasciculata (zF), and the zona reticularis (zR), as well as markers for the medulla, and further examined the distribution and behavior of DNA-synthesizing cells in rat adrenal glands during development. The results showed that 1) separation of the cortex and medulla, and the development of functional zonation in the cortex began at around the time of birth, 2) at fetal stages when cortical zonation was not established, DNA-synthesizing cells were found scattered throughout the gland, where they proliferated without significant migration, and 3) after birth in the adrenal cortex with established cortical zonation, DNA-synthesizing cells were localized near the undifferentiated zone between zG and zF, and then they migrated centripetally. Cell death appeared to occur in the innermost portion of the cortex, where many resident macrophages are present. These findings illustrate basic processes underlying adrenal development and suggest that the undifferentiated region is apparently the stem cell zone of the adrenal cortex that maintains the cortical zonation.

The development of the adrenal gland zona glomerulosa in the rat. A morphological, immunohistochemical and biochemical study.

We have studied the development of the adrenal gland in the rat comprising the ages ranging from 0 to 90 days after birth. The weight of the animals and that of the adrenal glands demonstrated a linear growth with time until 75 days, both in males and females. The area of the zona glomerulosa (ZG) increased in size from birth until approximately 40 days of age. After that, growth had a much smaller slope (females, r=0.84, P < 0.001; males, r=0.81, P < 0.001). Aldosterone secretion had a marked increase until 20 days of age and thereafter demonstrated a tendency for a decrease (females, r=-0.19, P < 0.02: males r=-0.26, P < 0.001). Plasma renin activity followed a trend parallel to that of aldosterone. The steroid precursor 18-OH-deoxycorticosterone (18-OH-DOC) demonstrated a different course as it increased progressively with age especially in the females (females, r=0.57, P < 0.001; males, r=0.40, P <0.001). The expression of the enzyme 3-beta-hydroxysteroid dehydrogenase (3-beta-HSD) was also studied by immunohistochemistry and it was shown to be very low at birth and starting to increase by 10 days of age. After 30/40 days of age the amount of this enzyme existing in the ZG was comparable with that of the outer zona fasciculata (ZF). We conclude that the development of the ZG in the rat has particularities that make it different from that of the rest of the cortex.

In-vitro and in-vivo studies of the effects of arginine-vasopressin on the secretion and growth of rat adrenal cortex.

Arginine-vasopressin (AVP) markedly increased basal aldosterone (ALDO) secretion by dispersed zona-glomerulosa (ZG) cells, and its effect was selectively reversed by V1-receptor antagonists (AVP-A1). Corticosterone (B) production by dispersed zona fasciculata (ZF) cells was not affected. The bolus intraperitoneal (i.p.) administration of AVP acutely raised the plasma concentrations of both ALDO and B in normal rats, but only that of ALDO in bilaterally adrenalectomized animals bearing regenerated adrenocortical autotransplants, which are deprived of medullary chromaffin cells. Accordingly, AVP raised ALDO and B secretions by adrenal slices (including both cortical and medullary tissues), and only ALDO production by autotransplant quarters. The B response of adrenal slices to AVP was blocked by alpha-helical-CRH and corticotropin-inhibiting peptide (two competitive inhibitors of CRH and ACTH, respectively), but not by 1-alprenolol (a beta-adrenoreceptor antagonist); ALDO response was not affected by any of these antagonists. A 7-day i.p. infusion with AVP increased the volume of ZG cells and ZG-like cells of autotransplants, as well as their basal and maximally angiotensin-II-stimulated ALDO secretory capacity; it also raised the volume, and basal and maximally ACTH-stimulated B secretory capacity of ZF cells, but it did not affect ZF-like cells of autotransplants. The simultaneous administration of AVP-A1 annulled all these effects of AVP. When infused alone, AVP-A1 caused a marked atrophy of ZG cells, coupled with a net drop in their steroidogenic capacity; however, AVP-A1 infusion did not change the morphology and function of either ZF cells or ZG-like and ZF-like cells of autotransplants. Taken together,, our findings allow us to draw the following conclusions: (i) AVP plays an important physiological role in the maintenance and stimulation of ZG growth and mineralocorticoid secretory activity in rats, the source of endogenous AVP exerting adrenoglomerulotropic action probably being adrenal chromaffin cells; and (ii) AVP indirectly stimulates the growth and glucocorticoid secretory activity of rat ZF cells, by activating intramedullary CRH/ACTH system; however, the physiological relevance of this effect of AVP appears to be doubtful.

