Ionic selectivity, saturation, and block in gramicidin A channels. II. Saturation behavior of single channel conductances and evidence for the existence of multiple binding sites in the channel.
about
Evaluation of surface tension and ion occupancy effects on gramicidin A channel lifetime.Mimicry of a host anion channel by a Helicobacter pylori pore-forming toxin.Modeling the gramicidin channel: interpretation of experimental data using rate theoryThe permeation properties of small organic cations in gramicidin A channels.Open channel noise. V. Fluctuating barriers to ion entry in gramicidin A channelsMembrane surface-charge titration probed by gramicidin A channel conductance.Membrane dipole potential modulates proton conductance through gramicidin channel: movement of negative ionic defects inside the channel.The role of Trp side chains in tuning single proton conduction through gramicidin channels.Gating gramicidin channels in lipid bilayers: reaction coordinates and the mechanism of dissociation.Ion movement through gramicidin A channels. Single-channel measurements at very high potentials.Binding constants of Li+, K+, and Tl+ in the gramicidin channel determined from water permeability measurementsWater transport and ion-water interaction in the gramicidin channel.A model for the effects of potential and external K+ concentration on the Cs+ blocking of inward rectification.Stochastic theory of ion movement in channels with single-ion occupancy. Application to sodium permeation of gramicidin channels.Large divalent cations and electrostatic potentials adjacent to membranes. Experimental results with hexamethonium.Structure and dynamics of ion transport through gramicidin A.Investigation of Ion Channel Activities of Gramicidin A in the Presence of Ionic Liquids Using Model Cell Membranes.K+-dependent paradoxical membrane depolarization and Na+ overload, major and reversible contributors to weakness by ion channel leaks.Single-Walled Carbon Nanotubes: Mimics of Biological Ion Channels.Tryptophan contributions to the empirical free-energy profile in gramicidin A/M heterodimer channels.Optimizing planar lipid bilayer single-channel recordings for high resolution with rapid voltage stepsIon currents through pores. The roles of diffusion and external access steps in determining the currents through narrow pores.Electroporation of the photosynthetic membrane: A study by intrinsic and external optical probes.The effects of gramicidin on electroporation of lipid bilayers.Solvent drag across gramicidin channels demonstrated by microelectrodes.Desformylgramicidin: a model channel with an extremely high water permeability.Voltage-dependent formation of gramicidin channels in lipid bilayers.Single channel H+ currents through reconstituted chloroplast ATP synthase CF0-CF1Influence of ion occupancy and membrane deformation on gramicidin A channel stability in lipid membranes.Nuclear magnetic resonance of 23Na ions interacting with the gramicidin channel.Effects of double-layer polarization on ion transport.Gramicidin-mediated currents at very low permeant ion concentrations.Simulation of voltage-driven hydrated cation transport through narrow transmembrane channels.Coupling between fluxes in one-particle pores with fluctuating energy profiles. A theoretical studyMicroscopic model for selective permeation in ion channels.The effects of double-layer polarization on the conductance of gramicidin channels.On the Effects of Interfacial Polarization. A Reply to S. B. Hladky.Stochastic transport through carbon nanotubes in lipid bilayers and live cell membranes.Ionic interactions in the Drosophila serotonin transporter identify it as a serotonin channel.The current-voltage behavior of ion channels: important features of the energy profile of the gramicidin channel deduced from the conductance-voltage characteristic in the limit of low ion concentration.
