Endocrine disruptors targeting ERbeta function.

Endocrine disruptive chemicals (EDCs) circulating in the environment constitute a risk to ecosystems, wildlife and human health. Oestrogen receptor (ER) alpha and beta are targeted by various kinds of EDCs but the molecular mechanisms and long-term consequences of exposure are largely unknown. Some biological effects of EDCs are mediated by the aryl hydrocarbon receptor (AhR), which is a key player in the cellular defence against xenobiotic substances. Adding complexity to the picture, there is also accumulating evidence that AhR-ER pathways have an intricate interplay at multiple levels. In this review, we discuss some EDCs that affect the oestrogen pathway by targeting ERbeta. Furthermore, we describe some effects of AhR activities on the oestrogen system. Mechanisms as well as potential adverse effects on human health are discussed.

Biotransformation of genistein and bisphenol A in cell lines used for screening endocrine disruptors.

In vitro assays provide the opportunity for generating alerts for chemicals which interact with hormone receptors and are also valuable tools for mechanistic research. However, the limited capabilities of in vitro models to metabolically activate or inactivate xenobiotics may lead to misinterpretation of the in vitro data if such information is not taken into account. The aim of this study was to investigate the metabolic capabilities of human HepG2, human MCF7 and mouse HC11 cell lines used for testing endocrine disruptors (EDs) toward radiolabelled bisphenol A and genistein, two estrogenic compounds for which metabolic pathways in vivo as in vitro are well known. Incubations were performed during 12-48 h with 250.10(3) cells in 12 wells plates and 5-25 microM of substrates. The kinetics of formation of the metabolites were studied. Rat liver slices were used as reference for comparison with the metabolic capabilities of the cell lines. HC11 cells did not show any biotransformation capability while the major biotransformation pathways in HepG2 and MCF7 cells were conjugation to sulfate and to a lesser extent to glucuronic acid. We detected no phase I metabolite, even in rat liver slices. These results suggest that HC11 cells should be a valuable cellular system to study the intrinsic estrogenic activity of the tested compound, while HepG2 and MCF7 cells can help to take into account part of the metabolic fate of the tested compound that occur in vivo. However, since phase I enzymes are poorly or not at all expressed in these systems, their use in endocrine disruptor testing may result in false negative for compounds for which bioactivation is a prerequisite.

Differential usage of nuclear export sequences regulates intracellular localization of the dioxin (aryl hydrocarbon) receptor.

The dioxin receptor belongs to the basic helix-loop helix/Per-Arnt-Sim (bHLH)/PAS family of proteins and functions as a ligand-dependent transcription factor to activate target genes. The function of the PAS domain of the dioxin receptor is only partially understood. Whereas the C-terminal half of the PAS domain has been shown to harbor ligand binding activity and to function as an accessory dimerization interface, the precise functional role of the N-terminal half of the PAS domain remains unclear. We have previously shown that this domain confers dimerization specificity to the dioxin receptor. Here we report the identification and characterization of a novel nuclear export sequence (NES) motif, located in the N-terminal portion of the PAS domain, in addition to the previously identified NES in the bHLH domain. By point mutagenesis, we have generated a dominant positive form of the PAS domain NES motif that inhibits accumulation of the dioxin receptor in the nuclear compartment of the cell. This mutant form of the receptor was furthermore unable to sustain reporter gene activation. Importantly, we demonstrate that the ligand-free and ligand-occupied forms of the dioxin receptor differentially employ the two NES motifs. In the absence of ligand, nuclear export is sustained via the PAS domain NES, whereas following ligand-dependent activation nuclear export of the receptor is mediated by the NES in the bHLH domain.

The hsp90 chaperone complex regulates intracellular localization of the dioxin receptor.

