Water in nonpolar confinement: from nanotubes to proteins and beyond.
about
Principles of conduction and hydrophobic gating in K+ channelsOptimizing water permeability through the hourglass shape of aquaporinsWater in cavity-ligand recognition.Dry amyloid fibril assembly in a yeast prion peptide is mediated by long-lived structures containing water wiresAn antifreeze protein folds with an interior network of more than 400 semi-clathrate watersGrid inhomogeneous solvation theory: hydration structure and thermodynamics of the miniature receptor cucurbit[7]urilTowards a structural biology of the hydrophobic effect in protein foldingNecessity of capillary modes in a minimal model of nanoscale hydrophobic solvationAb initio H2O in realistic hydrophilic confinement.An ab initio microscope: molecular contributions to the femtosecond time-dependent fluorescence shift of a Reichardt-type dye.Watching Proteins Wiggle: Mapping Structures with Two-Dimensional Infrared Spectroscopy.Solvent fluctuations in hydrophobic cavity-ligand binding kinetics.Internal water and microsecond dynamics in myoglobinNMR studies on the temperature-dependent dynamics of confined water.Properties of water confined in ionic liquids.Pore hydration states of KcsA potassium channels in membranesSitting at the edge: how biomolecules use hydrophobicity to tune their interactions and functionA review about nothing: are apolar cavities in proteins really empty?Phase transition of nanotube-confined water driven by electric field.Entropy of single-file water in (6,6) carbon nanotubesConformational changes of an ion channel detected through water-protein interactions using solid-state NMR spectroscopy.A one-dimensional dipole lattice model for water in narrow nanopores.Ion Rejection by Nanoporous Membranes in Pressure-Driven Molecular Dynamics Simulations.Non-bulk-like solvent behavior in the ribosome exit tunnel.Water in the polar and nonpolar cavities of the protein interleukin-1β.Formation of an Amine-Water Cyclic Pentamer: A New Type of Water Cluster in a PolyazacryptandWater in the active site of ketosteroid isomerase.Hydrophobic interactions and clustering in a porous capsule: option to remove hydrophobic materials from water.Role of electrostatics in modulating hydrophobic interactions and barriers to hydrophobic assembly.How Can Hydrophobic Association Be Enthalpy Driven?Synthetic chloride-selective carbon nanotubes examined by using molecular and stochastic dynamics.Unimpeded permeation of water through helium-leak-tight graphene-based membranes.Electrostatic contribution from solvent in modulating single-walled carbon nanotube associationElectrostatic field-exposed water in nanotube at constant axial pressure.From linking of metal-oxide building blocks in a dynamic library to giant clusters with unique properties and towards adaptive chemistry.Dynamics and energetics of hydrophobically confined water.Separating instability from aggregation propensity in γS-crystallin variants.Rapid X-ray photoreduction of dimetal-oxygen cofactors in ribonucleotide reductase.Tidal surge in the M2 proton channel, sensed by 2D IR spectroscopy.Macroscopically ordered water in nanopores
P2860
Q24600608-521BF6C7-D142-41E2-A856-EDBAEADCB91CQ24607996-1A8FDB83-4383-42EC-A832-062F882D115BQ24618521-3E0FE37F-8955-4148-A541-018831AA5F80Q24628864-4B4BCF73-F50E-4399-9362-35D659CA4364Q27689105-4EDDAB59-C3FD-44E1-ADEB-ECD6A1014C3DQ28387381-A78F9102-54EC-43ED-960F-AC218555AC74Q28828746-A24BC51F-33A3-4F3C-B80A-C013270A73C9Q28834342-4DB402CA-DDA2-47F4-8CB6-FBEF04106EB7Q30317092-C0185006-B500-4DEB-A0F7-0D04D4E8AEBDQ30317907-F46CF5D9-F6A6-466E-9CBF-F8D2D2B1BAEAQ30397133-D4235ACB-6A8D-48D8-A191-D847040A71B4Q30533272-BF558674-2C41-40D0-998D-0CF1CBE0AA06Q30574665-2D941D24-57EC-4AFC-B962-2B0D2504274FQ30840866-D32946C2-8839-4E4E-8626-029E6A5A3FD1Q30961333-212EF82D-2CF1-497A-B1B3-8EC1EF33900BQ30993548-9B14595B-CB84-4E5B-B68D-29FC5DB3F2ECQ33352827-97FCA7E6-5D5A-4B17-85BD-E9551ECEFE57Q33412209-E22EDCB1-957A-483C-A02B-7B1666A9C947Q33450225-F73BC624-AC0D-4DAF-97F3-A67C20F0F5E7Q33455392-3E04AFF6-C71F-4454-9D97-5A3AECFC9974Q33527484-7A779C60-D98D-4E68-8ADA-66C79F9827F6Q33703215-53CD69A1-8A58-4832-BA80-96277A8B8167Q33714418-23837204-3DFE-40EC-BDC0-A82A0D260D32Q33727971-3E87DF6E-F452-4741-8B09-38DA9251EA46Q33736938-98BC3B5B-B205-424E-9F30-9123D69CDAEBQ33863079-A1DAEF9E-A8E7-481A-8E1C-D38FD6519D88Q33944641-29906A12-AA12-4809-82C5-EC5B911B01B7Q33958539-18815426-BBC3-4168-864B-E15F34D402D4Q34046775-3244CE70-1638-4E3B-A269-40822D824B9AQ34124905-9EEA7D94-E1C4-442A-8F28-28B7D06B37D3Q34134610-DF7DA494-57B2-4A8F-8330-41250FFC1436Q34250071-1A467C79-8FED-43AF-B09C-6F41FE648244Q34296471-8E1FB72C-71E6-4A35-B514-A06782F93F28Q34347426-5910B6FA-F535-4093-ACE5-CF5FD3178F5AQ34403250-CB55AEE7-1E12-46CF-B422-F6433AF6F321Q34425748-22480A23-BD79-43D0-973B-213559BE3C39Q34494376-2F24F2CC-FF67-4BF9-9DEE-659EC76641ECQ34582760-F101F743-E82E-474D-ACCB-D2EE93D5F602Q34794456-C39AF392-6E6B-4E5E-8D24-A3444550DFC1Q34819765-7AB0E7C9-0CAD-4D4F-B4DB-C4D76D2D5227
P2860
Water in nonpolar confinement: from nanotubes to proteins and beyond.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on January 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Water in nonpolar confinement: from nanotubes to proteins and beyond.
@en
Water in nonpolar confinement: from nanotubes to proteins and beyond.
@nl
type
label
Water in nonpolar confinement: from nanotubes to proteins and beyond.
@en
Water in nonpolar confinement: from nanotubes to proteins and beyond.
@nl
prefLabel
Water in nonpolar confinement: from nanotubes to proteins and beyond.
@en
Water in nonpolar confinement: from nanotubes to proteins and beyond.
@nl
P1476
Water in nonpolar confinement: from nanotubes to proteins and beyond.
@en
P2093
Jayendran C Rasaiah
Shekhar Garde
P304
P356
10.1146/ANNUREV.PHYSCHEM.59.032607.093815
P577
2008-01-01T00:00:00Z