UMLS:C0406810 - FACTA Search

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Query: UMLS:C0406810 (NAME)
13,345 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The triazole antifungals myclobutanil, propiconazole and triadimefon cause varying degrees of hepatic toxicity and disrupt steroid hormone homeostasis in rodent in vivo models. To identify biological pathways consistently modulated across multiple timepoints and various study designs, gene expression profiling was conducted on rat livers from three separate studies with triazole treatment groups ranging from 6 h after a single oral gavage exposure, to prenatal to adult exposures via feed. To explore conservation of responses across species, gene expression from the rat liver studies were compared to in vitro data from rat and human primary hepatocytes exposed to the triazoles. Toxicogenomic data on triazoles from 33 different treatment groups and 135 samples (microarrays) identified thousands of probe sets and dozens of pathways differentially expressed across time, dose, and species--many of these were common to all three triazoles, or conserved between rodents and humans. Common and conserved pathways included androgen and estrogen metabolism, xenobiotic metabolism signaling through CAR and PXR, and CYP mediated metabolism. Differentially expressed genes included the Phase I xenobiotic, fatty acid, sterol and steroid metabolism genes Cyp2b2 and CYP2B6, Cyp3a1 and CYP3A4, and Cyp4a22 and CYP4A11; Phase II conjugation enzyme genes Ugt1a1 and UGT1A1; and Phase III ABC transporter genes Abcb1 and ABCB1. Gene expression changes caused by all three triazoles in liver and hepatocytes were concentrated in biological pathways regulating lipid, sterol and steroid homeostasis, identifying a potential common mode of action conserved between rodents and humans. Modulation of hepatic sterol and steroid metabolism is a plausible mode of action for changes in serum testosterone and adverse reproductive outcomes observed in rat studies, and may be relevant to human risk assessment.
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PMID:Toxicogenomic effects common to triazole antifungals and conserved between rats and humans. 1940 4

Nuclear xenobiotic receptor CAR activates transcription of the CYP2B6 gene by directly binding to the distal enhancer PB responsive enhancer module (PBREM). This CAR-mediated activation is synergized by transcription factors early growth response 1 (EGR1) and hepatocyte-enriched nuclear factor 4alpha (HNF4alpha) that bind to the proximal element OA response element KI (OARE(KI)) [Inoue, K., & Negishi, M. (2008). Nuclear receptor CAR requires early growth response 1 to activate the human cytochrome P450 2B6 gene. J. Biol. Chem. 283, 10425-10432]. Two additional EGR1 binding sites have now been found just downstream from PBREM. Internal deletion of EGR1 sites within the context of the -1.8 kb CYP2B6 promoter, which contains both PBREM and OARE(KI), revealed that the distal and proximal EGR1 sites are essential for EGR1 to synergize CAR-mediated transcription. Chromatin conformation capture 3C assays demonstrated that ERG1 may loop the distal PBREM towards the proximal OARE(KI) so that together, CAR and HNF4alpha synergistically activate the CYP2B6 promoter.
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PMID:Early growth response 1 loops the CYP2B6 promoter for synergistic activation by the distal and proximal nuclear receptors CAR and HNF4alpha. 1946 32

Energy balance is maintained by controlling both energy intake and energy expenditure. Thyroid hormones play a crucial role in regulating energy expenditure. Their levels are adjusted by a tight feedback-controlled regulation of thyroid hormone production/incretion and by their hepatic metabolism. Thyroid hormone degradation has previously been shown to be enhanced by treatment with phenobarbital or other antiepileptic drugs due to a CAR-dependent induction of phase II enzymes of xenobiotic metabolism. We have recently shown, that PPAR alpha agonists synergize with phenobarbital to induce another prototypical CAR target gene, CYP2B1. Therefore, it was tested whether a PPAR alpha agonist could enhance the phenobarbital-dependent acceleration of thyroid hormone elimination. In primary cultures of rat hepatocytes the apparent half-life of T3 was reduced after induction with a combination of phenobarbital and the PPAR alpha agonist WY14643 to a larger extent than after induction with either compound alone. The synergistic reduction of the half-life could be attributed to a synergistic induction of CAR and the CAR target genes that code for enzymes and transporters involved in the hepatic elimination of T3, such as OATP1A1, OATP1A3, UGT1A3 and UGT1A10. The PPAR alpha-dependent CAR induction and the subsequent induction of T3-eliminating enzymes might be of physiological significance for the fasting-induced reduction in energy expenditure by fatty acids as natural PPAR alpha ligands. The synergism of the PPAR alpha agonist WY14643 and phenobarbital in inducing thyroid hormone breakdown might serve as a paradigm for the synergistic disruption of endocrine control by other combinations of xenobiotics.
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PMID:Synergistic acceleration of thyroid hormone degradation by phenobarbital and the PPAR alpha agonist WY14643 in rat hepatocytes. 1963 Dec 32

