Suppression of DHEA sulfotransferase (Sult2A1) during the acute-phase response

The acute-phase response (APR) induces alterations in lipid metabolism, and our data suggest that this is associated with suppression of type II nuclear hormone receptors that are key regulators of fatty acid, cholesterol, and bile acid metabolism. Recently, the farnesoid X receptor (FXR), constitutive androstane receptor (CAR), and pregnane X receptor (PXR) were found to regulate DHEA sulfotransferase (Sult2A1), which plays an important role in DHEA sulfation and detoxification of bile acids. Because FXR, PXR, and CAR are suppressed during the APR, we hypothesized that Sult2A1 is downregulated during the APR. To induce the APR, mice were treated with LPS, which will then trigger the release of various cytokines, and the mRNA levels of Sult2A1 and the sulfate donor 3'-phosphoadenosine 5'-phosphosulfate synthase 2 (PAPSS2), as well as the enzyme activity of Sult2A1, were determined in the liver. We found that mRNA levels of Sult2A1 decrease in a time- and dose-dependent manner during the LPS-induced APR. Similar changes were observed in the mRNA levels of PAPSS2, the major synthase of PAPS in the liver. Moreover, hepatic Sult2A1 activity and serum levels of DHEA-sulfate (DHEA-S) were significantly decreased in LPS-treated animals. These results suggest that decreased levels or activities of FXR, PXR, and CAR during the APR could contribute to decreases in Sult2A1, resulting in decreased sulfation of DHEA and lower circulating level of DHEA-S. Finally, we found that both TNF and IL-1 caused a significant decrease in the mRNA level of Sult2A1 in Hep3B human hepatoma cells, suggesting that the proinflammatory cytokines TNF and IL-1 mediate the inhibitory effect of LPS on Sult2A1 mRNA level. Our study provides a possible mechanism by which infection and inflammation are associated with altered steroid metabolism and cholestasis.     

CAR and PXR: the xenobiotic-sensing receptors

The xenobiotic receptors CAR and PXR constitute two important members of the NR1I nuclear receptor family. They function as sensors of toxic byproducts derived from endogenous metabolism and of exogenous chemicals, in order to enhance their elimination. This unique function of CAR and PXR sets them apart from the steroid hormone receptors. In contrast, the steroid receptors, exemplified by the estrogen receptor (ER) and glucocorticoid receptor (GR), are the sensors that tightly monitor and respond to changes in circulating steroid hormone levels to maintain body homeostasis. This divergence of the chemical- and steroid-sensing functions has evolved to ensure the fidelity of the steroid hormone endocrine regulation while allowing development of metabolic elimination pathways for xenobiotics. The development of the xenobiotic receptors CAR and PXR also reflect the increasing complexity of metabolism in higher organisms, which necessitate novel mechanisms for handling and eliminating metabolic by-products and foreign compounds from the body. The purpose of this review is to discuss similarities and differences between the xenobiotic receptors CAR and PXR with the prototypical steroid hormone receptors ER and GR. Interesting differences in structure explain in part the divergence in function and activation mechanisms of CAR/PXR from ER/GR. In addition, the physiological roles of CAR and PXR will be reviewed, with discussion of interactions of CAR and PXR with endocrine signaling pathways.     

Identification by differential display of the IF1 inhibitor peptide of ATP synthase/ATPase as a gene inducible in rat liver by pregnenolone 16alpha-carbonitrile

The synthetic steroid, pregnenolone-16alpha-carbonitrile (PCN), activates hepatic metabolism and elimination of xenobiotics mediated by its interaction with the PXR, a nuclear receptor that binds PCN and such glucocorticoids as dexamethasone (Dex). We used mRNA differential display to define further the domain of genes under the control of PCN/PXR. We found 76 cDNA fragments representing mRNAs differentially expressed in the liver of rats treated with PCN or Dex. Sequence analysis of one of these revealed a PCN induced cDNA fragment as IF1, an inhibitor peptide of ATP synthase/ATPase complex. Northern blot analysis revealed that IF1 was detectable in untreated liver and was induced 2-3 fold following treatment with PCN. IF1 mRNA was not detected in lung, heart, kidney, or testes of control or PCN treated rats. We conclude that IF1 inhibitor peptide is a novel representative of an apparently large set of previously unrecognized genes coordinately controlled by the PCN/PXR system to maintain homeostasis during toxic stress.     

