Translational-entropy gain of solvent upon protein folding. - Wikidata - wikimedia - TriplyDB

Translational-entropy gain of solvent upon protein folding.

Translational-entropy gain of solvent upon protein folding.

http://www.wikidata.org/entity/Q42183805

about

Binding of an RNA aptamer and a partial peptide of a prion protein: crucial importance of water entropy in molecular recognition Atomic hydration potentials using a Monte Carlo Reference State (MCRS) for protein solvation modeling.Sodium perchlorate effects on the helical stability of a mainly alanine peptide.A scoring function based on solvation thermodynamics for protein structure prediction.Thermal unfolding of barstar and the properties of interfacial water around the unfolded forms.Confined water inside single-walled carbon nanotubes: global phase diagram and effect of finite length.Evolution of Escherichia coli to 42 °C and subsequent genetic engineering reveals adaptive mechanisms and novel mutations.Importance of translational entropy of water in biological self-assembly processes like protein folding.A new theoretical approach to biological self-assembly.Effects of salt or cosolvent addition on solubility of a hydrophobic solute in water: Relevance to those on thermal stability of a protein.Correlation analysis for heat denaturation of Trp-cage miniprotein with explicit solvent.Effects of monohydric alcohols and polyols on the thermal stability of a protein.Entropic potential field formed for a linear-motor protein near a filament: Statistical-mechanical analyses using simple models.Effects of heme on the thermal stability of mesophilic and thermophilic cytochromes c: comparison between experimental and theoretical results.About targets and causes in protein folding.Molecular origin of the hydrophobic effect: analysis using the angle-dependent integral equation theory.Unraveling protein folding mechanism by analyzing the hierarchy of models with increasing level of detail.Unified elucidation of the entropy-driven and -opposed hydrophobic effects.Hydrophobicity at low temperatures and cold denaturation of a protein.A driving force for polypeptide and protein collapse.Effects of sugars on the thermal stability of a protein.Physical origins of the high structural stability of CLN025 with only ten residues.On the physics of multidrug efflux through a biomolecular complex.Physical origin of hydrophobicity studied in terms of cold denaturation of proteins: comparison between water and simple fluids.Identification of thermostabilizing mutations for a membrane protein whose three-dimensional structure is unknown.Structural characteristics of yeast F1-ATPase before and after 16-degree rotation of the γ subunit: theoretical analysis focused on the water-entropy effect.Potential of mean force between a large solute and a biomolecular complex: a model analysis on protein flux through chaperonin system.Crucial importance of the water-entropy effect in predicting hot spots in protein-protein complexes.Morphometric approach to thermodynamic quantities of solvation of complex molecules: extension to multicomponent solvent.Effects of side-chain packing on the formation of secondary structures in protein folding.A theoretical analysis on characteristics of protein structures induced by cold denaturation.Pressure effects on structures formed by entropically driven self-assembly: illustration for denaturation of proteins.Molecular origin of the negative heat capacity of hydrophilic hydration.Thermodynamics of apoplastocyanin folding: comparison between experimental and theoretical results.Changes in thermodynamic quantities upon contact of two solutes in solvent under isochoric and isobaric conditions.Depletion potential between large spheres immersed in a multicomponent mixture of small spheres.A theoretical analysis on hydration thermodynamics of proteins.Crucial importance of translational entropy of water in pressure denaturation of proteins.Packaging effects on site-specific DNA-protein interactions.Emergence of secondary motifs in tubelike polymers in a solvent

P2860

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P2860

Translational-entropy gain of solvent upon protein folding.

http://www.wikidata.org/entity/Q42183805

description

2005 nî lūn-bûn

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2005年學術文章

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name

Translational-entropy gain of solvent upon protein folding.

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Translational-entropy gain of solvent upon protein folding.

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type

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Translational-entropy gain of solvent upon protein folding.

@en

Translational-entropy gain of solvent upon protein folding.

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prefLabel

Translational-entropy gain of solvent upon protein folding.

@en

Translational-entropy gain of solvent upon protein folding.

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BIOPHYSJ.104.057604

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Biophysical Journal

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Translational-entropy gain of solvent upon protein folding.

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Masahiro Kinoshita

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Yuichi Harano

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P2860

Contribution of the hydrophobic effect to the stability of human lysozyme: calorimetric studies and X-ray structural analyses of the nine valine to alanine mutants

Some factors in the interpretation of protein denaturation

Protein folding and misfolding

The interpretation of protein structures: total volume, group volume distributions and packing density

Native proteins are surface-molten solids: application of the Lindemann criterion for the solid versus liquid state

Dominant forces in protein folding

Mutagenesis of a buried polar interaction in an SH3 domain: sequence conservation provides the best prediction of stability effects.

The packing density in proteins: standard radii and volumes.

Protein packing: dependence on protein size, secondary structure and amino acid composition.

Polar group burial contributes more to protein stability than nonpolar group burial.

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10.1529/BIOPHYSJ.104.057604

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protein folding

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