Your search keyword '"B.D. Anderson"' showing total 2 results

1. Influence of a Transmembrane Protein on the Permeability of Small Molecules Across Lipid Membranes

Author

T.-X. Xiang and B.D. Anderson

Subjects

Octanol, Circular dichroism, Physiology, Lipid Bilayers, Static Electricity, Biophysics, Phosphatidic Acids, Permeability, chemistry.chemical_compound, Organic chemistry, Hydrogen bond, Circular Dichroism, Hippurates, Vesicle, Bilayer, Gramicidin, Membrane Proteins, Biological Transport, Hydrogen Bonding, Cell Biology, Solvent, Kinetics, Membrane, chemistry, Permeability (electromagnetism), Liposomes, Phosphatidylcholines, Solvents

Abstract

The influence of the nonchannel conformation of the transmembrane protein gramicidin A on the permeability coefficients of neutral and ionized alpha-X-p-methyl-hippuric acid analogues (XMHA) (X = H, OCH(3), CN, OH, COOH, and CONH(2)) across egg-lecithin membranes has been investigated in vesicle efflux experiments. Although 10 mol% gramicidin A increases lipid chain ordering, it enhances the transport of neutral XMHA analogues up to 8-fold, with more hydrophilic permeants exhibiting the greatest increase. Substituent contributions to the free energies of transfer of both neutral and anionic XMHA analogues from water into the bilayer barrier domain were calculated. Linear free-energy relationships were established between these values and those for solute partitioning from water into decadiene, chlorobutane, butyl ether, and octanol to assess barrier hydrophobicity. The barrier domain is similar for both neutral and ionized permeants and substantially more hydrophobic than octanol, thus establishing its location as being beyond the hydrated headgroup region and eliminating transient water pores as the transport pathway for these permeants, as the hydrated interface or water pores would be expected to be more hydrophilic than octanol. The addition of 10 mol% gramicidin A alters the barrier domain from a decadiene-like solvent to one possessing a greater hydrogen-bond accepting capacity. The permeability coefficients for ionized XMHAs increase with Na(+) or K(+) concentration, exhibiting saturability at high ion concentrations. This behavior can be quantitatively rationalized by Gouy-Chapman theory, though ion-pairing cannot be conclusively ruled out. The finding that transmembrane proteins alter barrier selectivity, favoring polar permeant transport, constitutes an important step toward understanding permeability in biomembranes.

Published

2000

2. The Barrier Domain for Solute Permeation Varies With Lipid Bilayer Phase Structure

Author

Y.-H. Xu, B.D. Anderson, and T.-X. Xiang

Subjects

Octanol, Phase transition, 1,2-Dipalmitoylphosphatidylcholine, Physiology, Lipid Bilayers, Intercalation (chemistry), Biophysics, Ultrafiltration, Hexadecane, Permeability, chemistry.chemical_compound, Organic chemistry, Lipid bilayer phase behavior, Lipid bilayer, Chemistry, Bilayer, Vesicle, Phospholipid Ethers, Cell Biology, Solutions, Kinetics, Crystallography, Cholesterol, Chromatography, Gel, Phosphatidylcholines, lipids (amino acids, peptides, and proteins)

Abstract

The chemical selectivities of the transport barriers in lipid bilayers varying in composition and phase structure (gel-phase DPPC and DHPC bilayers and liquid-crystalline DPPC/CHOL/50:50 mol% bilayers) have been investigated by determining functional group contributions to transport of a series of alpha-substituted p-toluic acid analogs obtained in vesicle efflux experiments. Linear free energy relationships are established between the free energies of transfer for this series of compounds from water to the barrier domain and corresponding values for their transfer from water into six model bulk solvents (hexadecane, hexadecene, decadiene, chlorobutane, butyl ether, and octanol) determined in partitioning experiments to compare the barrier microenvironment to that in these model solvents. The barrier microenvironment in all bilayers studied is substantially more hydrophobic than octanol, thus establishing the location of the barrier beyond the hydrated headgroup interfacial region, as the interface is expected to be more hydrophilic than octanol. The chemical nature of the barrier domain microenvironment varies with bilayer phase structure. The barrier regions in non-interdigitated DPPC and interdigitated DHPC gel-phase bilayers exhibit some degree of hydrogen-bond acceptor capacity as may occur if these domains lie in the vicinity of the ester/ether linkages between the headgroups and the acyl chains. Intercalation of 50 mol% cholesterol into DPPC bilayers, which induces a phase transition to a liquid-crystalline phase, substantially increases the apparent barrier domain hydrophobicity relative to gel-phase bilayers to a nonhydrogen bonding, hydrocarbonlike environment resembling hexadecene. This result, combined with similar observations in liquid-crystalline egg-PC bilayers (J. Pharm. Sci. (1994), 83:1511-1518), supports the notion that the transition from the gel-phase to liquid-crystalline phase shifts the barrier domain further into the bilayer interior (i.e., deeper within the ordered chain region).

Published

1998