The molecular chaperone complex hsp90-p23 interacts with the dioxin receptor, a ligand-dependent basic helix-loop-helix (bHLH)/Per-Arnt-Sim domain transcription factor. Whereas biochemical and genetic evidence indicates that hsp90 is important for maintenance of a high-affinity ligand binding conformation of the dioxin receptor, the role of hsp90-associated proteins in regulation of the dioxin receptor function remains unclear. Here we demonstrate that the integrity of the hsp90 complex characterized by the presence of the hsp90-associated cochaperone p23 and additional cochaperone proteins is important for regulation of the intracellular localization of the dioxin receptor by two mechanisms. First, in the absence of ligand, the dioxin receptor-hsp90 complex was associated with the immunophilin-like protein XAP2 to mediate cytoplasmic retention of the dioxin receptor. Second, upon exposure to ligand, the p23-associated hsp90 complex mediated interaction of the dioxin receptor with the nuclear import receptor protein pendulin and subsequent nuclear translocation of the receptor. Interestingly, these two modes of regulation target two distinct functional domains of the dioxin receptor. Whereas the nuclear localization signal-containing and hsp90-interacting bHLH domain of the receptor regulates ligand-dependent nuclear import, the interaction of the p23-hsp90-XAP2 complex with the ligand binding domain of the dioxin receptor was essential to mediate cytoplasmic retention of the ligand-free receptor form. In conclusion, these data suggest a novel role of the hsp90 molecular chaperone complex in regulation of the intracellular localization of the dioxin receptor.

The immunophilin-like protein XAP2 regulates ubiquitination and subcellular localization of the dioxin receptor.

The dioxin (aryl hydrocarbon) receptor is a ligand-dependent transcription factor that induces expression of a number of genes encoding drug metabolizing enzymes. The nonactivated form of the dioxin receptor is associated with heat shock protein (hsp) 90, the co-chaperone p23, and the immunophilin-like protein XAP2. Whereas hsp90 has a role in maintenance of the high-affinity ligand binding conformation of the dioxin receptor complex, and p23 stabilizes receptor-hsp90 interaction, the exact role of XAP2 is largely unknown. Here we show that XAP2 protected the ligand-free form of receptor against ubiquitination, resulting in increased dioxin receptor protein levels. Upon exposure to ligand, nuclear translocation of the dioxin receptor was markedly delayed by XAP2, indicating an additional role of XAP2 in regulation of the subcellular localization of the receptor by a mechanism of cytoplasmic retention. In order to mediate these effects, XAP2 required stable association with the hsp90-p23 molecular chaperone complex. The association of XAP2 as well as p23 with the dioxin receptor was determined by the functional state of hsp90. These data indicate a novel mode of regulation of dioxin receptor signaling by the hsp90-dependent molecular chaperone machinery.

A redox mechanism controls differential DNA binding activities of hypoxia-inducible factor (HIF) 1alpha and the HIF-like factor.

Hypoxia-inducible factor 1alpha (HIF-1alpha) and the HIF-like factor (HLF) are two highly related basic Helix-Loop-Helix/Per-Arnt-Sim (bHLH/PAS) homology transcription factors that undergo dramatically increased function at low oxygen levels. Despite strong similarities in their activation mechanisms (e.g. they both undergo rapid hypoxia-induced protein stabilization, bind identical target DNA sequences, and induce synthetic reporter genes to similar degrees), they are both essential for embryo survival via distinct functions during vascularization (HIF-1alpha) or catecholamine production (HLF). It is currently unknown how such specificity of action is achieved. We report here that DNA binding by HLF, but not by HIF-1alpha, is dependent upon reducing redox conditions. In vitro DNA binding and mammalian two-hybrid assays showed that a unique cysteine in the DNA-binding basic region of HLF is a target for the reducing activity of redox factor Ref-1. Although the N-terminal DNA-binding domain of HIF-1alpha can function in the absence of Ref-1, we found that the C-terminal region containing the transactivation domain requires Ref-1 for full activity. Our data reveal that the hypoxia-inducible factors are subject to complex redox control mechanisms that can target discrete regions of the proteins and are the first to establish a discriminating control mechanism for differential regulation of HIF-1alpha and HLF activity.

