A new mechanism of model membrane fusion determined from Monte Carlo simulation - Wikidata - thesis-toulmin - TriplyDB

A new mechanism of model membrane fusion determined from Monte Carlo simulation

A new mechanism of model membrane fusion determined from Monte Carlo simulation

http://www.wikidata.org/entity/Q34182668

about

Control of membrane fusion mechanism by lipid composition: predictions from ensemble molecular dynamics Cell entry of enveloped viruses Distinct initial SNARE configurations underlying the diversity of exocytosis Molecular mechanism of the synaptotagmin–SNARE interaction in Ca2+-triggered vesicle fusion Prm1 prevents contact-dependent lysis of yeast mating pairs.The plasma membrane proteins Prm1 and Fig1 ascertain fidelity of membrane fusion during yeast mating.Rapid membrane fusion of individual virus particles with supported lipid bilayers.High Transmembrane Voltage Raised by Close Contact Initiates Fusion Pore.Lipid mixing and content release in single-vesicle, SNARE-driven fusion assay with 1-5 ms resolution.The yeast cell fusion protein Prm1p requires covalent dimerization to promote membrane fusion Atomic-resolution simulations predict a transition state for vesicle fusion defined by contact of a few lipid tails.Single-molecule studies of the neuronal SNARE fusion machinery.Expansion of the fusion stalk and its implication for biological membrane fusion.Field theoretic study of bilayer membrane fusion. I. Hemifusion mechanism.Mitofusins and the mitochondrial permeability transition: the potential downside of mitochondrial fusion Line-tension controlled mechanism for influenza fusion.Field theoretic study of bilayer membrane fusion: II. Mechanism of a stalk-hole complex SNARE-mediated lipid mixing depends on the physical state of the vesicles.Persistent voids: a new structural metric for membrane fusion.Mechanics of surface area regulation in cells examined with confined lipid membranes General hydrophobic interaction potential for surfactant/lipid bilayers from direct force measurements between light-modulated bilayers.Field theoretic study of bilayer membrane fusion III: membranes with leaves of different composition.Cardiomyocyte deletion of mitofusin-1 leads to mitochondrial fragmentation and improves tolerance to ROS-induced mitochondrial dysfunction and cell death Activation thermodynamics of poly(ethylene glycol)-mediated model membrane fusion support mechanistic models of stalk and pore formation.Energetics of stalk intermediates in membrane fusion are controlled by lipid composition.Cooperative elastic stresses, the hydrophobic effect, and lipid tilt in membrane remodeling Trans-SNARE interactions elicit Ca2+ efflux from the yeast vacuole lumen.Calculation of free energy barriers to the fusion of small vesicles.Calculating Transition Energy Barriers and Characterizing Activation States for Steps of Fusion Domain formation in membranes caused by lipid wetting of protein.Interactions of membrane-active peptides with thick, neutral, nonzwitterionic bilayers.Mechanics of membrane fusion.Mechanisms of receptor/coreceptor-mediated entry of enveloped viruses.Membrane lysis during biological membrane fusion: collateral damage by misregulated fusion machines.Fructan and its relationship to abiotic stress tolerance in plants.Size-dependent protein segregation at membrane interfaces.Low amounts of sucrose are sufficient to depress the phase transition temperature of dry phosphatidylcholine, but not for lyoprotection of liposomes Rupturing the hemi-fission intermediate in membrane fission under tension: Reaction coordinates, kinetic pathways, and free-energy barriers.All-or-none versus graded: single-vesicle analysis reveals lipid composition effects on membrane permeabilization.Molecular dynamics simulation analysis of membrane defects and pore propensity of hemifusion diaphragms.

