SUMO regulation of FKBP51 activity and the stress response.

Glucocorticoids (GCs) actions are mostly mediated by the GC receptor (GR), a member of the nuclear receptor superfamily. Alterations of the GR activity have been associated to different diseases including mood disorders. FKBP51 is a GR chaperone that has gained much attention because it is a strong inhibitor of GR activity. FKBP51 exerts effects on many stress-related pathways and may be an important mediator of emotional behavior. Key proteins involved in the regulation of the stress response and antidepressant action are regulated by SUMOylation, a post-translational modification that has an important role in the regulation of neuronal physiology and disease. In this review, we focus on the role of SUMO-conjugation as a regulator of this pathway.

Tricyclic antidepressants target FKBP51 SUMOylation to restore glucocorticoid receptor activity.

FKBP51 is an important inhibitor of the glucocorticoid receptor (GR) signaling. High FKBP51 levels are associated to stress-related disorders, which are linked to GR resistance. SUMO conjugation to FKBP51 is necessary for FKBP51's inhibitory action on GR. The GR/FKBP51 pathway is target of antidepressant action. Thus we investigated if these drugs could inhibit FKBP51 SUMOylation and therefore restore GR activity. Screening cells using Ni2+ affinity and in vitro SUMOylation assays revealed that tricyclic antidepressants- particularly clomipramine- inhibited FKBP51 SUMOylation. Our data show that clomipramine binds to FKBP51 inhibiting its interaction with PIAS4 and therefore hindering its SUMOylation. The inhibition of FKBP51 SUMOylation decreased its binding to Hsp90 and GR facilitating FKBP52 recruitment, and enhancing GR activity. Reduction of PIAS4 expression in rat primary astrocytes impaired FKBP51 interaction with GR, while clomipramine could no longer exert its inhibitory action. This mechanism was verified in vivo in mice treated with clomipramine. These results describe the action of antidepressants as repressors of FKBP51 SUMOylation as a molecular switch for restoring GR sensitivity, thereby providing new potential routes of antidepressant intervention.

SUMO conjugation as regulator of the glucocorticoid receptor-FKBP51 cellular response to stress.

In order to adequately respond to stressful stimuli, glucocorticoids (GCs) target almost every tissue of the body. By exerting a negative feedback loop in the hypothalamic-pituitary-adrenal (HPA) axis GCs inhibit their own synthesis and restore homeostasis. GCs actions are mostly mediated by the GC receptor (GR), a member of the nuclear receptor superfamily. Alterations of the GR activity have been associatedto different diseases including mood disorders and can lead to severe complication. Therefore, understanding the molecular complexity of GR modulation is mandatory for the development of new and effective drugs for treating GR-associated disorders. FKBP51 is a GR chaperone that has gained much attention because it is a strong inhibitor of GR activity and has a crucial role in psychiatric diseases. Both GR and FKBP51 activity are regulated by SUMOylation, a posttranslational (PTM). In this review, we focus on the impact of SUMO-conjugation as a regulator of this pathway.

Regulatory and Mechanistic Actions of Glucocorticoids on T and Inflammatory Cells.

Glucocorticoids (GCs) play an important role in regulating the inflammatory and immune response and have been used since decades to treat various inflammatory and autoimmune disorders. Fine-tuning the glucocorticoid receptor (GR) activity is instrumental in the search for novel therapeutic strategies aimed to reduce pathological signaling and restoring homeostasis. Despite the primary anti-inflammatory actions of GCs, there are studies suggesting that under certain conditions GCs may also exert pro-inflammatory responses. For these reasons the understanding of the GR basic mechanisms of action on different immune cells in the periphery (e.g., macrophages, dendritic cells, neutrophils, and T cells) and in the brain (microglia) contexts, that we review in this chapter, is a continuous matter of interest and may reveal novel therapeutic targets for the treatment of immune and inflammatory response.

GR-independent down-modulation on GM-CSF bone marrow-derived dendritic cells by the selective glucocorticoid receptor modulator Compound A.