Evidence that the co-chaperone p23 regulates ligand responsiveness of the dioxin (Aryl hydrocarbon) receptor.

The dioxin (aryl hydrocarbon) receptor is a ligand-dependent transcription factor that induces expression of a number of genes encoding drug metabolizing enzymes. In the absence of ligand the dioxin receptor is present in the cytoplasmic compartment of the cell associated with the molecular chaperone hsp90, which has been implicated in regulating the correct folding of the ligand binding domain of the receptor. In this study we have examined a potential role of the hsp90-associated p23 protein in the activation process of the dioxin receptor to a DNA binding form. In an in vitro model we show that addition of ligand alone to the dioxin receptor fails to induce release of hsp90 from the dioxin receptor. In the presence of ligand, this release was, however, induced upon addition of purified preparations of Arnt. Interestingly, p23 was also found to be associated with the nonactivated form of the dioxin receptor. Following fractionation on sucrose gradients p23 was dissociated from the receptor-hsp90 complex generating a receptor form, which showed ligand-independent release of hsp90 by Arnt and, consequently, ligand-independent activation of the DNA binding activity of the dioxin receptor. Ligand dependence was reconstituted in the presence of molybdate, a transition metal ion known to stabilize the interaction between the molecular chaperone hsp90 and p23. Taken together these experiments suggest a role of p23 in modulating ligand responsiveness in the activation process of the dioxin receptor.

Role of the PAS domain in regulation of dimerization and DNA binding specificity of the dioxin receptor.

The dioxin receptor is a ligand-regulated transcription factor that mediates signal transduction by dioxin and related environmental pollutants. The receptor belongs to the basic helix-loop-helix (bHLH)-Per-Arnt-Sim (PAS) family of factors, which, in addition to the bHLH motif, contain a PAS region of homology. Upon activation, the dioxin receptor dimerizes with the bHLH-PAS factor Arnt, enabling the receptor to recognize xenobiotic response elements in the vicinity of target genes. We have studied the role of the PAS domain in dimerization and DNA binding specificity of the dioxin receptor and Arnt by monitoring the abilities of the individual bHLH domains and different bHLH-PAS fragments to dimerize and bind DNA in vitro and recognize target genes in vivo. The minimal bHLH domain of the dioxin receptor formed homodimeric complexes, heterodimerized with full-length Arnt, and together with Arnt was sufficient for recognition of target DNA in vitro and in vivo. In a similar fashion, only the bHLH domain of Arnt was necessary for DNA binding specificity in the presence of the dioxin receptor bHLH domain. Moreover, the bHLH domain of the dioxin receptor displayed a broad dimerization potential, as manifested by complex formation with, e.g. , the unrelated bHLH-Zip transcription factor USF. In contrast, a construct spanning the dioxin receptor bHLH domain and an N-terminal portion of the PAS domain failed to form homodimers and was capable of dimerizing only with Arnt. Thus, the PAS domain is essential to confer dimerization specificity of the dioxin receptor.

Activation of hypoxia-inducible factor 1alpha: posttranscriptional regulation and conformational change by recruitment of the Arnt transcription factor.

