Abstract
In addition to fatty acids, especially polyunsaturated species, cholesterol oxidizes and leads to various oxygenated derivatives, named oxysterols. They display a wide range of adverse biological properties. Monitoring oxysterols is important in the evaluation of the potential risks associated with lipid oxidation. In the present study, a quick and reliable method was developed for analysis of oxysterols, sterols, and fatty acid composition of phospholipids in the same biological sample. Total lipid extraction was determined after addition of several internal standards (epicoprostanol for sterols, 19-hydroxy-cholesterol for oxysterol and di-heptadecanoyl-phosphatidylcholine for phospholipid fatty acids). Cold acetone-mediated precipitation was then used to fractionate sterols from phospholipids. The phospholipid-containing precipitate was transmethylated for fatty acid analysis by gas chromatography. The sterol- and oxysterol-containing phase was saponified under mild conditions to avoid artificial oxysterol generation and was analyzed by gas chromatography after derivatization into trimethylsilyl ethers. The overall procedure was found to be specific with good recovery and reproducibility for sterols, oxysterols [mean coefficient of variation in percent (CV), 11.3%] as well as phospholipid fatty acids (CV, 5.6%). This procedure has been used to document in vitro free radical treated-human low-density lipoproteins and erythrocytes. Results demonstrated that this method is a useful tool in assessing qualitative and quantitative differences in oxysterols and phospholipid fatty acid patterns attributed to lipid oxidation.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Halliwell, B., and C.E. Cross, Oxygen-Derived Species: Their Relation to Human Disease and Environmental Stress, Environ. Health Perspect. 102 Suppl. 10:5–12 (1994).
Esterbauer, H., J. Gebicki, H. Puhl, and G. Jürgens, The Role of Lipid Peroxidation and Antioxidants in Oxidative Modification of LDL, Free Radical Biol. Med. 13:341–390 (1992).
Witztum, J.L., and D. Steinberg, Role of Oxidized Low Density Lipoprotein in Atherogenesis, J. Clin. Invest. 88:1785–1792 (1991).
Smith, L.L., and B.H. Johnson, Biological Activities of Oxysterols, Free Radical Biol. Med. 7:285–332 (1989).
Malavasi, B., M.F. Rasetti, P. Roma, R. Fogliatto, P. Allevi, A.L. Catapano, and G. Galli, Evidence for the Presence of 7-Hydroperoxycholest-5-en-3β-ol in Oxidized Human LDL, Chem. Phys. Lipids 62:209–214 (1992).
Blache, D., C. Rodriguez, and J. Davignon, Pro-Oxidant Effects of 7-Hydroperoxycholest-5-en-3β-ol on the Copper-Initiated Oxidation of Low Density Lipoprotein, FEBS Lett. 357:135–139 (1995).
Paniangvait, P., A.J. King, A.D. Jones, and B.G. German, Cholesterol Oxides in Foods of Animal Origin, J. Food Sci. 60:1159–1174 (1995).
Peng, S.-K., B. Hu, and R.J. Morin, Angiotoxicity and Atherogenicity of Cholesterol Oxides, J. Clin. Lab. Anal. 5:144–152 (1991).
Sevanian, A., H.N. Hodis, J. Hwang, L.L. McLeod, and H. Peterson, Characterization of Endothelial cell Injury by Cholesterol Oxidation Products Found in Oxidized LDL, J. Lipid Res. 36:1971–1986 (1995).
Kandutsch, A.A., H.W. Chen, and H. Heiniger, Biological Activity of Some Oxygenated Sterols, Science 201:498–501 (1978).
Zhang, H., H.J.K. Basra, and U.P. Steinbrecher, Effects of Oxidatively Modified LDL on Cholesterol Esterification in Cultured Macrophages, J. Lipid Res. 31:1361–1369 (1990).
Morin, R.J., B. Hu, S.-K. Peng, and A. Sevanian, Cholesterol Oxides and Carcinogenesis, J. Clin. Lab. Anal. 5:219–225 (1991).
Kumar, V., A. Amann, G. Ourisson, and B. Luu, Stereospecific Synthesis of 7β-Hydroxycholesterol and 7α-Hydroxycholesterol, Synth. Comm. 17:1229–1286 (1987).
Blache, D., C. Rodriguez, and J. Davignon, Enhanced Susceptibility of Cholesteryl Sulfate-Enriched Low Density Lipoproteins to Copper-Mediated Oxidation, FEBS Lett. 362:197–200 (1995).
