We have analysed the long-term psychoneuroendocrine effects of maternal deprivation (MD) [24 h at postnatal day (PND) 9] and/or exposure to chronic unpredictable stress (CUS) during the periadolescent period (PND 28 to PND 43) in male and female Wistar rats. Animals were tested in the elevated plus maze (EPM, anxiety) at PND 44 and in two memory tests, spontaneous alternation and novel object recognition (NOT) in adulthood. The expression of hippocampal glucocorticoid (GR) and mineralocorticoid (MR) receptors, as well as of synaptophysin, neural cell adhesion molecule and brain-derived neurotrophic factor, was analysed by in situ hybridisation in selected hippocampal regions. Endocrine determinations of leptin, testosterone and oestradiol plasma levels were carried out by radioimmunoassay. Young CUS animals showed decreased anxiety behaviour in the EPM (increased percentage of time and entries in the open arms) irrespective of neonatal treatment. Memory impairments were induced by the two stressful treatments as was revealed by the NOT, with males being most clearly affected. Although each stressful procedure, when considered separately, induced different (always decrements) effects on the three synaptic molecules analysed and affected males and females differently, the combination of MD and CUS induced an unique disruptive effect on the three synaptic plasticity players. MD induced a long-term significant decrease in hippocampal GR only in males, whereas CUS tended to increase MR in males and decrease MR in females. Both neonatal MD and periadolescent CUS induced marked reductions in testosterone and oestradiol in males, whereas MD male animals also showed significantly decreased leptin levels. By contrast, in females, none of the hormones analysed was altered by any of the stressful procedures. Taking our data together in support of the 'two-hit' hypothesis, MD during neonatal life and/or exposure to CUS during the periadolescent period induced a permanent deficit in memory, which was accompanied by a decrement in markers for hippocampal plasticity. The long-term effects on body weight and hormone levels, particularly among males, might reflect sex-dependent lasting metabolic alterations as well as an impaired reproductive function.
Chronically elevated circulating glucocorticoid levels are although to enhance vulnerability to psychopathology. Here we hypothesized that such sustained glucocorticoid levels, disturbing corticosterone pulsatility, attenuate glucocorticoid receptor signaling and target gene responsiveness to an acute challenge in the rat brain. Rats were implanted with vehicle or 40 or 100% corticosterone pellets known to flatten ultradian and circadian rhythmicity while maintaining daily average levels or mimic pathological conditions. Additionally, recovery from constant exposure was studied in groups that had the pellet removed 24 h prior to the challenge. Molecular markers for receptor responsiveness (receptor levels, nuclear translocation, promoter occupancy, and target gene expression) to an acute challenge mimicking the stress response (3 mg/kg ip) were studied in the hippocampal area. Implantation of 40 and 100% corticosterone pellets dose-dependently down-regulated glucocorticoid receptor and attenuated mineralocorticoid receptor and glucocorticoid receptor translocation to the acute challenge. Interestingly, whereas target gene Gilz expression to the challenge was already attenuated by tonic daily average levels (40%), Sgk-1 was affected only after constant high corticosterone exposure (100%), indicating altered receptor responsiveness due to treatment. Washout of 100% corticosterone recovered all molecular markers (partial), whereas removal of the 40% corticosterone pellet still attenuated responsiveness to the challenge. We propose that corticosteroid pulsatility is crucial in maintaining normal responsiveness to glucocorticoids. Whereas the results with 100% corticosterone are likely attributed to receptor saturation, subtle changes in the pattern of exposure (40%) induces changes at least as severe for glucocorticoid signaling as overt hypercorticism, suggesting an underlying mechanism sensitive to the pattern of hormone exposure.
