J.M.H.M. Reul

FEEDBACK ACTION AND TONIC INFLUENCE OF CORTICOSTEROIDS ON BRAIN FUNCTION: A CONCEPT ARISING FROM THE HETEROGENEITY OF BRAIN RECEPTOR SYSTEMS

Two types of corticosteroid receptors can be distinguished in rat brain. The type 1 receptor resembles the kidney mineralocorticoid receptor and has two functional expressions in brain, i.e. type 1 corticosterone (CORT) preferring sites (CR) and mineralocorticoid receptors (MR). The type 2 receptor is similar to the liver glucocorticoid receptor (GR). CORT binds to both CR and GR. The localization, binding specificity, and capacity of the receptor systems have served as criteria to evaluate steroid dependent events in brain biochemistry and behaviour. The GR is widely distributed in neurons and glial cells, with the highest density in frontal brain regions. The GR becomes occupied concomitant with rising plasma CORT levels after stress and as part of the circadian rhythm. The GR mediates the feedback action of CORT on stress-activated brain processes. The CR has its predominant localization in neurons of the septo-hippocampal complex and has a ten-fold higher affinity for CORT than that of the GR. The CR is, at all times of intact adrenocortical secretion, 90% or more occupied by endogenous hormone. The CR mediates a tonic influence exerted with stringent specificity by CORT on hippocampus-associated functions, e.g. cognition, mood, and affect. CORT, via the CR, thus contributes to hippocampus function in interpretation of sensory information, leading to appropriate neuroendocrine and behavioural responses, which are themselves subsequently subject to feedback action via the GR. The MR mediates the mineralocorticoid effect on salt and water balance and its behavioural corollary of salt appetite. The anatomical localization of the MR system is as yet ill-defined, although functional studies suggest circumventricular organs as mineralocorticoid target sites. The CR and the MR have in common the high affinity for mineralocorticoids, but the CR is defined by its exclusive responsiveness to CORT as its agonist. The CR and MR probably represent the same chemical receptor modality (type 1), which is expressed differentially depending on the presence of extravascular corticosteroid binding globulin (CBG) in the vicinity of the receptor. GR capacity is subject to autoregulation. Chronic stress, senescence, and chronic CORT administration reduce GR number, with, as a consequence, a less efficient feedback signal. The CR number seems not to be under the control of corticosteroids, probably since the receptor sites are extensively occupied by endogenous hormones. The CR number displays a circadian rhythm and is reduced during senescence.(ABSTRACT TRUNCATED AT 400 WORDS)

Anatomical resolution of two types of corticosterone receptor sites in rat brain with in vitro autoradiography and computerized image analysis

The rat brain contains two receptor systems for corticosterone (CORT): the glucocorticoid (GR) and corticosterone or mineralocorticoid-like (CR) receptor sites. We have studied the localization of these receptors by in vitro autoradiography and by in vitro cytosol binding assays in microdissected brain areas. In vitro autoradiography revealed that CR receptor sites are almost entirely restricted to the septal-hippocampal complex, whereas the presence of GR extends throughout the brain. Highest levels of GR are present in the lateral septum, hippocampal, cortical and thalamic regions and the paraventricular nucleus. In vitro determination of binding of 3H-labelled steroids to CR and GR in cytosol of punched out brain tissue revealed a similar neuroanatomical distribution as observed with the autoradiographic analysis. In addition, it was found that CORT binds to CR (KD approximately 0.5 nM) with 5-10-fold higher affinity than to GR (KD approximately 2.5-5 nM).

Differential Response of Type I and Type II Corticosteroid Receptors to Changes in Plasma Steroid Level and Circadian Rhythmicity

