Structural dimensions and their changes in a reentrant hexagonal-lamellar transition of phospholipids.

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Structural dimensions and their changes in a reentrant hexagonal-lamellar transition of phospholipids.

R P Rand and N L Fuller

Department of Biological Sciences, Brock University, St. Catharines, Ontario, Canada.

ABSTRACT

A hexagonal-lamellar-hexagonal (HII-L-HII) reentrant phase transitionsequence on dehydration of dioleoylphosphatidylethanolamineoccurs below 22 degrees C. This provides an unusual opportunityto measure how several structural dimensions change during thistransition. Using x-ray diffraction, we have measured thesedimensions with a hope of gaining some clue about the accompanyinginternal stresses. The principal dimensions described are molecularareas and molecular lengths projected onto the hexagonal lattice.In contrast with large changes in average area at the polarand hydrocarbon ends of the molecule, a position near the polargroup/hydrocarbon interface is one of constant molecular area.It remains constant both as the monolayers curl from changingwater content and in the transition from one structure to theother. In the L-to-HII transition, the most obvious change inmolecular length is a 25% decrease in the distance between aqueouscylinders, the interaxial direction. There is little changein the interstitial direction, the direction toward the intersticeequidistant from three aqueous cylinders. As the hexagonal phaseis dehydrated, a number of internal changes in molecular lengthsare described. Increases in the interaxial direction are muchlarger than in the interstitial. Simultaneously however, hydrocarbonchain lengths decrease, and polar group lengths increase. Itis likely that molecules move axially and the cylinders becomelonger with dehydration. These dimensions and their changesmight be used in the search for a better understanding of theenergetics of molecular packing, of the interpretation of spectroscopicmeasurements of these phases, and of the mechanics of lipidlayers.

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