出版社:American Society for Biochemistry and Molecular Biology
摘要:Oxidatively damaged low density lipoprotein (LDL) may cause macrophages to accumulate cholesterol in an unregulated manner, initiating the development of atherosclerotic lesions. Cultured smooth muscle cells oxidize LDL by a superoxide (O2.-)-dependent mechanism that requires L-cystine and redox-active transition metal ions in the incubation medium. To test the hypothesis that cellular reduction of L-cystine to a thiol might be involved, we exposed LDL to L-cysteine, glutathione, and D,L-homocysteine. In a cell-free system each thiol modified LDL by a pathway that required either Cu2+ or Fe3+. Thiol- and Cu(2+)-modified LDL underwent lipid peroxidation and exhibited a number of properties of cell-modified LDL, including increased mobility on agarose gel electrophoresis and fragmentation of apolipoprotein B-100. Superoxide dismutase inhibited modification of LDL by L-cysteine/Cu2+, whereas catalase and mannitol were without effect. In striking contrast, superoxide dismutase had little effect on oxidation of LDL by Cu2+ and either homocysteine or glutathione. Moreover, only L-cysteine/Cu(2+)-modified 125I-labeled LDL was degraded more rapidly than 125I-labeled LDL by human monocyte-derived macrophages: superoxide dismutase in the reaction mixture blocked the facilitated uptake of L-cysteine/Cu(2+)-modified 125I-labeled LDL, suggesting involvement of O2.-. These results indicate that LDL oxidation by L-cysteine and Cu2+ requires O2.- but not H2O2 or hydroxyl radical. The reaction may involve the metal ion-dependent formation of L-cystine radical anion which is oxidized by oxygen, yielding O2.- and the disulfide. LDL modified by L-cysteine and smooth muscle cells exhibit similar physical and biological properties, indicating that thiol-dependent generation of O2.- may be the oxidative mechanism in both systems. Thiols also promote lipid peroxidation by O2(.-)-independent reactions but human macrophages fail to rapidly degrade these oxidized LDLs.