Dendritic cells (DC) initiate the adaptive immune response. Glucocorticoids (GCs) down-modulate the function of DC. Compound A (CpdA, (2-(4-acetoxyphenyl)-2-chloro-N-methyl-ethylammonium chloride) is a plant-derived GR-ligand with marked dissociative properties. We investigated the effects of CpdA on in vitro generated GM-CSF-conditioned bone marrow-derived DC (BMDC). CpdA-exposed BMDC exhibited low expression of cell-surface molecules and diminution of the release of proinflammatory cytokines upon LPS stimulation; processes associated with BMDC maturation and activation. CpdA-treated BMDC were inefficient at Ag capture via mannose receptor-mediated endocytosis and displayed reduced T-cell priming. CpdA prevented the LPS-induced rise in pErk1/2 and pP38, kinases involved in TLR4 signaling. CpdA fully inhibited LPS-induced pAktSer473, a marker associated with the generation of tolerogenic DC. We used pharmacological blockade and selective genetic loss-of-function tools and demonstrated GR-independent inhibitory effects of CpdA in BMDC. Mechanistically, CpdA-mediated inactivation of the NF-κB intracellular signaling pathway was associated with a short-circuiting of pErk1/2 and pP38 upstream signaling. Assessment of the in vivo function of CpdA-treated BMDC pulsed with the hapten trinitrobenzenesulfonic acid showed impaired cell-mediated contact hypersensitivity. Collectively, we provide evidence that CpdA is an effective BMDC modulator that might have a benefit for immune disorders, even when GR is not directly targeted.

Co-Expression of Wild-Type P2X7R with Gln460Arg Variant Alters Receptor Function.

The P2X7 receptor is a member of the P2X family of ligand-gated ion channels. A single-nucleotide polymorphism leading to a glutamine (Gln) by arginine (Arg) substitution at codon 460 of the purinergic P2X7 receptor (P2X7R) has been associated with mood disorders. No change in function (loss or gain) has been described for this SNP so far. Here we show that although the P2X7R-Gln460Arg variant per se is not compromised in its function, co-expression of wild-type P2X7R with P2X7R-Gln460Arg impairs receptor function with respect to calcium influx, channel currents and intracellular signaling in vitro. Moreover, co-immunoprecipitation and FRET studies show that the P2X7R-Gln460Arg variant physically interacts with P2X7R-WT. Specific silencing of either the normal or polymorphic variant rescues the heterozygous loss of function phenotype and restores normal function. The described loss of function due to co-expression, unique for mutations in the P2RX7 gene so far, explains the mechanism by which the P2X7R-Gln460Arg variant affects the normal function of the channel and may represent a mechanism of action for other mutations.

Novel insights into the neuroendocrine control of inflammation: the role of GR and PARP1.

Inflammatory responses are elicited after injury, involving release of inflammatory mediators that ultimately lead, at the molecular level, to the activation of specific transcription factors (TFs; mainly activator protein 1 and nuclear factor-κB). These TFs propagate inflammation by inducing the expression of cytokines and chemokines. The neuroendocrine system has a determinant role in the maintenance of homeostasis, to avoid exacerbated inflammatory responses. Glucocorticoids (GCs) are the key neuroendocrine regulators of the inflammatory response. In this study, we describe the molecular mechanisms involved in the interplay between inflammatory cytokines, the neuroendocrine axis and GCs necessary for the control of inflammation. Targeting and modulation of the glucocorticoid receptor (GR) and its activity is a common therapeutic strategy to reduce pathological signaling. Poly (ADP-ribose) polymerase 1 (PARP1) is an enzyme that catalyzes the addition of PAR on target proteins, a post-translational modification termed PARylation. PARP1 has a central role in transcriptional regulation of inflammatory mediators, both in neuroendocrine tumors and in CNS cells. It is also involved in modulation of several nuclear receptors. Therefore, PARP1 and GR share common inflammatory pathways with antagonic roles in the control of inflammatory processes, which are crucial for the effective maintenance of homeostasis.

RSUME enhances glucocorticoid receptor SUMOylation and transcriptional activity.

