Phase separation in biological membranes: integration of theory and experiment - Wikidata - wikimedia - TriplyDB

Phase separation in biological membranes: integration of theory and experiment

Phase separation in biological membranes: integration of theory and experiment

http://www.wikidata.org/entity/Q37700666

about

Polymeric lipid assemblies as novel theranostic tools Nanoscopic substructures of raft-mimetic liquid-ordered membrane domains revealed by high-speed single-particle tracking.Phase diagram of a 4-component lipid mixture: DSPC/DOPC/POPC/chol.Phase diagram of a polyunsaturated lipid mixture: Brain sphingomyelin/1-stearoyl-2-docosahexaenoyl-sn-glycero-3-phosphocholine/cholesterol.Comparison of three ternary lipid bilayer mixtures: FRET and ESR reveal nanodomains.Confidence intervals for concentration and brightness from fluorescence fluctuation measurements Age-dependent changes in the sphingolipid composition of mouse CD4+ T cell membranes and immune synapses implicate glucosylceramides in age-related T cell dysfunction A mechanistic model of early FcεRI signaling: lipid rafts and the question of protection from dephosphorylation.Phase separation in lipid membranes Membrane budding Physical properties of the hybrid lipid POPC on micrometer-sized domains in mixed lipid membranes.Numerical simulation of endocytosis: Viscous flow driven by membranes with non-uniformly distributed curvature-inducing molecules.Phase behavior and domain size in sphingomyelin-containing lipid bilayers.Fast spatiotemporal correlation spectroscopy to determine protein lateral diffusion laws in live cell membranes Crystallization around solid-like nanosized docks can explain the specificity, diversity, and stability of membrane microdomains.Lipids and membrane lateral organization Escaping the flatlands: new approaches for studying the dynamic assembly and activation of GPCR signaling complexes.Functional selectivity in GPCR heterocomplexes.How sterol tilt regulates properties and organization of lipid membranes and membrane insertions.Cholesterol as a co-solvent and a ligand for membrane proteins.Lipid rafts in neurodegeneration and neuroprotection.Super-Resolution Microscopy: Shedding Light on the Cellular Plasma Membrane.Complex biomembrane mimetics on the sub-nanometer scale.Lipid Interactions and Organization in Complex Bilayer Membranes.Multidomain and ground state configurations of two-phase vesicles.Protein phosphatase 2A (PP2A) regulates low density lipoprotein uptake through regulating sterol response element-binding protein-2 (SREBP-2) DNA binding.Complex dynamics at the nanoscale in simple biomembranes Kinematics, material symmetry, and energy densities for lipid bilayers with spontaneous curvature.Unraveling sterol-dependent membrane phenotypes by analysis of protein abundance-ratio distributions in different membrane fractions under biochemical and endogenous sterol depletion.The role of membrane stiffness and actin turnover on the force exerted by DRG lamellipodia Lipid tubule growth by osmotic pressure.Curvature-Induced Spatial Ordering of Composition in Lipid Membranes Integrated multiscale biomaterials experiment and modelling: a perspective Super-resolution microscopy of lipid bilayer phases.Phases and fluctuations in a model for asymmetric inhomogeneous fluid membranes.Traveling waves and global oscillations triggered by attractive molecular interactions in an excitable system.Spherical harmonics analysis of surface density fluctuations of spherical ionic SDS and nonionic C12E8 micelles: A molecular dynamics study.Investigation of Nanoscopic Phase Separations in Lipid Membranes Using Inverse FCS.Nanoscale dynamics of phospholipids reveals an optimal assembly mechanism of pore-forming proteins in bilayer membranes.Microdomain evolution on giant unilamellar vesicles.

P2860

Q27027622-2E221F99-D525-45B1-A447-0DA0CE9953F0 Q27350332-DF321A59-4EBE-4202-BE09-0CCCBFA163E7 Q30542469-51294154-44C6-4624-A2B1-8CD231652F30 Q30683916-26BCA06C-13E0-45A2-B0FC-4A3D8104FF60 Q34306889-9562836F-5117-4102-B55A-ADF8FECEF8B4 Q34421252-DEDF3B02-0F1B-4376-A644-08C5CF554B2A Q34460494-810C4539-22B7-491B-8613-638475D3BF31 Q34532127-2EB0D764-B3D3-4F80-A3BE-43F0F2D1BF77 Q34706834-6672A8EC-33F0-4CA0-B3CF-EEBA9C9F7D72 Q35007633-D9D73795-009B-4D23-835D-46BD8CB57967 Q35715929-568637DF-9526-47A7-92F6-3F2D0DDDD5C7 Q36558229-7EBEE02B-31F6-4C70-94E2-8084E0C9DB76 Q36639938-C26FB2D3-1A68-41FF-B290-A6EABB527A8C Q37049357-25D40D18-2CD4-40BA-9A1D-126878ADF4FA Q37618993-74C5416A-58AF-48FB-B57D-F41A60FD365B Q37855539-3FAAB7BD-38F2-4CE2-A2CC-F9B40D9857C7 Q37865808-152CC35D-6763-4A72-B746-2053FF095F96 Q38017279-0A3C1C20-D1F6-487B-B341-0663DFC087B9 Q38071840-05FCD246-C1A0-4DAF-A7CF-16A4D68EED0A Q38155118-48BA0C4E-4BAE-4F4D-A955-F5EC936B1D69 Q38173298-3EDDA5EA-5FB7-469E-8B10-75CBBD273B15 Q39140535-1E7C905F-B2D6-4824-880B-E132E0E228C5 Q39440823-03EF5C6F-6E87-4376-BBCC-6935389B1283 Q39853789-B2F295DE-1769-438A-BB46-17C90A9F276C Q40433855-D7C8FEA4-2497-40FF-A0C6-E25856430B39 Q40756895-FC25DD7D-A9B9-4CC3-9FFF-0B75D51ED3C6 Q41320948-AB339602-889E-4900-BC36-58673B4273A0 Q41535549-D704397E-6DC5-406F-A054-96103F6D4D20 Q41786063-985DE909-15F0-4C96-9846-93E36D78D31F Q41827736-6509DD09-66A5-4043-80AF-8EDDED986B58 Q42093734-6BA09C29-ED1A-4735-A56B-242C82F63753 Q42291158-9B974C93-533E-46D2-8B5B-83C850284CD4 Q42659001-4ADA0F35-397D-40AE-AAC9-88657386EBD2 Q42708565-8901352B-388C-4B9B-B855-23B8863FB42A Q46398392-9F6E732D-4794-4A77-8B83-74C904507B64 Q46800440-F1D270BC-1904-44D4-8820-BBA0BD3672BE Q47893196-3267E6AB-BF9D-435B-B190-9842B84B90C3 Q50848929-3ABAD6FC-6074-459A-87CF-64E17F541039 Q51112810-EDAEECD0-0479-461D-9192-AB56DB41E826 Q51331255-0311F8CB-5A0F-4420-8003-B500EA10D52F

