Adrenocortical zonation and the adrenal renin-angiotensin system

Functional Zonation of the Adult Mammalian Adrenal Cortex

The standard model of adrenocortical zonation holds that the three main zones, glomerulosa, fasciculata, and reticularis each have a distinct function, producing mineralocorticoids (in fact just aldosterone), glucocorticoids, and androgens respectively. Moreover, each zone has its specific mechanism of regulation, though ACTH has actions throughout. Finally, the cells of the cortex originate from a stem cell population in the outer cortex or capsule, and migrate centripetally, changing their phenotype as they progress through the zones. Recent progress in understanding the development of the gland and the distribution of steroidogenic enzymes, trophic hormone receptors, and other factors suggests that this model needs refinement. Firstly, proliferation can take place throughout the gland, and although the stem cells are certainly located in the periphery, zonal replenishment can take place within zones. Perhaps more importantly, neither the distribution of enzymes nor receptors suggest that the individual zones are necessarily autonomous in their production of steroid. This is particularly true of the glomerulosa, which does not seem to have the full suite of enzymes required for aldosterone biosynthesis. Nor, in the rat anyway, does it express MC2R to account for the response of aldosterone to ACTH. It is known that in development, recruitment of stem cells is stimulated by signals from within the glomerulosa. Furthermore, throughout the cortex local regulatory factors, including cytokines, catecholamines and the tissue renin-angiotensin system, modify and refine the effects of the systemic trophic factors. In these and other ways it more and more appears that the functions of the gland should be viewed as an integrated whole, greater than the sum of its component parts.

Role of intramitochondrial arachidonic acid and acyl-CoA synthetase 4 in angiotensin II-regulated aldosterone synthesis in NCI-H295R adrenocortical cell line

Although the role of arachidonic acid (AA) in angiotensin II (ANG II)- and potassium-stimulated steroid production in zona glomerulosa cells is well documented, the mechanism responsible for AA release is not fully described. In this study we evaluated the mechanism involved in the release of intramitochondrial AA and its role in the regulation of aldosterone synthesis by ANG II in glomerulosa cells. We show that ANG II and potassium induce the expression of acyl-coenzyme A (CoA) thioesterase 2 and acyl-CoA synthetase 4, two enzymes involved in intramitochondrial AA generation/export system well characterized in other steroidogenic systems. We demonstrate that mitochondrial ATP is required for AA generation/export system, steroid production, and steroidogenic acute regulatory protein induction. We also demonstrate the role of protein tyrosine phosphatases regulating acyl-CoA synthetase 4 and steroidogenic acute regulatory protein induction, and hence ANG II-stimulated aldosterone synthesis.

Angiotensin II regulation of adrenocortical gene transcription

Angiotensin II (Ang II) is the key peptide hormone in the renin-angiotensin-aldosterone system (RAAS). Its ability to regulate levels of circulating aldosterone relies on actions on adrenal glomerulosa cells. Many of the Ang II effects on glomerulosa cells involve a precisely coordinated regulation of signaling cascades and gene expression. The development of genome-wide gene arrays has allowed the definition of transcriptome-wide effects of Ang II in adrenocortical cells. Analysis of the Ang II gene targets reveals broad effects on cellular gene expression, particularly the rapid induction of numerous transcription factors that may regulate long-term steroid metabolism and cell growth/proliferation. Herein we discuss the Ang II-induced genes in adrenocortical cells and review the progress in defining the role of these genes in zona glomerulosa function.

The role of corticosterone in the metabolic recovery after intrasplenic adrenal autotransplantation in rats

Transplantation of adrenal cortical tissue may represent an alternative treatment to reestablish glucocorticoid secretion in adrenal insufficiency. In the present work, performed in adrenalectomized rats and adrenalectomized rats with a complete autotransplanted adrenal into the spleen, several hormones and biochemical parameters were measured and compared to control animals, in order to examine hormone interactions. Rats were sacrificed three weeks after surgery, and plasma and tissue samples were obtained for hormone and biochemical measurements. In adrenalectomized animals, plasma corticosterone, aldosterone and insulin levels were profoundly decreased, whereas in autotransplanted rats plasma corticosterone levels showed a partial recovery, aldosterone plasma concentrations remained low, and plasma insulin levels increased to values close to those of the controls. Both groups showed a marked elevation of plasma ACTH levels, as well as significantly increased plasma glucagon concentrations. In autotransplanted animals, most of the biochemical parameters, which were altered in adrenalectomized rats, returned to normal levels. These results suggest that increased glucagon levels in adrenalectomized and autotransplanted animals, may contribute to the marked increase of plasma ACTH, and could also be important in the recovery of plasma glucose and hepatic glycogen observed in autografted rats. Since high glucagon concentrations alone were unable to normalize carbohydrate levels in adrenalectomized animals, it appears that glucagon can act only in the presence of corticosterone.

