0000000000131585

AUTHOR

Israel González-ramírez

showing 6 related works from this author

Cyclobutane Pyrimidine Photodimerization of DNA/RNA Nucleobases in the Triplet State

2010

The photoinduced formation of cyclobutane pyrimidine dimers in the triplet excited state of the DNA/RNA pyrimidine nucleobases pairs has been studied at the CASPT2 level of theory. A stepwise mechanism through the triplet state of the homodimer is proposed for the pairs of nucleobases cytosine, thymine, and uracil involving a singlet−triplet crossing intermediary structure of biradical character representing the most favorable triplet state conformation of the nucleobases as found in the DNA environment. The efficiency of the mechanism will be modulated by two factors: the effectiveness of the triplet−triplet energy transfer process from a donor photosensitizer molecule, which relates to th…

congenital hereditary and neonatal diseases and abnormalitiesPhysics::Biological PhysicsQuantitative Biology::BiomoleculesPyrimidineStereochemistryPyrimidine dimerUracilPhotochemistryQuantitative Biology::GenomicsNucleobaseThymineCyclobutanechemistry.chemical_compoundIntersystem crossingchemistryGeneral Materials SciencePhysical and Theoretical ChemistryCytosineThe Journal of Physical Chemistry Letters
researchProduct

Theoretical insight into the intrinsic ultrafast formation of cyclobutane pyrimidine dimers in UV-irradiated DNA: thymine versus cytosine.

2008

The higher formation yields measured in the ultrafast photoinduced formation of cyclobutane thymine dimers (T T) with respect to those of cytosine (C C) are explained, on the basis of ab initio CASPT2 results, by the existence in thymine of more reactive orientations and a less efficient photoreversibility, whereas in cytosine the funnel toward the photolesion becomes competitive with that mediating the internal conversion of the excited-cytosine monomer.

Models MolecularTime FactorsUltraviolet RaysAb initioPyrimidine dimerDNAInternal conversion (chemistry)PhotochemistrySurfaces Coatings and FilmsThymineCyclobutanechemistry.chemical_compoundCytosineMonomerchemistryPyrimidine DimersMaterials ChemistryNucleic Acid ConformationPhysical and Theoretical ChemistryCytosineDNAThymineDNA DamageThe journal of physical chemistry. B
researchProduct

Molecular Basis of DNA Photodimerization: Intrinsic Production of Cyclobutane Cytosine Dimers

2008

Based on CASPT2 results, the present contribution establishes for the first time that cytosine photodimer formation (CC) is mediated along the triplet and singlet manifold by a singlet-triplet crossing, (T1/S0)X, and by a conical intersection, (S1/S0)CI, respectively. The former can be accessed in a barrierless way from a great variety of photochemical avenues and exhibits a covalent single bond between the ethene C6-C6' carbon atoms of each monomer. The efficiency of the stepwise triplet mechanism, however, would be modulated by the effectiveness of the intersystem crossing mechanism. The results provide the grounds for the understanding of the potential photogenotoxicity of endogenous and…

Quantitative Biology::BiomoleculesPhotochemistryUltraviolet RaysChemistryDNAGeneral ChemistryConical intersectionPhotochemistryBiochemistryCatalysisCyclobutaneCytosinechemistry.chemical_compoundColloid and Surface ChemistryIntersystem crossingPyrimidine DimersCovalent bondExcited stateNucleic Acid ConformationSingle bondSinglet stateDimerizationCytosineDNA DamageJournal of the American Chemical Society
researchProduct

The role of pyrimidine nucleobase excimers in DNA photophysics and photoreactivity

2009

Abstract Quantum chemical studies using the accurate CASPT2//CASSCF procedure show that π-stacked interactions in biochromophores such as pyrimidine (Pyr) DNA/RNA nucleobases pairs yield excimer-like situations which behave as precursors of processes like charge transfer (CT) or photoreactivity and are the source of the emissive properties in DNA. Examples are the CT between adjacent DNA nucleobases in a strand of oligonucleotides and the photodimerization taking place in cytosine (C) pairs leading to cyclobutanecytosine (CBC) mutants. These processes take place through nonadiabatic photochemical mechanisms whose evolution is determined by the presence and accessibility of conical intersect…

PyrimidineStereochemistryOligonucleotideGeneral Chemical EngineeringRNAGeneral ChemistryPhotochemistryQuantum chemistryNucleobasechemistry.chemical_compoundchemistryYield (chemistry)CytosineDNAPure and Applied Chemistry
researchProduct

Singlet-Triplet States Interaction Regions in DNA/RNA Nucleobase Hypersurfaces.

2010

The present study provides new insight into the intrinsic mechanisms for the population of the triplet manifold in DNA nucleobases by determining, at the multiconfigurational CASSCF/CASPT2 level, the singlet-triplet states crossing regions and the main decay paths for their lowest singlet and triplet states after near-UV irradiation. The studied singlet-triplet interacting regions are accessible along the minimum energy path of the initially populated singlet bright (1)ππ* state. In particular, all five natural DNA/RNA nucleobases have, at the end of the main minimum energy path and near a conical intersection of the ground and (1)ππ* states, a low-energy, easily accessible, singlet-triplet…

Quantitative Biology::Biomoleculeseducation.field_of_studyChemistryGuaninePopulationConical intersectionQuantitative Biology::GenomicsComputer Science ApplicationsNucleobaseThyminechemistry.chemical_compoundExcited stateSinglet fissionSinglet statePhysical and Theoretical ChemistryAtomic physicseducationJournal of chemical theory and computation
researchProduct

On the N1-H and N3-H Bond Dissociation in Uracil by Low Energy Electrons: A CASSCF/CASPT2 Study.

2015

The dissociative electron-attachment (DEA) phenomena at the N1-H and N3-H bonds observed experimentally at low energies (<3 eV) in uracil are studied with the CASSCF/CASPT2 methodology. Two valence-bound π(-) and two dissociative σ(-) states of the uracil anionic species, together with the ground state of the neutral molecule, are proven to contribute to the shapes appearing in the experimental DEA cross sections. Conical intersections (CI) between the π(-) and σ(-) are established as the structures which activate the DEA processes. The N1-H and N3-H DEA mechanisms in uracil are described, and experimental observations are interpreted on the basis of two factors: (1) the relative energy of …

010304 chemical physicsChemistryHydrogen bondUracilElectronBond breaking010402 general chemistry01 natural sciencesDissociation (chemistry)0104 chemical sciencesComputer Science ApplicationsCrystallographychemistry.chemical_compoundLow energyComputational chemistry0103 physical sciencesPhysical and Theoretical ChemistryGround stateNeutral moleculeJournal of chemical theory and computation
researchProduct