Effects of prolonged cysteamine administration on the rat adrenal cortex: evidence that endogenous somatostatin is involved in the control of the growth and steroidogenic capacity of zona glomerulosa.

A week daily administration of cysteamine (CYS, 300 mg kg-1) lowered plasma aldosterone concentration in rats, without affecting PRA, kalaemia and the plasma levels of ACTH and corticosterone. Prolonged CYS treatment caused a notable hypertrophy of adrenal zona glomerulosa (ZG) and its parenchymal cells, without inducing any apparent change in zona fasciculata morphology. Isolated ZG cells from CYS-treated rats evidenced a notable enhancement in their basal and maximally-stimulated productions of aldosterone and corticosterone. All these effects of chronic CYS administration were completely reversed by the simultaneous infusion of rats with somatostatin (SRIF, 12 micrograms kg-1 h-1). CYS exposure was not found to directly affect the secretory activity of isolated ZG cells from normal rats. Since CYS is known to be a specific depletor of SRIF in different organs of rats, these findings suggest that endogenous SRIF may be involved in the modulation of ZG function.

Role of the endogenous adrenomedullin system in regulating the secretion and growth of rat adrenal cortex.

The expression of components of the adrenomedullin (AM) system (AM and its receptors) has been detected in mammalian adrenal zona glomerulosa (ZG) cells, and evidence has been provided that AM is able to inhibit agonist-stimulated aldosterone secretion from and to enhance the proliferative activity of ZG cells. However, there has been no evidence that the endogenous AM system acts as a physiological regulator of ZG function. Hence, we investigated whether the suppression of AM gene transcription by a specific antisense oligodeoxynucleotide (ODN) is able to alter the secretion and growth of rat ZG cells cultured in vitro. ZG cell cultures were examined 0, 2, 4, 6 and 8 days after treatment with scrambled sense (S)-ODN (control cultures) and AM antisense (A)-ODN. Control cultures, as well as freshly dispersed ZG cells and ODN-untreated cultures, expressed AM as mRNA and protein. A-ODN treatment suppressed AM expression within 4 days and the suppression lasted until day 6. Confluent control cultures displayed basal and angiotensin-II (Ang-II), K(+)- and adrenocorticotropic hormone (ACTH)-stimulated aldosterone secretions similar to those of ODN-untreated cultures. A-ODN treatment magnified the aldosterone response to Ang-II and K+ at days 4 and 6 (but not at day 8), without affecting the basal or ACTH-stimulated secretion. As compared to ODN-untreated and control cultures, non-confluent A-ODN-treated ones showed a 40% elongation in the duplication time, a significant decrease in the proliferation index, and a marked rise in apoptotic index from day 4 to day 8. In conclusion, our study validates the use of A-ODN to block the endogenous AM system, showing that suppression of AM-synthesis requires at least 2 days to become appreciable and persists for at least 6 days. Moreover, it provides the first evidence that endogenous AM plays a physiological role in cultured rat ZG cells, by exerting a buffering action on their acute secretory response to Ang-II and K+ and by maintaining normal basal proliferative and apoptotic activities.

Ghrelin enhances the growth of cultured human adrenal zona glomerulosa cells by exerting MAPK-mediated proliferogenic and antiapoptotic effects.

