Age-dependent expression of glucocorticoid- and mineralocorticoid receptors on neural precursor cell populations in the adult murine hippocampus

Steroid hormones are regulators of adult hippocampal neurogenesis and are central to hypotheses regarding adult neurogenesis in age-related and psychiatric disturbances associated with altered hippocampal plasticity--most notably dementias and major depression. Using immunohistochemistry, we examined the expression of glucocorticoid (GR) and mineralocorticoid (MR) receptors during adult hippocampal neurogenesis. In young mice only 27% of dividing cells in the subgranular zone expressed GR, whereas 4 weeks after division 87% had become positive for GR and MR. GR was expressed by 50% of the radial glia-like type-1 and type-2a progenitor cells, whereas MR was expressed only by mature calbindin-positive granule cells. Doublecortin-positive neuronal progenitor cells (type-2b) and early postmitotic calretinin-positive neurons were devoid of GR and MR expression. Fifty per cent of the intermediate type-3 cells showed GR expression, possibly reflecting cells terminating maturation. Thus, all subpopulations of dividing precursor cells showed an identical receptor profile (50% GR, no MR), except for type-2b cells, which expressed neither receptor. There was also no overlap between calretinin and GR early postnatally (P8) or after physical activity or exposure to an enriched environment, both of which are potent neurogenic stimuli. In contrast, in old age calretinin-positive young neurons became GR and MR positive, suggesting increased steroid sensitivity. Age also increased the expression of GR in type-1 and type-2a precursor cells. Other intermediates were so rare in old age that they could not be studied. This course and variability of receptor expression in aging might help to explain differential vulnerability of adult neural precursor cells to corticoid-mediated influences.     

Brain mineralocorticoid receptors in cognition and cardiovascular homeostasis

Mineralocorticoid receptors (MR) mediate diverse functions supporting osmotic and hemodynamic homeostasis, response to injury and inflammation, and neuronal changes required for learning and memory. Inappropriate MR activation in kidneys, heart, vessels, and brain hemodynamic control centers results in cardiovascular and renal pathology and hypertension. MR binds aldosterone, cortisol and corticosterone with similar affinity, while the glucocorticoid receptor (GR) has less affinity for cortisol and corticosterone. As glucocorticoids are more abundant than aldosterone, aldosterone activates MR in cells co-expressing enzymes with 11β-hydroxydehydrogenase activity to inactivate them. MR and GR co-expressed in the same cell interact at the molecular and functional level and these functions may be complementary or opposing depending on the cell type. Thus the balance between MR and GR expression and activation is crucial for normal function. Where 11β-hydroxydehydrogenase 2 (11β-HSD2) that inactivates cortisol and corticosterone in aldosterone target cells of the kidney and nucleus tractus solitarius (NTS) is not expressed, as in most neurons, MR are activated at basal glucocorticoid concentrations, GR at stress concentrations. An exception may be pre-autonomic neurons of the PVN which express MR and 11β-HSD1 in the absence of hexose-6-phosphate dehydrogenase required to generate the requisite cofactor for reductase activity, thus it acts as a dehydrogenase. MR antagonists, valuable adjuncts to the treatment of cardiovascular disease, also inhibit MR in the brain that are crucial for memory formation and exacerbate detrimental effects of excessive GR activation on cognition and mood. 11β-HSD1 inhibitors combat metabolic and cognitive diseases related to glucocorticoid excess, but may exacerbate MR action where 11β-HSD1 acts as a dehydrogenase, while non-selective 11β-HSD1&2 inhibitors cause injurious disruption of MR hemodynamic control. MR functions in the brain are multifaceted and optimal MR:GR activity is crucial. Therefore selectively targeting down-stream effectors of MR specific actions may be a better therapeutic goal.     

Corticosteroids and the brain

Mineralocorticoid (MR) and glucocorticoid receptors (GR) are expressed in the central nervous system. Radioligand binding studies, autoradiography, immunocytochemistry and in situ hybridization have shown that MR and GR are found in abundance in neurons of the limbic system (hippocampus), a structure involved in mood, affect and subtle control of the hypothalamic-pituitary-adrenal (HPA) axis. In the hippocampus MR binds corticosterone (CORT) as well as aldosterone (ALDO) with high affinity. MR seems mainly occupied by CORT in the face of its 2-3 order higher circulating concentration. GR binds CORT with a 6-10-fold lower affinity. MR and GR gene expression, as well as the native receptor proteins, seem to be controlled in a coordinative manner. When GR is down-regulated by excess homologous steroid, MR appears to be increased. Down regulation of MR reduces GR as well. MR and GR display a differential ontogenetic pattern. Ontogeny, particularly that of GR, can be permanently influenced when animals are exposed during the first post-natal week of maternal deprivation, handling, CORT or ACTH1-24 injections. These MR and GR changes persist into senescence and have been proposed to result in altered CORT responsiveness, stress regulation, behavioural adaptation and brain aging.     

