Search results for "molecular mechanics"

showing 10 items of 55 documents

Unraveling the Reaction Mechanism of Enzymatic C5-Cytosine Methylation of DNA. A Combined Molecular Dynamics and QM/MM Study of Wild Type and Gln119 …

2016

M.HhaI is a DNA methyltransferase from Haemophilus hemolyticus that catalyzes the transfer of a methyl group from S-adenosyl-l-methionine (SAM) to the C5 position of a cytosine. This enzyme is a paradigmatic model for C5 DNA methyltransferases due to its major homology to mammalian enzymes and to the availability of high-resolution structures of the DNA–enzyme complex. In spite of the number of experimental and theoretical analyses carried out for this system, many mechanistic details remain unraveled. We have used full atomistic classical molecular dynamics simulations to explore the protein–SAM–DNA ternary complex, where the target cytosine base is flipped out into the active site for bot…

MethyltransferaseStereochemistry010402 general chemistry01 natural sciencesMolecular mechanicsenzyme catalysisCatalysisQM/MMchemistry.chemical_compound0103 physical sciencesA-DNATernary complex010304 chemical physicsbiologyChemistryActive siteGeneral Chemistryfree energy profiles0104 chemical sciencesreaction mechanismsBiochemistrybiology.proteinQM/MM methodsstring methodDNA-methylationCytosineDNA
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Model building and molecular mechanics calculations of mitoxantrone-deoxytetranucleotide complexes: Molecular foundations of DNA intercalation as cyt…

1996

Several intercalation complexes of the antitumor-active drug mitoxantrone with base paired tetranucleotides were constructed by molecular modeling using computer graphics and molecular mechanics calculations. The mitoxantrone molecule favours DNA binding into CG intercalation site. The two side chains of the drug are orientated into the major groove and fixed by hydrogen bonds with the nucleotide bases. This molecular study can be helpful for understanding the mode of action of cytostatically active compounds and to design new structurally related compounds of the anthraquinone drug type.

MitoxantroneMolecular modelChemistryStereochemistryHydrogen bondIntercalation (chemistry)General ChemistryMolecular mechanicsNucleobaseDNA IntercalationComputational chemistrymedicineMoleculemedicine.drugMonatshefte f�r Chemie Chemical Monthly
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Mechanistic insights into the phosphoryl transfer reaction in cyclin-dependent kinase 2: a QM/MM study

2019

AbstractCyclin-dependent kinase 2 (CDK2) is an important member of the CDK family exerting its most important function in the regulation of the cell cycle. It catalyzes the transfer of the gamma phosphate group from an ATP (adenosine triphosphate) molecule to a Serine/Threonine residue of a peptide substrate. Due to the importance of this enzyme, and protein kinases in general, a detailed understanding of the reaction mechanism is desired. Thus, in this work the phosphoryl transfer reaction catalyzed by CDK2 was revisited and studied by means of hybrid quantum mechanics/molecular mechanics (QM/MM) calculations. Our results show that the base-assisted mechanism is preferred over the substrat…

Models MolecularComposite ParticlesProtein ConformationPhysical ChemistryBiochemistry01 natural sciencesSubstrate Specificitychemistry.chemical_compoundPhosphorylationPost-Translational ModificationFree Energy0303 health sciencesMultidisciplinarybiologyKinasePhysicsQChemical ReactionsRChemistryReaction DynamicsPhysical SciencesThermodynamicsMedicineProtonsResearch ArticleChemical ElementsAtomsStereochemistryScienceMolecular Dynamics Simulation010402 general chemistryMolecular mechanicsReactantsQM/MMStructure-Activity Relationship03 medical and health sciencesCyclin-dependent kinaseParticle PhysicsNuclear PhysicsNucleons030304 developmental biologyChemical BondingCyclin-Dependent Kinase 2Cyclin-dependent kinase 2Biology and Life SciencesProteinsActive siteHydrogen BondingTransition StateBond order0104 chemical sciencesOxygenModels Chemicalchemistrybiology.proteinQuantum TheoryAdenosine triphosphate
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Theoretical site-directed mutagenesis: Asp168Ala mutant of lactate dehydrogenase

2008

Molecular simulations based on the use of hybrid quantum mechanics/molecular mechanics methods are able to provide detailed information about the complex enzymatic reactions and the consequences of specific mutations on the activity of the enzyme. In this work, the reduction of pyruvate to lactate catalysed by wild-type and Asp168Ala mutant lactate dehydrogenase (LDH) has been studied by means of simulations using a very flexible molecular model consisting of the full tetramer of the enzyme, together with the cofactor NADH, the substrate and solvent water molecules. Our results indicate that the Asp168Ala mutation provokes a shift in the p K a value of Glu199 that becomes unprotonated at n…