Adrenocortical zonation and ACTH

The clear morphological distinction between the cells of the different adrenocortical zones has attracted speculation and experiment to interpret their functions and the ways in which they are regulated. Considerable data have been produced in recent years that has benefited a fuller understanding of the processes of steroidogenesis and of cell proliferation at the molecular level. This now enables the reexamination of earlier concepts. It is evident that there is considerable species variation, and this article, dealing mainly with the rat, reaches conclusions that do not necessarily apply to other mammals. In the rat adrenal, however, the evidence suggests that the greatest differences between the functions of the zones are between the glomerulosa and the fasciculata. Here the sometimes all-or-nothing demarcation in their complement of components associated with steroidogenesis or with cell proliferation suggests a stark division of labor. In this model the fasciculata is the main engine of steroid hormone output and the glomerulosa is the site of cell proliferation, recruitment, and differentiation. Regulating these functions are angiotensin II and other paracrine components that modulate and maintain the glomerulosa, and ACTH, that maintains the fasciculata, and recruits new fasciculata cells by transformation of proliferating glomerulosa cells. Grafted onto this mostly vegetative function of the glomerulosa is CYP11B2, limited to just a fraction of the outer glomerulosa in rats on a normal laboratory diet and generating aldosterone (and 18-hydroxycorticosterone) from precursors whose origin is not, from the evidence summarized here, very clear, but may include the fasciculata, directly or indirectly. The biosynthesis of aldosterone in the rat certainly requires reinterpretation.

Interferon-inducible genes in the rat adrenal gland and vascular smooth muscle cells

Chronic stimulation of the renin-angiotensin system results in increased zona glomerulosa cells and in cells expressing the final enzyme in the synthesis of aldosterone, the cytochrome P-450 aldosterone synthase. The genes activated during adrenal remodeling are not well defined. We have reported that the expression of interferon-inducible genes, 9-27, 1-8D and 1-8U in H295R cells is stimulated by A-II. The 9-27 gene is expressed mainly in leukocytes and is associated with cell proliferation. In this study, we searched for similar genes in a rat zona glomerulosa cDNA library, and examined the regulation of the expression of these genes. We found the Rat8 gene, which has been reported to be similar to human interferon-inducible genes, as well as two similar genes, No. 10 (1096 bp), and No. 16 (630 bp). Rat8 gene and No. 16 were mainly expressed in zona glomerulosa. The product of No. 10 is thought to be a secreted protein, unlike those of 8 and 16, and its expression in the adrenal was weak in comparison. The control of the expression of rat8 or No. 16 genes differs depending on the tissue. Expression in A10 cells (derived from rat embryo thoracic aorta) was not stimulated by A-II, nor was it influenced by salt intake in the adrenal gland, but it was reduced in vascular smooth muscle cells (VSMC) of rats on a low sodium diet. These results show that genes similar to the human 1-8 gene family are expressed in rat adrenal glomerulosa cells and VSMC, but their expression is not regulated by A-II. The function of these genes in VSMC and adrenal is unknown.

Angiotensin stimulates the expression of interferon-inducible genes in H295R cells

Angiotensin-II (A-II) induces proliferation of zona glomerulosa cells and stimulates expression of cytochrome P-450 aldosterone synthase. The genes activated during this adrenal remodeling are not well defined. To clarify this mechanism, we sought to identify the genes whose expression is stimulated by A-II in the H295R cell line. Using a subtractive hybridization technique, we identified one clone whose expression was stimulated by A-II. The sequence of this gene was homologous to the human interferon-inducible genes, 9-27, 1-8D and 1-8U. The 5' portion of the gene was identical to the 1-8D gene product and the 3' was identical to the 9-27 gene product, but the existence of a transcript was not demonstrated by RT-PCR. The expression of these three genes was stimulated by A-II, with the 9-27 gene being most abundant. Potassium and forskolin also stimulated the expression of the 9-27 gene in the H295R cells, but not as effectively as did A-II or interferon-gamma.

Differentiated corticosteroid production and regeneration after selective transplantation of cultured and noncultured adrenocortical cells in the adrenalectomized rat

Syngeneic transplantation of adrenocytes was investigated in Lewis rats in regard to differentiated hormone secretion and cortex regeneration after bilateral adrenalectomy as an alternative to steroid substitution.

