Authors:
Xu, XL
Bittman, R
Duportail, G
Heissler, D
Vilcheze, C
London, E
Citation: Xl. Xu et al., Effect of the structure of natural sterols and sphingolipids on the formation of ordered sphingolipid/sterol domains (rafts), J BIOL CHEM, 276(36), 2001, pp. 33540-33546
Authors:
Wollstein, R
Wolf, Y
Sklair-Levy, M
Matan, Y
London, E
Nyska, M
Citation: R. Wollstein et al., Obliteration of a late traumatic posterior tibial artery pseudoaneurysm byduplex compression, J TRAUMA, 48(6), 2000, pp. 1156-1158
Citation: E. London et al., Fluorescence quenching assay of sphingolipid/phospholipid phase separationin model membranes, METH ENZYM, 312, 2000, pp. 272-290
Authors:
Galynker, II
Watras-Ganz, S
Miner, C
Rosenthal, RN
Jarlais, DCD
Richman, BL
London, E
Citation: Ii. Galynker et al., Cerebral metabolism in opiate-dependent subjects: Effects of methadone maintenance, MT SINAI J, 67(5-6), 2000, pp. 381-387
Citation: Da. Brown et E. London, Structure and function of sphingolipid- and cholesterol-rich membrane rafts, J BIOL CHEM, 275(23), 2000, pp. 17221-17224
Citation: Xl. Xu et E. London, The effect of sterol structure on membrane lipid domains reveals how cholesterol can induce lipid domain formation, BIOCHEM, 39(5), 2000, pp. 843-849
Citation: S. Lew et al., The effects of polar and/or ionizable residues in the core and flanking regions of hydrophobic helices on transmembrane conformation and oligomerization, BIOCHEM, 39(32), 2000, pp. 9632-9640
Citation: E. London et Da. Brown, Insolubility of lipids in Triton X-100: physical origin and relationship to sphingolipid/cholesterol membrane domains (rafts), BBA-BIOMEMB, 1508(1-2), 2000, pp. 182-195
Authors:
London, E
Rudich, S
McVicar, J
Wolfe, B
Perez, R
Citation: E. London et al., Equivalent renal allograft function with laparoscopic versus open live donor nephrectomies, TRANSPLAN P, 31(1-2), 1999, pp. 258-260
Authors:
Ren, JH
Kachel, K
Kim, H
Malenbaum, SE
Collier, RJ
London, E
Citation: Jh. Ren et al., Interaction of diphtheria toxin T domain with molten globule-like proteinsand its implications for translocation, SCIENCE, 284(5416), 1999, pp. 955-957
Citation: Jc. Sharpe et E. London, Diphtheria toxin forms pores of different sizes depending on its concentration in membranes: Probable relationship to oligomerization, J MEMBR BIO, 171(3), 1999, pp. 209-221
Citation: Jc. Sharpe et al., The effects of inhibitors upon pore formation by diphtheria toxin and diphtheria toxin T domain, J MEMBR BIO, 171(3), 1999, pp. 223-233
Citation: Rd. Kaiser et E. London, Location of diphenylhexatriene (DPH) and its derivatives within membranes:Comparison of different fluorescence quenching analyses of membrane depth (vol 37, pg 8180, 1998), BIOCHEM, 38(8), 1999, pp. 2610-2610
Citation: Jh. Ren et al., Membrane translocation of charged residues at the tips of hydrophobic helices in the T domain of diphtheria toxin, BIOCHEM, 38(3), 1999, pp. 976-984
Citation: Jh. Ren et al., Control of the transmembrane orientation and interhelical interactions within membranes by hydrophobic helix length, BIOCHEM, 38(18), 1999, pp. 5905-5912
Citation: Se. Malenbaum et al., Membrane topography of the T domain of diphtheria toxin probed with singletryptophan mutants, BIOCHEM, 37(51), 1998, pp. 17915-17922