P2860

Phase separation in biological membranes: integration of theory and experiment

http://www.wikidata.org/entity/Q37700666

description

article científic

@ca

article scientifique

@fr

articolo scientifico

@it

artigo científico

@pt

bilimsel makale

@tr

scientific article published on January 2010

@en

vedecký článok

@sk

vetenskaplig artikel

@sv

videnskabelig artikel

@da

vědecký článek

@cs

name

Phase separation in biological membranes: integration of theory and experiment

@en

Phase separation in biological membranes: integration of theory and experiment.

@nl

type

label

Phase separation in biological membranes: integration of theory and experiment

@en

Phase separation in biological membranes: integration of theory and experiment.

@nl

prefLabel

Phase separation in biological membranes: integration of theory and experiment

@en

Phase separation in biological membranes: integration of theory and experiment.

@nl

P1433

Q37700666-AC463E9D-99B9-4F2C-BB6C-022FE5AD72E2

P1476

Q37700666-B318A829-868A-44B1-AF2B-B2C3D2D7F625

P2093

Q37700666-929371D6-1C12-4716-A6DA-3803FA450599

Q37700666-DC7248C7-D2BB-4E82-B72A-4D90CB1583F4

Q37700666-FD25877D-FDEA-4C7E-BD95-578FBA5F256A

P2860

Q37700666-0458A2DF-23A6-4410-BDB1-1E9AD5BC0F55

Q37700666-0AF2C1E7-3B81-4C4B-8157-8DEB8465958E

Q37700666-0BD8C361-2D3F-456B-99D8-3DF5FD8C482B

Q37700666-11C1C2F3-A2D4-4C30-85F0-6E1B4243EFE3

Q37700666-147D5ECC-068B-4833-9564-4423B60852FA

Q37700666-14AEBAAA-181F-4418-A62F-B992DC31FD8E

Q37700666-16B09CEA-E93B-4F09-99BE-B308838CF038

Q37700666-1EBB57C0-C952-48EF-88B7-371F6CC0AB57

Q37700666-1F2C340B-16FE-483D-B45A-10E3A4009A15

Q37700666-24373C6F-5C5F-4AA2-9C4E-7D72FA6A7DDC

P304

Q37700666-6712C22A-BFB3-4ABF-A206-FF76A5386B47

P31

Q37700666-09DBD37E-F3EE-4DF0-B09A-0B911BB4799D

P356

Q37700666-FDD913CE-86A2-4ECA-9116-EF22ED69DF4F

P478

Q37700666-923CB5EF-2D78-449B-A3DC-FAA252426F80

P50

Q37700666-0E3262EF-59BA-4ECC-AFB7-F06C445BBD11

P577

Q37700666-4E336F1E-BADE-4880-82CA-1EEF9465493F

P5875

Q37700666-677CA875-940B-447E-BA07-8A0A83F52B3E

P698

Q37700666-6164B8D4-7D6E-440B-9C07-7C8B5F7C3600

P932

Q37700666-D3C2FE21-4F48-4CAA-A3D8-E7238D827592

P356

ANNUREV.BIOPHYS.093008.131238

P1433

Annual Review of Biophysics

P1476

Phase separation in biological membranes: integration of theory and experiment

@en

P2093

Eliot Fried

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

Elliot L Elson

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

Guy M Genin

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

P2860

The fluid mosaic model of the structure of cell membranes

Model systems, lipid rafts, and cell membranes

Direct observation of the nanoscale dynamics of membrane lipids in a living cell

Characterization of cholesterol-sphingomyelin domains and their dynamics in bilayer membranes

Ternary phase diagram of dipalmitoyl-PC/dilauroyl-PC/cholesterol: nanoscopic domain formation driven by cholesterol

Two Photon Fluorescence Microscopy of Coexisting Lipid Domains in Giant Unilamellar Vesicles of Binary Phospholipid Mixtures

Line tensions, correlation lengths, and critical exponents in lipid membranes near critical points

Nanoscopic lipid domain dynamics revealed by atomic force microscopy

The state of lipid rafts: from model membranes to cells.

Nanoscale organization of multiple GPI-anchored proteins in living cell membranes.

P304

207-226

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

P31

scholarly article

P356

10.1146/ANNUREV.BIOPHYS.093008.131238

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

P478

39

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

P50

P577

2010-01-01T00:00:00Z

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

P5875

41654910

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

P698

20192775

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

P932

3694198

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