Hepatocyte nuclear factor 4-alpha (HNF4alpha, NR2A1) is a nuclear receptor (NR) required for liver development and for controlling the expression of many hepatic-specific genes associated with important metabolic pathways. Many studies have also identified HNF4alpha as a direct transactivator of numerous xenobiotic-metabolizing cytochrome P450 (CYP) genes, suggesting that this factor is a global regulator which supports CYP transcription in the liver. Moreover, HNF4alpha expression displays a significant variability in human liver which may account for a proportion of the inter-individual variability in the expression of drug-metabolism genes and the clearance rate of a wide variety of prescribed drugs. In the last few years, a number of complex interactions and cross-talks between HNF4alpha and other transcription factors and coregulators have also surfaced, and the impact on CYP gene expression has been demonstrated. Thus, it is now clear that HNF4alpha modulates CYP expression in the liver by interacting with the xenosensor receptors (PXR and CAR), the glucocorticoid receptor (GR), the feeding-fasting cycle target PGC-1alpha, the sexual-dimorphism factor Stat5b, and other liver-enriched factors, such as C/EBPs. In addition to regulating drug elimination pathways, HNF4alpha also triggers pleiotropic effects on cholesterol and fatty acid metabolism, glucose homeostasis and inflammation. As a whole, current evidence indicates that HNF4alpha is a central regulator in the network of NRs that integrates drug-metabolism not only with the liver intermediate metabolism, but also with a number of patho-physiological conditions where the CYP expression is altered. The purpose of this review is to summarize and discuss these studies and their conclusions, with particular emphasis on the role of HNF4alpha in the regulation of drug-metabolizing CYP genes in the human liver.
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PMID:Transcriptional regulation of cytochrome p450 genes by the nuclear receptor hepatocyte nuclear factor 4-alpha. 1968 47

Constitutive androstane receptor CAR (NR1I3) has been identified as a central mediator of coordinate responses to xenobiotic and endobiotic stress. Here we use leptin-deficient mice (ob/ob) and ob/ob, CAR(-/-) double mutant mice to identify a metabolic role of CAR in type 2 diabetes. Activation of CAR significantly reduces serum glucose levels and improves glucose tolerance and insulin sensitivity. Gene expression analyses and hyperinsulinemic euglycemic clamp results suggest that CAR activation ameliorates hyperglycemia by suppressing glucose production and stimulating glucose uptake and usage in the liver. In addition, CAR activation dramatically improves fatty liver by both inhibition of hepatic lipogenesis and induction of beta-oxidation. We conclude that CAR activation improves type 2 diabetes, and that these actions of CAR suggest therapeutic approaches to the disease.
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PMID:Activation of nuclear receptor CAR ameliorates diabetes and fatty liver disease. 1985 Aug 73

