Homogeneous and Heterogeneous Bilayers of Ternary Lipid Compositions Containing Equimolar Ceramide and Cholesterol.

ABSTRACT

Cell membranes have been proposed to be laterally inhomogeneous, particularly in the case of mammalian cells, due to the presence of "domains" enriched in sphingolipids and cholesterol (Chol). Among membrane sphingolipids, sphingomyelin (SM) in the cell plasma membrane is known to be degraded to ceramide (Cer) by acid sphingomyelinases under stress conditions. Since cholesterol (Chol) is abundant in the plasma membrane, the study of ternary mixtures SMCholCer is interesting from the point of view of membrane biophysics, and it might be physiologically relevant. In previous studies, we have described the homogeneous gel phase formed by phospholipidCholCer at 542323 mol ratios, where phospholipid was either SM or dipalmitoylphosphatidylcholine (DPPC). We now provide new data, based on trans-parinaric acid and diphenylhexatriene fluorescence, supporting that the gel phase includes all three components in a single bilayer. The main question addressed in this paper is the stability of the ternary gel phase when bilayer composition is changed, specifically when the SM proportion is varied. To this aim, we have prepared bilayers of composition phospholipidCholCer at XYY ratios, in which phospholipid increased between 54 and 70 mol %. The N-palmitoyl derivatives of SM (pSM) and Cer (pCer) have been used. We observe that for X = 54 or 60 mol %, a gel phase is clearly predominant. However, when the proportion of phospholipid increases beyond 60 mol %, i.e., in 661717 or 701515 mixtures, a lateral phase separation occurs at the micrometer scale. These data can be interpreted in terms of a pCerChol interaction, that would predominate at the lower phospholipid concentrations. The putative pCerChol complexes (or nanodomains) would mix well with the phospholipid. At the higher SM concentrations pSMpCer and pSMChol interactions would become more important, giving rise to the coexisting gel and liquid-ordered phases respectively. Heterogeneity, or lateral phase separation, occurs more easily with pSM than with DPPC, indicating a higher affinity of SM over DPPC for Chol or Cer. The observation that heterogeneity, or lateral phase separation, occurs more easily with pSM than with DPPC, indicates a higher affinity of SM over DPPC for Chol or Cer, and can be related to cell regulation through the sphingolipid signaling pathway.