Permeation of protons, potassium ions, and small polar molecules through phospholipid bilayers as a function of membrane thickness.

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Permeation of protons, potassium ions, and small polar molecules through phospholipid bilayers as a function of membrane thickness.

S Paula, A G Volkov, A N Van Hoek, T H Haines and D W Deamer

Department of Chemistry and Biochemistry, University of California, Santa Cruz 95064, USA. stefan@chemistry.ucsc.edu

ABSTRACT

Two mechanisms have been proposed to account for solute permeationof lipid bilayers. Partitioning into the hydrophobic phase ofthe bilayer, followed by diffusion, is accepted by many forthe permeation of water and other small neutral solutes, buttransient pores have also been proposed to account for bothwater and ionic solute permeation. These two mechanisms makedistinctively different predictions about the permeability coefficientas a function of bilayer thickness. Whereas the solubility-diffusionmechanism predicts only a modest variation related to bilayerthickness, the pore model predicts an exponential relationship.To test these models, we measured the permeability of phospholipidbilayers to protons, potassium ions, water, urea, and glycerol.Bilayers were prepared as liposomes, and thickness was variedsystematically by using unsaturated lipids with chain lengthsranging from 14 to 24 carbon atoms. The permeability coefficientof water and neutral polar solutes displayed a modest dependenceon bilayer thickness, with an approximately linear fivefolddecrease as the carbon number varied from 14 to 24 atoms. Incontrast, the permeability to protons and potassium ions decreasedsharply by two orders of magnitude between 14 and 18 carbonatoms, and leveled off, when the chain length was further extendedto 24 carbon atoms. The results for water and the neutral permeatingsolutes are best explained by the solubility-diffusion mechanism.The results for protons and potassium ions in shorter-chainlipids are consistent with the transient pore model, but betterfit the theoretical line predicted by the solubility-diffusionmodel at longer chain lengths.

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