Cholestasis results in the intrahepatic retention of cytotoxic bile acid and it can thus lead to liver injury and/or liver fibrosis. Cholestatic liver damage is counteracted by a variety of intrinsic hepatoprotective mechanisms including a complex network of drug metabolizing enzymes and transporters. During the last decade, much progress has been made in dissecting the mechanisms which regulate the hepatic xeno- and endobiotic metabolism by nuclear receptors. The xenobiotic receptors CAR and PXR are two important members of the NR1I nuclear receptor family. They function as sensors of toxic byproducts derived from the endogenous metabolism and of exogenous chemicals, in order to enhance their elimination. Ligands for both receptors, including phenobarbital, have already been used to treat cholestatic liver diseases before the mechanisms of these receptors were revealed. Furthermore, Yin Zhi Huang, a traditional Chinese herbal medicine, which has been used to prevent and treat neonatal jaundice, was identified to be a CAR ligand which also accelerates bilirubin clearance. Therefore, CAR and PXR have a protective effect on cholestasis by activating both detoxification enzymes and transporters. As a result, novel compounds targeting CAR and PXR with specific effects and fewer side effects will therefore be useful for the treatment of cholestatic liver diseases. This article will review the current knowledge on xenobiotic-sensing nuclear receptors CAR and PXR, while also discussing their potential role in the treatment of cholestatic liver diseases.
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PMID:Xenobiotic-sensing nuclear receptors CAR and PXR as drug targets in cholestatic liver disease. 1992 51

Cytochrome P450 1a1 (Cyp1a1) is a phase I xenobiotic-metabolizing enzyme, the expression of which is mainly driven by the aryl hydrocarbon receptor (AhR). Cyp1a1 messenger (m)RNA is labile. Our study indicates that 1-nitropyrene (1-NP) highly induced Cyp1a1 protein expression, although its induction of AhR transactivation activity was negligible. The fact that the nuclear receptors, CAR, FXR LXR, or PXR, did not induce Cyp1a1 expression indicates that they do not mediate 1-NP's action. When the AhR transcript was degraded by small hairpin (sh)RNA-AhR, 1-NP-induced Cyp1a1 expression largely decreased. In addition, 1-NP did not induce Cyp1a1 in AhR pathway-deficient mutant cells, which indicates that the AhR is essential for 1-NP's action. When Cyp1a1's turnover was examined, 1-NP was able to stabilize the 1-NP- and benzo[a]pyrene (BaP)-induced Cyp1a1 mRNA, but not protein. 1-NP-induced Cyp1a1 mRNA stabilization was mediated by Akt, but not by p38 MAPK, MEK1/2, or JNK. Among aryl hydrocarbons with four annealed phenyl rings, including pyrene, 1-NP, fluoranthene, 3-nitrofluoranthene, chrysene, and 6-nitrochrysene, only 1-NP was able to stabilize Cyp1a1 mRNA. 1-NP's action was gene specific. In conclusion, stabilizing Cyp1a1 mRNA greatly contributed to 1-NP-induced Cyp1a1 expression, which provides new insight into gene regulation by the AhR ligand and mRNA stabilization.
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PMID:1-Nitropyrene stabilizes the mRNA of cytochrome P450 1a1, a carcinogen-metabolizing enzyme, via the Akt pathway. 1996 Nov 61

The aryl hydrocarbon receptor (AHR) is a ligand-activated transcription factor involved in the regulation of multiple cellular pathways, such as xenobiotic metabolism and Th17 cell differentiation. Identification of key physiologically relevant ligands that regulate AHR function remains to be accomplished. Screening of indole metabolites has identified indoxyl 3-sulfate (I3S) as a potent endogenous ligand that selectively activates the human AHR at nanomolar concentrations in primary human hepatocytes, regulating transcription of multiple genes, including CYP1A1, CYP1A2, CYP1B1, UGT1A1, UGT1A6, IL6, and SAA1. Furthermore, I3S exhibits an approximately 500-fold greater potency in terms of transcriptional activation of the human AHR relative to the mouse AHR in cell lines. Structure-function studies reveal that the sulfate group is an important determinant for efficient AHR activation. This is the first phase II enzymatic product identified that can significantly activate the AHR, and ligand competition binding assays indicate that I3S is a direct AHR ligand. I3S failed to activate either CAR or PXR. The physiological importance of I3S lies in the fact that it is a key uremic toxin that accumulates to high micromolar concentrations in kidney dialysis patients, but its mechanism of action is unknown. I3S represents the first identified relatively high potency endogenous AHR ligand that plays a key role in human disease progression. These studies provide evidence that the production of I3S can lead to AHR activation and altered drug metabolism. Our results also suggest that prolonged activation of the AHR by I3S may contribute to toxicity observed in kidney dialysis patients and thus represent a possible therapeutic target.
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PMID:The uremic toxin 3-indoxyl sulfate is a potent endogenous agonist for the human aryl hydrocarbon receptor. 2000 May 89