METHODS

Purified cell suspensions of glomerulosa (density 1.061 +/- 0.001 g/ml) and fasciculata (density 1.034 +/- 0.003 g/ml) cells were obtained by density gradient separation and were transplanted under the kidney capsule either immediately or after a 29-day culture period. Animals were killed after transplantation of cultured glomerulosa (CG-Tx) or cultured fasciculata cells (CF-Tx), noncultured glomerulosa cells (G-Tx) or non-cultured fasciculata cells (F-Tx), or both cell types (GF-Tx) for morphological studies after 30, 120, and 360 days. Plasma samples were drawn for measurement of corticosterone and aldosterone as well as 24 hr-urine for sodium and potassium levels at day 3, 30, 120, and 360 after transplantation.

RESULTS

In primary culture fasciculata cell number remained stationary although glomerulosa cell number increased to almost 10-fold. Vital cortex cells were demonstrated in each explanted graft by histochemistry but only group G-Tx, CG-Tx, and GF-Tx (purified cell suspensions of zona glomerulosa and fasciculata) showed neocortex-like structures. We found plasma (urine) corticosterone to decrease from preoperatively 256-304 ng/ml (226-239 ng/day) in untreated animals to levels about half as high 3 days after transplantation, increasing to normal values in all study groups 30 days after treatment (data given as range). Plasma aldosterone concentrations, 150-180 pg/ml in untreated rats, decreased to nondetectable levels for 1 week after bilateral adrenalectomy. At day 30 group GF-Tx, G-Tx, and CG-Tx showed comparable aldosterone plasma concentrations (104-122 pg/ml); however, levels in F-Tx and CF-Tx were 19-49 pg/ml, and did not increase significantly within the observation period.

CONCLUSIONS

Cells derived from the zona glomerulosa maintain viability, produce both aldosterone and corticosterone, and regenerate a neocortex with cells that histologically resemble both zona glomerulosa and fasciculata cells. They are therefore suitable for adrenocortical transplantation. In contrast, cells derived from the zona fasciculata maintain viability, but do not regenerate zona glomerulosa and do not produce aldosterone. These results suggest that the cell migration model, in which zona glomerulosa cells can acquire the phenotype of zona fasciculata cells as they can migrate centripetally, is more likely the correct explanation of adrenocortical zonation.

Remodeling of turkey adrenal steroidogenic tissue induced by dietary protein restriction: the potential role of cell death

The present study focused on the cellular remodeling of steroidogenic tissue in the domestic turkey (Meleagris gallopavo) adrenal gland in response to dietary protein restriction stress. Immature male turkeys (1 week old) were fed isocaloric synthetic diets containing either 28% (control) or 8% (restriction) soy protein for 4 weeks. Adrenal glands were processed for the isolation of density- separable, visibly distinct adrenal steroidogenic cell subpopulations: three low-density subpopulations [LDAC-1 (rho = 1. 0350-1.0490 g/ml), LDAC-2 (rho = 1.0490-1.0570 g/ml), and LDAC-3 (rho = 1.0570-1.0585 g/ml)] and one high-density subpopulation [HDAC (rho = 1.0590-1.0720 g/ml)]. Dietary protein restriction increased the proportion of LDAC-3 and HDAC by 98 and 350%, respectively, and decreased LDAC-2 by 46%. LDAC-1 also showed signs of proportional decrement. To determine the role of cell death in this process, the potential for apoptosis was assessed in adrenal tissue and isolated adrenal steroidogenic cells using short-term culture followed by analysis of oligonucleosome formation. Basal, culture-triggered oligonucleosome formation of tissue and cells derived from protein-restricted birds was 80% greater than that of tissue and cells derived from control birds. This differential in apoptotic potential persisted with a variety of treatments, in vitro. Apoptotic potential was suppressed by human adrenocorticotropin and enhanced by angiotensin II (Ang II). The proapoptotic effect of Ang II (100 nM) with adrenal fragments was inhibited by the Ang II receptor antagonist [Sar(1), Ile(8)]ang II (10 microM) to below basal values (by about 60%), but the inhibition was surmountable by high concentrations (10 and 100 microM) of Ang II. The antagonist also attenuated basal, culture-triggered DNA fragmentation of tissue and cells, suggesting that at least part of the basal DNA fragmentation was due to intrinsically generated Ang II. Differences in apoptotic potential were also apparent with cell subpopulations. Compared to control subpopulations, protein restriction enhanced basal oligonucleosome formation in LDAC-1 and -2 by 38 and 122%, respectively, and reduced it in LDAC-3 and HDAC by 53 and 70%, respectively. These data suggest a role for apoptotic cell death in the remodeling of turkey adrenal steroidogenic tissue induced by dietary protein restriction. In addition, other data suggest that Ang II is an important regulator of adrenal steroidogenic cell turnover in the avian adrenal gland.