QSAR modeling of different minimum potency levels for in vitro human CAR activation and inhibition and screening of 80,086 REACH and 54,971 U.S. substances

K.K Chinen,K Klimenko,C Taxvig,N.G Nikolov,E.B Wedebye

doi:10.1016/j.comtox.2020.100121

Abstract

The human Constitutive Androstane Receptor (hCAR) is together with the human Pregnane X Receptor (hPXR) a key regulator of the metabolism and excretion of xenobiotics and endogenous compounds. Inhibition or activation of hCAR by xenobiotics can alter protein expression, leading to decreased or enhanced turnover of both xenobiotics and endogenous substances. Impacts from these alternations can potentially disturb physiological homeostasis and cause adverse effects. Tens-of-thousands of manufactured substances of which humans are potentially exposed are not tested for their potential to inhibit or activate hCAR. In this study, the U.S. Toxicology in the 21st Century (Tox21) high-throughput in vitro assay results for hCAR inhibition and activation were used in a comprehensive in-house process to derive training sets for different potency cut-offs, and to develop suites of quantitative structure–activity relationship (QSAR) models with binary outputs. Final, expanded models, which include substances from the external validation sets, were developed for select minimum potency levels. Rigorous cross- and external validations demonstrated good predictive accuracies for the models. The final models were applied to screen 80,086 EU and 54,971 U.S. substances, and the models predicted around 60% of the substances within their respective applicability domains (AD). Finally, statistical comparisons of hCAR predictions and QSAR predictions for a number of other endpoints related to e.g. Pregnane X, aryl hydrocarbon, estrogen and androgen receptors, as well as genotoxicity, cancer, sensitization and teratogenicity from the Danish (Q)SAR database were made to explore possible implications related to hCAR antagonists and agonists. The final models from this study will be made available in the free Danish (Q)SAR Models website. Predictions made with models from this study for 650,000 substances will be made available in the free Danish (Q)SAR Database. Predictions from the models developed in this study can for example contribute to priority setting, read-across cases and weight-of-evidence assessments of chemicals.

Highlights

The constitutive androstane receptor (CAR) belongs to the human nuclear receptor (NR) superfamily, a 48-member group [1,2] of “orphan” and “adopted-orphan” NRs [3,4,5]
We developed a set of criteria, which we applied to process the data for our quantitative structure–activity relationship (QSAR) model development, including setting a minimum absolute effect which should be seen at a maximum concentration threshold and which should occur at a non-cytotoxic concentration
In this study we developed and validated QSAR models for human Constitutive Androstane Receptor (hCAR) antagonism and hCAR agonism for a number of different effect concentration thresholds and used final expanded models for 25% absolute effect at maximum 20 μM and 50 μM to screen 80,086 REACH substances and 54,971 U.S United States Environmental Protection Agency (EPA) substances for hCAR antagonism and agonism

Summary

Introduction

The constitutive androstane receptor (CAR) belongs to the human nuclear receptor (NR) superfamily, a 48-member group [1,2] of “orphan” and “adopted-orphan” NRs [3,4,5]. The CAR protein is encoded by the NR1I3 gene from the NR subfamily 1, group I, member 3. CAR is expressed mainly in the liver and small intestine [1,3,13] and mediates the induction of metabolizing enzymes, such as cytochrome P450 3A (CYP3A) isoenzymes, conjugation enzymes such as UDP glucuronosyltransferase family 1 member A1, and transporters such as P-glycoprotein [14,15,16,17]. Along with the NR PXR, CAR is a principal regulator of the metabolism of xenobiotic compounds [16,18,19]. PXR and CAR cross-regulate their target genes cytochrome P450 (CYP) CYP2B and CYP3A [20]. CAR plays an important role in the metabolism of a number of endogenous substances such as thyroid and steroid hormones, cholesterol, bile acids, bilirubin, glucose, and lipids [16,19]

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