Design of molecular function: channels of communication.
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Crystal Structure of a Voltage-gated K+ Channel Pore Module in a Closed State in Lipid MembranesInflammasome-activated gasdermin D causes pyroptosis by forming membrane poresMolecular dynamics simulations of water within models of ion channels.Structure and dynamics of the pore-lining helix of the nicotinic receptor: MD simulations in water, lipid bilayers, and transbilayer bundles.Conformation and environment of channel-forming peptides: a simulation studyMutation of conserved negatively charged residues in the S2 and S3 transmembrane segments of a mammalian K+ channel selectively modulates channel gatingA single tryptophan on M2 of glutamate receptor channels confers high permeability to divalent cations.The transmembrane domain of the acetylcholine receptor: insights from simulations on synthetic peptide modelsStructure-function correlates of Vpu, a membrane protein of HIV-1.Membrane Assembly and Ion Transport Ability of a Fluorinated NanoporeChannel formation by antiapoptotic protein Bcl-2.Synthetic, biologically active amphiphilic peptidesDesign of amphiphilic protein maquettes: controlling assembly, membrane insertion, and cofactor interactionsElectrostatics and the ion selectivity of ligand-gated channels.Pores formed by the nicotinic receptor m2delta Peptide: a molecular dynamics simulation study.Molecular dynamics simulation of the M2 helices within the nicotinic acetylcholine receptor transmembrane domain: structure and collective motions.Peptide models for membrane channels.Structural and functional modularity of voltage-gated potassium channels.Assigning functions to residues in the acetylcholine receptor channel region (review).NMR and ion selective electrode studies of hydraphile channels correlate with biological activity in E. coli and B. subtilis.The dielectric properties of water within model transbilayer pores.Molecular dynamics study of water and Na+ ions in models of the pore region of the nicotinic acetylcholine receptor.The pore domain of the nicotinic acetylcholine receptor: molecular modeling, pore dimensions, and electrostatics.The C- and N-Terminal Residues of Synthetic Heptapeptide Ion Channels Influence Transport Efficacy Through Phospholipid Bilayers.Synthetic cation transporters incorporating crown ethers and calixarenes as headgroups and central relays: a comparison of sodium and chloride selectivity.Identification of an ion channel activity of the Vpu transmembrane domain and its involvement in the regulation of virus release from HIV-1-infected cells.The alpha7 nicotinic acetylcholine receptor: molecular modelling, electrostatics, and energetics.Role of natriuretic peptides in ion transport mechanisms.Structural compatibility between the putative voltage sensor of voltage-gated K+ channels and the prokaryotic KcsA channel.Membrane topology of Kch, a putative K+ channel from Escherichia coli.Biomimetically Inspired Signaling
P2860
Q27674713-EE6DC6A8-6F1E-495D-8B02-108F998EB3B3Q28511994-F6BB604D-BD89-40AC-9624-2F1F150A56D0Q30177006-9B6F1FC1-955D-4601-B78A-EC5620F12E6DQ30588345-54E2D1E2-CBA2-45FA-978D-6188BBB58943Q31028141-70334CD1-8A45-4B2F-A572-DD5F944B0BFAQ33906801-7384BA12-7798-4B4E-834B-F343EF82BE96Q34040307-631B184E-0A3B-4A0D-89F8-CC332ABEA8D1Q34189110-DCCE9924-3F1C-4C4A-B029-7333BBA9FDF2Q35217961-27F1058A-DE9C-4510-BF62-89873B0BBE87Q36190028-E9476D7F-3AB9-4AF2-83DD-F584355D8C9CQ36765713-53B1A32D-2D70-4C2E-A582-3FE0AF59DE52Q36859083-930CE859-416B-484E-9427-710700FB89C0Q36951818-55FE1C9D-2B73-42BD-9BDE-205AE937D317Q40127813-654E9179-164F-41EC-8E19-DF36AC0522C8Q40225895-82B416BA-C544-404C-AF42-3D95B386AAA6Q40329021-A38BD35C-BE62-49CB-8DB9-2A8E1C4197D7Q40979536-06A52AE3-2EAD-4CB0-99FA-FE16A739292EQ41710008-7FBE0E78-A2A1-49D7-87AA-F554AAE2D6E8Q41716127-D07B6BAD-5CDC-43B6-8FF2-DFF3D8EBB5EEQ41970265-760E3C11-91CC-4C8A-85E6-4F65C79CD5B6Q42002043-DF9E3D2B-AE9C-4256-AD0B-15DA99785680Q42266105-A62099DE-1D77-4A67-8A04-529D136862E0Q42536371-30DB3806-FE92-49AA-A716-DD917FFE97D0Q42565141-5840A383-C14A-45B3-9260-9C6199707B81Q42775733-548B1E2E-E0B4-438A-A06C-0151CB77BCEEQ45765997-7A0E0C5E-767F-4D2E-B932-44419A948DF2Q46646720-8E2E9D9B-3F02-4A7C-AC72-27EB12299F23Q48299627-2B95BCA7-77CA-4619-ADDA-78D281F5294BQ50717057-C860FDC2-A0D8-4D62-A677-23CA38F3CF84Q54578900-529C29A8-6E99-4ACC-90F5-5F85E6CE1971Q57401194-8F8DC4E9-5FD1-404E-8D64-8BF581B22921
P2860
Design of molecular function: channels of communication.
description
1995 nî lūn-bûn
@nan
1995 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
1995 թվականի հունվարին հրատարակված գիտական հոդված
@hy
1995年の論文
@ja
1995年論文
@yue
1995年論文
@zh-hant
1995年論文
@zh-hk
1995年論文
@zh-mo
1995年論文
@zh-tw
1995年论文
@wuu
name
Design of molecular function: channels of communication.
@ast
Design of molecular function: channels of communication.
@en
type
label
Design of molecular function: channels of communication.
@ast
Design of molecular function: channels of communication.
@en
prefLabel
Design of molecular function: channels of communication.
@ast
Design of molecular function: channels of communication.
@en
P1476
Design of molecular function: channels of communication.
@en
P2093
P356
10.1146/ANNUREV.BB.24.060195.000335
P577
1995-01-01T00:00:00Z