Glucocorticoid receptor (GR) activity is modulated by posttranslational modifications, including phosphorylation, ubiquitination, and SUMOylation. The GR has three SUMOylation sites: lysine 297 (K297) and K313 in the N-terminal domain (NTD) and K721 within the ligand-binding domain. SUMOylation of the NTD sites mediates the negative effect of the synergy control motifs of GR on promoters with closely spaced GR binding sites. There is scarce evidence on the role of SUMO conjugation to K721 and its impact on GR transcriptional activity. We have previously shown that RSUME (RWD-containing SUMOylation enhancer) increases protein SUMOylation. We now demonstrate that RSUME interacts with the GR and increases its SUMOylation. RSUME regulates GR transcriptional activity and the expression of its endogenous target genes, FKBP51 and S100P. RSUME uncovers a positive role for the third SUMOylation site, K721, on GR-mediated transcription, demonstrating that GR SUMOylation acts positively in the presence of a SUMOylation enhancer. Both mutation of K721 and small interfering RNA-mediated RSUME knockdown diminish GRIP1 coactivator activity. RSUME, whose expression is induced under stress conditions, is a key factor in heat shock-induced GR SUMOylation. These results show that inhibitory and stimulatory SUMO sites are present in the GR and at higher SUMOylation levels the stimulatory one becomes dominant.

Compound A, a dissociated glucocorticoid receptor modulator, inhibits T-bet (Th1) and induces GATA-3 (Th2) activity in immune cells.

BACKGROUND: Compound A (CpdA) is a dissociating non-steroidal glucocorticoid receptor (GR) ligand which has anti-inflammatory properties exerted by down-modulating proinflammatory gene expression. By favouring GR monomer formation, CpdA does not enhance glucocorticoid (GC) response element-driven gene expression, resulting in a reduced side effect profile as compared to GCs. Considering the importance of Th1/Th2 balance in the final outcome of immune and inflammatory responses, we analyzed how selective GR modulation differentially regulates the activity of T-bet and GATA-3, master drivers of Th1 and Th2 differentiation, respectively. RESULTS: Using Western analysis and reporter gene assays, we show in murine T cells that, similar to GCs, CpdA inhibits T-bet activity via a transrepressive mechanism. Different from GCs, CpdA induces GATA-3 activity by p38 MAPK-induction of GATA-3 phosphorylation and nuclear translocation. CpdA effects are reversed by the GR antagonist RU38486, proving the involvement of GR in these actions. ELISA assays demonstrate that modulation of T-bet and GATA-3 impacts on cytokine production shown by a decrease in IFN-γ and an increase in IL-5 production, respectively. CONCLUSIONS: Taken together, through their effect favoring Th2 over Th1 responses, particular dissociated GR ligands, for which CpdA represents a paradigm, hold potential for the application in Th1-mediated immune disorders.

Underlying mechanisms of cAMP- and glucocorticoid-mediated inhibition of FasL expression in activation-induced cell death.

Glucocorticoids (GCs) and cAMP-dependent signaling pathways exert diverse and relevant immune regulatory functions, including a tight control of T cell death and homeostasis. Both of these signaling molecules inhibit TCR-induced cell death and FasL expression, but the underlying mechanisms are still poorly understood. Therefore, to address this question, we performed a comprehensive screening of signaling pathways downstream of the TCR, in order to define which of them are targets of cAMP- and GC-mediated inhibition. We found that cAMP inhibited NF-κB and ERK pathways through a PKA-dependent mechanism, while Dexamethasone blocked TCR-induced NF-κB signaling. Although GCs and cAMP inhibited the induction of endogenous FasL mRNA expression triggered by TCR activation, they potentiated TCR-mediated induction of FasL promoter activity in transient transfection assays. However, when the same FasL promoter was stably transfected, the facilitatory effect of GCs and cAMP became inhibitory, thus resembling the effects on endogenous FasL mRNA expression. Hence, the endogenous chromatinization status known to occur in integrated or genomic vs. episomic DNA might be critical for proper regulation of FasL expression by cAMP and GCs. Our results suggest that the chromatinization status of the FasL promoter may function as a molecular switch, controlling cAMP and GC responsiveness and explaining why these agents inhibit FasL expression in T cells but induce FasL in other cell types.

Disease-modifying immunotherapy for the management of autoimmune diabetes.

Type 1 diabetes (T1D) is a T cell-mediated autoimmune disease that destroys the insulin-secreting beta-cells of the pancreas. It is now possible to predict those candidates that will progress to T1D before the full onset of the disease. Prevention of uncontrollable autoimmunity against beta-cells in therapies for T1D is mandatory to preserve the beta-cell mass. Therefore, immunomodulatory strategies directed to inhibiting the activity of self-reactive T cell clones as well as induction of regulatory T cells would be beneficial for prevention of T1D or recurrence of beta-cell autoimmunity against islet cell allografts.

