The Role of Proton Transfer on Mutations

Srivastava, Ruby

doi:10.3389/fchem.2019.00536

Cited by 46 publications

(37 citation statements)

References 189 publications

(223 reference statements)

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“…The ability to display the contribution of intra- and inter-molecular variation of the charge density following inner shell ionization provides valuable information on the stability of hydrogen-bonded biomolecules, like for example DNA base pairs in interaction with a damaging radiation. It is indeed known that charge transfer via hydrogen bond, like for example the transport of the protons, can lead to induced and spontaneous mutations 13 , 14 .…”

Section: Discussionmentioning

confidence: 99%

Unravelling molecular interactions in uracil clusters by XPS measurements assisted by ab initio and tight-binding simulations

Mattioli

Avaldi

Bolognesi

et al. 2020

Sci Rep

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The C, N and O 1s XPS spectra of uracil clusters in the gas phase have been measured. A new bottom-up approach, which relies on computational simulations starting from the crystallographic structure of uracil, has been adopted to interpret the measured spectra. this approach sheds light on the different molecular interactions (H-bond, π-stacking, dispersion interactions) at work in the cluster and provides a good understanding of the observed XPS chemical shifts with respect to the isolated molecule in terms of intramolecular and intermolecular screening occurring after the corehole ionization. the proposed bottom-up approach, reasonably expensive in terms of computational resources, has been validated by finite-temperature molecular dynamics simulations of clusters composed of up to fifty molecules.

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Section: Discussionmentioning

confidence: 99%

Unravelling molecular interactions in uracil clusters by XPS measurements assisted by ab initio and tight-binding simulations

Mattioli

Avaldi

Bolognesi

et al. 2020

Sci Rep

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“…[45] Proton transfer is also observed, at low temperature, in cationic adenine-thymine stacks,i nitiating important competition to catch the protonb y different electron lone pairs in the surrounding environment. [24] The role of water molecules wasp ut forwarda st he triggering factor leading to proton transfer,e ven if the precise molecular mechanism and the role of hydration were not completely analyzed.R ecently,t he photo-oxidation and quenching of guanine radical cations in aG -quadruplex environment has also been studied by QM/MM dynamics at multiconfiguration level. More specifically,apreference for the deprotonation of the imino protono faguanine in the loop has been observed, which is coherent with the fact that the deprotonation appears to be facilitated for moietiest hat are not engaged in hydrogen bonds with other nucleobases.…”

Section: Resultsmentioning

confidence: 99%

“…These include protone xchanges in the hydrogen-bonded nucleobases, leading to the formationo f' rare tautomers'. [24] Notably,Z engtao et al observed that proton trans-fer at low temperatures is assisted by water through displacement polarization and oriented polarization mechanisms. [25] Particular attention has been devoted in the past to chemical reactions triggered under the ionization of DNA nucleobases.…”

Section: Introductionmentioning

confidence: 99%

DNA Nucleobase under Ionizing Radiation: Unexpected Proton Transfer by Thymine Cation in Water Nanodroplets

Semmeq

Badawi

Hasnaoui

et al. 2020

Chemistry A European J

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The effect of ionizing radiation on DNA constituents is a widely studied fundamental process using experimental and computational techniques. In particular, radiation effects on nucleobases are usually tackled by mass spectrometry in which the nucleobase is embedded in a water nanodroplet. Here, we present a multiscale theoretical study revealing the effects and the dynamics of water droplets towards neutral and ionized thymine. In particular, by using both hybrid quantum mechanics/molecular mechanics and full ab initio molecular dynamics, we reveal an unexpected proton transfer from thymine cation to a nearby water molecule. This leads to the formation of a neutral radical thymine and a Zundel structure, while the hydrated proton localizes at the interface between the deprotonated thymine and the water droplet. This observation opens entirely novel perspectives concerning the reactivity and further fragmentation of ionized nucleobases.

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“…Since the Löwdin works [26][27][28][29] , which suggested that the genetic code stored in the DNA depends upon the stability of the hydrogen-bonded base pairs and the transport of the protons along these hydrogen bonds, several important works were devoted to understanding the endogenous spontaneous DNA mutations which origin is not yet elucidated. These include proton exchanges in the hydrogenbonded nucleobases leading to the formation of "rare tautomers" 30 . Notably, Zengtao et al observed that proton transfer at low temperatures is assisted by water through displacement polarization and oriented polarization mechanisms.…”

mentioning

confidence: 99%

“…Proton transfer is also observed, at low temperature, in cationic adenine-thymine stacks, initiating important competition to catch the proton by different electron lone pairs in the surrounding environment 30 . Although, the role of water molecules was put forward as the triggering-factor leading to proton transfer, the precise molecular mechanism and the role of hydration were not completely analyzed.…”

mentioning

confidence: 99%

DNA Nucleobase Under Ionizing Radiation: Unexpected Proton Transfer by Thymine Cation in Water Nanodroplets

Semmeq

Badawi

Hasnaoui

et al. 2020

Preprint

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<p>The effects of ionizing radiation on DNA constituents is a widely studied fundamental process using experimental and computational techniques. In particular radiation effects on nucleobases are usually tackled by mass spectrometry in which the nucleobase is embedded in a water nanodroplet. Here we present a multiscale theoretical study revealing the effects and the dynamics of water droplets towards neutral and ionized thymine. In particular, by using both hybrid quantum mechanics/ molecular mechanics and fully ab initio molecular dynamics we reveal an unexpected proton transfer from thymine cation to a nearby water molecule. This leads to the formation of a neutral radical thymine and a Zundel structure, while the hydrated proton localizes at the interface between the deprotonated thymine and the water droplet. This observation opens entirely novel perspective concerning the reactivity and further fragmentation of ionized nucleobases.</p>

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The Role of Proton Transfer on Mutations

Cited by 46 publications

References 189 publications

Unravelling molecular interactions in uracil clusters by XPS measurements assisted by ab initio and tight-binding simulations

Unravelling molecular interactions in uracil clusters by XPS measurements assisted by ab initio and tight-binding simulations

DNA Nucleobase under Ionizing Radiation: Unexpected Proton Transfer by Thymine Cation in Water Nanodroplets

DNA Nucleobase Under Ionizing Radiation: Unexpected Proton Transfer by Thymine Cation in Water Nanodroplets

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