Ectopic expression of MHC class II genes (RT1.B(I) beta/alpha) in rat hepatocytes in vivo and in culture can be elicited by treatment with the pregnane X receptor agonists pregnenolone 16 alpha-carbonitrile and dexamethasone

The synthetic steroid, pregnenolone-16-alpha-carbonitrile (PCN), has served for decades as a probe for a postulated series of hepatic defenses activated under situations of environmental "stress". PCN, an antiglucocorticoid, and also such glucocorticoids as dexamethasone (Dex) appear to stimulate hepatic metabolism and elimination of xenobiotics by binding to the nuclear pregnane X receptor (PXR) which then interacts with a distinct DNA response element associated with induction of cytochrome P450 3A genes. To explore the full domain of genes controlled by PCN/PXR, we used differential display to detect rat liver mRNA species selectively induced by PCN or by Dex. Sequence analysis identified one of many PCN induced cDNA fragments as RT1.B(I)beta, a member of the major histocompatability class II (MHC) gene family usually found only in antigen presenting cells. Northern blot analysis of RNA from rat liver or from cultured hepatocytes confirmed that amounts of RT1.B(I)beta mRNA and also of its companion gene, RT1.B(I)alpha mRNA, became readily detectable within 3-6 hours following treatment with PCN or Dex, whereas no induction was observed in spleen RNA. Induction by PCN of RT1.B(I)beta immunoreactive protein was localized to the hepatocytes as judged by immunofluorescence. We conclude that ectopic expression of MHC II genes, an unprecedented effect of steroids or drugs, is rapidly evoked by PCN acting on the liver, directly. The concept of a set of genes coordinately controlled to maintain homeostasis in parenchymal tissues during toxic stress must now be extended to include the immune system.     

Inflammation and drug metabolism: NF-kappB and the CAR and PXR xeno-receptors

Decreased drug metabolism, hyperbilirubinemia and intrahepatic cholestasis are frequently observed during inflammation. Additionally, it has long been appreciated that exposure to drug metabolism-inducing xenobiotics can impair immune function. The nuclear receptor CAR (constitutive androstane receptor or NR1I3) and PXR (pregnane X receptor, NR1I2) control phase I (cytochrome P450 2B and 3A), phase II (GSTA, UGT1A1), and transporter (MDR1, SLC21A6, MRP2) genes involved in drugs metabolism, bile acids and bilirubin clearance in response to xenobiotics. It is well known that inflammation, through the activation of NF-kappaB pathway, leads to a decrease of CAR, PXR and RXRalpha expression and the expression of their target genes. In addition, a new study reveals the mutual repression between PXR and NF-kappaB signaling pathways, providing a molecular mechanism linking xenobiotic metabolism and inflammation.     

Identification of a novel human constitutive androstane receptor (CAR) agonist and its use in the identification of CAR target genes

The orphan nuclear constitutive androstane receptor (CAR) is proposed to play a central role in the response to xenochemical stress. Identification of CAR target genes in humans has been limited by the lack of a selective CAR agonist. We report the identification of 6-(4-chlorophenyl)imidazo[2,1-b][1,3]thiazole-5-carbaldehyde O-(3,4-dichlorobenzyl)oxime (CITCO) as a novel human CAR agonist with the following characteristics: (a) potent activity in an in vitro fluorescence-based CAR activation assay; (b) selectivity for CAR over other nuclear receptors, including the xenobiotic pregnane X receptor (PXR); (c) the ability to induce human CAR nuclear translocation; and (d) the ability to induce the prototypical CAR target gene CYP2B6 in primary human hepatocytes. Using primary cultures of human hepatocytes, the effects of CITCO on gene expression were compared with those of the PXR ligand rifampicin. The relative expression of a number of genes encoding proteins involved in various aspects of steroid and xenobiotic metabolism was analyzed. Notably, CAR and PXR activators differentially regulated the expression of several genes, demonstrating that these two nuclear receptors subserve overlapping but distinct biological functions in human hepatocytes.     