Intracellular molecular signaling. Basis for specificity to glucocorticoid anti-inflammatory actions.

The molecular interaction between hormonal and cytokine signals is crucial for providing specificity to their actions and represents a key step for understanding, at the molecular level, the ultimate response of physiological neuroendocrine-immune interactions. In this article we will describe new insights into the mechanisms underlying glucocorticoid-mediated anti-inflammatory action, focused on the regulation of immune-cytokine pathways. There are different levels of interaction between intracellular signals elicited by glucocorticoids and cytokines, with the final outcome being regulation of gene expression. One such interaction involves the molecular cross-talk between the activated glucocorticoid receptor (GR) and transcription factors implicated in the regulation of cytokine synthesis and function. This interaction results in the regulation of gene transcription, as we will illustrate with the helper T (Th)1 and Th2 transcription factors T-bet and GATA-3, respectively, implicated in the outcome of specific adaptive immune responses. A further level of mutual regulation is the posttranslational modification of GR by the ubiquitin-proteasome and sumoylation systems. These posttranslational modifications regulate GR activity and will be discussed for the small ubiquitin-related modifier (SUMO) pathway and its enhancer RWD RING finger-containing proteins, WD-repeat-containing proteins, and yeast DEAD (DEXD)-like helicases-containing sumoylation enhancer (RSUME). The impact of posttranslational modifications on inflammatory pathways, such as nuclear factor-kappabeta and regulated cytokines, will also be discussed.

Glucocorticoids inhibit GATA-3 phosphorylation and activity in T cells.

Glucocorticoid (GC) immunosuppression and anti-inflammatory action involve the regulation of several transcription factors (TFs). GCs inhibit the acute production of T-helper (Th) 1 and Th2 cytokines but ultimately favor a shift toward Th2 phenotype. GCs inhibit the transcriptional activity of T-bet Th1 TF by a transrepression mechanism. Here we analyze GC regulation of GATA-3, the master driver of Th2 differentiation. We found that GCs inhibit GATA-3 transcriptional activity. We demonstrate that this mechanism does not involve physical interaction between the glucocorticoid receptor (GR) and GATA-3 or reduction of GATA-3 binding to DNA, as described previously for T-bet. Instead, GCs inhibit GATA-3 activity by inhibition of p38 mitogen-activated protein kinase induced GATA-3 phosphorylation. GCs also inhibit GATA-3 mRNA and protein expression. Finally, GATA-3 inhibition affects the interleukin-5 gene, a central Th2 cytokine. The IC(50) of dexamethasone is 10 nM with a maximum effect at 100 nM. All inhibitory actions were blocked by the GR antagonist RU38486 (1 uM), proving the specificity of GR action. In view of the crucial role of GATA-3 in T-cell differentiation and inflammation, we propose that the mechanism of GATA-3 inhibition compared with that in T-bet may have relevant implications in understanding and modulating the anti-inflammatory and Th-regulatory properties of GCs.

Mecanismos moleculares de acción de algunas drogas inmunosupresoras / Molecular mechanisms of action of some immunosuppresive drugs

Los tratamientos utilizados para desordenes inmunológicos son de origen empírico, utilizando drogas inmunosupresoras identificadas a través de la selección de un gran número de compuestos naturales y sintéticos. Las drogas inmunosupresoras son ampliamente utilizadas en tratamientos clínicos de desordenes autoinmunes, en la prevención de rechazo a transplantes así como también en desordenes de carácter no autoinmune tales como las alergias. El diseño de las terapias inmunosupresoras está basado en controlar una respuesta inmune exacerbada. La base fisiopatológica de este concepto es en modular la acción de células mononucleares, siendo el principal punto de control las células T. Estas drogas inhiben la función normal de protección del sistema inmune llevando a la aparición de complicaciones en las terapias de inmunosupresión. Las drogas inmunosupresoras tienen diferentes blancos en el proceso de inmunidad celular. Según su modo de acción pueden clasificarse en cuatro categorías: drogas antinflamatorias de la familia de los corticosteroides, inmunosupresoras específicas inhibidoras de la calcineurina, citotóxicas o antiproliferativas y anticuerpos específicos. En este trabajo describimos el mecanismo de acción molecular de agentes inmunosupresores tales como, esteroides, ciclosporina, tacrolimo, azatioprina, ciclofosfamida, sirolimus, mofetil mecofenolato, leflunomida y anticuerpos específicos, para contribuir a la comprensión de cómo utilizar y mejorar estos agentes.

