Multiscale QM/MM Molecular Dynamics Study on the First Steps of Guanine Damage by Free Hydroxyl Radicals in Solution

Abolfath, Ramin M.; Biswas, Pradip Kumar; Rajnarayanam, R.; Brabec, Thomas; Kodym, Reinhard; Papież, Lech

doi:10.1021/jp300258n

Cited by 52 publications

(67 citation statements)

References 40 publications

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“…2 reveals more details on H 2 O 2 formation and their lower reactivity with DNA-molecule. Consistent with our recent QM/MM calculation in the solution 15 , we observe that because of the hydrogen bond network forming between OH-radicals and water molecules the time for hydrogen abstraction is longer compare to similar simulation in vacuum.…”

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confidence: 90%

“…Recently ab-initio simulations of the hydrogen abstraction were developed [11][12][13][14][15] . However realistic modeling of DNA molecule with its environment requires extensive computer resources and is a major draw-back of QM methods.…”

mentioning

confidence: 99%

“…However realistic modeling of DNA molecule with its environment requires extensive computer resources and is a major draw-back of QM methods. The DFT calculation for hydrogen abstraction in vacuum is limited to the initial damage of a single base [11][12][13] or single sugar-moiety 15 . Despite recent advances in QM/MM methods that allows simulation of larger molecules 14 and inclusion of solvation 15 , the real time simulation of DNA-damage remains still elusive.…”

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confidence: 99%

“…The oxygen from OH radical weaken the C-N bond that attaches the sugar-moiety with the nucleotide-base. To investigate such possibility and the consistency of ReaxFF with DFT, we employed an ab-initio CPMD calculation in vacuum as well as a QMMM CPMD-GROMACS that allows adding realistic solution 15 . The results are shown in Fig.…”

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Reactive Molecular Dynamics Study on the First Steps of DNA Damage by Free Hydroxyl Radicals

2011

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We employ a large scale molecular simulation based on bond-order ReaxFF to simulate the chemical reaction and study the damage to a large fragment of DNA-molecule in the solution by ionizing radiation. We illustrate that the randomly distributed clusters of diatomic OH-radicals that are primary products of megavoltage ionizing radiation in water-based systems are the main source of hydrogen-abstraction as well as formation of carbonyl-and hydroxyl-groups in the sugar-moiety that create holes in the sugar-rings. These holes grow up slowly between DNA-bases and DNA-backbone and the damage collectively propagate to DNA single and double strand break.PACS numbers: 87.64.Aa It is known that megavoltage radiation (X/γ-rays, α-particles, and heavy ions) ionizes the water molecule and creates neutral free-radicals and aqueous electrons 1-9 . In particular OH-radicals with a very short life-time that is reported to be within nano-seconds 10 , are major contributors to the single/double strand breaking of the DNA molecules and the nucleotide-base damage, as 2/3 of environment surrounding DNA molecules in the cell-nucleus is composed of water molecules 4 . Various effects of the ionizing radiation on biological systems that ranges from the development of genetic aberrations, carcinogenesis to aging, have attributed to the role of free radicals.Computational modeling is a valuable tool in understanding the basic mechanisms that underlie DNA damage. Great effort has been devoted to the statistical modeling of the damage sites based on Monte-Carlo (MC) sampling, using empirical reaction rates and radiation scattering cross-sections 4-9 . These models are limited to MC sampling on a static structure of DNA or dynamical models based on molecular-mechanics (MM) and empirical force-fields (FF), e.g. AMBER/CHARMM FF, that are developed for simulation of the non-reactive aspects of bio-molecules.The reactive aspects and the time evolution of the multi-site DNA damages driven by cascade of chemical reactions, that are beyond MM methods and empirical FF, require the calculation of the potential energies onthe-fly using first-principle quantum mechanical (QM) models. Recently ab-initio simulations of the hydrogen abstraction were developed 11-15 . However realistic modeling of DNA molecule with its environment requires extensive computer resources and is a major draw-back of QM methods. The DFT calculation for hydrogen abstraction in vacuum is limited to the initial damage of a single base [11][12][13] or single sugar-moiety 15 . Despite recent advances in QM/MM methods that allows simulation of larger molecules 14 and inclusion of solvation 15 , the real time simulation of DNA-damage remains still elusive.To address the above considerations regarding to the large scale modeling of DNA-damage, we have studied the evolution of randomly distributed hydroxyl-radicals in small pockets surrounding the DNA-molecule at room temperature using molecular dynamics simulations where the atomic interactions are described by the reactive force f...

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confidence: 99%

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confidence: 99%

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Reactive Molecular Dynamics Study on the First Steps of DNA Damage by Free Hydroxyl Radicals

2011

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“…Classical molecular mechanics (MM) and MD simulations cannot consider the effect of electrons and spins explicitly, so that these classical simulations cannot properly describe the reaction mechanism controlled by radicals. Recently, theoretical studies based on ab initio molecular orbital (MO) calculations were carried out [10][11][12][13][14][15]. However, these studies were performed only on the DNA bases, and there is no MO or density functional theory (DFT) calculation investigating the difference in the reaction mechanism between G-C and A-T base pairs induced by OH and H radicals.…”

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DFT study on the attacking mechanisms of H and OH radicals to G-C and A-T base pairs in water

Okutsu¹,

Shimamura²,

Shimizu³

et al. 2016

AIP Conference Proceedings

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Improvement of cross-tension strength using concave electrode in resistance spot welding of high-strength steel sheets AIP Conference Proceedings 1709, 020003 (2016) Abstract.To elucidate the effect of radicals on DNA base pairs, we investigated the attacking mechanism of OH and H radicals to the G-C and A-T base pairs, using the density functional theory (DFT) calculations in water approximated by the continuum solvation model. The DFT calculations revealed that the OH radical abstracts the hydrogen atom of a NH 2 group of G or A base and induces a tautomeric reaction for an A-T base pair more significantly than for a G-C base pair. On the other hand, the H radical prefers to bind to the Cytosine NH 2 group of G-C base pair and induce a tautomeric reaction from G-C to G*-C*, whose activation free energy is considerably small (-0.1 kcal/mol) in comparison with that (42.9 kcal/mol) for the reaction of an A-T base pair. Accordingly, our DFT calculations elucidated that OH and H radicals have a significant effect on A-T and G-C base pairs, respectively. This finding will be useful for predicting the effect of radiation on the genetic information recorded in the base sequences of DNA duplexes.

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Molecular Modeling of Nucleic Acid Structure: Energy and Sampling

Cheatham

Brooks

Kollman

2001

CP Nucleic Acid Chemistry

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Multiscale QM/MM Molecular Dynamics Study on the First Steps of Guanine Damage by Free Hydroxyl Radicals in Solution

Cited by 52 publications

References 40 publications

Reactive Molecular Dynamics Study on the First Steps of DNA Damage by Free Hydroxyl Radicals

Reactive Molecular Dynamics Study on the First Steps of DNA Damage by Free Hydroxyl Radicals

DFT study on the attacking mechanisms of H and OH radicals to G-C and A-T base pairs in water

Molecular Modeling of Nucleic Acid Structure: Energy and Sampling

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