Search results for "Chalcone isomerase"

showing 3 items of 3 documents

Comparative computational analysis of different active site conformations and substrates in a chalcone isomerase catalyzed reaction.

2006

Chalcone isomerase catalyzes the transformation of chalcones to flavanones. We present a computational study of the rate-limiting chemical step, an intramolecular Michael addition of a 2'-oxyanion to the alpha,beta-double bound. By using quantum mechanical/molecular mechanical hybrid methods we traced the free-energy profiles associated with the reaction of two different substrates (chalcone and 6'-deoxychalcone) in two different conformations of the active site that are described in the different crystallographic structures available. We have obtained significant differences (about 4 kcal/mol) in the free-energy barriers calculated for the two active sites. According to our results, the ac…

Chalcone isomeraseAnionsModels MolecularChalconeStereochemistryProtein ConformationMolecular ConformationCatalysisCatalysischemistry.chemical_compoundAtomMaterials ChemistryComputer SimulationPhysical and Theoretical ChemistryIntramolecular LyasesBinding SitesbiologyActive siteSubstrate (chemistry)Hydrogen-Ion ConcentrationCarbonSurfaces Coatings and FilmsKineticschemistryModels ChemicalIntramolecular forcebiology.proteinMichael reactionQuantum TheoryThermodynamicsSoftwareThe journal of physical chemistry. B
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Enzymatic effects on reactant and transition states. The case of chalcone isomerase.

2007

Chalcone isomerase catalyzes the transformation of chalcone to naringerin as a part of flavonoid biosynthetic pathways. The global reaction takes place through a conformational change of the substrate followed by chemical reaction, being thus an excellent example to analyze current theories about enzyme catalysis. We here present a detailed theoretical study of the enzymatic action on the conformational pre-equilibria and on the chemical steps for two different substrates of this enzyme. Free-energy profiles are obtained in terms of potentials of mean force using hybrid quantum mechanics/molecular mechanics potentials. The role of the enzyme becomes clear when compared to the counterpart eq…

Chalcone isomeraseChalconeStereochemistryProtein ConformationCrystallography X-RayBiochemistryChemical reactionCatalysisEnzyme catalysischemistry.chemical_compoundColloid and Surface ChemistryChalconeChalconesComputational chemistryTransition state analogIntramolecular LyasesBinding SitesbiologyChemistrySubstrate (chemistry)Active siteStereoisomerismGeneral ChemistryTransition stateKineticsbiology.proteinJournal of the American Chemical Society
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A Novel Strategy to Study Electrostatic Effects in Chemical Reactions: Differences between the Role of Solvent and the Active Site of Chalcone Isomer…

2015

The electrostatic behavior of active site residues in enzyme catalysis is quite different from that of water molecules in solution. To highlight the electrostatic differences between both environments, we propose a QM/MM strategy to study the role of the environment in chemical reactions. The novelty of the present communication is that free energy surfaces are generated by means of two distinguished reaction coordinates: a solute coordinate and the electrostatic potential created by the environment. This is applied to analyze the origin of catalysis in the transformation of a chalcone into a flavanone, a Michael addition that requires the desolvation of the nucleophile.

Chalcone isomeraseChalconebiologyChemistryActive siteNanotechnologyChemical reactionComputer Science ApplicationsEnzyme catalysischemistry.chemical_compoundComputational chemistrybiology.proteinMichael reactionMoleculePhysical and Theoretical ChemistryFlavanoneJournal of Chemical Theory and Computation
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