Ziouzenkova O, Sevanian A, Abuja P M, Ramos P, Esterbauer H
Institute of Biochemistry, University of Graz, Austria.
Free Radic Biol Med. 1998 Mar 1;24(4):607-23. doi: 10.1016/s0891-5849(97)00324-9.
Oxidation of LDL (0.1 microM) in PBS with copper concentrations ranging from 0.03 to 10 microM, equal to 0.3-100 Cu2+/LDL, was investigated by monitoring the formation of conjugated dienes at 234 nm. With all 8 LDL samples examined, the kinetics changed strongly at submicromolar Cu2+ concentrations. Based on time-course of the formation of conjugated dienes, cholesteryl linoleate hydroxides and hydroperoxides as well as the antioxidant consumption, two oxidation types were distinguished. Type A oxidations, observed at relatively high Cu2+ concentrations of 10-100 Cu2+/ LDL, represented the conventional kinetics of LDL oxidation with an inhibition period (= lag-time) followed by a propagation phase. In contrast, type C oxidations proceeded after a negligibly short lag time followed by a distinct propagation phase. The rate of this propagation increased rapidly to 0.5 mol diene/mol LDL and then slowed down in the presence of alpha-,gamma-tocopherols and carotenoids, which were consumed faster than tocopherols. The increase in diene absorption was due to the formation of both hydroxides and hydroperoxides suggesting a high initial decomposition of hydroperoxides. At submicromolar concentrations of about 0.1 to 0.5 microM, type C and type A oxidation can be combined resulting in 4 consecutive oxidation phases, i.e. 1st inhibition and 1st propagation (belonging to type C), followed by 2nd inhibition and 2nd propagation (belonging to type A). Increasing copper concentrations lowered the 1st propagation and shortened the 2nd inhibition periods until they melted into one apparent kinetic phase. Decreasing [Cu2+] increased the 1st propagation and 2nd inhibition but lowered the 2nd propagation phase until it completely disappeared. A threshold copper concentration, denoted as Cu(lim), can be calculated as a kinetic constant based on the Cu2+-dependence for the rate of 2nd propagation. Below Cu(lim), LDL oxidation proceeds only via type C kinetics. The Cu2+-dependence of the oxidation kinetics suggests that LDL contains two different Cu2+ biding sites. Cu2+ at the low-affinity binding sites, with half-saturation at 5-50 Cu2+/LDL, initiates and accelerates the 2nd propagation by decomposing lipid hydroperoxides. Cu2+ bound to the high-affinity binding sites, with half-saturation at 0.3-2.0 Cu2+/LDL, is responsible for the 1st propagation. Arguments in favor and against this propagation being due to tocopherol mediated peroxidation (TMP) are discussed. If the lag-time concept is extended to the conjugated diene curves seen for combined oxidation profiles, then a true inhibition phase does not apply to this time interval, but instead represents the time elapsed before the onset of the 2nd propagation phase.
在含有浓度范围为0.03至10微摩尔(相当于0.3 - 100个Cu2+/LDL)铜离子的磷酸盐缓冲盐溶液(PBS)中,通过监测234纳米处共轭二烯的形成,研究了0.1微摩尔低密度脂蛋白(LDL)的氧化情况。在所检测的全部8个LDL样品中,亚微摩尔浓度的Cu2+会使动力学发生显著变化。基于共轭二烯、亚油酸胆固醇酯氢氧化物和氢过氧化物的形成时间进程以及抗氧化剂的消耗情况,区分出了两种氧化类型。在相对较高的Cu2+浓度(10 - 100个Cu2+/LDL)下观察到的A型氧化,代表了LDL氧化的传统动力学,即有一个抑制期(= 延迟期),随后是一个增殖期。相比之下,C型氧化在极短的可忽略不计的延迟期后开始,接着是一个明显的增殖期。该增殖速率迅速增加至0.5摩尔二烯/摩尔LDL,然后在α - 、γ - 生育酚和类胡萝卜素存在的情况下减慢,这些物质的消耗速度比生育酚快。二烯吸收的增加是由于氢氧化物和氢过氧化物的形成,这表明氢过氧化物有较高的初始分解率。在约0.1至0.5微摩尔的亚微摩尔浓度下,C型和A型氧化可以结合,产生4个连续的氧化阶段,即第一次抑制和第一次增殖(属于C型),接着是第二次抑制和第二次增殖(属于A型)。铜离子浓度增加会降低第一次增殖并缩短第二次抑制期,直到它们融合为一个明显的动力学阶段。降低[Cu2+]会增加第一次增殖和第二次抑制,但会降低第二次增殖阶段,直到它完全消失。可以根据第二次增殖速率对Cu2+的依赖性,将一个阈值铜浓度(记为Cu(lim))计算为一个动力学常数。低于Cu(lim)时,LDL氧化仅通过C型动力学进行。氧化动力学对Cu2+的依赖性表明LDL含有两个不同的Cu2+结合位点。低亲和力结合位点上的Cu2+,在5 - 50个Cu2+/LDL时达到半饱和,通过分解脂质氢过氧化物引发并加速第二次增殖。与高亲和力结合位点结合的Cu2+,在0.3 - 2.0个Cu2+/LDL时达到半饱和,负责第一次增殖。讨论了支持和反对这种增殖是由于生育酚介导的过氧化作用(TMP)的论据。如果将延迟期概念扩展到组合氧化曲线中看到的共轭二烯曲线,那么真正的抑制期并不适用于这个时间间隔,而是代表第二次增殖阶段开始之前所经过的时间。
