6533b829fe1ef96bd128a59c
RESEARCH PRODUCT
A TDDFT-based Study on the Proton-DNA Collision
Rodrigo SeraideGustavo BrunettoAngel RubioAngel RubioAngel RubioUmberto De GiovanniniUmberto De GiovanniniMario A. Bernalsubject
Models MolecularBase pairFirst-principlesFOS: Physical sciences02 engineering and technology010402 general chemistry01 natural sciencesDissociation (chemistry)Settore FIS/03 - Fisica Della Materiachemistry.chemical_compoundFragmentationPhysics - Chemical PhysicsMaterials ChemistryPhysics - Biological PhysicsPhysical and Theoretical ChemistryBase PairingChemical Physics (physics.chem-ph)ChemistryTime-dependent density functional theoryDNA021001 nanoscience & nanotechnologyCollisionPhosphateCharged particle0104 chemical sciencesSurfaces Coatings and FilmsEnergy TransferBiological Physics (physics.bio-ph)Chemical physicsQuantum TheoryDensity functional theoryProtonsAtomic physics0210 nano-technologyDNADNA Damagedescription
The interaction of heavy charged particles with DNA is of interest for several areas, from hadrontherapy to aero-space industry. In this paper, a TD-DFT study on the interaction of a 4 keV proton with an isolated DNA base pair was carried out. Ehrenfest dynamics was used to study the evolution of the system during and after the proton impact up to about 193 fs. This time was long enough to observe the dissociation of the target, which occurs between 80-100 fs. The effect of base pair linking to the DNA double helix was emulated by fixing the four O3' atoms responsible for the attachment. The base pair tends to dissociate into its main components, namely the phosphate groups, sugars and nitrogenous bases. A central impact with energy transfer of 17.9 eV only produces base damage while keeping the backbone intact. An impact on a phosphate group with energy transfer of about 60 eV leads to backbone break at that site together with base damage, while the opposite backbone site integrity is kept is this situation. As the whole system is perturbed during such a collision, no atom remains passive. These results suggest that base damage accompanies all backbone breaks since hydrogen bonds that keep bases together are much weaker that those between the other components of the DNA.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-05-09 |