about
Mechanisms of viral entry: sneaking in the front doorDissecting Virus Infectious Cycles by Cryo-Electron MicroscopyDynamic Viral Glycoprotein Machines: Approaches for Probing Transient States That Drive Membrane FusionCell entry of enveloped virusesThe full-length cell-cell fusogen EFF-1 is monomeric and upright on the membrane.Fusion of Enveloped Viruses in Endosomes.Viral membrane fusion.Structure and accessibility of HA trimers on intact 2009 H1N1 pandemic influenza virus to stem region-specific neutralizing antibodiesInfluenza A induced cellular signal transduction pathways.Visualization of the two-step fusion process of the retrovirus avian sarcoma/leukosis virus by cryo-electron tomography.Visualization and Sequencing of Membrane Remodeling Leading to Influenza Virus Fusion.Viral fusion: how Flu induces dimples on liposomes.It's what's inside that mattersExpansion of the fusion stalk and its implication for biological membrane fusion.Spatial structure peculiarities of influenza A virus matrix M1 protein in an acidic solution that simulates the internal lysosomal medium.Structural changes in Influenza virus at low pH characterized by cryo-electron tomographyMitofusins and the mitochondrial permeability transition: the potential downside of mitochondrial fusionLine-tension controlled mechanism for influenza fusion.Two conserved residues are important for inducing highly ordered membrane domains by the transmembrane domain of influenza hemagglutinin.Direct three-dimensional visualization of membrane disruption by amyloid fibrilsAt low pH, influenza virus matrix protein M1 undergoes a conformational change prior to dissociating from the membrane.Structural analysis of influenza A virus matrix protein M1 and its self-assemblies at low pH.A cool hybrid approach to the herpesvirus 'life' cycle.Stochastic fusion simulations and experiments suggest passive and active roles of hemagglutinin during membrane fusion.Electron tomography imaging of surface glycoproteins on human parainfluenza virus 3: association of receptor binding and fusion proteins before receptor engagementViral life cycles captured in three-dimensions with electron microscopy tomography.Capturing a fusion intermediate of influenza hemagglutinin with a cholesterol-conjugated peptide, a new antiviral strategy for influenza virus.Influenza virus-mediated membrane fusion: Structural insights from electron microscopy.Capture and imaging of a prehairpin fusion intermediate of the paramyxovirus PIV5The Interaction between Influenza HA Fusion Peptide and Transmembrane Domain Affects Membrane StructurepH-Dependent Formation and Disintegration of the Influenza A Virus Protein Scaffold To Provide Tension for Membrane FusionInfluenza-virus membrane fusion by cooperative fold-back of stochastically induced hemagglutinin intermediates.The hemifusion structure induced by influenza virus haemagglutinin is determined by physical properties of the target membranesProtein-lipid interactions critical to replication of the influenza A virus.pH-Controlled two-step uncoating of influenza virus.Palmitoylation contributes to membrane curvature in Influenza A virus assembly and hemagglutinin-mediated membrane fusion.Low pH and Anionic Lipid-dependent Fusion of Uukuniemi Phlebovirus to Liposomes.Structure and organization of paramyxovirus particles.Crystal structure of an orthomyxovirus matrix protein reveals mechanisms for self-polymerization and membrane association.Cryomicroscopy provides structural snapshots of influenza virus membrane fusion.
P2860
Q22252690-C50833BA-530D-4F47-B631-EBBCF79F6DA7Q26700032-44345DBA-C730-4566-A2A4-A08DD899F7C0Q26772129-61DFBD96-37E9-46B5-9AC7-3B7C8BF6F434Q26863682-11080277-034C-4416-85E7-8F16D41B50A7Q27683968-C9F9D265-8CD7-471F-9BBD-1E31BC42D396Q28073406-85C08013-E6C0-4AF8-A58B-03600C664F8BQ28080422-022A2605-4522-4EC5-9D62-4262D73C9FC9Q28396120-80ECCD2C-DE35-4005-BB34-4FD1884AE6CAQ30353167-0CC50A0A-CABB-4C1A-A3F1-0987C34A96C5Q30419638-E069D3BD-4E3E-43F7-9214-50364F363820Q30784849-D5FEC1E5-0176-49EE-9EFA-B32A94F48CE0Q33550068-E9A93F1C-629A-4491-B0BA-E47C414DA5F6Q33990993-A504A29F-DA16-49FA-AABF-12B95A547665Q34002261-4196C153-0FBB-4177-ABB7-E48DBF88FF96Q34045278-4CC907A0-FFDF-402D-9F5A-13DDAB0458A2Q34132726-C58B308D-8E58-49DC-A97C-1799812C5D8CQ34277591-B1D6DE5C-EC9B-4DE7-96E8-77DBA106B205Q34325691-711CBE1A-2DC6-4E01-B50A-47DD68A46934Q34439432-4CE46585-0B62-4739-B802-F8A2F7B9BFDCQ34489472-FA96490E-BEF9-4E89-9975-2877124B3FC0Q34610979-9E540209-6174-44CB-A238-13434F4176F5Q35072754-DDDCEA71-44EF-4E4A-9D62-0D20B1D3F223Q35098318-DC3C79DB-7CE8-48AE-963B-3D9012579CD2Q35100328-D6B41C29-0E81-4A00-B1F6-3C114EED7DD5Q35111139-2DF8F14E-F401-48FD-B4A2-9F21AD846428Q35185628-87FBC5B7-1C54-4531-9F5B-DFC8BE47FC74Q35604856-1FC4A469-2A61-4D64-A9F5-F9C8F80D4E81Q35626070-FD867C9B-C24F-438B-9CD9-55DEBCF5C380Q35641392-5DC84B5C-0016-4EBA-93FB-8DBD224EFE0FQ36426451-5A590044-F771-459B-876A-7D3D07358EE3Q36433928-0E7633A0-9627-4F1C-A179-0123E959B70EQ36626209-67F1A292-352F-4C16-9281-5C2C9ACD8A47Q36926306-FE1DB26A-90EA-4068-A847-0746453C3A9EQ37222632-72EDC88D-B177-4093-975E-809144842097Q38623080-ECF92ACE-D332-436E-9B4F-2105E1710ECDQ38631745-1D601FA3-CEBE-4EB1-B704-DBC0CAD0D98DQ38799398-BA4608A9-E477-4CF6-B4D3-68982D576505Q39364461-AB2A299A-F505-450B-8BC3-35E7FB30DEB5Q40109947-BD2ECFA8-F61C-4E11-989A-FB7BFA388F67Q40584230-6DFDA319-74B5-4879-B2A2-9AFEDD9D0486
P2860
description
2010 nî lūn-bûn
@nan
2010 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Architecture of a nascent viral fusion pore.
@ast
Architecture of a nascent viral fusion pore.
@en
type
label
Architecture of a nascent viral fusion pore.
@ast
Architecture of a nascent viral fusion pore.
@en
prefLabel
Architecture of a nascent viral fusion pore.
@ast
Architecture of a nascent viral fusion pore.
@en
P2860
P356
P1433
P1476
Architecture of a nascent viral fusion pore.
@en
P2093
Kelly K Lee
P2860
P304
P356
10.1038/EMBOJ.2010.13
P407
P577
2010-02-18T00:00:00Z