Method to Predict Crowding Effects by Postprocessing Molecular Dynamics Trajectories: Application to the Flap Dynamics of HIV-1 Protease. - Wikidata - awgldk - TriplyDB

Method to Predict Crowding Effects by Postprocessing Molecular Dynamics Trajectories: Application to the Flap Dynamics of HIV-1 Protease.

Method to Predict Crowding Effects by Postprocessing Molecular Dynamics Trajectories: Application to the Flap Dynamics of HIV-1 Protease.

http://www.wikidata.org/entity/Q39586183

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Effects of macromolecular crowding on protein conformational changes Gated Diffusion-controlled Reactions Theoretical frameworks for multiscale modeling and simulation Using simulations to provide the framework for experimental protein folding studies The folding transition-state ensemble of a four-helix bundle protein: helix propensity as a determinant and macromolecular crowding as a probe.Further Development of the FFT-based Method for Atomistic Modeling of Protein Folding and Binding under Crowding: Optimization of Accuracy and Speed.A method for computing association rate constants of atomistically represented proteins under macromolecular crowding.Generalized fundamental measure theory for atomistic modeling of macromolecular crowding.Rate theories for biologists Simulation and Modeling of Crowding Effects on the Thermodynamic and Kinetic Properties of Proteins with Atomic Details.Influence of crowded cellular environments on protein folding, binding, and oligomerization: biological consequences and potentials of atomistic modeling.Competitive interactions of ligands and macromolecular crowders with maltose binding protein.An FFT-based method for modeling protein folding and binding under crowding: benchmarking on ellipsoidal and all-atom crowders Effects of Macromolecular Crowding on the Conformational Ensembles of Disordered Proteins.Folding free energy surfaces of three small proteins under crowding: validation of the postprocessing method by direct simulation Reaching new levels of realism in modeling biological macromolecules in cellular environments.Challenges in structural approaches to cell modeling.Protein folding, binding, and droplet formation in cell-like conditions.Variable interactions between protein crowders and biomolecular solutes are important in understanding cellular crowding Crowding in Cellular Environments at an Atomistic Level from Computer Simulations.

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P2860

Method to Predict Crowding Effects by Postprocessing Molecular Dynamics Trajectories: Application to the Flap Dynamics of HIV-1 Protease.

http://www.wikidata.org/entity/Q39586183

description

2009 nî lūn-bûn

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2009年の論文

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2009年論文

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2009年論文

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2009年論文

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2009年論文

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2009年論文

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2009年论文

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2009年论文

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2009年论文

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name

Method to Predict Crowding Eff ...... ap Dynamics of HIV-1 Protease.

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Method to Predict Crowding Eff ...... ap Dynamics of HIV-1 Protease.

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type

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Method to Predict Crowding Eff ...... ap Dynamics of HIV-1 Protease.

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Method to Predict Crowding Eff ...... ap Dynamics of HIV-1 Protease.

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prefLabel

Method to Predict Crowding Eff ...... ap Dynamics of HIV-1 Protease.

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Method to Predict Crowding Eff ...... ap Dynamics of HIV-1 Protease.

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Journal of Physical Chemistry Letters

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Method to Predict Crowding Eff ...... lap Dynamics of HIV-1 Protease

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J Andrew McCammon

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Sanbo Qin

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P2860

Macromolecular crowding and confinement: biochemical, biophysical, and potential physiological consequences

HIV-1 Protease Inhibitors from Inverse Design in the Substrate Envelope Exhibit Subnanomolar Binding to Drug-Resistant Variants

Effect of Flap Mutations on Structure of HIV-1 Protease and Inhibition by Saquinavir and Darunavir

Protein structure determination in living cells by in-cell NMR spectroscopy

HIV-1 protease substrate binding and product release pathways explored with coarse-grained molecular dynamics.

HIV-1 protease flaps spontaneously open and reclose in molecular dynamics simulations.

Molecular crowding enhances native state stability and refolding rates of globular proteins.

Solution structure of HIV-1 protease flaps probed by comparison of molecular dynamics simulation ensembles and EPR experiments.

Gated binding of ligands to HIV-1 protease: Brownian dynamics simulations in a coarse-grained model.

Molecular crowding enhances native structure and stability of alpha/beta protein flavodoxin.

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107-110

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10.1021/JZ900023W

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1

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Huan-Xiang Zhou

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2009-11-09T00:00:00Z

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41944416

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20228897

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