Search results for "cytosine"

showing 10 items of 117 documents

Modelling Photoionisation in Isocytosine: Potential Formation of Longer‐Lived Excited State Cations in its Keto Form

2021

Abstract Studying the effects of UV and VUV radiation on non‐canonical DNA/RNA nucleobases allows us to compare how they release excess energy following absorption with respect to their canonical counterparts. This has attracted much research attention in recent years because of its likely influence on the origin of our genetic lexicon in prebiotic times. Here we present a CASSCF and XMS‐CASPT2 theoretical study of the photoionisation of non‐canonical pyrimidine nucleobase isocytosine in both its keto and enol tautomeric forms. We analyse their lowest energy cationic excited states including 2π+ , 2nO+ and 2nN+ and compare these to the corresponding electronic states in cytosine. Investigat…

Models MolecularCASPT2Ultraviolet RaysADNPhysics Atomic Molecular & ChemicalRELAXATION DYNAMICSCASSCFArticleCytosineMOLECULAR WAVE-FUNCTIONSCationsIMPLEMENTATION0307 Theoretical and Computational ChemistryPhysical and Theoretical Chemistry0306 Physical Chemistry (incl. Structural)Radiació ionitzantScience & TechnologyChemical PhysicsMolecular StructureChemistry PhysicalConical IntersectionsPhysicsSPECTROSCOPIC FINGERPRINTSDNAArticlesKetonesPhotochemical ProcessesURACILAtomic and Molecular Physics and OpticsChemistryPhotostability2ND-ORDER PERTURBATION-THEORYPhotoionisationPhysical SciencesANO BASIS-SETSSIMULATION0202 Atomic Molecular Nuclear Particle and Plasma PhysicsCASSCF/CASPT2RNAELECTRON CORRELATIONDNA/RNAChemPhysChem
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Toward the understanding of DNA fluorescence: The singlet excimer of cytosine

2006

By using the multiconfigurational second-order perturbation method CASPT2, including corrections for the basis set superposition error, the lowest-singlet excited state of the face-to-face π-stacked cytosine homodimer is revealed to be bound by about half an eV, being the source of an emissive feature consistent with the observed redshifted fluorescence. Gloria.Olaso@uv.es Daniel.Roca@uv.es Luis.Serrano@uv.es Manuela.Merchan@uv.es

Models MolecularDNA ; Molecular biophysics ; Fluorescence ; Excimers ; Perturbation theory ; Excited states ; Red shift ; BiochemistryTime FactorsLightUltraviolet RaysOligonucleotidesGeneral Physics and AstronomyPerturbation theoryExcimerBiochemistryFluorescenceCytosinechemistry.chemical_compoundSinglet statePhysical and Theoretical ChemistryPerturbation theory:FÍSICA::Química física [UNESCO]ExcimersChemistry PhysicalExcited statesDNAMolecular biophysicsFluorescenceRed shiftUNESCO::FÍSICA::Química físicaMicroscopy FluorescenceModels ChemicalchemistryExcited stateAtomic physicsLuminescenceDimerizationCytosineDNAThe Journal of Chemical Physics
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The Topological Analysis of the ELFx Localization Function: Quantitative Prediction of Hydrogen Bonds in the Guanine–Cytosine Pair

2021

International audience; In this contribution, we recall and test a new methodology designed to identify the favorable reaction pathway between two reactants. Applied to the formation of the DNA guanine (G) –cytosine (C) pair, we successfully predict the best orientation between the base pairs held together by hydrogen bonds and leading to the formation of the typical Watson Crick structure of the GC pair. Beyond the global minimum, some local stationary points of the targeted pair are also clearly identified.

