Membrane Transition Temperature Determines Cisplatin ResponseRoles for SH2 and SH3 domains in Lyn kinase association with activated FcepsilonRI in RBL mast cells revealed by patterned surface analysis.An introduction to critical points for biophysicists; observations of compositional heterogeneity in lipid membranesLine tensions, correlation lengths, and critical exponents in lipid membranes near critical pointsMolecular mechanisms of spontaneous and directed mast cell motility.Steady-state cross-correlations for live two-colour super-resolution localization data sets.Correlation functions quantify super-resolution images and estimate apparent clustering due to over-countingNonequilibrium behavior in supported lipid membranes containing cholesterol.Far-red organic fluorophores contain a fluorescent impurity.Sterol structure determines miscibility versus melting transitions in lipid vesicles.Closed-loop miscibility gap and quantitative tie-lines in ternary membranes containing diphytanoyl PC.Growth Conditions and Cell Cycle Phase Modulate Phase Transition Temperatures in RBL-2H3 Derived Plasma Membrane Vesicles.Phosphatidylinositol-(4,5)-Bisphosphate Acyl Chains Differentiate Membrane Binding of HIV-1 Gag from That of the Phospholipase Cδ1 Pleckstrin Homology DomainProbing protein heterogeneity in the plasma membrane using PALM and pair correlation analysis.Seeing spots: complex phase behavior in simple membranes.Adhesion stabilizes robust lipid heterogeneity in supercritical membranes at physiological temperatureEzrin tunes the magnitude of humoral immunity.Distinct stages of stimulated FcεRI receptor clustering and immobilization are identified through superresolution imaging.Dimerization of mammalian kinesin-3 motors results in superprocessive motionProtein sorting by lipid phase-like domains supports emergent signaling function in B lymphocyte plasma membranes.Liquid general anesthetics lower critical temperatures in plasma membrane vesicles.Super-Resolution Microscopy: Shedding Light on the Cellular Plasma Membrane.Bovine and human cathelicidin cationic host defense peptides similarly suppress transcriptional responses to bacterial lipopolysaccharide.Basic motifs target PSGL-1, CD43, and CD44 to plasma membrane sites where HIV-1 assembles.Quantitative nanoscale analysis of IgE-FcεRI clustering and coupling to early signaling proteins.Erratum: steady-state cross-correlations for live two-colour super-resolution localization data sets.Critical fluctuations in plasma membrane vesicles.On the binding preference of human groups IIA and X phospholipases A2 for membranes with anionic phospholipids.Critical Casimir forces in cellular membranes.Organization in lipid membranes containing cholesterol.Fluorescent Probes Alter Miscibility Phase Boundaries in Ternary VesiclesDiffusion of Liquid Domains in Lipid Bilayer MembranesLipids out of orderMiscibility phase diagrams of giant vesicles containing sphingomyelin
P50
Q28550413-F641A9BB-498E-43E3-A099-6124C78CD84EQ30157264-36E46073-10F7-4024-990F-487D1602C892Q30474520-B5EFED67-4284-4F2D-AC84-D2040BBD4E05Q30482295-F5198C31-4B57-4A96-BCE0-47E5B39797A9Q30525710-B95E3849-682C-40CD-AAAD-4AF940835938Q30654359-D0A68228-A58F-4005-83D5-145D715B8DC5Q34181716-C836EF3F-ECBB-44DD-93FF-79EB3BAF0295Q34185620-8C9DFAE7-3AF7-4727-88A3-D26F5094458AQ34269324-5CA9F971-2060-4ACB-8835-2F8197F3262EQ34351114-42B4456F-2847-4836-850E-F688E459C7F5Q34646754-2676B807-734D-4174-A4E1-8A07FF177A71Q35773927-FCA94B02-72FE-430F-9577-D2A1CBC71292Q35861246-1697B4D3-B59D-41E4-8245-2262C81FE53BQ36103862-AB4C8B6B-54ED-4F41-ACAF-D6AC2C461C0FQ36206889-05300360-D9F0-4C4F-9B7F-7CBAC0DFA65DQ36621909-2384969A-885D-41CC-8704-65D81A10B833Q37256630-78DD4BA3-9F55-4543-A820-B65D784FE248Q37338045-537C1B63-C2E3-464F-A371-94AFC9590F44Q37712013-059022EF-E642-4D7C-886E-3D9837B85BFDQ37730562-16C53169-2514-4112-8D37-20E9A314A202Q39041422-A19DD3DF-14F6-4B7F-A5E6-662DB91B4CB1Q39140535-48E850E6-217C-483E-A834-CAD55DB98080Q40237762-64542377-6338-45D7-AF82-47A65DF40CE8Q41844831-0662C579-A682-4806-B42E-7961D497983EQ42203097-BCD38CA2-D400-4FEB-9A98-C4643FC781ABQ43249757-51CAC978-6A42-401D-9DA6-C5F1100D7AEDQ43629978-0B3B854B-FE07-4142-9413-338B924A3357Q44147123-E6E44B08-5ACE-4C4D-A2F3-FEE5330A1503Q50285064-44AB7705-554C-4AE3-B7B2-9FFF93B2F523Q50315443-8C530D1F-D89B-4DD8-BD70-BA950CE809DCQ57366202-AF6510A7-AD0B-48D3-A984-C0661F7CB71EQ57366221-C309B40E-9A64-43E7-B2F2-DC38AAAE41C4Q80890027-A28F7E92-545B-4221-BE12-42C2A042B944Q81764267-414B81B9-3936-46B4-9BE3-F888DF5ECAB4
P50
description
American biophysicist
@en
biofísica estadounidense
@es
wetenschapper
@nl
հետազոտող
@hy
name
Sarah L Veatch
@ast
Sarah L Veatch
@nl
Sarah L Veatch
@sl
Sarah Veatch
@en
Sarah Veatch
@es
type
label
Sarah L Veatch
@ast
Sarah L Veatch
@nl
Sarah L Veatch
@sl
Sarah Veatch
@en
Sarah Veatch
@es
altLabel
Sarah L. Veatch
@en
Sarah L. Veatch
@es
Sarah Louise Veatch
@en
Sarah Louise Veatch
@es
prefLabel
Sarah L Veatch
@ast
Sarah L Veatch
@nl
Sarah L Veatch
@sl
Sarah Veatch
@en
Sarah Veatch
@es
P106
P1960
lQBc1WMAAAAJ
P21
P31
P496
0000-0002-9317-2308