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RESEARCH PRODUCT
Free energy profiles for two ubiquitous damaging agents: methylation and hydroxylation of guanine in B-DNA
Elise DumontRaymond GrüberIñaki TuñónA. BelliliJuan Arandasubject
0301 basic medicineGuanineGuanineDNA damageStereochemistryEntropyGeneral Physics and Astronomy010402 general chemistryHydroxylation01 natural sciencesHydroxylation03 medical and health scienceschemistry.chemical_compoundComputational chemistry[CHIM.ANAL]Chemical Sciences/Analytical chemistryPhysical and Theoretical ChemistryExergonic reactionchemistry.chemical_classificationHydroxyl RadicalBiomoleculeDNA Methylation0104 chemical sciences030104 developmental biologychemistryEnergy TransferDNA methylationHydroxyl radicalDNA B-Form[CHIM.RADIO]Chemical Sciences/RadiochemistryDNAdescription
International audience; DNA methylation and hydroxylation are two ubiquitous reactions in DNA damage induction, yet insights are scarce concerning the free energy of activation within B-DNA. We resort to multiscale simulations to investigate the attack of a hydroxyl radical and of the primary diazonium onto a guanine embedded in a solvated dodecamer. Reaction free energy profiles characterize two strongly exergonic processes, yet allow unprecedented quantification of the barrier towards this damage reaction, not higher than 6 kcal mol−1 and sometimes inexistent, and of the exergonicities. In the case of the [G(C8)-OH]˙ intermediate, we challenge the functional dependence of such simulations: recently-proposed functionals, such as M06-2X and LC-BLYP, agree on a ∼4 kcal mol−1 barrier, whereas the hybrid GGA B3LYP functional predicts a barrier-less pathway. In the long term, multiscale approaches can help build up a unified panorama of DNA lesion induction. These results stress the importance of DFT/MM-MD simulations involving new functionals towards the sound modelling of biomolecule damage even in the ground state.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2017-05-26 |