Steatosis is the first step in the development of non-alcoholic fatty liver disease (NAFLD). However, the mechanisms involved in its pathogenesis are not fully understood. Many nuclear receptors (NRs) involved in energy homeostasis and biotransformation constitute a network connecting fatty acids, cholesterol and xenobiotic metabolisms; therefore, multiple NRs and their ligands may play a prominent role in liver fat metabolism and accumulation. In this study we have attempted to gain insight into the relevance of the NR superfamily in NAFLD by investigating the steatogenic potential of 76 different NR ligands in fatty acid overloaded human hepatocytes and hepatoma cells. Moreover, we have determined the mRNA expression level of 24 NRs to correlate the steatogenic potential of the ligands with the expression of their associated NRs in the cultured cells. Our results demonstrate that 18% of the examined NR ligands enhanced lipid accumulation in human hepatocytes and/or hepatoma cells. Among them, ligands of PPARgamma (e.g., thiazolidinediones), LXR (paxilline and 24(S),25-epoxycholesterol), PXR (hyperforin), CAR (3alpha,5alpha-androstenol), ERalpha (tamoxifen), FXR (Z-guggulsterone), VDR (25-hydroxyvitamin D3) and particular retinoids and farnesoids showed a significant pro-steatotic effect. The mRNA level of most of the NRs examined was well preserved in human hepatocytes, but HepG2 showed a deranged profile, where many of the receptors had a marginal or negligible level of expression in comparison with the human liver. By comparing the steatogenic effect of NR ligands with the NR expression levels, we conclude that LXR, PXR, RAR and PPARgamma ligands likely induce fat accumulation by a NR-dependent mechanism. Indeed, over-expression of PXR in HepG2 cells enhanced the steatogenic effect of hyperforin and rifampicin. However, the accumulation of fat induced by other ligands did not correlate with the expression of their associated NR. Our results also suggest that human hepatocytes cultured with free fatty acids offer a highly valuable in vitro system to investigate the pathogenesis and therapeutics of the human fatty liver.
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PMID:Enhanced steatosis by nuclear receptor ligands: a study in cultured human hepatocytes and hepatoma cells with a characterized nuclear receptor expression profile. 2007 22

In addition to their role in dietary lipid absorption bile acids are signaling modules activating nuclear receptors and at least one G-protein coupled receptors named the TGR5. With a different rank of potency primary and secondary bile acids activates a subset of nuclear receptors including the farnesoid-X-receptor (FXR, NR1H4); the constitutive androstane receptor (CAR, NR1H3), the pregnane-x- receptor (PXR, NR1H2), the vitamin D receptor (VDR, NR1H1). Originally, these receptors were characterized for their role as bile acid and xenobiotic sensors, emerging evidence, however, indicates that FXR, PXR and VDR and their ligands are important for the modulation of immune and inflammatory reactions in entero-hepatic tissues. The immune phenotype FXR deficient mice indicates that these receptors are essential for the maintenance of immune homeostasis. A common theme of all bile acid-activated receptor is their ability to counter-regulate effector activities of cells of innate immunity establishing that signals generated by these receptors and their ligands function as a braking signals for inflammation in entero-hepatic tissues. In this review, we will spotlight the molecular mechanisms of receptor/ligand function and how bile acid-activated receptors regulate the innate immunity in the gastrointestinal tract and liver. The ability of these receptors to integrate metabolic and inflammatory signaling makes them particularly attractive targets for intervention in immune-mediated diseases.
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PMID:Counter-regulatory role of bile acid activated receptors in immunity and inflammation. 2064 38

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