Search results for " Simulation"

showing 10 items of 4034 documents

Sequence Determines Degree of Knottedness in a Coarse-Grained Protein Model

2015

Knots are abundant in globular homopolymers but rare in globular proteins. To shed new light on this long-standing conundrum, we study the influence of sequence on the formation of knots in proteins under native conditions within the framework of the hydrophobic-polar (HP) lattice protein model. By employing large scale Wang-Landau simulations combined with suitable Monte Carlo trial moves we show that, even though knots are still abundant on average, sequence introduces large variability in the degree of self-entanglements. Moreover, we are able to design sequences which are either almost always or almost never knotted. Our findings serve as proof of concept that the introduction of just o…

Protein ConformationFOS: Physical sciencesGeneral Physics and AstronomyCondensed Matter - Soft Condensed Matterstomatognathic systemComputer SimulationMathematicsSequence (medicine)chemistry.chemical_classificationQuantitative Biology::BiomoleculesDegree (graph theory)Proteinsfood and beveragesBiomolecules (q-bio.BM)Knot theoryAmino acidsurgical procedures operativeModels ChemicalQuantitative Biology - BiomoleculeschemistryFOS: Biological sciencesProtein modelSoft Condensed Matter (cond-mat.soft)Biological systemHydrophobic and Hydrophilic InteractionsMonte Carlo MethodPhysical Review Letters

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Conformational clamping by a membrane ligand activates the EphA2 receptor

2021

AbstractThe EphA2 receptor is a promising drug target for cancer treatment, since EphA2 activation can inhibit metastasis and tumor progression. It has been recently described that the TYPE7 peptide activates EphA2 using a novel mechanism that involves binding to the single transmembrane domain of the receptor. TYPE7 is a conditional transmembrane (TM) ligand, which only inserts into membranes at neutral pH in the presence of the TM region of EphA2. However, how membrane interactions can activate EphA2 is not known. We systematically altered the sequence of TYPE7 to identify the binding motif used to activate EphA2. With the resulting six peptides, we performed biophysical and cell migratio…

Protein ConformationSequence HomologyTm ligandsPeptideMolecular Dynamics SimulationLigandsReceptor tyrosine kinaseArticleBimolecular fluorescence complementationProtein DomainsStructural BiologyCell MovementCell surface receptorTumor Cells CulturedHumansAmino Acid SequenceReceptorMolecular BiologyMelanomachemistry.chemical_classificationBinding SitesMembranesbiologyChemistryReceptor EphA2Membrane ProteinsLigand (biochemistry)Peptide FragmentsTransmembrane proteinTransmembrane domainMembranebiology.proteinBiophysicsProtein MultimerizationProtein Binding

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Reconstructing the free-energy landscape of Met-enkephalin using dihedral principal component analysis and well-tempered metadynamics

2013

Well-Tempered Metadynamics (WTmetaD) is an efficient method to enhance the reconstruction of the free-energy surface of proteins. WTmetaD guarantees a faster convergence in the long time limit in comparison with the standard metadynamics. It still suffers however from the same limitation, i.e. the non trivial choice of pertinent collective variables (CVs). To circumvent this problem, we couple WTmetaD with a set of CVs generated from a dihedral Principal Component Analysis (dPCA) on the Ramachadran dihedral angles describing the backbone structure of the protein. The dPCA provides a generic method to extract relevant CVs built from internal coordinates. We illustrate the robustness of this …

Protein ConformationSurface PropertiesEnkephalin MethionineFOS: Physical sciencesGeneral Physics and AstronomyDihedral angle01 natural scienceslaw.invention03 medical and health scienceslaw0103 physical sciencesComputer SimulationCartesian coordinate systemPhysics - Biological PhysicsStatistical physicsPhysical and Theoretical ChemistryProtein secondary structureReference modelComputingMilieux_MISCELLANEOUS030304 developmental biologyMathematicsPrincipal Component AnalysisQuantitative Biology::Biomolecules0303 health sciences010304 chemical physicsMetadynamicsEnergy landscapeBiomolecules (q-bio.BM)Condensed Matter - Other Condensed Matter[CHIM.THEO]Chemical Sciences/Theoretical and/or physical chemistryQuantitative Biology - BiomoleculesBiological Physics (physics.bio-ph)FOS: Biological sciencesPrincipal component analysis[ CHIM.THEO ] Chemical Sciences/Theoretical and/or physical chemistryPhysics::Accelerator PhysicsThermodynamicsEnergy MetabolismAlgorithmsOther Condensed Matter (cond-mat.other)Ramachandran plot