Durand, P., and D. Blache, Enhanced Platelet Thromboxane Synthesis and Reduced Macrophage-Dependent Fibrinolytic Activity Related to Oxidative Stress in Oral Contraceptive-Treated Female Rats, Atherosclerosis 121:205–216 (1996).
Folch, J., M. Lees, and G.H. Sloane-Stanley, A Simple Method for the Isolation and Purification of Total Lipids from Animal Tissues, J. Biol. Chem. 226:497–509 (1957).
Rose, H.G., and M. Oklander, Improved Procedure for the Extraction of Lipids from Human Erythrocytes, J. Lipid Res. 6:428–431 (1965).
Morrisson, W.R., and L.M. Smith, Preparation of Fatty Acid Methyl Esters and Dimethyl Acetates from Lipids with Boronfluoride Methanol, Ibid.600–608 (1964).
Polette, A., P. Durand, B. Floccard, and D. Blache, A Method for Specific Analysis of Free Fatty Acids in Biological Samples by Capillary Gas Chromatography, Anal. Biochem. 206:241–245 (1992).
Won Park, S., and P.B. Addis, Capillary Column Gas-Liquid Chromatographic Resolution of Oxidized Cholesterol Derivatives, Ibid.275–283 (1985).
Higley, N.A., S.L. Taylor, A.M. Herian, and K. Lee, Cholesterol Oxides in Processed Meats, Meat Sci. 16:175–188 (1986).
Van de Bovenkamp, P., T.G. Kosmeijer-Schuil, and M.B. Katan, Quantification of Oxysterols in Dutch Food: Egg Products and Mixed Diets, Lipids 23:1079–1085 (1988).
Dzeletovic, S., O. Breuer, E. Lund, and U. Diczfalusy, Determination of Cholesterol Oxidation Products in Human Plasma by Isotope Dilution-Mass Spectrometry, Anal. Biochem. 225:73–80 (1995).
Juanéda, P., G. Rocquelin, and P.O. Astorg, Separation and Quantification of Heart and Liver Phospholipid Classes by High-Performance Liquid Chromatography Using a New Light-Scattering Detector, Lipids 25:756–759 (1990).
Dzeletovic, S., A. Babiker, E. Lund, and U. Diczfalusy, Time Course of Oxysterol Formation During In Vitro Oxidation of Low Density Lipoprotein, Chem. Phys. Lipids 78:119–128 (1995).
Brown, A.J., R.T. Dean, and W. Jessup, Free and Esterified Oxysterol: Formation During Copper-Oxidation of Low Density Lipoprotein and Uptake by Macrophages, J. Lipid Res. 37:320–335 (1996).
Durand, P., M. Prost, and D. Blache, Pro-thrombotic Effects of a Folic Acid Deficient Diet in Rat Platelets and Macrophages Related to Elevated Homocysteine and Decreased n-3 Polyunsaturated Fatty Acids, Atherosclerosis 121:231–243 (1996).
Blache, D., and M. Prost, Free Radical Attack: Biological Test for Human Resistance Capability, in Proceedings of the IX College Park Colloquium on Chemical Evolution: A Lunar-Based Chemical Analysis Laboratory (LBCAL), edited by C. Ponnamperuma, and C.W. Gehrke, NASA, Washington, D.C., 1992, pp. 82–98.
Smith, L.L., Cholesterol Autoxidation, Chem. Phys. Lipids 44:87–125 (1987).
Pie, J.E., K. Spahis, and C. Seillan, Evaluation of Oxidative Degradation of Cholesterol in Food and Food Ingredients: Identification and Quantification of Cholesterol Oxides, J. Agric. Food Chem. 38:973–979 (1990).
Rose-Salin, C., A.C. Huggett, J.O. Bosset, R. Tabacchi, and L.B. Fay, Quantification of Cholesterol Oxidation Products in Milk Powders Using [2H7]Cholesterol to Monitor Autoxidation Artifacts, Ibid.935–941 (1995).
Author information
Authors and Affiliations
Corresponding author
About this article
Cite this article
Blache, D., Durand, P., Girodon, F. et al. Determination of sterols, oxysterols, and fatty acids of phospholipids in cells and lipoproteins: A one-sample method. J Amer Oil Chem Soc 75, 107–113 (1998). https://doi.org/10.1007/s11746-998-0019-6
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/s11746-998-0019-6