In response to hypoxia the hypoxia-inducible factor-1 (HIF-1) mediates transcriptional activation of a network of genes encoding erythropoietin, vascular endothelial growth factor, and several glycolytic enzymes. HIF-1 consists of a heterodimer of two basic helix-loop-helix PAS (Per/Arnt/Sim) proteins, HIF-1alpha and Arnt. HIF-1alpha and Arnt mRNAs are constitutively expressed and were not altered upon exposure of HeLa or HepG2 cells to hypoxia, suggesting that the activity of the HIF-1alpha-Arnt complex may be regulated by some as yet unknown posttranscriptional mechanism. In support of this model, we demonstrate here that Arnt protein levels were not increased under conditions that induce an hypoxic response in HeLa and HepG2 cells. However, under identical conditions, HIF-1alpha protein levels were rapidly and dramatically up-regulated, as assessed by immunoblot analysis. In addition, HIF-1alpha acquired a new conformational state upon dimerization with Arnt, rendering HIF-1alpha more resistant to proteolytic digestion in vitro. Dimerization as such was not sufficient to elicit the conformational change in HIF-1alpha, since truncated forms of Arnt that are capable of dimerizing with HIF-1alpha did not induce this effect. Moreover, the high affinity DNA binding form of the HIF-1alpha-Arnt complex was only generated by forms of Arnt capable of eliciting the allosteric change in conformation. In conclusion, the combination of enhanced protein levels and allosteric change by dimerization defines a novel mechanism for modulation of transcription factor activity.

A cellular factor stimulates ligand-dependent release of hsp90 from the basic helix-loop-helix dioxin receptor.

In response to dioxin, the nuclear basic helix-loop-helix (bHLH) dioxin receptor forms a complex with the bHLH partner factor Arnt that regulates target gene transcription by binding to dioxin-responsive sequence motifs. Previously, we have demonstrated that the latent form of dioxin receptor present in extracts from untreated cells is stably associated with molecular chaperone protein hsp90, and Arnt is not a component of this complex. Here, we used a coimmunoprecipitation assay to demonstrate that the in vitro-translated dioxin receptor, but not Arnt, is stably associated with hsp90. Although it showed ligand-binding activity, the in vitro-translated dioxin receptor failed to dissociate from hsp90 upon exposure to ligand. Addition of a specific fraction from wild-type hepatoma cells, however, to the in vitro-expressed receptor promoted dioxin-dependent release of hsp90. This stimulatory effect was mediated via the bHLH dimerization and DNA-binding motif of the receptor. Moreover, ligand-dependent release of hsp90 from the receptor was not promoted by fractionated cytosolic extracts from mutant hepatoma cells which are deficient in the function of bHLH dioxin receptor partner factor Arnt. Thus, our results provide a novel model for regulation of bHLH factor activity and suggest that derepression of the dioxin receptor by ligand-induced release of hsp90 may require bHLH-mediated concomitant recruitment of an additional cellular factor, possibly the structurally related bHLH dimerization partner factor Arnt. In support of this model, addition of in vitro-expressed wild-type Arnt, but not a mutated form of Arnt lacking the bHLH motif, promoted release of hsp90 from the dioxin receptor in the presence of dioxin.

Ligand-dependent recruitment of the Arnt coregulator determines DNA recognition by the dioxin receptor.

The intracellular basic region/helix-loop-helix (bHLH) dioxin receptor mediates signal transduction by dioxin (2,3,7,8-tetrachlorodibenzo-p-dioxin) and functions as a ligand-activated DNA binding protein directly interacting with target genes by binding to dioxin response elements. Here we show that the partially purified, ligand-bound receptor alone could not bind target DNA. In contrast, DNA binding by the receptor could be induced by addition of a cytosolic auxiliary activity which functionally and biochemically corresponded to the bHLH factor Arnt. While Arnt exhibited no detectable affinity for the dioxin response element in the absence of the dioxin receptor, it strongly promoted the DNA binding function of the ligand-activated but not the ligand-free receptor forms. Arnt also functionally reconstituted in vitro the DNA binding activity of a mutant, nuclear translocation-deficient dioxin receptor phenotype in cytosolic extracts from a dioxin-resistant hepatoma cell line. Importantly, coimmunoprecipitation experiments showed that Arnt physically interacted in solution with the ligand-activated dioxin receptor but failed to heterodimerize with the ligand-free, hsp90-associated receptor form. Mutational analysis suggested that the functional interaction between these two factors occurred via the bHLH motif of Arnt. These data suggest that dioxin receptor activity is governed by a complex pattern of combinatorial regulation involving repression by hsp90 and then by ligand-dependent recruitment of the positive coregulator Arnt. The dioxin receptor system also provides the first example of signal-controlled dimerization of bHLH factors.

