William R. Veatch scite author profile

Gramicidin A is thought to form a dimer channel through which alkali cations and hydrogen ions can passively permeate lipid bilayer membranes. The present work describes four conformational species which have been isolated from a single organic solvent system and individually characterized by circular dichroism, proton nuclear magacetate, and dioxane were Spectrograde (Matheson Coleman and Bell). Ethanol was "Rossville Gold Shield" (Commercial Solvents Corporation); dimethyl sulfoxide was "spectroanalyzed" (Fisher); and the chloroform was analytical grade (Baker).Thin-Layer Chromatography. All silica thin-layer chromatography (tic) plates were from Quantum Industries. The plates were developed in dioxane-water (100:1) (v/v) and visualized with the tryptophan reagent, A(A-dimethylaminobenzaldehyde (Greenstein and Winitz, 1961). Absolute spot mobilities relative to the solvent front were approximately 0.4 for species 4, 0.3 for 3, 0.15 for 2, and 0.04

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The dimeric nature of the gramicidin A transmembrane channel: Conductance and fluorescence energy transfer studies of hybrid channels

Veatch

Stryer

1977

Journal of Molecular Biology

241

164

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Simultaneous fluorescence and conductance studies of planar bilayer membranes containing a highly active and fluorescent analog of gramicidin A

Veatch

Mathies

Eisenberg

et al. 1975

Journal of Molecular Biology

185

133

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Lateral mobility of band 3 in the human erythrocyte membrane studied by fluorescence photobleaching recovery: Evidence for control by cytoskeletal interactions

Golan

Veatch

1980

Proc. Natl. Acad. Sci. U.S.A.

206

116

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Band 3,. the major intrinsic protein of the human erythrocyte membrane, was specifically labeled with the covalent fluorescent probe eosin isothiocyanate. The lateral mobility of labeled bans 3 in the plane of the membrane under various conditions of ionic strength and temperature was examined by using the fluorescence photobleaching recovery technique. Low temperature (210C) and high ionic strength (46 mM NaPO4) favored immobilization of band 3 (10% mobile) as well as slow diffusion of the mobile fraction (diffusion coefficient D = 4 X 101 cm2 sec'1). Increasing temperature (370C) and decreasing ionic strength (13 mM NaPO4) led to an increase in the fraction of mobile band 3 (90% mobile) and a reversible increase in the diffusion rate of the mobile fraction (D = 200 X 10-11 cm2 sec'). The increase in the fraction of mobile band 3 was markedly dissociated, however, from the increase in the diffusion rate of the mobile fraction. Thus, the fraction of mobile band 3 always increased at higher ionic strength and lower temperature than the ionic strength and temperature at which the diffusion rate increased. This dissociation was manifested kinetically on prolonged incubation of ghosts at constant ionic strength and temperatures the diffusion rate of the mobile fraction increased slowly at first and much more rapidly after the initial lag period, whereas the fraction of mobile band 3 increased almost immediately to 90% and remained maximal for the duration of the experiment. Further, changes in diffusion rate with temperature were promptly and totally reversible, whereas increases in the mobile fraction were only slowly and partially reversible. These effects were shown not to be due to complete dissociation of spectrin, the major protein of the erythrocyte cytoskeleton, from the membrane. This evidence suggests control of band 3 lateral mobility by at least two separate processes. The process that determines the diffusion coefficient of the mobile band 3 is completely reversible, and it probably involves a metastable state of cytoskeleton structure intermediate between tight binding to the membrane and complete dissociation from it.Extensions of the fluid-mosaic model for membrane structure (1) have emphasized the importance of intramembranous (especially transmembranous) forces in the modulation of lateral mobility of integral membrane proteins (2, 3). Immunologic phenomena such as antibody-induced patching and capping and anchorage modulation (reviewed in ref.3) demonstrate a functional role for such forces in mammalian cell membranes. With reference to the human erythrocyte membrane, qualitative evidence for cytoskeletal control of integral membrane protein distribution and mobility has emerged from freeze-fracture electron microscopic studies (4-7). Direct examination of the lateral mobility of fluorescently labeled transmembrane proteins (chiefly band 3 and glycophorin) by the cell fusion (8) and photobleaching recovery (9) techniques has also suggested restricted mobility for these proteins.A definitiv...

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Conformation of gramicidin A in phospholipid vesicles: circular dichroism studies of effects of ion binding, chemical modification, and lipid structure

Wallace¹,

Veatch²,

Blout³

1981

Biochemistry

159

111

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William R. Veatch

Conformation of gramicidin A

The dimeric nature of the gramicidin A transmembrane channel: Conductance and fluorescence energy transfer studies of hybrid channels

Simultaneous fluorescence and conductance studies of planar bilayer membranes containing a highly active and fluorescent analog of gramicidin A

Lateral mobility of band 3 in the human erythrocyte membrane studied by fluorescence photobleaching recovery: Evidence for control by cytoskeletal interactions

Conformation of gramicidin A in phospholipid vesicles: circular dichroism studies of effects of ion binding, chemical modification, and lipid structure

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