M. Raimondi scite author profile

The fluorescence generalized polarization (GP) of 2-dimethylamino-6-lauroylnaphthalene (Laurdan) reveals different effects of cholesterol on the phase behavior of phospholipid bilayers. Phospholipid vesicles composed of gel, liquid-crystalline, and coexisting domains of the two phases have been studied at temperatures from 1 to 65 degrees C, without cholesterol and with cholesterol concentrations of 3-50 mol %. Laurdan GP measurements show the general effect of cholesterol of increasing the molecular dynamics of the gel and of decreasing the molecular dynamics of the liquid-crystalline phase. In the liquid-crystalline phase, the increased order yields Laurdan GP values close to those obtained in the gel phase. At cholesterol concentrations > 15 mol % a phase transition cannot be detected. Using the wavelength dependence of the excitation and emission GP spectra we determine that differences between the two phospholipid phases cannot be detected. In particular, in vesicles composed of coexisting gel and liquid-crystalline phases the GP wavelength dependence characteristic of coexisting domains cannot be observed at cholesterol concentrations > or = 15 mol %. Cholesterol causes the decrease in both the polarity and the dipolar relaxation effects on the neighborhood of the fluorescent naphthalene moiety of Laurdan. Probably because of a cholesterol-induced increase in the bilayer packing, these effects do not occur continuously with the increase of cholesterol concentration in the bilayer. Cholesterol concentrations inducing higher Laurdan GP values have been determined at about 5, 10, 15, 30, and 45 mol % with respect to phospholipids. We propose that the formation of ordered molecular microdomains at critical cholesterol concentrations can explain the occurrence of the observed discontinuities.

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Evidence for an Increase in Water Concentration in Bilayers after Oxidative Damage of Phospholipids Induced by Ionizing Radiation

Parasassi

Giusti

Gratton

et al. 1994

International Journal of Radiation Biology

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. The two membrane fluorescent probes 2-dimethylamino-6-lauroyl-naphthalene (Laurdan) and 2-dimethylamino-6-propionyl-naphthalene (Prodan) have been used to study the molecular basis of the damage induced in phospholipid membranes by ionizing radiation . Laurdan and Prodan display a spectral sensitivity to the polarity of their environment, showing a red shift of both excitation and emission spectra with increase of the polarity of their environment . Owing to their chemical differences, the two probes are anchored in the membrane with different strengths . In aqueous environments Laurdan is not fluorescent while Prodan shows appreciable fluorescence . Laurdan and Prodan show an opposite response to oxidative damage produced in phospholipid bilayers by ionizing radiation . The results support the model recently developed of water penetration in the bilayer as a consequence of oxidative damage .

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Cholesterol protects the phospholipid bilayer from oxidative damage

Parasassi

Giusti

Raimondi

et al. 1995

Free Radical Biology and Medicine

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Abstract--The measurement of fluorescence lifetime distribution of 1,6-diphenyl-l,3,5-hexatriene is used for the detection of oxidative damage produced in phospholipid membranes by ionizing radiation. The recently developed method is based on the linear relationship between the width of the probe lifetime distribution and the logarithm of the dose. The molecular origin of the damage resides in the production of hydroperoxide residues at the level of acyl chains double bonds. A chemiluminescence assay was used to quantitate the amount of produced hydroperoxides. Consequences of the produced damages include an increased disorder in the upper portion of the bilayer, accompanied by the penetration of water molecules. In the presence of the physiological concentration of cholesterol in phospholipid bilayers, the amount of hydroperoxides produced by ionizing radiation is dramatically reduced. The packing effect of cholesterol in phospholipid bilayers is well recognized, as well as its influence on the reduction of water concentration in the bilayer. The dramatic reduction of hydroperoxides concentration observed when irradiation is performed in the presence of cholesterol probably originates from a steric hindrance to the radical chain reaction through the unsaturated lipids due to the presence of cholesterol.

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M. Raimondi

Absence of lipid gel-phase domains in seven mammalian cell lines and in four primary cell types

Abrupt modifications of phospholipid bilayer properties at critical cholesterol concentrations

Evidence for an Increase in Water Concentration in Bilayers after Oxidative Damage of Phospholipids Induced by Ionizing Radiation

Cholesterol protects the phospholipid bilayer from oxidative damage

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