Corticosterone (CORT) binds to two receptor systems in rat brain: the type I CORT-preferring receptor (CR) and the type II glucocorticoid receptor (GR). Discrimination between the two receptor types can be achieved with the pure synthetic glucocorticoid RU 28362. In this study, we show that the binding capacity of GR in the rat hippocampus exhibits a strikingly different response from CR to adrenalectomy (ADX), chronic steroid replacement, hypophysectomy (HYPOX) and during circadian variation. Under those experimental conditions neither receptor site showed changes in binding affinity. After ADX, CR number remained relatively constant for a period of 13 days, while GR capacity increased by 133%, a level which was reached 5 days post-surgery. CR capacity showed circadian variation, since CR number was 65% higher in the evening than in the morning. GR capacities at those two time points were not significantly different. Replacement with subcutaneous CORT implants (100-mg pellets) for 7 days following ADX rats did not affect CR number, but caused a 38% decrease in GR number compared to control animals (cholesterol-treated, 7-day-ADX rats). On the other hand, dexamethasone (DEX) implants (5-, 15-, 25-mg pellets) elicited a dose-dependent increase in CR capacity (up to 99%) and a dose-dependent decrease in GR capacity (40-44%). Finally, 2 weeks after HYPOX, CR and GR numbers were increased by 60 and 38%, respectively. We conclude that the type II GR capacity responds in an autoregulatory manner to changes in circulating plasma glucocorticoid levels, while type I CR does not.

Corticosteroid receptor types in brain: regulation and putative function

The hypothalamic-pituitary-adrenal (HPA) axis plays an essential role as humoral communication system in adaptive processes. The amine, peptide and steroid components of the axis are apparently needed to maintain homeostasis. Disturbances in homeostasis trigger HPA activity and as the final link in the subsequent cascade of humoral events, function the corticosteriods. In our studies on neuroendocrine aspects of adaptation we have focused on corticosteroid receptors. Here we will summarize biochemical and physiological evidence for the presence of two types of corticosteriod receptors in the brain. These receptors appear to play a key function in the integrative response to stress and participate in regulation of ongoing as well as long-term influences on the adaptive process. Intrinsic to the receptors is their plasticity, which permits the adjustment of receptor number and affinity to changing environmental conditions. Regulation of receptor number appears, however, strikingly different for each receptor type, i.e. homologous vs heterologous regulation. Experiments involving neurotrophic peptides have opened up the route towards understanding this differential regulation. Such peptides not only stimulate adrenocortical hormone secretion, they also seem to modulate steroid receptor number and to facilitate the expression of the steroid receptor.

Neurotrophic ACTH analogue promotes plasticity of type I corticosteroid receptor in brain of senescent male rats

Age-related changes were studied in the concentration of type-I and type-II corticosteroid receptors in the hippocampus of young adult (3 months) and aged (28.5 to 30.5 months) male rats. Using 3H-labelled ligands, in vitro binding of type-I and type-II corticosteroid receptors in the soluble cell fraction (cytosol) revealed an age-related decrease in concentration of both receptor types of 52% and 28%, respectively. Infusion of young and aged male rats for 2 weeks with the ACTH4-9 [adrenocorticotropin4-9] peptide analogue ORG 2766 (0.5 micrograms/0.5 microliter/hr) resulted in only a minor increase (+8%) in the number of type-I receptors in young rats. In the aged animals, however, the type-I receptor concentration was 68% higher than in the vehicle-treated aged animals. In contrast, no effect of the peptide treatment was noted on the concentration of type-II receptors in either young or aged rats. Furthermore, no effect was found for either age or treatment with peptide on the affinity of type-I and type-II receptors for their respective ligands. Binding of 3H-labelled ligands to brain sections of young and aged rats was performed using in vitro autoradiography. Quantitative image analysis of the film showed that in senescence there is a marked reduction in both type-I (62-75%) and type-II (29-56%) receptor concentrations in the hippocampal subregions (CA1, CA2, CA3 and dentate gyrus) as well as in the lateral septum. Treatment of aged rats with ORG 2766 selectively reversed the age-associated reduction in type-I receptors, while the peptide did not affect the type-II receptors.(ABSTRACT TRUNCATED AT 250 WORDS)

Function and plasticity of brain corticosteroid receptor systems: Action of neuropeptides