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Protein Thermal Denaturation and Matrix Glass Transition in Different Protein−Trehalose−Water Systems

2011

Biopreservation by saccharides is a widely studied issue due to its scientific and technological importance; in particular, ternary amorphous protein-saccharide-water systems are extensively exploited to model the characteristics of the in vivo biopreservation process. We present here a differential scanning calorimetry (DSC) study on amorphous trehalose-water systems with embedded different proteins (myoglobin, lysozyme, BSA, hemoglobin), which differ for charge, surface, and volume properties. In our study, the protein/trehalose molar ratio is kept constant at 1/40, while the water/sugar molar ratio is varied between 2 and 300; results are compared with those obtained for binary trehalose…

Protein DenaturationdenaturationMolecular Dynamics SimulationPhase TransitionDSCMatrix (chemical analysis)Hemoglobinschemistry.chemical_compoundDifferential scanning calorimetryMaterials ChemistryAnimalsglass transitionPhysical and Theoretical ChemistrytrehaloseSettore CHIM/02 - Chimica FisicaChromatographyCalorimetry Differential ScanningMyoglobinTemperatureProteinsWaterSerum Albumin BovineTrehaloseSettore FIS/07 - Fisica Applicata(Beni Culturali Ambientali Biol.e Medicin)Surfaces Coatings and FilmsAmorphous solidchemistryChemical engineeringMyoglobinconfinementCattleMuramidaseLysozymeTernary operationGlass transitionThe Journal of Physical Chemistry B

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New Insights into Protein (Un)Folding Dynamics.

2015

A fundamental open problem in biophysics is how the folded structure of the main chain (MC) of a protein is determined by the physics of the interactions between the side-chains (SCs). All-atom molecular dynamics simulations of a model protein (Trp-cage) revealed that strong correlations between the motions of the SCs and the MC occur transiently at 380 K in unfolded segments of the protein, and during the simulations of the whole amino-acid sequence at 450 K. The high correlation between the SC and MC fluctuations is a fundamental property of the unfolded state and is also relevant to unstructured proteins as Intrinsically Disordered Proteins (IDPs), for which new reaction coordinates are …

Protein FoldingChemistryOpen problemBiophysicsProteinsSequence (biology)Molecular Dynamics SimulationIntrinsically disordered proteinsArticleFolding (chemistry)Intrinsically Disordered ProteinsCrystallographyMolecular dynamicsSide chainBiophysicsHumansThermodynamicsGeneral Materials ScienceProtein foldingAmino Acid SequencePhysical and Theoretical ChemistryPeptidesPeptide sequenceThe journal of physical chemistry letters

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Functional and dysfunctional conformers of human neuroserpin characterized by optical spectroscopies and Molecular Dynamics

2015

Neuroserpin (NS) is a serine protease inhibitor (SERPIN) involved in different neurological pathologies, including the Familial Encephalopathy with Neuroserpin Inclusion Bodies (FENIB), related to the aberrant polymerization of NS mutants. Here we present an in vitro and in silico characterization of native neuroserpin and its dysfunctional conformation isoforms: the proteolytically cleaved conformer, the inactive latent conformer, and the polymeric species. Based on circular dichroism and fluorescence spectroscopy, we present an experimental validation of the latent model and highlight the main structural features of the different conformers. In particular, emission spectra of aromatic res…

Protein FoldingCircular dichroismSerine Proteinase InhibitorsProtein ConformationStereochemistryNeuroserpinBiophysicsEpilepsies MyoclonicMolecular Dynamics SimulationSerpinMolecular DynamicsBiochemistryProtein Structure SecondaryArticleFluorescenceAnalytical ChemistryMolecular dynamicsProtein structureNeuroserpinmedicineHumansProtein IsoformsFluorescence emission spectra; circular dichroism; neuroserpin latent conformationneuroserpin latent conformationFamilial encephalopathy with neuroserpin inclusion bodiesMolecular BiologyConformational isomerismSerpinsFluorescence emission spectraSerpinChemistryCircular DichroismConformational diseaseNeuropeptidesHydrogen Bondingmedicine.diseaseSettore FIS/07 - Fisica Applicata(Beni Culturali Ambientali Biol.e Medicin)Heredodegenerative Disorders Nervous SystemProtein foldingBiochimica et Biophysica Acta (BBA) - Proteins and Proteomics

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A Stevedore's protein knot.