Ghrelin is an endogenous ligand of the growth hormone secretagogue receptor (GHS-R), two subtypes of which have been identified and named GHS-R1a and GHS-R1b. Evidence has been provided that ghrelin and its receptors are expressed in the adrenal gland, and we have investigated the possible role of the ghrelin system in the functional regulation of the human adrenal cortex. Reverse transcription-polymerase chain reaction detected the expression of both subtypes of GHS-Rs exclusively in the zona glomerulosa (ZG). Ghrelin did not significantly affect either basal or agonist-stimulated aldosterone secretion from cultured ZG cells. In contrast, ghrelin raised proliferative activity and decreased apoptotic deletion rate of ZG cells, the maximal effective concentration being 10(-8) M. The growth effects of 10(-8) M ghrelin on cultured ZG cells were not affected by either the protein kinase (PK)A and PKC antagonists H-89 and calphostin-C or the mitogen-activated PK (MAPK) p38 antagonist SB-293580, but were abolished by both the tyrosine kinase (TK) and MAPK p42/p44 antagonists tyrphostin-23 (10(-5) M) and PD-98059 (10(-4) M), respectively. Ghrelin (10(-8) M) enhanced TK and MAPK p42/p44 activities of ZG cells. Preincubation with 10(-5) M tyrphostin-23 blocked the ghrelin-induced stimulation of both TK and MAPK p42/p44, while preincubation with 10(-4) M PD-98059 only annulled MAPK p42/p44 stimulation. Collectively, our findings allow us to conclude that ghrelin, acting via GHS-Rs exclusively located in the ZG, enhances the growth of human adrenal cortex, through a mechanism involving the activation of the TK-dependent MAPK p42/p44 cascade.

Further investigations on the effects of neuropeptide Y on the secretion and growth of rat adrenal zona glomerulosa.

NPY is a regulatory peptide, high levels of which are contained in adrenal glands of several mammals and which is co-released with catecholamines during various stressful conditions. The acute and chronic effects of NPY on adrenocortical secretion and growth were studied in the rat. NPY concentration-dependently increased aldosterone (ALDO), but not corticosterone (B) secretion of adrenal slices (maximal effective concentration was 10(-7) M). Two competitive inhibitors of NPY receptors, named PYX-1 and PYX-2, were found to dose-dependently inhibit ALDO response of adrenal preparations to 10(-7) M NPY; PYX-2 was more efficient than PYX-1, and at a concentration of 10(-5) M completely annulled the effect of 10(-7) M NPY. The acute bolus intraperitoneal (i.p.) injection of NPY (3 nmol/kg) raised plasma ALDO concentration (PAC), but not that of B (PBC); this effect of NPY was blocked by the simultaneous injection of PYX-2 (300 nmol/kg). The prolonged i.p. infusion with NPY (3 nmol/kg/h for 7 days) increased PAC (but not PBC) and induced a marked hypertrophy of the zona glomerulosa (ZG) and its parenchymal cells; dispersed ZG cells obtained from NPY-infused rats displayed a significantly enhanced basal and maximally agonist-stimulated ALDO production. The simultaneous infusion with PYX-2 (300 nmol/kg/h) completely annulled all these effects of NPY. The acute or chronic administration of PYX-2 alone did not evoke any apparent effect on the ZG secretion and growth. In light of these findings the following conclusions can be drawn: (i) NPY is able to stimulate not only the secretion, but also the growth of adrenal ZG in rats, via a receptor-mediated mechanism (since this effect is blocked by PYX-2); (ii) endogenous NPY does not play a prominent role in the physiological maintenance of secretion and growth of rat ZG (since PYX-2 alone is ineffective); (iii) NPY may play a crucial role in the fine tuning of the ZG functions in conditions requiring an increased release of mineralocorticoid hormones.

Neurotensin stimulates the growth and secretion of rat adrenal zona glomerulosa.

Within 2 days neurotensin (NT) and ACTH administrations markedly enhanced the average volume of zona glomerulosa (ZG) cells and plasma aldosterone concentration (PAC) in intact rats. In dexamethasone-treated rats, both NT and ACTH evoked a clearcut ZG-cell hypertrophy, but only NT was able to raise PAC. In conclusion, our findings indicate that NT is a potent stimulator of the growth and secretion of rat ZG in vivo, and suggest that the mechanism underlying this action of NT does not involve the well-known NT-induced stimulation of ACTH release.

