about
Liposome-based liquid handling platform featuring addition, mixing, and aliquoting of femtoliter volumesRepair of traumatic plasmalemmal damage to neurons and other eukaryotic cellsThe curious ability of polyethylene glycol fusion technologies to restore lost behaviors after nerve severanceCoupling of the fusion and budding of giant phospholipid vesicles containing macromolecules.HOPS initiates vacuole docking by tethering membranes before trans-SNARE complex assembly.Splaying of aliphatic tails plays a central role in barrier crossing during liposome fusionAggregation and fusion of low-density lipoproteins in vivo and in vitro.Optical nanomanipulations of malignant cells: controlled cell damage and fusion.TMEPAI/PMEPA1 enhances tumorigenic activities in lung cancer cellsAffinity for, and localization of, PEG-functionalized silica nanoparticles to sites of damage in an ex vivo spinal cord injury model.An in vitro protocol for recording from spinal motoneurons of adult ratsPushing the science forward: chitosan nanoparticles and functional repair of CNS tissue after spinal cord injury.Filament rigidity causes F-actin depletion from nonbinding surfaces.The fusion of membranes and vesicles: pathway and energy barriers from dissipative particle dynamics.The tethering complex HOPS catalyzes assembly of the soluble SNARE Vam7 into fusogenic trans-SNARE complexes.Scaling up synthetic biology: Do not forget the chassis.Cellular mechanisms of plasmalemmal sealing and axonal repair by polyethylene glycol and methylene blue.Inhibition of mitochondrial fusion by α-synuclein is rescued by PINK1, Parkin and DJ-1.Effective repair of traumatically injured spinal cord by nanoscale block copolymer micelles.Induction of multinucleated cells and apoptosis in the PC-3 prostate cancer cell line by low concentrations of polyethylene glycol 1000.Observations of membrane fusion in a liposome dispersion: the missing fusion intermediate?Phosphatidylserine inhibits and calcium promotes model membrane fusion.A novel assay for detecting fusion pore formation: implications for the fusion mechanism.Multiple and distinct strategies of yeast SNAREs to confer the specificity of membrane fusion.Near-instant surface-selective fluorogenic protein quantification using sulfonated triarylmethane dyes and fluorogen activating proteins.Phosphatidylserine-Dependent Catalysis of Stalk and Pore Formation by Synaptobrevin JMR-TMD Peptide.Wild-type and mutant hemagglutinin fusion peptides alter bilayer structure as well as kinetics and activation thermodynamics of stalk and pore formation differently: mechanistic implications.Rapid, effective, and long-lasting behavioral recovery produced by microsutures, methylene blue, and polyethylene glycol after completely cutting rat sciatic nerves.Novel method for preparing spheroplasts from cells with an internal cellulosic cell wall.Anomalous viscosity effect in the early stages of the ion-assisted adhesion/fusion event between lipid bilayers: a theoretical and computational study.Protective effect of low molecular weight polyethylene glycol on the repair of experimentally damaged neural membranes in rat's spinal cord.Fusion between tumor cells enhances melanoma metastatic potential.Combined depletion and electrostatic forces in polymer-induced membrane adhesion: a theoretical model.Polyethylene glycol solutions rapidly restore and maintain axonal continuity, neuromuscular structures, and behaviors lost after sciatic nerve transections in female rats.
P2860
Q27320146-037E7320-1B51-4CB0-B105-507D548834AEQ28073117-2A5A06AC-EE59-4C90-8769-B9E0328F1481Q28081248-B2522C1C-F402-48F8-BF68-1FF450F6CE2CQ30513903-7226DFAF-6155-49BB-B49D-6BBFFA834C55Q33948566-0FB61A17-8807-46F7-B1D9-E8B7560FC413Q34087176-F912D2A7-9A23-4E42-B10B-9B5B3EC8BCE8Q34133240-C607975A-95CF-41B6-B3AA-C20599F91CA9Q34202505-56C66810-35EF-4114-A143-CD09E1BE6327Q35051925-FB77E114-A8A3-4D9D-9A6C-B1376046A298Q36547886-07CC97F3-E7DD-4F75-B9E3-3DA89F1F9D19Q36805061-451AC714-1831-4A44-A678-91A10BA74159Q36934660-52E2270C-74EB-4028-8550-484B3F009446Q37068270-E2F37D4A-3F67-46A2-BE72-F852E63BCAE0Q37263194-FB4B20BB-3EAD-4F6E-BF8E-3F94CE632ED7Q37348768-BA058D58-6016-4ECB-A38E-93DC9A31D8F5Q37973942-209350E3-9FE9-4501-B082-7CA9FF240041Q39402113-1C33E8D9-7F0A-4C6C-AA98-D30DC2FF04E8Q39655865-EF8F9AAB-DB5E-4764-A404-18573283F05AQ39750629-A7899833-3D16-4451-BD9D-0D5CBDC0746DQ39996400-A7C5AE99-31DD-4480-AEFB-F960D166F53CQ40650211-7D55A8C1-A23C-4328-8626-CC998541895AQ41413524-7DF3D308-A18C-48CF-A4E8-3E70C0AEC048Q41851592-DB481F49-FC77-4E83-AB9F-3F4A2F9CAB2DQ41909157-B456D9F1-F1F6-4919-8275-66A5DD3212FFQ42065231-7D8A1A93-AF59-4EB2-9B38-9CB429CCDF5EQ42142889-3D80790E-5C89-4039-A8F6-4EE27CF7D165Q42250651-84DF4478-0CBB-4A10-82DA-92C841237503Q42634799-D6053209-AB6F-4762-9C77-1BCBEEC972D1Q42761849-FD02B1B7-994C-4606-9FE7-B545CF98E1DFQ43423196-0C00FB1C-B6CC-42BC-8DAE-6B9ADFEA8327Q45814144-114CE04B-2540-4096-8D0A-51F6E33E6E0BQ48496509-7A474DBC-34DC-4894-9B79-60D829E47D1FQ51426691-94FA23D4-EFA7-4506-AD4D-BBB15DC61747Q53409942-30559B69-A5AD-4DD7-BA0C-2EF4BF89A01A
P2860
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年論文
@yue
2006年論文
@zh-hant
2006年論文
@zh-hk
2006年論文
@zh-mo
2006年論文
@zh-tw
2006年论文
@wuu
2006年论文
@zh
2006年论文
@zh-cn
name
PEG as a tool to gain insight into membrane fusion.
@ast
PEG as a tool to gain insight into membrane fusion.
@en
type
label
PEG as a tool to gain insight into membrane fusion.
@ast
PEG as a tool to gain insight into membrane fusion.
@en
prefLabel
PEG as a tool to gain insight into membrane fusion.
@ast
PEG as a tool to gain insight into membrane fusion.
@en
P1476
PEG as a tool to gain insight into membrane fusion
@en
P2093
Barry R Lentz
P2860
P2888
P304
P356
10.1007/S00249-006-0097-Z
P577
2006-10-13T00:00:00Z