Models MolecularELF<sub>x</sub>Base pairGuaninePharmaceutical ScienceOrganic chemistryMolecular Structure of Nucleic Acids: A Structure for Deoxyribose Nucleic Acid010402 general chemistry01 natural sciencesArticleAnalytical ChemistryELFxchemistry.chemical_compoundQD241-441Nucleophilebase pair0103 physical sciencesDrug Discovery[CHIM]Chemical SciencesguaninePhysical and Theoretical Chemistrycytosinehydrogen bond010304 chemical physicsHydrogen bondHydrogen BondingDNA0104 chemical sciencesELF xelectrophilicCrystallographyELFchemistryChemistry (miscellaneous)ElectrophileMolecular MedicineNucleic Acid ConformationDNACytosinenucleophilicMolecules
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NMR study of hexanucleotide d(CCGCGG)2 containing two triplet repeats of fragile X syndrome

2003

Abstract Long repeated stretches of d(CCG) and tri-nucleotide are crucial mutations that cause hereditary forms of mental retardation (fragile X-syndrome). Moreover, the alternating (CG) di-nucleotide is one of the candidates for Z-DNA conformation. Solution NMR structure of d(CCGCGG) 2 has been solved and is discussed. The determined NMR solution structure is a distorted highly bent B-DNA conformation with increased flexibility in both terminal residues. This conformation differs significantly from the Z-DNA tetramer structure reported for the same hexamer in the crystal state at similar ionic strength by Malinina and co-workers. Crystal structure of d(CCGCGG) 2 at high salt concentration …

Models MolecularMagnetic Resonance SpectroscopyOligonucleotidesBiophysicsCrystal structureRandom hexamerRing (chemistry)Biochemistrychemistry.chemical_compoundTetramerNucleic AcidsHumansMoleculeComputer SimulationMolecular BiologyRecombination Geneticchemistry.chemical_classificationChemistryDNACell BiologyFuranoseCrystallographyIonic strengthFragile X SyndromeNucleic Acid ConformationTrinucleotide Repeat ExpansionCytosineBiochemical and Biophysical Research Communications
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Mapping the tRNA binding site on the surface of human DNMT2 methyltransferase.

2012

The DNMT2 enzyme methylates tRNA-Asp at position C38. Because there is no tRNA–Dnmt2 cocrystal structure available, we have mapped the tRNA binding site of DNMT2 by systematically mutating surface-exposed lysine and arginine residues to alanine and studying the tRNA methylation activity and binding of the corresponding variants. After mutating 20 lysine and arginine residues, we identified eight of them that caused large (>4-fold) decreases in catalytic activity. These residues cluster within and next to a surface cleft in the protein, which is large enough to accommodate the tRNA anticodon loop and stem. This cleft is located next to the binding pocket for the cofactor S-adenosyl-l-methion…

Models MolecularMethyltransferaseProtein ConformationLysineMolecular Sequence DataBiologyBiochemistryMethylationCofactorRNA TransferAnimalsHumansAmino Acid SequenceDNA (Cytosine-5-)-MethyltransferasesCloning MolecularAlaninechemistry.chemical_classificationTRNA methylationBinding SitesCircular DichroismTRNA bindingEnzymeDrosophila melanogasterchemistryBiochemistryAmino Acid SubstitutionTransfer RNAbiology.proteinMutagenesis Site-DirectedNucleic Acid ConformationSequence AlignmentBiochemistry
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Photoinduced intersystem crossing in DNA oxidative lesions and epigenetic intermediates

2020

[EN] The propensity of 5-formyluracil and 5-formylcytosine, i.e. oxidative lesions and epigenetic intermediates, in acting as intrinsic DNA photosensitizers is unraveled by using a combination of molecular modeling, simulation and spectroscopy. Exploration of potential energy surfaces and non-adiabatic dynamics confirm a higher intersystem crossing rate for 5-formyluracil, whereas the kinetic models evidence different equilibria in the excited states for both compounds.