P2860

Q21145657-E793E647-471C-4620-BEA0-CB689111EA6B Q26863682-BA383496-401D-4F28-8771-C078F38F8ADF Q26866150-E745F9BE-3DA4-40BA-B41B-6C9563255608 Q27659974-FF1EA992-1BC6-4C86-B656-03232DB938F0 Q27933298-D5E2792E-D861-468F-90D1-5A8A9F046D0F Q30478914-5B3B3FD9-D7BF-473D-8831-C50A6D48C381 Q30479669-B7A80406-5E3E-4B9D-AE7E-84804A81C4FB Q30831345-8B6A4EE4-3D7F-4A56-9C56-BD8A290D2452 Q33446904-DF6FD3EF-371A-4FBE-98C4-BF6D9DB47E92 Q33582274-64C6DBEC-4268-4CB1-AB18-F1394D984319 Q33619201-1357DA01-7AE9-4188-AD80-71D5E4B7CF4A Q33789507-B7893BA3-C0E3-4EBA-BD10-0148D297CB56 Q34002261-E1280B33-0B6B-46BC-8899-24A6CFFE2FAC Q34187706-E7C9BCCF-8742-4E7E-AEA0-4E694387686B Q34277591-EEDB91C8-B8F8-4B36-AA83-BAFB06B7BBBC Q34325691-4355C7D6-905D-4A9B-A459-B82F799B9DDC Q34353236-4D2A8B0D-A881-4382-86FB-1189C0F78233 Q34418818-661CA57E-0E2B-49F2-A5D9-D2F60425C9EE Q34626588-104B2453-EDF9-4289-89ED-729E7B0E6377 Q35022066-91705275-43A7-4D22-8A4A-F3F046F2F2E0 Q35229420-E195166D-43EF-491E-8148-0A26D207DDAB Q35794563-27739F35-C682-4528-B726-A2ECA2831267 Q35906435-202C509B-F024-4F33-94CC-5FAF473F1A0A Q36045509-46B74910-65F8-418B-9EB5-BA0A9753E484 Q36056533-954D1408-9FF4-4E8E-AC52-D95084BE2D57 Q36189199-A4327CA1-5919-4BC8-8968-7385FC2EFF61 Q36322360-ADE34318-C8DD-495F-B877-1CD6C5A1E121 Q36459141-D12017CB-4DA7-4635-8C99-AF8719A5AF07 Q36678687-4309A6D9-3C98-46F5-A881-E183CADC1C9B Q36833434-6D793FBF-6CAC-4D6F-AC37-D2E2DB302F35 Q36868899-BF5C5C9A-1A2E-40E5-A42C-0EC8FBD27019 Q36901510-2D397C81-750C-4F68-97F2-C0CB9133B72B Q37263225-DBAA8B9B-848C-48E7-8B29-AE2F5B2EC028 Q37292928-E6C9CC9A-8ECF-49B6-8680-C45D122DB956 Q37416046-42B647BD-14A4-4092-AEDC-08EA91DAE6F7 Q37495024-514898F9-B3F7-4411-8A51-B07496FBC430 Q38316330-21CC8FEB-C558-4CAD-AEF8-75DA20FAC032 Q40082309-56C857E4-6B4E-41C3-A659-46BBE5C5B5B4 Q41152752-80B37905-3495-434F-AB47-A633E454FFFE Q41767241-BDBA9B6B-A092-4746-BD2C-63857CFEAE84