Development of adrenal cortical zonation and expression of key elements of adrenal androgen production in the chimpanzee (Pan troglodytes) from birth to adulthood.

The basis for the pattern of adrenal androgen production in the chimpanzee, which resembles that of humans, is poorly defined. We characterized the developmental zonation and expression of elements of the androgen biosynthetic pathway in the chimpanzee adrenal. The newborn adrenal contained a broad fetal zone (FZ) expressing CYP17, SULT2A1, and Cytochrome B5 (CB5) but not HSD3B; the outer cortex expressed HSD3B but not SULT2A1 or CB5. During infancy, the FZ involuted and the HSD3B-expressing outer cortex broadened. By 3years of age, a thin layer of cells that expressed CB5, SULT2A1, and CYP17 adjoined the medulla and likely represented the zona reticularis; the outer cortex consisted of distinct zonae fasiculata and glomerulosa. Thereafter, the zona reticularis broadened as also occurs in the human. The adult chimpanzee adrenal displayed other human-like characteristics: intramedullary clusters of reticularis-like cells and also a cortical cuff of zona fasiculata-like cells adjoining the central vein.

Adrenocortical zonation results from lineage conversion of differentiated zona glomerulosa cells.

Lineage conversion of differentiated cells in response to hormonal feedback has yet to be described. To investigate this, we studied the adrenal cortex, which is composed of functionally distinct concentric layers that develop postnatally, the outer zona glomerulosa (zG) and the inner zona fasciculata (zF). These layers have separate functions, are continuously renewed in response to physiological demands, and are regulated by discrete hormonal feedback loops. Their cellular origin, lineage relationship, and renewal mechanism, however, remain poorly understood. Cell-fate mapping and gene-deletion studies using zG-specific Cre expression demonstrate that differentiated zG cells undergo lineage conversion into zF cells. In addition, zG maintenance is dependent on the master transcriptional regulator Steroidogenic Factor 1 (SF-1), and zG-specific Sf-1 deletion prevents lineage conversion. These findings demonstrate that adrenocortical zonation and regeneration result from lineage conversion and may provide a paradigm for homeostatic cellular renewal in other tissues.

Sonic hedgehog signaling during adrenal development.

It has been speculated for a number of years that Sonic hedgehog (Shh) signaling plays an important role in adrenal development. Over the past two years several reports have described the expression and function of Shh pathway genes in the adrenal cortex, using primarily mouse models. The key findings are that Shh signals produced by a population of partially differentiated cortical cells located in the outer cortex/zona glomerulosa are received by non-cortical mesenchymal cells located predominantly in the overlying capsule. This signal is required for growth of both the capsule and the cortex, but not for cortical zonation or steroidogenic cell differentiation. Using molecular genetic tools to define the adrenocortical cell lineages that are descended from both Shh signaling and receiving cells, both capsule and cortical cells were found to have properties of adrenocortical stem and/or progenitor cells. Here we place these observations within the context of prior studies on adrenal development, postnatal adrenal maintenance and adrenocortical stem/progenitor cell lineages.

Effects of intrauterine malnutrition on the renal morphology of Wistar rats: a systematic review