Two types of corticosteroid receptors may be distinguished in rat brain. Type 1 resembles the kidney mineralocorticoid receptor and Type 2 is similar to the liver glucocorticoid receptor (GR). Type 1 receptor system displays two functional expressions, i.e. Type 1 corticosterone (CORT)-preferring sites (CR) and Type 1 mineralocorticoid receptors (MR). MR occurs in circumventricular organs and mediates behaviors such as salt appetite. CR has its principal localization in neurons of the hippocampus, and mediates tonic influences of CORT on hippocampus-associated functions. CR responds with stringent specificity to CORT. Differentiation between CR and MR is due to a different accessibility of the receptor by CORT and ALDO, which seems dependent on the presence of extravascular corticosteroid binding globulin (CBG). GR has a wide distribution in brain, occurs in neurons and glial cells and has its principal localization in such regions as the paraventricular nucleus and the n. tractus solitarii (site of CRF synthesis and of blood pressure regulation, respectively). GR mediates the feedback action of CORT on stress-activated brain processes. GR is subject to autoregulation by CORT. Chronic stress, senescence, and chronic CORT administration reduce receptor number, while GR capacity is increased after adrenalectomy. Reduced GR receptor number results in a less-efficient feedback action. The CORT signal via CR probably can only be altered via changes in CR density evoked rather by neural factors than by autoregulation. CR density is reduced at senescence, but is increased to receptor number of young control animals after chronic treatment with a behaviorally potent ACTH-(4-9) analogue, Org 2766. CR plasticity is prominent for the hippocampus, which is a structure involved in cognition, emotional state and subtle regulation of pituitary-adrenal function.

Central Action of Adrenal Steroids During Stress and Adaptation

Corticosteroids interact with receptors in the central nervous system. These receptors display heterogeneity and can be distinguished as corticosterone- and aldosterone-binding mineralocorticoid receptors and dexamethasone-binding glucocorticoid receptors. Ligand specificity of mineralocorticoid receptors for either corticosterone or aldosterone seems to be determined by co-localized transcortin and the enzyme, 11 beta-hydroxysteroid dehydrogenase. Aldosterone-selective mineralocorticoid receptors appear to be present in the circumventricular organs and the AV3V region of the hypothalamus and mediate behavior that is driven by salt appetite. Highest concentrations of mineralocorticoid receptors are found in neurons of the hippocampus. These limbic mineralocorticoid receptor sites mediate tonic influences of corticosterone on brain processes. Glucocorticoid receptors bind corticosterone with a tenfold lower affinity than do mineralocorticoid receptors, and are widely distributed in neuronal and glial cells of the brain. Glucocorticoid receptors are involved in the termination of the stress response (negative feedback). Studies involving measurement of glucocorticoid receptor mRNA and binding sites have revealed that glucocorticoid receptors are subject to autoregulation. After ADX, glucocorticoid receptor concentration increases, but is reduced after chronic stress, chronic administration of glucocorticoids, and at senescence. A diminished glucocorticoid receptor concentration may compromise the negative feedback action exerted by glucocorticoids after stress. After ADX, mineralocorticoid receptor binding is acutely up-regulated and reaches its maximum between 7 and 24 hours post-ADX. Mineralocorticoid receptor mRNA level shows a transient increase following ADX. Long-term ADX has no effect on the mineralocorticoid receptor concentration, but, interestingly, chronic dexamethasone treatment results in an up-regulation of mineralocorticoid receptors. Mineralocorticoid receptor level is decreased at senescence, but this age-related decrement can be reversed by chronic treatment with the ACTH4-9 analog, ORG 2766. Functionally, mineralocorticoid receptors and glucocorticoid receptors are involved in different aspects of the organization of the stress response, and in conjunction they control the stress responsiveness of the animal.

Corticosteroid receptor analyses in rat and hamster brains reveal species specificity in the type I and type II receptors

In vitro cytosol binding, receptor autoradiography with radiolabelled corticosteroid analogs, and immunocytochemistry with monoclonal antibodies have revealed the presence of two receptor systems for corticosteroids in rat and hamster brains. The type I receptor is found mainly in the hippocampal region, and in the hamster it binds cortisol (F) and corticosterone (B) with similar affinity while in the rat (a species which unlike the hamster secretes solely B) the type I receptor shows high affinity to B and not to F. The type II receptor is more widely distributed in the brain and it binds to F (hamster) or B (rat) with affinity 4-6-fold lower than to the type I. in vivo, the hamster type I and II retain F much more than B while those in the rat show the opposite. In conclusion, the present study clearly indicates species-specificity in type I and type II receptor systems in these animals. Furthermore, the type I receptor displays in vivo stringent preference for retention of the animals predominantly circulating corticosteroid (F in hamster, in B in rat).