Models MolecularMutantBiomedical EngineeringBiophysicsMutation MissenseBioengineeringBiochemistryMolecular mechanicsCofactorEnzyme catalysisBiomaterialschemistry.chemical_compoundLactate dehydrogenaseComputer SimulationSite-directed mutagenesisbiologyL-Lactate DehydrogenaseMolecular StructureWild typeSubstrate (chemistry)Computational BiologychemistryBiochemistrybiology.proteinBiophysicsMutagenesis Site-DirectedBiotechnologyResearch Article
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Understanding the different activities of highly promiscuous MbtI by computational methods

2012

Salicylate synthase from Mycobacterium tuberculosis, MbtI, is a highly promiscuous Mg(2+) dependent enzyme with up to four distinct activities detected in vitro: isochorismate synthase (IS), isochorismate pyruvate lyase (IPL), salicylate synthase (SS) and chorismate mutase (CM). In this paper, Molecular Dynamic (MD) simulations employing hybrid quantum mechanics/molecular mechanics (QM/MM) potentials have been carried out to get a detailed knowledge of the IS and the IPL activities at the molecular level. According to our simulations, the architecture of the MbtI active site allows catalyzing the two reactions: the isochorismate formation, by means of a stepwise mechanism, and the salicylat…

Models MolecularPericyclic reactionbiologyATP synthaseStereochemistryChemistryGeneral Physics and AstronomyActive siteSubstrate (chemistry)LyasesMycobacterium tuberculosisHydrogen-Ion ConcentrationMolecular Dynamics SimulationLyaseMolecular mechanicsBiochemistryIsochorismate synthasebiology.proteinChorismate mutaseBiocatalysisQuantum TheoryMagnesiumPhysical and Theoretical Chemistry
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A Quantum Mechanic/Molecular Mechanic Study of the Wild-Type and N155S Mutant HIV-1 Integrase Complexed with Diketo Acid

2008

Integrase (IN) is one of the three human immunodeficiency virus type 1 (HIV-1) enzymes essential for effective viral replication. Recently, mutation studies have been reported that have shown that a certain degree of viral resistance to diketo acids (DKAs) appears when some amino acid residues of the IN active site are mutated. Mutations represent a fascinating experimental challenge, and we invite theoretical simulations for the disclosure of still unexplored features of enzyme reactions. The aim of this work is to understand the molecular mechanisms of HIV-1 IN drug resistance, which will be useful for designing anti-HIV inhibitors with unique resistance profiles. In this study, we use mo…

Models MolecularProtein ConformationStereochemistryBiophysicsIntegrase inhibitorIntegrase InhibitorsHIV IntegraseBiophysical Theory and ModelingMechanicsMolecular mechanicsProtein structureComputer SimulationMagnesiumTernary complexBinding SitesbiologyChemistryAminobutyratesWild typeActive siteLigand (biochemistry)PhenylbutyratesIntegraseModels ChemicalMultiprotein ComplexesMutagenesis Site-Directedbiology.proteinQuantum TheoryProtein BindingBiophysical Journal
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Promiscuity in alkaline phosphatase superfamily. Unraveling evolution through molecular simulations.

2011

We here present a theoretical study of the alkaline hydrolysis of a phosphodiester (methyl p-nitrophenyl phosphate or MpNPP) in the active site of Escherichia coli alkaline phosphatase (AP), a monoesterase that also presents promiscuous activity as a diesterase. The analysis of our simulations, carried out by means of molecular dynamics (MD) simulations with hybrid quantum mechanics/molecular mechanics (QM/MM) potentials, shows that the reaction takes place through a D(N)A(N) or dissociative mechanism, the same mechanism employed by AP in the hydrolysis of monoesters. The promiscuous activity observed in this superfamily can be then explained on the basis of a conserved reaction mechanism. …

Models MolecularReaction mechanismStereochemistrydnaNAlkaline hydrolysis (body disposal)AlkaliesMolecular Dynamics SimulationBiochemistryMolecular mechanicsCatalysisMolecular dynamicsColloid and Surface ChemistryCatalytic DomainphosphodiesterEscherichia colibiologyChemistryHydrolysisActive siteGeneral ChemistryAlkaline PhosphataseEnzymesEnzyme ActivationPhosphodiester bondbiology.proteinAlkaline phosphataseQuantum Theoryalkaline phosphataseJournal of the American Chemical Society
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Can multiscale simulations unravel the function of metallo-enzymes to improve knowledge-based drug discovery?