Cross-coupling of signal transduction pathways: the dioxin receptor mediates induction of cytochrome P-450IA1 expression via a protein kinase C-dependent mechanism.

Signal transduction by dioxin (2,3,7,8-tetrachlorodibenzo-p-dioxin) is mediated by the intracellular dioxin receptor which, in its dioxin-activated state, regulates transcription of target genes encoding drug-metabolizing enzymes, such as cytochrome P-450IA1 and glutathione S-transferase Ya. Exposure of the dioxin receptor to dioxin leads to an apparent translocation of the receptor to the nucleus in vivo and to a rapid conversion of the receptor from a latent, non-DNA-binding form to a species that binds to dioxin-responsive positive control elements in vitro. This DNA-binding form of receptor appears to be a heterodimeric complex with the helix-loop-helix factor Arnt. In this study, we show that activation of the cytochrome P-450IA1 gene and minimal dioxin-responsive reporter constructs by the dioxin receptor was inhibited following prolonged treatment of human keratinocytes with the phorbol ester 12-O-tetradecanoylphorbol-13-acetate. Inhibition of the receptor-mediated activation response was also achieved by treatment of the cells with a number of protein kinase inhibitors, one of which, calphostin C, shows selectivity for protein kinase C. Taken together, these data suggest that protein kinase C-dependent phosphorylation may play an essential role in the dioxin signaling pathway. This hypothesis is supported by the observation that pretreatment of the cells with 12-O-tetradecanoylphorbol-13-acetate inhibited the DNA-binding activity of the dioxin receptor in vivo. In vivo, the dioxin receptor was found to be a phosphoprotein. In vitro, dephosphorylation of the ligand-activated, heteromeric dioxin receptor form or dephosphorylation of the individual ligand-binding and Arnt receptor subunits inhibited the xenobiotic response element-binding activity. Moreover, dephosphorylation experiments with the individual receptor subunits prior to assembly of the xenobiotic response element-binding receptor form indicated that phosphorylation seemed to be important for the DNA-binding activity per se of the receptor, whereas Arnt appeared to require phosphorylation to interact with the receptor. Finally, a protein kinase C inhibitor-sensitive cytosolic catalytic activity that could restore the DNA-binding activity of the dephosphorylated dioxin receptor form was identified.

Dual roles of the 90-kDa heat shock protein hsp90 in modulating functional activities of the dioxin receptor. Evidence that the dioxin receptor functionally belongs to a subclass of nuclear receptors which require hsp90 both for ligand binding activity and repression of intrinsic DNA binding activity.

Signal transduction by dioxin (2,3,7,8-tetrachloro-dibenzo-p-dioxin) is mediated by the intracellular dioxin receptor which, in its dioxin-activated state, regulates transcription of target genes encoding drug metabolizing enzymes such as cytochrome P-450IA1 and glutathione S-transferase Ya. Upon binding of dioxin the receptor translocates from the cytoplasm to the nucleus in vivo and is converted from a latent non-DNA binding form to a species which binds to dioxin-responsive positive control elements in vitro. The latent receptor form is associated with an inhibitory protein (the 90-kDa heat shock protein, hsp90), the release of which is necessary to unmask the DNA binding activity of the receptor. Here we have established a protocol to disrupt the hsp90-receptor complex in the absence of ligand. We show that it was possible to covalently cross-link with dioxin only the hsp90-associated form of dioxin receptor. In contrast, the disrupted hsp90-free form of receptor did not form a stable complex with dioxin but bound DNA constitutively. Moreover, we could partially reconstitute the ligand binding activity of the salt-disrupted hsp90-free dioxin receptor by incubation with hsp90-containing reticulocyte lysate but not by incubation with wheat germ lysate which lacks immuno-detectable levels of hsp90. Thus, we demonstrate that the dioxin receptor loses its high affinity ligand binding activity following release of hsp90 and that it is possible to reverse this process. In conclusion, hsp90 appears to play dual roles in the modulation of functional activities of the dioxin receptor: (i) it represses the intrinsic DNA binding activity of the receptor and (ii) it appears to determine the ability of the receptor to assume and/or maintain a ligand binding conformation.