Transcriptional activation of cytochrome P450 CYP2C45 by drugs is mediated by the chicken xenobiotic receptor (CXR) interacting with a phenobarbital response enhancer unit

Cytochromes P450 (CYP)-2C enzymes fulfill an important role in xenobiotic metabolism and therefore have extensively been studied in rodents and humans. However, no CYP2C genes have been described in avian species to date. In this paper, we report the cloning, functional analysis, and regulation of chicken CYP2C45. The sequence shares up to 58% amino acid identity with CYP2Cs in other species. The overexpression of CYP2C45 in chicken hepatoma cells leghorn male hepatoma (LMH) led to increased scoparone metabolism. CYP2C45 regulation was studied in LMH cells at the mRNA level and in reporter gene assays using a construct containing 2.6 kb of its 5'-flanking region. Exposure of LMH cells to phenobarbital or metyrapone led to a 95- or 210-fold increase in CYP2C45 mRNA and a 140- or 290-fold increase in reporter gene expression, respectively. A phenobarbital response enhancer unit (PBRU) of 239 bp containing a DR-4 nuclear receptor binding site was identified within the 2.6-kb fragment. Site-specific mutation of the DR-4 revealed the requirement of this motif for CYP2C45 induction by drugs. The chicken xenobiotic receptor CXR interacted with the PBRU in electromobility shift and transactivation assays. Furthermore, the related nuclear receptors, mouse PXR and mouse CAR, transactivated this enhancer element, suggesting evolutionary conservation of nuclear receptor-DNA interactions in CYP2C induction.     

Selective activation of vitamin D receptor by lithocholic acid acetate, a bile acid derivative

The vitamin D receptor (VDR), a member of the nuclear receptor superfamily, mediates the biological actions of the active form of vitamin D, 1alpha,25-dihydroxyvitamin D(3). It regulates calcium homeostasis, immunity, cellular differentiation, and other physiological processes. Recently, VDR was found to respond to bile acids as well as other nuclear receptors, farnesoid X receptor (FXR) and pregnane X receptor (PXR). The toxic bile acid lithocholic acid (LCA) induces its metabolism through VDR interaction. To elucidate the structure-function relationship between VDR and bile acids, we examined the effect of several LCA derivatives on VDR activation and identified compounds with more potent activity than LCA. LCA acetate is the most potent of these VDR agonists. It binds directly to VDR and activates the receptor with 30 times the potency of LCA and has no or minimal activity on FXR and PXR. LCA acetate effectively induced the expression of VDR target genes in intestinal cells. Unlike LCA, LCA acetate inhibited the proliferation of human monoblastic leukemia cells and induced their monocytic differentiation. We propose a docking model for LCA acetate binding to VDR. The development of VDR agonists derived from bile acids should be useful to elucidate ligand-selective VDR functions.     

Rat pregnane X receptor: molecular cloning, tissue distribution, and xenobiotic regulation.

An orphan nuclear receptor, termed the pregnane X receptor (PXR), has recently been cloned from mouse and human and defines a novel steroid signaling pathway (Cell 92, 73-82, 1998; Proc. Natl. Acad. Sci. USA 95, 12208-122313, 1998). Transient cotransfection experiments demonstrate that the PXR responds to structurally dissimilar compounds and confers the induction of cytochrome P4503A (CYP3A), a subfamily of enzymes that involve the metabolism of two-thirds of drugs and other xenobiotics. In this report, we describe the molecular cloning, tissue distribution, and xenobiotic regulation of a rat PXR designated rPXR-1. rPXR-1 exhibits a 95% sequence identity with the mouse PXR, but only 79% identity with the human PXR, providing the molecular basis that rats and mice have a similar CYP3A induction profile but differ from humans. rPXR-1 gene was expressed abundantly in liver, intestine, and, to a lesser extent, kidney, lung, and stomach. The tissue distribution and the relative abundance of rPXR-1 mRNA among these tissues resemble those of CYP3A, suggesting that PXR is important not only for induction but also for constitutive expression of these enzymes. Xenobiotics known to induce liver microsomal enzymes showed differential effects on the rPXR-1 expression as determined by Northern blot analysis. Dexamethasone, for example, increased the accumulation of rPXR-1 mRNA, whereas troleandomycin slightly suppressed it. Compounds that increase PXR expression (inducers) and compounds that interact with PXR (ligands) likely have synergistic effects on CYP3A induction, which provides a novel molecular explanation for drug-drug interactions.     

