about
A single-vesicle content mixing assay for SNARE-mediated membrane fusion.Single-Vesicle Fusion Assay Reveals Munc18-1 Binding to the SNARE Core Is Sufficient for Stimulating Membrane FusionSingle-molecule FRET study of SNARE-mediated membrane fusionOpen syntaxin docks synaptic vesiclesComplexin cross-links prefusion SNAREs into a zigzag arrayHigh cholesterol obviates a prolonged hemifusion intermediate in fast SNARE-mediated membrane fusionReconstituting SNARE-mediated membrane fusion at the single liposome level.Rapid fusion of synaptic vesicles with reconstituted target SNARE membranesSingle SNARE-mediated vesicle fusion observed in vitro by polarized TIRFMDocking and fast fusion of synaptobrevin vesicles depends on the lipid compositions of the vesicle and the acceptor SNARE complex-containing target membrane.Single vesicle millisecond fusion kinetics reveals number of SNARE complexes optimal for fast SNARE-mediated membrane fusion.Supported double membranesImaging fast SNARE mediated-membrane fusion in planar-supported bilayers.Triggering and visualizing the aggregation and fusion of lipid membranes in microfluidic chambersMultiple intermediates in SNARE-induced membrane fusion.Rapid membrane fusion of individual virus particles with supported lipid bilayers.Kinetics of DNA-mediated docking reactions between vesicles tethered to supported lipid bilayersProductive hemifusion intermediates in fast vesicle fusion driven by neuronal SNAREs.The dynamics of somatic exocytosis in monoaminergic neurons.Robust polarity establishment occurs via an endocytosis-based cortical corralling mechanism.A single vesicle-vesicle fusion assay for in vitro studies of SNAREs and accessory proteins.Single molecule mechanical probing of the SNARE protein interactions.Atomic force microscope spectroscopy reveals a hemifusion intermediate during soluble N-ethylmaleimide-sensitive factor-attachment protein receptors-mediated membrane fusionA fluorescence-based technique to construct size distributions from single-object measurements: application to the extrusion of lipid vesicles.Lipid mixing and content release in single-vesicle, SNARE-driven fusion assay with 1-5 ms resolution.Model of SNARE-mediated membrane adhesion kinetics.Pulling force generated by interacting SNAREs facilitates membrane hemifusion.Single Molecule Measurements of Interaction Free Energies Between the Proteins Within Binary and Ternary SNARE ComplexesInvestigation of SNARE-Mediated Membrane Fusion Mechanism Using Atomic Force Microscopy.Atomic-resolution simulations predict a transition state for vesicle fusion defined by contact of a few lipid tails.A fast, single-vesicle fusion assay mimics physiological SNARE requirements.Single-molecule studies of the neuronal SNARE fusion machinery.Accessory proteins stabilize the acceptor complex for synaptobrevin, the 1:1 syntaxin/SNAP-25 complexNonaggregated α-synuclein influences SNARE-dependent vesicle docking via membrane binding.Docking, not fusion, as the rate-limiting step in a SNARE-driven vesicle fusion assayMembrane bridging and hemifusion by denaturated Munc18.Protein determinants of SNARE-mediated lipid mixing.Model systems for membrane fusion.Solution single-vesicle assay reveals PIP2-mediated sequential actions of synaptotagmin-1 on SNAREs.Are there too many or too few SNAREs in proteoliposomes?
P2860
Q24601072-9FE8B7F8-43F8-40BA-B308-06FC64AEA7A8Q24622854-417CDB03-DE44-440B-9C93-C3A14E8DF022Q27024748-A546D9B0-D334-44EC-9969-1A0F5E239482Q27334556-4E11F239-B3FE-43CB-9EE7-437554F1FB70Q27670976-128694B7-8C53-4B27-907F-18BCBEBCA1C1Q30278968-E51B8C6D-9824-48DF-B5C8-53E26370BB24Q30299902-B92D62D7-7363-4EC6-95E8-0DCD290158EDQ30413162-124BF343-B6B1-41F5-9B2F-8B3EED372A8AQ30429282-D5ACF89D-6241-465E-9B71-52E0D115BC15Q30429848-87AA7881-B08E-4B4D-8C48-AE1548549652Q30434163-119AF45D-0A36-4332-A6AD-94D343E8989AQ30434672-C1F64734-6DBB-458B-8E40-847229BD8A10Q30437774-86757643-6198-4A08-B4F2-C3EC057627B7Q30477428-54AC520D-D0EA-4584-9999-8263AE17E4C9Q30478481-B4106564-8752-417A-8DB4-D8A8AAB0B3ECQ30479669-666AC8DC-CE26-4730-9BC9-FB4EA744C054Q30480860-745F7CF7-4EC4-459E-A476-2318F4677416Q30481113-938F26C7-2506-4B76-BFAA-D5602FE92050Q30527965-447E3567-F67E-424D-835B-92DFAEC14A23Q30536170-E678F32A-541B-485B-935D-4E127020F446Q30643815-7DC65999-7AB3-4505-8D7C-4EF99B943EFAQ33241577-677090B0-82AA-4AB7-AE21-4140CB7B3061Q33299157-3F098FEF-04DC-45BB-B85E-6EACEE89BCEFQ33329460-403E388C-D6DB-4B46-ABF4-D1021DB78157Q33446904-BB2F7D05-13CC-491A-A47A-855443B064C1Q33489548-11C22A66-232B-4A4D-8EB0-C91DAD53EA53Q33519916-D36EC904-EAC1-46EF-939A-98FA690D35A1Q33526994-62A113A0-945D-49DE-8C04-DD6393D054F7Q33540688-DF7105F0-59B8-40C7-91BA-9A32903D724BQ33619201-427F49F0-A629-4A9A-BDC8-556A31FA3282Q33734625-0D879597-D3F0-45A9-A9A6-8D7834B92175Q33789507-59D8330F-FE20-4BC5-80B6-6FC9D65D2D0CQ33797927-72CF1AC1-50F2-4D82-A698-384ABB430973Q33824692-613EB5CB-A76B-40C6-A2EC-F77BC7785CECQ33888728-B1D278BB-1288-4284-811B-983D9C6F59E0Q33963890-8F012D12-B348-472E-AEC8-6E57FF1A256BQ33999406-50B69622-A732-4FAD-866B-9FA5CC549A33Q34154703-6B06F51C-4AA1-4ED3-ABB6-E890721040CDQ34190825-42DDC17B-9318-4B3B-B4A2-91D48B218A3BQ34481444-4B4C54FF-1977-4EEB-ADC1-38476E248738
P2860
description
2005 nî lūn-bûn
@nan
2005 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
2005 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
name
SNARE-driven, 25-millisecond vesicle fusion in vitro.
@ast
SNARE-driven, 25-millisecond vesicle fusion in vitro.
@en
type
label
SNARE-driven, 25-millisecond vesicle fusion in vitro.
@ast
SNARE-driven, 25-millisecond vesicle fusion in vitro.
@en
prefLabel
SNARE-driven, 25-millisecond vesicle fusion in vitro.
@ast
SNARE-driven, 25-millisecond vesicle fusion in vitro.
@en
P2093
P2860
P1433
P1476
SNARE-driven, 25-millisecond vesicle fusion in vitro.
@en
P2093
Akhil Bhalla
Edwin R Chapman
James C Weisshaar
Tingting Liu
Ward C Tucker
P2860
P304
P356
10.1529/BIOPHYSJ.105.062539
P407
P577
2005-07-29T00:00:00Z