2009

Protein knots, mostly regarded as intriguing oddities, are gradually being recognized as significant structural motifs. Seven distinctly knotted folds have already been identified. It is by and large unclear how these exceptional structures actually fold, and only recently, experiments and simulations have begun to shed some light on this issue. In checking the new protein structures submitted to the Protein Data Bank, we encountered the most complex and the smallest knots to date: A recently uncovered α-haloacid dehalogenase structure contains a knot with six crossings, a so-called Stevedore knot, in a projection onto a plane. The smallest protein knot is present in an as yet unclassified …

Protein FoldingHydrolasesProtein ConformationComputational Biology/Macromolecular Structure Analysis02 engineering and technologyBiologyMolecular Dynamics SimulationComputational Biology/Molecular DynamicsCombinatorics03 medical and health sciencesCellular and Molecular NeuroscienceKnot (unit)Protein structureGeneticsStructural motifDatabases ProteinMolecular Biologylcsh:QH301-705.5Ecology Evolution Behavior and Systematics030304 developmental biology0303 health sciencesTopological complexityQuantitative Biology::BiomoleculesEcologycomputer.file_format021001 nanoscience & nanotechnologyProtein Data BankMathematics::Geometric TopologyComputational Theory and MathematicsBiochemistrylcsh:Biology (General)Modeling and SimulationProtein foldingStevedore knot0210 nano-technologySingle loopcomputerResearch ArticlePLoS Computational Biology

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Structures and folding pathways of topologically knotted proteins

2010

In the last decade, a new class of proteins has emerged that contain a topological knot in their backbone. Although these structures are rare, they nevertheless challenge our understanding of protein folding. In this review, we provide a short overview of topologically knotted proteins with an emphasis on newly discovered structures. We discuss the current knowledge in the field, including recent developments in both experimental and computational studies that have shed light on how these intricate structures fold.

Protein FoldingQuantitative Biology::BiomoleculesProtein ConformationChemistryProteinsNanotechnologyComputational biologyCondensed Matter PhysicsProtein structureComputer GraphicsAnimalsHumansComputer SimulationGeneral Materials ScienceProtein foldingAmino Acid SequenceDatabases ProteinKnot (mathematics)Journal of Physics: Condensed Matter

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Transmembrane but not soluble helices fold inside the ribosome tunnel

2018

Integral membrane proteins are assembled into the ER membrane via a continuous ribosome-translocon channel. The hydrophobicity and thickness of the core of the membrane bilayer leads to the expectation that transmembrane (TM) segments minimize the cost of harbouring polar polypeptide backbones by adopting a regular pattern of hydrogen bonds to form α-helices before integration. Co-translational folding of nascent chains into an α-helical conformation in the ribosomal tunnel has been demonstrated previously, but the features governing this folding are not well understood. In particular, little is known about what features influence the propensity to acquire α-helical structure in the ribosom…

Protein FoldingSequence Homology Amino AcidScienceQProteïnes de membranaMembrane ProteinsMolecular Dynamics SimulationEndoplasmic ReticulumArticleProtein Structure SecondaryAnimalslcsh:QAmino Acid Sequencelcsh:ScienceHydrophobic and Hydrophilic InteractionsSignal Recognition ParticleRibosomes

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Investigation of protein folding by coarse-grained molecular dynamics with the UNRES force field.

2010

Coarse-grained molecular dynamics simulations offer a dramatic extension of the time-scale of simulations compared to all-atom approaches. In this article, we describe the use of the physics-based united-residue (UNRES) force field, developed in our laboratory, in protein-structure simulations. We demonstrate that this force field offers about a 4000-times extension of the simulation time scale; this feature arises both from averaging out the fast-moving degrees of freedom and reduction of the cost of energy and force calculations compared to all-atom approaches with explicit solvent. With massively parallel computers, microsecond folding simulation times of proteins containing about 1000 r…

Protein FoldingStaphylococcus aureusRotationMolecular Dynamics SimulationKinetic energyForce field (chemistry)Protein Structure SecondaryArticleMolecular dynamicsMiceProtein structureBacterial ProteinsComputational chemistryAnimalsStatistical physicsPhysical and Theoretical ChemistryMassively parallelQuantitative Biology::BiomoleculesPrincipal Component AnalysisModels StatisticalChemistryProteinsMicrosecondKineticsBundleSolventsThermodynamicsProtein foldingTranscriptional Elongation FactorsCarrier ProteinsAlgorithmsProtein BindingThe journal of physical chemistry. A

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