Corticosteroid receptor mRNA expression in the brains of patients with epilepsy

The effects of corticosteroids in the brain are mediated through the glucocorticoid receptor (GR) and the mineralocorticoid receptor (MR). We used a sensitive competitive RT-PCR assay to quantify the amounts of GR and MR mRNA in human brain tissue specimens from patients with focal epilepsies. GR and MR mRNAs were expressed at approximately the same levels in the temporal lobe, frontal lobe, and hippocampus as compared to tissues with high glucocorticoid/mineralocorticoid receptor expression (liver/kidney). GR and MR mRNA concentrations in the temporal lobe increased markedly during childhood and reached adult levels at puberty. GR and MR mRNA expression was significantly higher in the temporal lobe and frontal lobe cortex of women than in those of men. In women, MR and GR mRNA concentrations were markedly lower in hippocampal tissue than in frontal and temporal lobe cortex tissue. In conclusion, our data demonstrate sex- and site-dependent expression of corticosteroid receptor mRNA in the human brain.     

The neuronal mineralocorticoid receptor as a mediator of glucocorticoid response

The cloning of the mineralocorticoid receptor (MR) and the glucocorticoid receptor (GR) cDNAs provides a basis for understanding the actions of glucocorticoids in the central nervous system. Structural evidence is presented for the identity of the type I corticosteroid binding site as the MR expressed in the brain. This identification is supported by the anatomical distribution of MR mRNA, determined by in situ hybridization histochemistry, which parallels the steroid autoradiographic localization of the type I sites. An in vitro assay for MR and GR function demonstrates that these receptors respond to different levels of glucocorticoid, suggesting that together they confer a larger dynamic range of sensitivity to this hormone. These studies lead to a new hypothesis for glucocorticoid action in the central nervous system.     

Differential regulation of mouse mammary tumor virus-bacterial chloramphenicol acetyltransferase chimeric gene by human mineralocorticoid hormone-receptor complexes.

The brain tissues of the rat and mouse express two types of corticosteroid binding proteins, the glucocorticoid (GR) and aldosterone (MR) receptors. Unlike the type II (GR) receptor, type I receptor has a high affinity for aldosterone (ALDO) and corticosterone and is structurally similar to the kidney mineralocorticoid receptor (MR). The results reported in this study provide direct evidence for the interaction of dexamethasone (DEX), triamcinolone acetonide (TA), dexamethasone-21-mesylate (DXM) and 11-deoxycorticosterone (DOC) with human MR expressed in cells by transient co-transfection of a hMR expression vector. The interactions of hMR with DEX, TA, DXM, DOC, promegestone (R5020) and methyltrienelone (R1881) were measured by trans-activation of mouse mammary tumor virus long terminal repeat fused to bacterial chloramphenicol acetyltransferase (MMTV-tk-CAT) in gene co-transfection experiments and by cell free hormone binding assay. The incubation of various steroid hormones in the presence of [3H]ALDO in a competition assay with extracts prepared from HeLa cells co-transfected with hMR expression vector, showed that hMR expressed under these conditions has a high relative affinity for DEX which is similar to ALDO, TA and DOC. Incubation with DXM under these conditions showed very little competition, as was observed with R1881 and R5020. Incubation of the co-transfected cells with DEX, ALDO, DOC, R5020, TA, R1881 and DXM demonstrated that the level of trans-activation did not reflect the previously observed order of binding affinity for the hMR. The level of transactivation was always higher with DEX and TA compared to ALDO and DOC. Analysis of the binding of labeled glucocorticoid regulatory element (GRE) and hMR incubated with DEX, ALDO and DXM by gel shift analysis demonstrated that the trans-activation of MMTV-tk-CAT by hMR is a result of the interaction of hMR with GRE in the MMTV-LTR.     

Cortisol receptor expression differs in the brains of rainbow trout selected for divergent cortisol responses

In rainbow trout (Oncorhynchus mykiss), selection for divergent post-stress plasma cortisol levels has yielded low (LR)- and high (HR) responsive lines, differing in behavioural and physiological aspects of stress coping. For instance, LR fish display prolonged retention of a fear response and of previously learnt routines, compared to HR fish. This study aims at investigating putative central nervous system mechanisms controlling behaviour and memory retention. The stress hormone cortisol is known to affect several aspects of cognition, including memory retention. Cortisol acts through glucocorticoid receptors 1 and 2 (GR1 and 2) and a mineralcorticoid receptor (MR), all of which are abundantly expressed in the salmonid brain. We hypothesized that different expressions of MR and GRs in LR and HR trout brains could be involved in the observed differences in cognition. We quantified the mRNA expression of GR1, GR2 and MR in different brain regions of stressed and non-stressed LR and HR trout. The expression of MR was higher in LR than in HR fish in all brain parts investigated. This could be associated with reduced anxiety and enhanced memory retention in LR fish. MR and GR1 expression was also subject to negative regulation by stress in a site-specific manner.     

