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ABSTRACT: Stress and corticosterone affect, via glucocorticoid receptors, cellular physiology in the rodent brain. A well-documented example concerns corticosteroid effects on high-voltage activated (L type) calcium currents in the hippocampal CA1 area. We tested whether corticosterone also affects calcium currents in another hippocampal area that highly expresses glucocorticoid receptors, i.e. the dentate gyrus (DG). Remarkably, corticosterone (100 nm, given for 20 min, 1-4.5 hr before recording) did not change high-voltage activated calcium currents in the DG, whereas currents in the CA1 area of the same rats were increased. Follow-up studies revealed that no apparent dissociation between the two areas was observed with respect to transcriptional regulation of calcium channel subunits; thus, in both areas corticosterone increased mRNA levels of the calcium channel-beta4 but not the (alpha) Ca(v)1.2 subunit. At the protein level, however, beta4 and Ca(v)1.2 levels were significantly up-regulated by corticosterone in the CA1 but not the DG area. These data suggest that stress-induced elevations in the level of corticosterone result in a regionally differentiated physiological response that is not simply determined by the glucocorticoid receptor distribution and that the observed regional differentiation may be caused by a gene involved in the translational machinery or in mechanisms regulating mRNA or protein stability.
Endocrinology 08/2009; 150(10):4615-24. · 4.46 Impact Factor
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ABSTRACT: Adaptation to stress in vertebrates occurs via activation of hormonal and neuronal signaling cascades in which corticotropin-releasing 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.
Proceedings of the National Academy of Sciences 06/2009; 106(19):8038-42. · 9.68 Impact Factor
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ABSTRACT: Glucocorticoid negative feedback of the hypothalamus-pituitary-adrenal axis is mediated in part by direct repression of gene transcription in glucocorticoid receptor (GR) expressing cells. We have investigated the cross talk between the two main signaling pathways involved in activation and repression of corticotrophin releasing hormone (CRH) mRNA expression: cyclic AMP (cAMP) and GR. We report that in the At-T20 cell-line the glucocorticoid-mediated repression of the cAMP-induced human CRH proximal promoter activity depends on the relative timing of activation of both signaling pathways. Activation of the GR prior to or in conjunction with cAMP signaling results in an effective repression of the cAMP-induced transcription of the CRH gene. In contrast, activation of the GR 10 minutes after onset of cAMP treatment, results in a significant loss of GR-mediated repression. In addition, translocation of ligand-activated GR to the nucleus was found as early as 10 minutes after glucocorticoid treatment. Interestingly, while both signaling cascades counteract each other on the CRH proximal promoter, they synergize on a synthetic promoter containing 'positive' response elements. Since the order of activation of both signaling pathways may vary considerably in vivo, we conclude that a critical time-window exists for effective repression of the CRH gene by glucocorticoids.
PLoS ONE 02/2009; 4(1):e4327. · 4.09 Impact Factor
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ABSTRACT: While the actions of glucocorticoids on brain functions have been comprehensively studied, the underlying genomic mechanisms are poorly understood. In this study, we show that glucocorticoid-induced leucine zipper (GILZ) mRNA is strongly and ubiquitously induced in rat brain. To decipher the molecular mechanisms underlying these genomic effects, it is of interest to identify the regulatory sites in the promoter region. Alignment of the rat GILZ promoter with the well-characterized human promoter resulted in poor sequence homology. Consequently, we analyzed the rat 5' flanking sequence by Matrix REDUCE and identified two high-affinity glucocorticoid response elements (GRE) located 2 kb upstream of the transcription start site. These findings were corroborated using the glucocorticoid receptor (GR) expressing Ns-1 PC12 rat cell-line. In these cells, dexamethasone treatment leads to a progressive increase of GILZ mRNA expression levels via a GR-dependent mechanism. Subsequently, using chromatin immunoprecipitation assays we show that the two high-affinity GREs are located within the GR-binding regions. Lastly, we demonstrate using multiple tissue in situ hybridization a marked increase in mRNA expression levels in spleen, thymus, heart, lung, liver, muscle, testis, kidney, colon, ileum, as well as in brain and conclude that the GILZ gene can be used to study glucocorticoid effects in many additional rodent tissues.
Journal of Neurochemistry 09/2008; 106(6):2515-23. · 4.06 Impact Factor
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ABSTRACT: Glucocorticoid hormones are important regulators of homeostasis. They are used clinically as highly effective anti-inflammatory compounds and have been prescribed for more than fifty years for a variety of conditions. They mediate their genomic actions by binding to two different intracellular receptors in target cells. The pharmacology of glucocorticoids largely depends on ligand concentration and receptor expression levels in target tissue. However, their genomic actions also critically depend on coactivators and corepressors recruitment. We discuss how various non-receptor factors affect glucocorticoid potency and efficacy with respect to their genomic effects. Differential recruitment of coregulators may account for many ligand- and cell-specific effects of glucocorticoids. This is best illustrated by the recent identification of selective glucocorticoid receptor agonists that induce distinct conformational changes to the receptors resulting in altered protein-protein interactions and consequently different regulation of gene expression. We conclude that these new molecular insights will contribute to the design of safer glucocorticoids that retain full pharmacological properties with reduced side-effects.
European Journal of Pharmacology 06/2008; 585(2-3):483-91. · 2.52 Impact Factor
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Siem van der Laan
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ABSTRACT: Currently, the raising awareness of the role of glucocorticoids in the onset of numerous (neuro)-pathologies constitutes the increasing necessity of understanding the mechanisms of action of glucocorticoids in bodily processes and brain functioning. Glucocorticoids mediate their effects by binding to intracellular receptors which act as transcription factors. A remarkable and yet unexplained phenomenon described more than two decades ago, is the cell-specific effects glucocorticoids bring about on gene expression in brain. For example, while glucocorticoids suppress corticotrophin-releasing hormone (CRH) synthesis in the hypothalamus, production of CRH in the central nucleus of the amygdala (CeA) is stimulated by increased hormone levels. Inasmuch as the neuroanatomical distribution of the corticosteroid receptors does not satisfactorily explain these effects, it is of interest to decipher the role of recently discovered coregu lator proteins that modulate the direction and the magnitude of steroid receptor-driven transcription. Therefore, in the current thesis the expression and function of central coregulators was studied: the coactivators SRC1a and SRC1e along with the corepressors N-CoR and SMRT were found to be expressed in brain and involved in regulation of CRH gene expression. Finally, a method that allows detection of coregulator recruitment by steroid receptors in brain tissue was developed.