P2860
Q28339017-88A096CE-E953-42C4-8950-DA560AA9F832Q30437777-D7CEA0F4-435E-434B-B211-2533FECD3EC0Q33442976-7190FAA2-D327-4F3A-B04D-F45BFE1B839FQ34092314-2430DE38-29D7-4845-880F-B92CE1D1740FQ34125649-24D09B71-6C5C-4CC5-868E-54ED3578D2CDQ34169042-CD77E3C2-EE5E-4D0A-8F09-EB5ED55BA7F2Q34177190-29A15823-94A9-4F80-924E-7265D929CC87Q34178476-38269827-4A6A-4A85-BF98-FF4F876390B3Q34184441-B86A70CC-A95C-4736-BB50-8838BFE136BAQ34249806-8EE19464-ABD8-4718-840A-B515A551155BQ34252416-2F199078-076B-4EA9-AB67-293A48405914Q34252425-E683721A-1604-4E69-B156-03F113A118E5Q34255033-D846B93F-340D-43D7-993F-A74CCD41AF98Q34259307-03DB3AEC-A0D5-4DBC-B491-99B3EAD48212Q34534508-C584FF7D-2C37-4B5B-9C1D-162671B510C4Q34535279-615344DB-1E6E-461D-A122-4E9BEEC654F7Q35865387-7E3F8419-9649-4E0E-A717-3C99790ACABAQ37102151-354F67A6-AB8F-4CB0-A281-CE6CC3ABCDC9Q37635131-C2D67EA0-784F-475A-850D-9C43B2C70C17Q38719666-0689A09D-03AB-4422-A5B6-483C314FC588Q39243851-0AFDEB2B-DA65-4CC8-AA76-D8923A65F3FAQ39341194-10A5DA08-0BF8-487E-8584-9C6215BDBA4AQ39634101-612B0B65-1D31-444C-8555-1144163E03E0Q40144402-A1449B39-706F-4C56-A873-A1A7ECF031A8Q40163105-3C99571A-AF99-401F-9E53-E5E38A41D101Q40173545-A0F3EF25-0333-4FB5-A154-8034C9F7AD79Q40187614-87FD1576-F35A-47AC-A6FD-788FCD0E6EE4Q40819422-85AFCF34-6B3E-4A69-A585-625B73C6D212Q41092701-D7722C2D-EF4F-4CF6-AB98-20F53C1DA34EQ41137257-23340F99-15BD-454A-9909-E2A1DA5316DCQ41159891-05A137F1-AEC9-4F31-8574-CC541D5B0A7AQ41168440-64DDFAB7-880A-478F-9BE2-92CC813CB9A4Q41170136-4311442D-2881-4574-BA1F-7A29CDBD032DQ41910867-390FBE35-07A6-4FB2-AF3C-B52267AA78C0Q42580730-34BF2E7B-BEE8-4BE1-96C6-37F4CB24229EQ43174254-33D333AA-9C05-4068-827F-FE83F8278EA2Q46069021-EDF1273A-D47C-4F1E-85F0-B5824465084BQ46975335-A73C2491-F6FF-4688-A73C-4E2331B1D813Q47072017-58439482-AEA2-4605-91CB-B5078787BDBCQ48666160-56711486-1057-4B7A-A4DB-5BC1F908C6F1
P2860
Ionic selectivity, saturation, and block in gramicidin A channels. II. Saturation behavior of single channel conductances and evidence for the existence of multiple binding sites in the channel.
description
1978 nî lūn-bûn
@nan
1978年の論文
@ja
1978年学术文章
@wuu
1978年学术文章
@zh-cn
1978年学术文章
@zh-hans
1978年学术文章
@zh-my
1978年学术文章
@zh-sg
1978年學術文章
@yue
1978年學術文章
@zh
1978年學術文章
@zh-hant
name
Ionic selectivity, saturation, ...... binding sites in the channel.
@en
Ionic selectivity, saturation, ...... binding sites in the channel.
@nl
type
label
Ionic selectivity, saturation, ...... binding sites in the channel.
@en
Ionic selectivity, saturation, ...... binding sites in the channel.
@nl
prefLabel
Ionic selectivity, saturation, ...... binding sites in the channel.
@en
Ionic selectivity, saturation, ...... binding sites in the channel.
@nl
P356
P1476
Ionic selectivity, saturation, ...... binding sites in the channel.
@en
P2093
G Eisenman
J Sandblom
P2888
P304
P356
10.1007/BF01871143
P50
P577
1978-04-01T00:00:00Z