Liver cells contain constitutive DNase I-hypersensitive sites at the xenobiotic response elements 1 and 2 (XRE1 and -2) of the rat cytochrome P-450IA1 gene and a constitutive, nuclear XRE-binding factor that is distinct from the dioxin receptor.

Dioxin stimulates transcription from the cytochrome P-450IA1 promoter by interaction with the intracellular dioxin receptor. Upon binding of ligand, the receptor is converted to a form which specifically interacts in vitro with two dioxin-responsive positive control elements located in close proximity to each other about 1 kb upstream of the rat cytochrome P-450IA1 gene transcription start point. In rat liver, the cytochrome P-450IA1 gene is marked at the chromatin level by two DNase I-hypersensitive sites that map to the location of the response elements and exist prior to induction of transcription by the dioxin receptor ligand beta-naphthoflavone. In addition, a DNase I-hypersensitive site is detected near the transcription initiation site and is altered in nuclease sensitivity by induction. The presence of the constitutive DNase I-hypersensitive sites at the dioxin response elements correlates with the presence of a constitutive, labile factor which specifically recognizes these elements in vitro. This factor appears to be distinct from the dioxin receptor, which is observed only in nuclear extract from treated cells. In conclusion, these data suggest that a certain protein-DNA architecture may be maintained at the response elements at different stages of gene expression.

Inhibition of the specific DNA binding activity of the dioxin receptor by phosphatase treatment.

The dioxin receptor stimulates transcription of the cytochrome P-450IA1 gene in response to dioxin. Exposure of the intracellular dioxin receptor to dioxin leads to a rapid conversion of the receptor from a latent form to a DNA binding species which specifically recognizes dioxin-responsive positive control elements in vitro. In this report, we show that treatment of in vivo or in vitro ligand-activated receptor with potato acid phosphatase significantly reduced or abolished its specific DNA binding activity. This effect was inhibited in the presence of sodium phosphate. In control experiments, the ligand-activated glucocorticoid receptor was not inactivated by phosphatase treatment. Moreover, phosphatase treatment did not induce any detectable degradation of covalently labeled dioxin receptor, arguing against protease contamination as a cause for receptor inactivation. Finally, phosphatase-inactivated dioxin receptor exhibited bona fide levels of ligand binding activity. Taken together, these data suggest that phosphorylation may regulate the DNA binding activity of the ligand-occupied dioxin receptor.

Assembly of a glucocorticoid receptor complex prior to DNA binding enhances its specific interaction with a glucocorticoid response element.

Gel retardation analysis with full- and half-palindromic sequences using partially purified glucocorticoid receptor (GR) resulted in GR-glucocorticoid response element (GRE) species of identical mobilities, suggesting that formation of the dimeric GR protein complex is not catalyzed by DNA binding. These results are in contrast to the behavior of the isolated DNA binding domain of the glucocorticoid receptor where dimerization occurred on the GRE. Density gradient centrifugation of cytosolic GR resulted in two forms, a 4 S peak characteristic of the monomeric GR and a fraction which sediments at 6 S which is consistent with the observed size of the dimeric GR. These two forms were found to differ in their ability to bind to specific DNA sequences with the 6 S species having a higher affinity for a GRE. Taken together our results are consistent with a two-step model for hormone-induced transformation of GR: dissociation of the multimeric untransformed complex and dimerization of the GR to yield a high affinity DNA binding species.