Adaptation to stress in vertebrates occurs via activation of hormonal and neuronal signaling cascades in which corticotropinreleasing hormone (CRH) plays a central role. Expression of brain CRH is subject to strong, brain-region specific regulation by glucocorticoid hormones and neurogenic intracellular signals. We hypothesized that Steroid Receptor Coactivator 1 (SRC-1), a transcriptional coregulator of the glucocorticoid receptor, is involved in the sensitivity of CRH regulation by stress-related factors. In the brains of SRC-1 knockout mice we found basal CRH mRNA levels to be lower in the central nucleus of the amygdala. Hypothalamic CRH up-regulation after chronic (but not acute) stress, as well as region-dependent up-and down-regulation induced by synthetic glucocorticoids, were significantly attenuated compared with wild type. The impaired induction of the crh gene by neurogenic signals was corroborated in AtT-20 cells, where siRNA and overexpression experiments showed that SRC-1 is necessary for full induction of a CRH promoter reporter gene by forskolin, suggestive of involvement of transcription factor CREB. In conclusion, SRC-1 is involved in positive and negative regulation of the crh gene, and an important factor for the adaptive capacity of stress.adaptation ͉ amygdala ͉ HPA axis ͉ neuroendocrinology ͉ transcription B rain corticotropin-releasing hormone (CRH) plays a pivotal role in the mammalian response to stress. CRH synthesized by neurons in the central nucleus of the amygdala (CeA) mediates the effect of stress on emotional states, including fear and anxiety (1, 2). From the paraventricular nucleus of the hypothalamus (PVN) CRH coordinates autonomic outflow and the activity of the hypothalamus-pituitary-adrenal (HPA) axis. The latter leads to secretion of the adrenal glucocorticoid hormones, which in turn orchestrate the adaptation to stress of virtually all tissues in the body (3-5).As part of adaptation, CRH expression itself is strongly regulated in response to stress-induced elevations of glucocorticoids and neurogenic signals. In the core of the HPA-axis, activation of the glucocorticoid receptor (GR) can repress transcription from the crh gene as part of negative feedback, whereas stress-related noradrenergic and glutamatergic excitatory signals can activate the gene, in part via activation of the transcription factor CREB. In the CeA, both GR activation and excitatory signals can lead to an increased CRH expression (6, 7). These modulations are considered crucial for stress adaptation, and a considerable amount of research has been devoted to understand how transcriptional signals are integrated at the level of the CRH promoter, both in vitro and in vivo (8, 9). Nevertheless, the regulation of the crh gene in vivo is far from understood.Transcriptional coregulators constitute an expanding class of molecules that act as mediators and integrators of signals carried by nuclear receptors, such as GR (10). The p160 coregulator Steroid Receptor Coactivator (SRC-1) is strongly expressed in br...
Nuclear receptor coregulators are proteins that modulate the transcriptional activity of steroid receptors and may explain cell-specific effects of glucocorticoid receptor action. Based on the uneven distribution of a number of coregulators in CRH-expressing cells in the hypothalamus of the rat brain, we tested the hypothesis that these proteins are involved as mediators in the glucocorticoid-induced repression of the CRH promoter. Therefore, we assessed the role of coregulator proteins on both induction and repression of CRH in the AtT-20 cell line, a model system for CRH repression by glucocorticoids. The steroid receptor coactivator 1a (SRC1a), SRC-1e, nuclear corepressor (N-CoR), and silencing mediator of the retinoid and thyroid hormone receptor (SMRT) were studied in this system. We show that the concentration of glucocorticoid receptor and the type of ligand, i.e. corticosterone or dexamethasone, determines the repression. Furthermore, overexpression of SRC1a, but not SRC1e, increased both efficacy and potency of the glucocorticoid receptor-mediated repression of the forskolin-induced CRH promoter. Unexpectedly, cotransfection of the corepressors N-CoR and SMRT did not affect the corticosterone-dependent repression but resulted in a marked decrease of the forskolin stimulation of the CRH gene. Altogether, our data demonstrate that 1) the concentration of the receptor, 2) the type of ligand, and 3) the coregulator recruited all determine the expression and the repression of the CRH gene. We conclude that modulation of coregulator activity may play a role in the control of the hypothalamus-pituitary-adrenal axis.
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