2019

Metallo-enzymes are a large class of biomolecules promoting specialized chemical reactions. Quantum-classical quantum mechanics/molecular mechanics molecular dynamics, describing the metal site at quantum mechanics level, while accounting for the rest of system at molecular mechanics level, has an accessible time-scale limited by its computational cost. Hence, it must be integrated with classical molecular dynamics and enhanced sampling simulations to disentangle the functions of metallo-enzymes. In this review, we provide an overview of these computational methods and their capabilities. In particular, we will focus on some systems such as CYP19A1 a Fe-dependent enzyme involved in estroge…

Models MolecularSpliceosomeQM/MM molecular dynamicsProtein ConformationComputer scienceMetallo enzymeComputational biology01 natural sciencesMolecular mechanicsribozymeStructure-Activity Relationship03 medical and health sciencesMolecular dynamicsMM molecular dynamicsAromataseCatalytic DomainDrug Discoverysteroid synthesisCYP19A1RNA CatalyticDensity Functional Theory030304 developmental biologyQMPharmacologychemistry.chemical_classificationDNA processing enzymes0303 health sciencesMetallo-proteinsbiologyDrug discoveryBiomoleculeRibozymeDNABiosynthetic PathwaysEnzymes0104 chemical sciences010404 medicinal & biomolecular chemistrychemistrySettore CHIM/03 - Chimica Generale E InorganicaMetalsbiology.proteinRNAThermodynamicsMolecular MedicinespliceosomeFunction (biology)Protein BindingFuture Medicinal Chemistry
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A Computational Study of the Protein-Ligand Interactions in CDK2 Inhibitors: Using Quantum Mechanics/Molecular Mechanics Interaction Energy as a Pred…

2006

ABSTRACT: We report a combined quantum mechanics/molecular mechanics (QM/MM) study to determine the protein-ligand interaction energy between CDK2 (cyclin-dependent kinase 2) and five inhibitors with the N2 -substituted 6-cyclohexylmethoxypurine scaffold. The computational results in this work show that the QM/MM interaction energy is strongly correlated to the biological activity and can be used as a predictor, at least within a family of substrates. A detailed analysis of the protein-ligand structures obtained from molecular dynamics simulations shows specific interactions within the active site that, in some cases, have not been reported before to our knowledge. The computed interaction …

Models MolecularWork (thermodynamics)Protein ConformationBiophysicsBiophysical Theory and ModelingMechanicsMolecular mechanicssymbols.namesakeMolecular dynamicsProtein structureSimulación por ComputadorDiseño de FármacosModelos QuímicosUnión ProteicaQuantum mechanicsModelos MolecularesConformación ProteicaComputer SimulationProtein Kinase InhibitorsBinding SitesbiologyChemistryCyclin-Dependent Kinase 2Active siteInteraction energyModels ChemicalPurinesDrug Designsymbolsbiology.proteinQuantum Theoryvan der Waals forceQuinasa 2 Dependiente de la CiclinaProtein BindingProtein ligandBiophysical Journal
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Theoretical Study of Catalytic Efficiency of a Diels–Alderase Catalytic Antibody: An Indirect Effect Produced During the Maturation Process

2007

The Diels–Alder reaction is one of the most important and versatile transformations available to organic chemists for the construction of complex natural products, therapeutics agents, and synthetic materials. Given the lack of efficient enzymes capable of catalyzing this kind of reaction, it is of interest to ask whether a biological catalyst could be designed from an antibody-combining site. In the present work, a theoretical study of the different behavior of a germline catalytic antibody (CA) and its matured form, 39 A-11, that catalyze a Diels–Alder reaction has been carried out. A free-energy perturbation technique based on a hybrid quantum-mechanics/molecular-mechanics scheme, togeth…

Models MolecularWork (thermodynamics)StereochemistryAntibodies CatalyticCatalytic antibodyCrystallography X-RayCatalysisCatalysisenergy calculationsDiels–Alder reactionsantibodiesComputer SimulationMaturation processquantum mechanics/molecular mechanicsGerm-Line Mutationmutatgenesischemistry.chemical_classificationMolecular StructureInternal energyChemistryOrganic ChemistrySubstrate (chemistry)General ChemistryCombinatorial chemistryIndirect effectEnzymeAmino Acid SubstitutionModels ChemicalQuantum TheoryChemistry - A European Journal
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