Glucocorticoid and Mineralocorticoid Receptors in the Brain: A Transcriptional Perspective

Although the fact that genetic predisposition and environmental exposures interact to shape development and function of the human brain and, ultimately, the risk of psychiatric disorders has drawn wide interest, the corresponding molecular mechanisms have not yet been elucidated. We found that a functional polymorphism altering chromatin interaction between the transcription start site and long-range enhancers in the FK506 binding protein 5 (FKBP5) gene, an important regulator of the stress hormone system, increased the risk of developing stress-related psychiatric disorders in adulthood by allele-specific, childhood trauma-dependent DNA demethylation in functional glucocorticoid response elements of FKBP5. This demethylation was linked to increased stress-dependent gene transcription followed by a long-term dysregulation of the stress hormone system and a global effect on the function of immune cells and brain areas associated with stress regulation. This identification of molecular mechanisms of genotype-directed long-term environmental reactivity will be useful for designing more effective treatment strategies for stress-related disorders.

Two receptor systems for corticosterone (CORT) can be distinguished in rat brain: mineralocorticoid-like or CORT receptors (CR) and glucocorticoid receptors (GR). The microdistribution and extent of occupation of each receptor population by CORT were studied. The CR system is restricted predominantly to the lateral septum and hippocampus. Within the hippocampus, the highest density occurs in the subiculum +/- CA1 cell field (144 fmol/mg protein) and the dentate gyrus (104 fmol/mg protein). Affinity of CR for CORT was very high (Kd, approximately 0.5 nM). The GR system has a more widespread distribution in the brain. The highest density for GR is in the lateral septum (195 fmol/mg protein), the dentate gyrus (133 fmol/mg protein), the nucleus tractus solitarii and central amygdala. Substantial amounts of GR are present in the paraventricular nucleus and locus coeruleus and low amounts in the raphe area and the subiculum + CA1 cell field. The affinity of GR for CORT (Kd, approximately 2.5-5 nM) was 6- to 10-fold lower than that of CR. Occupation of CR by endogenous ligand was 89.5% during morning trough levels of pituitary-adrenal activity (plasma CORT, 1.4 micrograms/100 ml). Similar levels of occupation (88.7% and 97.6%) were observed at the diurnal peak (plasma CORT, 27 micrograms/100 ml) and after 1 h of restraint stress (plasma CORT, 25 micrograms/100 ml), respectively. Furthermore, a dose of 1 microgram CORT/100 g BW, sc, resulted in 80% CORT receptor occupation, whereas GR were not occupied. For 50% occupation of GR, doses needed to be increased to 50-100 micrograms/100 g BW, and for 95% occupation, a dose of 1 mg CORT was required. The plasma CORT level at the time of half-maximal GR occupation was about 25 micrograms/100 ml, which is in the range of levels attained after stress or during the diurnal peak of pituitary-adrenal activity. Thus, CR are extensively filled (greater than 90%) with endogenous CORT under most circumstances, while GR become occupied concurrent with increasing plasma CORT concentrations due to stress or diurnal rhythm. We conclude that CORT action via CR may be involved in a tonic (permissive) influence on brain function with the septohippocampal complex as a primary target. In view of the almost complete occupation of CR by endogenous hormones, the regulation of the CORT signal via CR will, most likely, be by alterations in the number of such receptors. In contrast, CORT action via GR is involved in its feedback action on stress-activated brain mechanisms, and GR occur widely in the brain.(ABSTRACT TRUNCATED AT 400 WORDS)