Distribution of Corticosteroid Receptors in Mature Oligodendrocytes and Oligodendrocyte Progenitors of the Adult Mouse Brain

The expression of glucocorticoid receptors (GRs) was investigated immunohistochemically in two different lineages of oligodendrocytes, using carbonic anhydrase (CA) II and neuron glial antigen (NG) 2 as markers of mature oligodendrocytes and oligodendrocyte progenitors, respectively. We focused on the gray matter regions, including CA1, CA3 and the dentate gyrus of the hippocampus, the primary somatosensory cortex barrel field and the basolateral amygdala, and the white matter regions, including the corpus callosum, external capsule and fimbria of the hippocampus. More than 80% of CAII-immunoreactive (IR) cells and more than 95% of NG2-IR cells expressed GRs in various regions of the brain. In contrast, neither CAII-IR cells nor NG2-IR cells expressed mineralocorticoid receptors (MRs) in the same regions. The intensity of GR expression was drastically reduced in CA II-IR cells and NG2-IR cells in the same regions in adrenalectomized mice. Finally, steroid receptor co-activator (SRC)-1 and p300, both of which are cofactors for GR, were expressed in the gray and white matter regions in NG2-IR cells, but not in CAII-IR cells. These results suggest that the expression of GRs in oligodendrocytes and their progenitor cells mediates several functions in vivo, including differentiation and myelination, as a major target of glucocorticoids and their cofactors.     

Mineralocorticoid receptor function in bone metabolism and its role in glucocorticoid-induced osteopenia

Although the mineralocorticoid receptor (MR) is expressed in osteoblasts and osteocytes and frequently co-localizes with the glucocorticoid receptors (GR), its pathophysiological functions in bone remain elusive. We report here that pharmacologic inhibition of MR function with eplerenone resulted in increased bone mass, with stimulation of bone formation and suppression of resorption, while specific genetic deletion of MR in osteoblast lineage cells had no effect. Further, treatment with eplerenone as well as specific deletion of MR in osteocytes ameliorated the cortical bone thinning caused by slow-release prednisolone pellets. Thus, MR may be involved in the deleterious effects of glucocorticoid excess on cortical bone.     

Corticosteroids, receptors, and the organ-specific functions of 11 beta-hydroxysteroid dehydrogenase.

Reversible oxidation of the biologically active corticosteroids to the inactive 11-dehydrocorticosteroids is catalyzed by 11 beta-hydroxysteroid dehydrogenase (11 beta HSD). The properties of the enzyme based on clinical observations of individuals with defective 11 beta HSD expression, and laboratory studies of the properties and behavior of the enzyme, are consistent with separate 11 beta-dehydrogenase and 11-oxoreductase species. However, recombinant enzyme expressed in mammalian cells retain both activities, leading to the conclusion that 11 beta HSD is a unique, reversible enzyme. 11 beta HSD is present in most tissues, but its specific functions in most tissues are unknown. How the enzyme may mediate corticosteroid-receptor interaction is illustrated by studies using kidney, testis, and brain. In kidney, 11 beta HSD prevents glucocorticoids from competing inappropriately with aldosterone for mineralocorticoid receptor (MR). Lack of enzyme in humans due to natural causes or inhibition by pharmacological agents results in maximum activation of MR by glucocorticoids, leading to the clinical symptoms of apparent mineralocorticoid excess. Leydig cells of the testes synthesize testosterone, a process that is suppressed by events initiated by the binding of corticosteroid to glucocorticoid receptors (GR). Depletion of active steroid mediated by 11 beta HSD may initiate testosterone production at puberty and affect testosterone production during adult life, as for example during periods of stress. The heterogeneous distribution of MR and GR in the brain reflects the specific regional effects of glucocorticoids and mineralocorticoids on neural function. Colocalization of 11 beta HSD and corticosteroid receptors in brain may be important in controlling the specificity of corticosteroid interaction with GR and MR. The patterns of 11 beta HSD-steroid-receptor interaction illustrated with these three tissues may provide models applicable to other tissues in which corticosteroid receptors and 11 beta HSD coexist.