Correlation between the free energy of a channel-forming voltage-gated peptide and the spontaneous curvature of bilayer lipids.
about
The role of hydrophobic interactions in positioning of peripheral proteins in membranesRab1a and Rab5a preferentially bind to binary lipid compositions with higher stored curvature elastic energyVoltage-dependent insertion of alamethicin at phospholipid/water and octane/water interfaces.Interaction of synthetic HA2 influenza fusion peptide analog with model membranesThe secretory carrier membrane protein family: structure and membrane topology.Continuum solvent model calculations of alamethicin-membrane interactions: thermodynamic aspects.Single giant vesicle rupture events reveal multiple mechanisms of glass-supported bilayer formation.Interaction of an amphipathic peptide with phosphatidycholine/phosphatidylethanolamine mixed membranesAssessing the nature of lipid raft membranesLipid bilayer composition influences small multidrug transporters.Meet me on the other side: trans-bilayer modulation of a model voltage-gated ion channel activity by membrane electrostatics asymmetryMelittin-induced bilayer leakage depends on lipid material properties: evidence for toroidal pores.Effect of average phospholipid curvature on supported bilayer formation on glass by vesicle fusion.Activity determinants of helical antimicrobial peptides: a large-scale computational studyParadoxical lipid dependence of pores formed by the Escherichia coli alpha-hemolysin in planar phospholipid bilayer membranes.Hydrophobic surfactant proteins strongly induce negative curvatureInclusion of lateral pressure/curvature stress effects in implicit membrane modelsSystematic coarse-graining of a multicomponent lipid bilayerCurvature forces in membrane lipid-protein interactions.Influence of membrane composition on the binding and folding of a membrane lytic peptide from the non-enveloped flock house virus.ProP-ProP and ProP-phospholipid interactions determine the subcellular distribution of osmosensing transporter ProP in Escherichia coli.Calculations suggest a pathway for the transverse diffusion of a hydrophobic peptide across a lipid bilayer.Size distribution of barrel-stave aggregates of membrane peptides: influence of the bilayer lateral pressure profile.Lateral pressure profile, spontaneous curvature frustration, and the incorporation and conformation of proteins in membranes.Effect of lipid composition on the topography of membrane-associated hydrophobic helices: stabilization of transmembrane topography by anionic lipids.Melittin-lipid bilayer interactions and the role of cholesterol.Bilayers as protein solvents: role of bilayer structure and elastic properties.Physical properties of mixed bilayers containing lamellar and nonlamellar lipids: insights from coarse-grain molecular dynamics simulations.Folding a viral peptide in different membrane environments: pathway and sampling analyses.Bax-type apoptotic proteins porate pure lipid bilayers through a mechanism sensitive to intrinsic monolayer curvature.Measurements of the effect of membrane asymmetry on the mechanical properties of lipid bilayers
P2860
Q21093294-64EEF567-41C8-441C-AC6B-508E01118B5FQ24297143-9C2282A5-1088-4C64-9EF9-5B81269F6945Q28346217-979C797D-14EC-4458-ABCC-8E0C6674C460Q28367669-CC7F6C73-FEFE-4750-9B08-877EAE0E01D6Q30168763-9AB45C07-DC58-48D0-A52F-E7E88F326513Q30447495-4A236FA0-187D-4545-9919-4F72E326751BQ30479411-7AE45CF1-FA9F-4FFC-8230-020E1AC99EA8Q31121981-1BFAAFCA-7FBC-458B-9363-C9F0D16D5C16Q33275288-7B33ACD5-1EFE-4AB6-8401-32BDDA204D68Q33387030-8FB3548C-1F43-42BF-B3F2-06B052CB8BCCQ34043043-04AAC6EB-10AB-43AF-8F23-F4A91E9855B1Q34189385-6634AD67-B5A6-40C5-A892-4E77E0CC2CD6Q34354088-42CB73A4-5888-4D43-B294-80E505C5D08DQ34776684-EDBE4F6C-46F9-4DBC-B152-689A9E81BEDAQ35121277-B957053D-6AD5-4B51-B4BC-F999D67F6606Q36062901-D0DD48A2-15A3-4AFA-876B-141EA953DA04Q36592908-C54A6646-9ED7-44CE-AEBB-70C24FC3E8ECQ37077745-CD6E76DB-783B-407E-B8FB-EDB835437E0DQ37524721-97E602F2-4195-4FCF-BD5E-7DCF767FAB09Q38843789-7B2655F5-BCAE-4F48-BED0-96F4C7C2AC19Q39226790-CEA4AADE-21AA-442A-9337-13B77FC8416BQ40173072-4FBCF0DB-968B-4FB4-A6E5-46E1B6C21590Q40206272-4842DD20-C557-4D3C-84FF-1E9665B0E877Q40321363-7FE63B7D-6754-46B2-83C2-735D4D1C2506Q41785862-457C7F72-4EE7-4E81-B9C4-2F216A84B3F8Q41867473-7B025264-C9CB-4367-A90C-0EBA4DC65665Q42861287-0C12176D-8453-4B83-A504-94A46C50C3B1Q44166640-A7B63500-2A72-4546-B7B2-AD6FA56DF02BQ52691099-FDF381AB-2108-47F9-944A-3D3DF8794C2AQ54536632-1B36E0B5-6B53-4A2C-99F8-B2115F4A6C0EQ57905160-5A24FD1C-F7AD-4F11-8EA2-BB9FA92B7955
P2860
Correlation between the free energy of a channel-forming voltage-gated peptide and the spontaneous curvature of bilayer lipids.
description
1999 nî lūn-bûn
@nan
1999 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
1999 թվականի մայիսին հրատարակված գիտական հոդված
@hy
1999年の論文
@ja
1999年学术文章
@wuu
1999年学术文章
@zh-cn
1999年学术文章
@zh-hans
1999年学术文章
@zh-my
1999年学术文章
@zh-sg
1999年學術文章
@yue
name
Correlation between the free e ...... s curvature of bilayer lipids.
@ast
Correlation between the free e ...... s curvature of bilayer lipids.
@en
type
label
Correlation between the free e ...... s curvature of bilayer lipids.
@ast
Correlation between the free e ...... s curvature of bilayer lipids.
@en
prefLabel
Correlation between the free e ...... s curvature of bilayer lipids.
@ast
Correlation between the free e ...... s curvature of bilayer lipids.
@en
P356
P1433
P1476
Correlation between the free e ...... s curvature of bilayer lipids.
@en
P2093
P304
P356
10.1021/BI9828167
P407
P577
1999-05-01T00:00:00Z