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Cellular levels and molecular dynamics simulations of estragole DNA adducts point at inefficient repair resulting from limited distortion of the double-stranded DNA helix

Shuo Yang, Matthias Diem, Jakob Liu, Sebastiaan Wesseling, Jacques Vervoort, Chris Oostenbrink, Ivonne M.C.M. Rietjens

2020Archives of Toxicology13 citationsDOIOpen Access PDF

Abstract

Abstract Estragole, naturally occurring in a variety of herbs and spices, can form DNA adducts after bioactivation. Estragole DNA adduct formation and repair was studied in in vitro liver cell models, and a molecular dynamics simulation was used to investigate the conformation dependent (in)efficiency of N 2 -( trans -isoestragol-3′-yl)-2′-deoxyguanosine (E-3′- N 2 -dG) DNA adduct repair. HepG2, HepaRG cells, primary rat hepatocytes and CHO cells (including CHO wild-type and three NER-deficient mutants) were exposed to 50 μM estragole or 1′-hydroxyestragole and DNA adduct formation was quantified by LC–MS immediately following exposure and after a period of repair. Results obtained from CHO cell lines indicated that NER plays a role in repair of E-3′- N 2 -dG adducts, however, with limited efficiency since in the CHO wt cells 80% DNA adducts remained upon 24 h repair. Inefficiency of DNA repair was also found in HepaRG cells and primary rat hepatocytes. Changes in DNA structure resulting from E-3′- N 2 -dG adduct formation were investigated by molecular dynamics simulations. Results from molecular dynamics simulations revealed that conformational changes in double-stranded DNA by E-3′- N 2 -dG adduct formation are small, providing a possible explanation for the restrained repair, which may require larger distortions in the DNA structure. NER-mediated enzymatic repair of E-3′- N 2 -dG DNA adducts upon exposure to estragole will be limited, providing opportunities for accumulation of damage upon repeated daily exposure. The inability of this enzymatic repair is likely due to a limited distortion of the DNA double-stranded helix resulting in inefficient activation of nucleotide excision repair.

Topics & Concepts

EstragoleDNADNA repairAdductChemistryDNA adductDNA damageBiochemistryMolecular biologyBiophysicsBiologyOrganic chemistryEssential oilChromatographyDNA Repair MechanismsCancer therapeutics and mechanismsDrug Transport and Resistance Mechanisms
Cellular levels and molecular dynamics simulations of estragole DNA adducts point at inefficient repair resulting from limited distortion of the double-stranded DNA helix | Litcius