P2860

A new mechanism of model membrane fusion determined from Monte Carlo simulation

http://www.wikidata.org/entity/Q34182668

description

2003 nî lūn-bûn

@nan

2003 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած

@hyw

2003 թվականի սեպտեմբերին հրատարակված գիտական հոդված

@hy

2003年の論文

@ja

2003年論文

@yue

2003年論文

@zh-hant

2003年論文

@zh-hk

2003年論文

@zh-mo

2003年論文

@zh-tw

2003年论文

@wuu

name

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@ast

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@en

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@nl

type

label

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@ast

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@en

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@nl

prefLabel

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@ast

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@en

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@nl

P1433

Q34182668-0286CBDC-44D5-43A5-B69F-56CADE637CDF

P1476

Q34182668-55F6B213-7A98-4BC4-981A-88B94787528F

P2093

Q34182668-0C22DE34-ACAF-49E8-A3B2-59A31085D414

Q34182668-6E3E57B0-4D3E-4872-8777-A14EBAF6A371

Q34182668-A04EB307-0203-4220-B707-03BDE76A3855

P2860

Q34182668-02832949-FACA-47B0-91EC-A4FCA5F65E8F

Q34182668-1A96DE5E-41C6-4871-8532-04F8144953DB

Q34182668-2B841017-2437-4A5B-88DC-343FBC68B25A

Q34182668-38489FB6-4C2E-4771-A6F1-34845943CA3A

Q34182668-4E924553-6FB0-4B01-8170-03D1D5BD353C

Q34182668-5698CA15-4731-49C0-AF93-67F0D595FA92

Q34182668-5F580D2E-58C1-4E56-AF2E-8960B3B9BF21

Q34182668-7012C622-8558-4D70-B6FC-467C8C6EB5BD

Q34182668-7BF63657-70F9-4F26-917E-79CC5217474C

Q34182668-7C57C12B-73EC-42DA-A83B-8CB3B972F59F

P304

Q34182668-6E2A6E71-FE3D-4C75-93A6-D2AEE5B8DEAD

P31

Q34182668-ED2F2B8A-C79D-459F-BA67-19D7CF65EC6E

P356

Q34182668-437BBA55-671E-44A0-B4EB-7929636EFA23

P407

Q34182668-4637D3B6-A7B8-4EFB-AE18-D3FBFB9B79D7

P433

Q34182668-16E90D11-8A63-4FF4-BD36-C3DBF03535A6

P478

Q34182668-D76C854C-7E72-4584-82BD-4C682AF342EC

P577

Q34182668-52856160-652A-46B2-972C-CB721276960E

P698

Q34182668-6D769973-21F2-489B-AA44-3BEAE7F82B25

P818

Q34182668-4A5BE5AF-4F5B-452E-8AA0-59E8059007D1

P932

Q34182668-8360D2E4-6050-4CAB-8D3A-E190A1F8AE02

P356

S0006-3495(03)74592-5

P1433

Biophysical Journal

P1476

A new mechanism of model membrane fusion determined from Monte Carlo simulation

@en

P2093

K Katsov

http://www.w3.org/2001/XMLSchema#string

M Müller

http://www.w3.org/2001/XMLSchema#string

M Schick

http://www.w3.org/2001/XMLSchema#string

P2860

Energetics of intermediates in membrane fusion: comparison of stalk and inverted micellar intermediate mechanisms

SNARE-mediated membrane fusion

GPI-anchored influenza hemagglutinin induces hemifusion to both red blood cell and planar bilayer membranes.

Protein machines and lipid assemblies: current views of cell membrane fusion.

Measured effects of diacylglycerol on structural and elastic properties of phospholipid membranes.

Observation of a membrane fusion intermediate structure.

Lipid intermediates in membrane fusion: formation, structure, and decay of hemifusion diaphragm.

Membrane permeability changes at early stages of influenza hemagglutinin-mediated fusion.

A quantitative model for membrane fusion based on low-energy intermediates.

The first milliseconds of the pore formed by a fusogenic viral envelope protein during membrane fusion.

P304

1611-1623

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1016/S0006-3495(03)74592-5

http://www.w3.org/2001/XMLSchema#string

P407

P433

3

http://www.w3.org/2001/XMLSchema#string

P478

85

http://www.w3.org/2001/XMLSchema#string

P577

2003-09-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

12944277

http://www.w3.org/2001/XMLSchema#string

P818

cond-mat/0212310

http://www.w3.org/2001/XMLSchema#string

P932

1303336

http://www.w3.org/2001/XMLSchema#string