Introduction: Many epidemiological studies suggest that the intrauterine environment is extremely importantto the determination of the individual’s future health. Alterations in the maternal nutritional state, reflectedon the weight on birth, may program the litter for the development of diseases on the adult age. Studies withanimals exposed to intrauterine malnutrition have suggested a reduction in the number of glomeruli, as wellas arterial pressure increase. To review in the literature the alterations of the renal physiology of adult Wistarrats exposed to malnourishment during intrauterine life. Material and methods: A search was performedin the following databases: SciELO, MEDLINE, PUBMED, SCIENCE DIRECT and LILACS. The mainsearch terms were “malnutrition” and “renal function” both in Portuguese and in English. Were includedoriginal articles involving albino rats. Were excluded the review articles as well as those involving humanbeings. Results: According to Franco et al. (2009) the renal function and the number of glomeruli werereduced by the intrauterine malnutrition, predisposing the adult animals to renal diseases. For Chen and Chou(2009) the glomerular ultrastructure is not affected by maternal undernutrition, suggesting that this factordoes not contribute to the hypertension pathogenesis after maternal malnutrition. Conclusion: Intrauterinemalnourishment seems to interfere in the renal functions programming with alterations to the glomerulimorphology, but its mechanisms are yet uncertain. More randomized studies and clinical essays are suggestedin order to comprehend the factors that cause such process.

Zone-specific cell proliferation during compensatory adrenal growth in rats.

Compensatory adrenal growth after unilateral adrenalectomy (ULA) leads to adrenocortical hyperplasia. Because zonal growth contributions are not clear, we characterized the phenotype of cortical cells that proliferate using immunofluorescence histochemistry and zone-specific cell counting. Rats underwent ULA, sham adrenalectomy (sham), or no surgery and were killed at 2 or 5 days. Adrenals were weighed and sections immunostained for Ki67 (proliferation), cytochrome P-450 aldosterone synthase (P450aldo, glomerulosa), and cytochrome P-450 11beta-hydroxylase (P45011beta, fasciculata). Unbiased stereology was used to count proliferating glomerulosa and fasciculata cells. Adrenal weight increased after ULA compared with sham and no surgery at both time points, and there was no difference between sham and no surgery. However, either ULA or sham increased Ki67-positive cells in the outer fasciculata at both time points compared with no surgery. Outer fasciculata-restricted proliferation is thus associated with adrenal weight gain in ULA but not sham. Experiment repetition using proliferating cell nuclear antigen and bromodeoxyuridine showed similar results. After ULA, adrenal DNA, RNA, and protein increased at both time points, whereas after sham, only adrenal DNA increased at 2 days. Compensatory growth thus results from hyperplasia and hypertrophy, whereas sham induces only a transient adrenal hyperplasia. Dexamethasone pretreatment prevented the increase in adrenal weight after ULA and blocked Ki67 labeling in the outer fasciculata but not zona glomerulosa in all groups. These results clearly show that the outer fasciculata is the primary adrenal zone responsible for compensatory growth, responding to steroid-suppressible stress signals that alone are ineffective in increasing adrenal mass.

Morphologic development of the adrenal cortex in squirrel monkeys (Saimiri sciureus).

This study describes the morphology of the squirrel monkey (Saimiri sciureus) adrenal gland in the perinatal period. Adrenals of fetal monkeys had a broad central zone of large eosinophilic cells (fetal zone) surrounded by a subcapsular band of small dark cells (definitive zone). Adrenals of stillborn and neonatal monkeys had a reduced fetal zone and an expanded definitive zone that was differentiated into distinct zona fasciculata and zona glomerulosa. By day 18 postpartum, no remnant of the fetal zone remained.

Morphological changes of the adrenal gland following soft-laser irradiation of the pineal gland.

We present the results obtained in the adrenal gland of white rats (average weight 220 g) following irradiation of the pineal gland with laser light. Irradiation was carried out with a 5 mW Politec 750 Helium-Neon laser. Total irradiation time was 5 min, with rest intervals of 1 min for every minute of irradiation. Pineal gland irradiation was done under "open sky", i.e., directly at the gland. The effects of the suprarenal gland were studied 3, 7 and 10 d postirradiation. Morphological signs of an increasing activity have been observed in all layers of the cortex and in the medulla of the gland. The highest increase was found 7 d after irradiation in the fascicular zone and in the medulla, and after 3 d in the glomerular and reticular zone. We suggest that laser light induces an inhibitory effect observed at the suprarenal gland. This effect is similar to that found following pinealectomy, showing once again that the pineal gland exerts control on the suprarenal gland, mediated by luminous stimuli.