Solubilisation of model membrane by DDAO surfactant - partitioning, permeabilisation and liposome-micelle transition.

Solubilisation of model membranes of dioleoylphosphatidylcholine (DOPC) and DOPCcholesterol (CHOL) induced by surfactant N,N-dimethyl-1-dodecanamine-N-oxide (DDAO) was studied. At the maintained pH ~ 7.5, the DDAO molecules are in their neutral state with respect to the pK ~ 5. Pore formation in lipid bilayer was studied by fluorescence probe leakage method. The changes in the size of lipid aggregates upon increasing DDAO concentration were followed turbidimetrically. Effective ratio Re at different steps of the solubilisation process was determined. The molar partition coefficient of DDAO in case of the DOPC membrane is Kp = 2262 ± 379, for DOPC-CHOL membrane Kp = 2092 ± 594. Within the experimental error, the partition coefficient, as well as effective ratios Re, are not considerably influenced when one third of DOPC molecules is substituted with CHOL (DOPC:CHOL = 2:1). Constituents of buffer (50 mmol/dm3 PBS, 150 mmol/dm3 NaCl) caused aggregation of DOPC and DOPC-CHOL unilamellar liposomes at zero and low DDAO concentration, as was shown by SANS, turbidimetry and DIC microscopy. After solubilisation of bilayer structures by surfactant, mixed DOPC-DDAO and DOPC-CHOL-DDAO micelles with the shape of cylinders with elliptical cross section were detected.

Cholesterol protects phosphatidylcholine liposomes from N,N-dimethyl-1-dodekanamine N-oxide influence.

The interaction of N,N-dimethyl-1-dodekanamine N-oxide (C12(CH3)2NO) with egg yolk phosphatidylcholine (EYPC) liposomes containing cholesterol (CHOL) was studied. The perturbation of CHOL-EYPC bilayers in unilamellar liposomes (ULL) was observed by the leakage of fluorescent probe calcein. Weak leakage is observed at low surfactant concentration cC12NO (minimal perturbation of the bilayer) followed by an intensive leakage at a middle cC12NO (creation of pores). No change in fluorescence intensity was measured at high cC12NO (calcein totally released from liposomes). The higher CHOL amount in the bilayer, the more surfactant is needed to create pores in the bilayer. Solubiliazation of CHOL-EYPC ULL induced by C12NO was studied turbidimetrically. The solubilization curve consists of three parts: saturation of bilayer at low cC12NO (liposomes are preserved), followed by solubilization (liposome - mixed micelle transition) and post-solubilization. The c12NO concentration needed for the onset of the soubilization raises with the increase of nCHOL:nEYPC. The structure of liposomes is still preserved at total calcein release for all nCHOL:nEYPC.