Models MolecularMolecular modelLightOxidative phosphorylation010402 general chemistry01 natural sciencesCatalysisEpigenesis Geneticchemistry.chemical_compoundCytosineQUIMICA ORGANICAMaterials Chemistry[CHIM]Chemical SciencesHumansComputer SimulationEpigeneticsSpectroscopyUracilComputingMilieux_MISCELLANEOUS010405 organic chemistryChemistryMetals and AlloysGeneral ChemistryDNAPotential energy0104 chemical sciencesSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsKineticsIntersystem crossingExcited stateCeramics and CompositesBiophysicsOxidation-ReductionDNAMutagens
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Modelling Photoionisation in Isocytosine: Potential Formation of Longer‐Lived Excited State Cations in its Keto Form

2021

The front cover artwork is provided by Dr. Javier Segarra-Martí (University of Valencia, Spain) and Prof. Michael J. Bearpark (Imperial College London, UK). The image shows the ultrafast photoionisation of DNA canonical nucleobase cytosine and the slower ionization process in non-canonical base isocytosine embedded within a DNA backbone. Read the full text of the Article at 10.1002/cphc.202100402.

Models MolecularPhysicsMolecular StructurebiologyUltraviolet RaysDNAKetonesPhotochemical Processesbiology.organism_classificationAtomic and Molecular Physics and OpticsNucleobaseCytosinechemistry.chemical_compoundCrystallographyFront coverchemistryCationsIonizationExcited stateA-DNAIsocytosinePhysical and Theoretical ChemistryValenciaChemPhysChem
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Theoretical Study of the Catalytic Mechanism of DNA-(N4-Cytosine)-Methyltransferase from the Bacterium Proteus vulgaris

2010

In this paper the reaction mechanism for methylation of cytosine at the exocyclic N4 position catalyzed by M.PvuII has been explored by means of hybrid quantum mechanics/molecular mechanics (QM/MM) methods. A reaction model was prepared by placing a single cytosine base in the active site of the enzyme. In this model the exocyclic amino group of the base establishes hydrogen bond interactions with the hydroxyl oxygen atom of Ser53 and the carbonyl oxygen atom of Pro54. The reaction mechanism involves a direct methyl transfer from AdoMet to the N4 atom and a proton transfer from this atom to Ser53, which in turn transfers a proton to Asp96. Different timings for the proton transfers and meth…

Models MolecularReaction mechanismProtonbiologyHydrogen bondStereochemistrySite-Specific DNA-Methyltransferase (Cytosine-N4-Specific)Active siteMethylationDNA MethylationPhotochemistryProtein Structure TertiarySurfaces Coatings and FilmsCatalysischemistry.chemical_compoundchemistryBiocatalysisMaterials Chemistrybiology.proteinProteus vulgarisQuantum TheoryPhysical and Theoretical ChemistryCytosineDNAThe Journal of Physical Chemistry B
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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
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Communication: Electronic UV-Vis transient spectra of the ·OH reaction products of uracil, thymine, cytosine, and 5,6-dihydrouracil by using the comp…

2013

Addition of ∙OH radicals to pyrimidine nucleobases is a common reaction in DNA/RNA damage by reactive oxygen species. Among several experimental techniques, transient absorption spectroscopy has been during the last decades used to characterize such compounds. Discrepancies have however appeared in the assignment of the adduct or adducts responsible for the reported transient absorption UV-Vis spectra. In order to get an accurate assignment of the transient spectra and a unified description of the absorption properties of the ∙OH reaction products of pyrimidines, a systematic complete active space self-consistent field second-order perturbation (CASPT2//CASSCF) theory study has been carried…

Molecular StructurePyrimidineHydroxyl RadicalGeneral Physics and AstronomyDihydrouracilElectronsUracilHydrogen atom abstractionPhotochemistryThymineAdductNucleobaseCytosinechemistry.chemical_compoundchemistryComputational chemistryQuantum TheorySpectrophotometry UltravioletPhysical and Theoretical ChemistryUracilThymineCytosineThe Journal of Chemical Physics
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