A number of natural and synthetic substances are used in the treatment of immunological disorders. The immunosuppressive drugs are widely utilized in clinical treatments of autoimmune disorders, in the prevention of transplant rejection as well as in non-autoimmune diseases such as allergy. The design of immunosuppressive therapies is based on the control of the exacerbated immune response. The pathophysiologic mean of this concept is to modulate the action of mononuclear cells, being T cells the main targets. Immunosuppressive agents have different molecular targets, and an important drawback in their use is that they also inhibit the normal immune system response. Depending on their mode of action, immunosuppressive drugs can be classified in four different groups: antinflammatory drugs of the corticosteroid family, inhibitors of the calcineurin pathway, cytototoxic or antiproliferative drugs and specific antibodies. In this article, we focus on the molecular action of immunosuppressive drugs such as steroids, cyclosporine, tacrolimus, azathioprine, cyclophosphamide, sirolimus, mycophenolate mofetil, leflunomide and specific antibodies, providing data to characterize and improve the use of these agents.

[Molecular mechanisms of action of some immunosuppressive drugs]. / Mecanismos moleculares de acción de algunas drogas inmunosupresoras.

A number of natural and synthetic substances are used in the treatment of immunological disorders. The immunosuppressive drugs are widely utilized in clinical treatments of autoimmune disorders, in the prevention of transplant rejection as well as in non-autoimmune diseases such as allergy. The design of immunosuppressive therapies is based on the control of the exacerbated immune response. The pathophysiologic mean of this concept is to modulate the action of mononuclear cells, being T cells the main targets. Immunosuppressive agents have different molecular targets, and an important drawback in their use is that they also inhibit the normal immune system response. Depending on their mode of action, immunosuppressive drugs can be classified in four different groups: antinflammatory drugs of the corticosteroid family, inhibitors of the calcineurin pathway, cytototoxic or antiproliferative drugs and specific antibodies. In this article, we focus on the molecular action of immunosuppressive drugs such as steroids, cyclosporine, tacrolimus, azathioprine, cyclophosphamide, sirolimus, mycophenolate mofetil, leflunomide and specific antibodies, providing data to characterize and improve the use of these agents.

Glucocorticoids in the regulation of transcription factors that control cytokine synthesis.

The interaction at different levels between intracellular signals elicited by cytokines and activated glucocorticoid receptors (GR) is essential for the regulation of immune responses. We describe different levels of interaction between glucocorticoids and cytokines which result in the induction or repression of gene transcription. These include the regulation of cytokine receptor expression, the molecular cross-talk between the GR and transcription factors (TFs) activated by cytokine signaling, the interaction with several signaling pathways and also posttranslational modifications of both GR and TFs. Also, an overview of the implications of chromatin remodeling in this interplay is discussed. The complexity of the intricate network involved in the interaction between GR and TFs is pivotal for the final outcome of cytokines biological action.

The activated glucocorticoid receptor inhibits the transcription factor T-bet by direct protein-protein interaction.

Glucocorticoids (GCs) immunosuppression acts via regulation of several transcription factors (TF), including activating protein (AP)-1, NF-kappaB, and NFAT. GCs inhibit Th1 cytokines and promote a shift toward Th2 differentiation. Th1 phenotype depends on TF T-bet. In this study, we examined GC regulation of T-bet. We found that GCs inhibit T-bet transcriptional activity. We show that glucocorticoid receptor (GR) physically interacts with T-bet both in transfected cell lines and in primary splenocyte cultures with endogenous GR and T-bet. This interaction also blocks GR-dependent transcription. We show both in vitro and in vivo at endogenous binding sites that the mechanism underlying T-bet inhibition further involves reduction of T-bet binding to DNA. Using specific mutations of GR, we demonstrate that the first zinc finger region of GR is required for T-bet inhibition. GCs additionally inhibit T-bet both at mRNA and protein expression levels, revealing another layer of GR action on T-bet. Finally, we examined the functional consequences of GR/T-bet interaction on IFN-gamma, showing that GCs inhibit transcriptional activity of T-bet on its promoter. In view of the crucial role of T-bet in T cell differentiation and inflammation, we propose that GR inhibitory interaction with T-bet may be an important mechanism underlying the immunosuppressive properties of GCs.