Crystal structure of the pregnane X receptor-estradiol complex provides insights into endobiotic recognition

The human nuclear pregnane X receptor (PXR) responds to a wide variety of xenobiotic and endobiotic compounds, including pregnanes, progesterones, corticosterones, lithocholic acids, and 17beta-estradiol. In response to these ligands, the receptor controls the expression of genes central to the metabolism and excretion of potentially harmful chemicals from both exogenous and endogenous sources. Although the structural basis of PXR's interaction with small and large xenobiotics has been examined, the detailed nature of its binding to endobiotics, including steroid-like ligands, remains unclear. We report the crystal structure of the human PXR ligand-binding domain (LBD) in complex with 17beta-estradiol, a representative steroid ligand, at 2.65 A resolution. Estradiol is found to occupy only one region of PXR's expansive ligand-binding pocket, leaving a notable 1000 A3 of space unoccupied, and to bridge between the key polar residues Ser-247 and Arg-410 in the PXR LBD. Positioning the steroid scaffold in this way allows it to make several direct contacts to alphaAF of the receptor's AF-2 region. The PXR-estradiol complex was compared with that of other nuclear receptors, including the estrogen receptor, in complexes with analogous ligands. It was found that PXR's placement of the steroid is remarkably distinct relative to other members of the nuclear receptor superfamily. Using the PXR-estradiol complex as a guide, the binding of other steroid- and cholesterol-like molecules was then considered. The results provide detailed insights into the manner in which human PXR responds to a wide range of endobiotic compounds.     

Involvement of the xenobiotic response element (XRE) in Ah receptor-mediated induction of human UDP-glucuronosyltransferase 1A1

UDP-glucuronosyltransferase 1A1 (UGT1A1) plays an important physiological role by contributing to the metabolism of endogenous substances such as bilirubin in addition to xenobiotics and drugs. The UGT1A1 gene has been shown to be inducible by nuclear receptors steroid xenobiotic receptor (SXR) and the constitutive active receptor, CAR. In this report, we show that in human hepatoma HepG2 cells the UGT1A1 gene is also inducible with aryl hydrocarbon receptor (Ah receptor) ligands such as 2,3,7,8-tetrachlodibenzo-p-dioxin (TCDD), beta-naphthoflavone, and benzo[a]pyrene metabolites. Induction was monitored by increases in protein and catalytic activity as well as UGT1A1 mRNA. To examine the molecular interactions that control UGT1A1 expression, the gene was characterized and induction by Ah receptor ligands was regionalized to bases -3338 to -3287. Nucleotide sequence analysis of this UGT1A1 enhancer region revealed a xenobiotic response element (XRE) at -3381/-3299. The dependence of the XRE on UGT1A1-luciferase activity was demonstrated by a loss of Ah receptor ligand inducibility when the XRE core region (CACGCA) was deleted or mutated. Gel mobility shift analysis confirmed that TCDD induction of nuclear proteins specifically bound to the UGT1A1-XRE, and competition experiments with Ah receptor and Arnt antibodies demonstrated that the nuclear protein was the Ah receptor. These observations reveal that the Ah receptor is involved in human UGT1A1 induction.     

Impairment of Bilirubin Clearance and Intestinal Interleukin-6 Expression in Bile Duct-Ligated Vitamin D Receptor Null Mice

The vitamin D receptor (VDR) mediates the physiological and pharmacological actions of 1α,25-dihydroxyvitamin D₃ in bone and calcium metabolism, cellular growth and differentiation, and immunity. VDR also responds to secondary bile acids and belongs to the NR1I subfamily of the nuclear receptor superfamily, which regulates expression of xenobiotic metabolism genes. When compared to knockout mouse investigations of the other NR1I nuclear receptors, pregnane X receptor and constitutive androstane receptor, an understanding of the role of VDR in xenobiotic metabolism remains limited. We examined the effect of VDR deletion in a mouse model of cholestasis. We performed bile duct ligation (BDL) on VDR-null mice and compared blood biochemistry, mRNA expression of genes involved in bile acid and bilirubin metabolism, cytokine production, and expression of inflammatory regulators with those of wild-type mice. VDR-null mice had elevated plasma conjugated bilirubin levels three days after BDL compared with wild-type mice. Urine bilirubin levels and renal mRNA and/or protein expression of multidrug resistance-associated proteins 2 and 4 were decreased in VDR-null mice, suggesting impaired excretion of conjugated bilirubin into urine. While VDR-null kidney showed mRNA expression of interleukin-6 (IL-6) after BDL and VDR-null macrophages had higher IL-6 protein levels after lipopolysaccharide stimulation, the induction of intestinal Il6 mRNA expression and plasma IL-6 protein levels after BDL was impaired in VDR-null mice. Immunoblotting analysis showed that expression of an immune regulator, IκBα, was elevated in the jejunum of VDR-null mice, a possible mechanism for the attenuated induction of Il6 expression in the intestine after BDL. Increased expression of IκBα may be a consequence of compensatory mechanisms for VDR deletion. These results reveal a role of VDR in bilirubin clearance during cholestasis. VDR is also suggested to contribute to tissue-selective immune regulation.