about
Mechanical properties of lipid bilayers and regulation of mechanosensitive function: from biological to biomimetic channelsNovel formulations for antimicrobial peptidesSpatial structure of zervamicin IIB bound to DPC micelles: implications for voltage-gatingA synthetic all D-amino acid peptide corresponding to the N-terminal sequence of HIV-1 gp41 recognizes the wild-type fusion peptide in the membrane and inhibits HIV-1 envelope glycoprotein-mediated cell fusionAqueous solubilization of transmembrane peptide sequences with retention of membrane insertion and functionInfluence of membrane-spanning alpha-helical peptides on the phase behavior of the dioleoylphosphatidylcholine/water system.Modulation of mitochondrial Ca2+ by nitric oxide in cultured bovine vascular endothelial cells.Characteristics and function of cardiac mitochondrial nitric oxide synthase.Molecular modeling of the reductase domain to elucidate the reaction mechanism of reduction of peptidyl thioester into its corresponding alcohol in non-ribosomal peptide synthetases.Polymorphism and interactions of a viral fusion peptide in a compressed lipid monolayer.Cluster organization and pore structure of ion channels formed by beticolin 3, a nonpeptidic fungal toxinAsymmetrical ion-channel model inferred from two-dimensional crystallization of a peptide antibiotic.NMR structures of the second transmembrane domain of the human glycine receptor alpha(1) subunit: model of pore architecture and channel gating.Spontaneous changes in mitochondrial membrane potential in single isolated brain mitochondriaHow did cells get their size?Oncolytic activities of host defense peptides.Inorganic polyphosphate is a potent activator of the mitochondrial permeability transition pore in cardiac myocytes.Crystal structure of the channel-forming polypeptide antiamoebin in a membrane-mimetic environment.Direct visualization of the alamethicin pore formed in a planar phospholipid matrix.Mitochondria-mediated cardioprotection by trimetazidine in rabbit heart failure.Composite S-layer lipid structuresElectron spin resonance in membrane research: protein-lipid interactions from challenging beginnings to state of the art.Structure of magainin and alamethicin in model membranes studied by x-ray reflectivityDesformylgramicidin: a model channel with an extremely high water permeability.Conformation of peptides in lipid membranes studied by x-ray grazing incidence scattering.Backbone dynamics of alamethicin bound to lipid membranes: spin-echo electron paramagnetic resonance of TOAC-spin labels.Utilizing ESEEM spectroscopy to locate the position of specific regions of membrane-active peptides within model membranesIntramembrane water associated with TOAC spin-labeled alamethicin: electron spin-echo envelope modulation by D2O.Mastoparan effects in skeletal muscle damage: An ultrastructural view until now concealed.IS3 peptide-formed ion channels in rat skeletal muscle cell membranes.Gaegurin 4, a peptide antibiotic of frog skin, forms voltage-dependent channels in planar lipid bilayers.Peptide model helices in lipid membranes: insertion, positioning, and lipid response on aggregation studied by X-ray scattering.A single-residue deletion alters the lipid selectivity of a K+ channel-associated peptide in the beta-conformation: spin label electron spin resonance studies.Dichroic ratios in polarized Fourier transform infrared for nonaxial symmetry of beta-sheet structures.Catalytic activity of NADH-ubiquinone oxidoreductase (complex I) in intact mitochondria. evidence for the slow active/inactive transition.Origins of globular structure in proteins.Total syntheses in solution of TOAC-labelled alamethicin F50/5 analogues.Assembling an ion channel: ORF 3a from SARS-CoV
P2860
Q26864371-3A8288D8-9899-4C17-B4BA-BD5313C7DAAEQ26991771-FFCAADCC-E4B5-4380-878B-B454EA92807EQ27637462-4AD144F4-4C24-4CB7-8BE1-B8A4EB3BCE53Q28379574-63A5409A-48F4-4025-96A3-91D85AEE7E4FQ32135063-CBFD9BC1-6DC3-4064-8849-9AFF0F1D251AQ32163240-4BF33A70-AE11-4BF9-85CA-E93007815BFDQ33215301-4F1AED32-53A1-4673-AAF0-24522F1F0C65Q33395207-B8D07C9E-F9C4-43D0-8AD8-6BB1DEFD4763Q33523394-ADBEE74E-4402-4D2D-A8C7-EB59E0D9F540Q34170662-80396682-1553-4D31-B1A3-30EF4BF57F1DQ34171926-573F5991-B145-4BD4-A989-2FFB4E2C3983Q34173262-13DA3C99-24EC-405C-A8C1-DD0B8F1B530EQ34178286-BBD30B4A-FA3A-4AB3-8BFB-C161002BEBA9Q34183696-4F435BEC-2C04-41F0-A025-2EBBBBE9F91EQ34968961-76538EDC-066A-4895-96B3-867C1FFEF164Q35600198-C53F9F29-D411-4AFB-9F33-F5CAE3960442Q35931855-13CD511E-070B-47C3-8A3B-649E9C586926Q36089557-DE834D58-5A80-41E9-8188-51985F22B60FQ36504320-45559783-1910-412F-9B9E-1DFD75D4B2FAQ36896507-34F87AF0-5EB5-466C-B43B-78CB4990EF38Q37419962-1E2DE91F-1A3B-47F4-8C12-3007F91CC683Q37577692-31A9396C-7E31-4DB0-A03D-58A8D7141421Q38719298-352F059B-2D5B-420F-AED7-3360DA47D078Q40173545-FE7F3C9A-691D-4EC5-B47E-2109639F2F64Q40288252-71CF6F53-CB0E-4854-B845-DBE697DBD069Q42011760-C7A320E1-21E3-42E8-BCCD-1A58F201F542Q42087234-BFA68D8A-4316-4AB5-8115-F15FDEDEAAD4Q42123566-E39EC467-465B-41C6-B119-7CB048947109Q42522395-CE90C705-5F98-44FE-89AA-2A845BEFBF96Q42595998-A97ACFE5-827A-4968-A353-B478EE058B28Q42598834-F673E8F0-9CFF-4217-A1E0-99DFC9FF15D6Q42709611-10AE2D9A-1696-4E99-B608-EC8A693CB13FQ42929167-840CA4CA-ECB5-46F2-A202-D0C187B75EA6Q42933715-A2244B32-672F-4458-9E41-C429847D141DQ43513177-6BC38538-67B2-48C1-92EA-944BED38AB70Q47750043-9682DBB5-33B7-419A-AED9-C6A52599CCCBQ53810351-497E508A-4194-4E7D-89D7-7207F58188EDQ57243789-3ABE0AB2-B0DE-4CD2-A2AC-55AE3EE6E8E1
P2860
description
1996 nî lūn-bûn
@nan
1996年の論文
@ja
1996年論文
@yue
1996年論文
@zh-hant
1996年論文
@zh-hk
1996年論文
@zh-mo
1996年論文
@zh-tw
1996年论文
@wuu
1996年论文
@zh
1996年论文
@zh-cn
name
Peptide models for membrane channels.
@en
type
label
Peptide models for membrane channels.
@en
prefLabel
Peptide models for membrane channels.
@en
P2860
P356
P1433
P1476
Peptide models for membrane channels.
@en
P2093
P2860
P304
P356
10.1042/BJ3150345
P407
P478
315 ( Pt 2)
P577
1996-04-01T00:00:00Z