Molecular understanding of cytokine-steroid hormone dialogue: implications for human diseases.

Highly sophisticated mechanisms confer upon the immune system the capacity to respond with a certain degree of autonomy. However, the final outcome of an adaptative immune response depends on the interaction with other systems of the organism. The immune-neuroendocrine systems have an intimate cross-communication, making possible a satisfactory response to environmental changes. Part of this interaction occurs through cytokines and steroid hormones. The last step of this crosstalk is at the molecular level. In this article we will focus on the physical and functional interrelationship between cytokine signaling pathway-activated transcription factors (TFs) and steroid receptors in different cell models, where the signals triggered by cytokines and steroid hormones have major roles: (1) the ligand-dependent-activated glucocorticoid receptor (GR) influence the genetic program that specifies lineage commitment in T helper (Th) cell differentiation. How posttranslational modifications of several TFs as well as nuclear hormone receptors could be implicated in the molecular crosstalk between the immune-neuroendocrine messengers is discussed. (2) glucocorticoid (GC) antagonism on the TCR-induced T cell apoptosis. (3) estrogen receptor/TGF-beta family proteins molecular interaction implicated on pituitary prolactinomas pathogenesis. The functional crosstalk at the molecular level between immune and steroids signals is essential to determine an integrative response to both mediators (which in the last instance results in a new gene activation/repression profile) and constitutes the ultimate integrative level of interaction between the immune and neuroendocrine systems.

Cytokine signaling/transcription factor cross-talk in T cell activation and Th1-Th2 differentiation.

The secretion of interleukin 2 (IL-2) is a key event in T cell activation. IL-2 allows T cells to enter into the S phase of the cell cycle and divide. After the activation phase takes place, T lymphocytes proliferate and differentiate to generate effector T cells. Thereby, T helper (Th) precursor cells, which are functionally immature, may become Th1 or Th2 effector cells. These subsets are responsible for cell-mediated immunity and humoral responses, respectively. Both T cell activation and Th differentiation are processes that depend on changes in the pattern of gene expression. The expression and changes in the genes responsible for these events are regulated by transcription factors. This review will focus on both the transcription factors involved in the control of IL-2 as well as those that are key to T helper differentiation.

Integrating systemic information at the molecular level: cross-talk between steroid receptors and cytokine signaling on different target cells.

An essential event in immune activation is the increase of cytokines in both plasma and immune tissues. Steroid hormones influence several adaptive responses in both health and disease. Cytokines and steroids have an intimate cross-communication in many systems, making possible a satisfactory adaptive response to environmental changes. The ultimate level of integration of the cytokine-steroids cross-talk is the molecular level. We have demonstrated this in four types of cross-talk mechanisms on different cells in which steroids have major roles: (1) The tumor necrosis factor (TNF)-glucocorticoid receptor (GR) transcriptional interaction in cellular targets of TNF-induced cytotoxicity. TNF potentiates the transactivation activity of GR and the priming with TNF increases the protective action of GR on TNF-induced cytotoxicity. (2) The GR-T cell receptor (TCR) antagonism in GR-TCR-induced T cell apoptosis and its modulation by cAMP. cAMP inhibits the TCR-induced apoptosis through a PKA-CREB-dependent mechanism and potentiates glucocorticoid-induced apoptosis by means of a CREB-independent mechanism. (3) The GR influence on Th1-Th2 cytokine expression and differentiation. Glucocorticoids inhibit the induction of GATA-3 and T-bet transcription factors. (4) The influence of ER/Smad-4 signaling cross-communication on prolactinoma pathogenesis. Physical and functional interactions between Smad-4 and estrogen receptors take place in prolactinoma cells, providing a molecular explanation to link the tumorigenic action of these two important players of prolactinoma pathogenesis. The molecular cross-talk between steroids and transcription factors is the mechanism that provides the basis for the outcome of adaptive responses integrating the systemic information provided by hormones and cytokines.