Effect of temperature and phase transition on oxidation resistance of low density lipoprotein

Site-specific effect of radical scavengers on the resistance of low density lipoprotein to copper-mediated oxidative stress: influence of alpha-tocopherol and temperature

The radical scavenging capacity of active nitroxide spin label radicals located at different depths in the surface monolayer of native and alpha-tocopherol enriched low density lipoprotein (LDL) has been evaluated at early stages of copper-mediated lipid peroxidation. Spin labels induced a concentration-dependent prolongation in lag time and a pronounced decrease in the initial rate of conjugated diene (CD) formation. These effects strongly argue for a protective, antioxidative action of spin labels, which in turn become destroyed with the extent of oxidation by radical recombination reactions. The results revealed that the decrease in spectral intensity proceeds at a higher rate for nitroxide radicals located in a more hydrophobic environment. The loss in spin label activity is accompanied by simultaneous alpha-tocopherol consumption and progresses rather independently of initial alpha-tocopherol content. The data provided no evidence that spin labels either save alpha-tocopherol or compete with it for radicals. The authors, therefore, deduce that due to enhanced accessibility and mobility, spin labels located in the interior of LDL eliminate lipid-derived radicals, which otherwise would promote lipid peroxidation. Lowering of temperature clearly below the core-lipid phase transition temperature of LDL exerts a significant effect on the kinetics of copper-induced LDL oxidation, whereas the characteristics of the radical scavenging mechanisms of the spin label molecules located in the surrounding phospholipid monolayer are conserved. Taken together, the susceptibility of LDL to primary oxidative stress conditions was efficiently retarded by small amounts of radical scavengers. This effect was more pronounced for nitroxide radicals embedded deeper in the phospholipid monolayer and was rather independent of alpha-tocopherol enrichment.

Protein-bound acrolein: potential markers for oxidative stress

Acrolein (CH2==CH---CHO) is known as a ubiquitous pollutant in the environment. Here we show that this notorious aldehyde is not just a pollutant, but also a lipid peroxidation product that could be ubiquitously generated in biological systems. Upon incubation with BSA, acrolein was rapidly incorporated into the protein and generated the protein-linked carbonyl derivative, a putative marker of oxidatively modified proteins under oxidative stress. To verify the presence of protein-bound acrolein in vivo, the mAb (mAb5F6) against the acrolein-modified keyhole limpet hemocyanin was raised. It was found that the acrolein-lysine adduct, Nepsilon-(3-formyl-3, 4-dehydropiperidino)lysine, constitutes an epitope of the antibody. Immunohistochemical analysis of atherosclerotic lesions from a human aorta demonstrated that antigenic materials recognized by mAb5F6 indeed constituted the lesions, in which intense positivity was associated primarily with macrophage-derived foam cells and the thickening neointima of arterial walls. The observations that (i) oxidative modification of low-density lipoprotein with Cu2+ generated the acrolein-low-density lipoprotein adducts and (ii) the iron-catalyzed oxidation of arachidonate in the presence of protein resulted in the formation of antigenic materials suggested that polyunsaturated fatty acids are sources of acrolein that cause the production of protein-bound acrolein. These data suggest that the protein-bound acrolein represents potential markers of oxidative stress and long-term damage to protein in aging, atherosclerosis, and diabetes.

Copper can promote oxidation of LDL by markedly different mechanisms

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.

Kinetic analysis of copper-induced peroxidation of LDL

We have employed our recently developed spectroscopic method of continuous monitoring of lipid oxidation to study the formation and decomposition of hydroperoxides in the time course of LDL oxidation. The results show satisfactory agreement with simulated time courses based on the following assumptions: (a) Both the rates of formation and decomposition of hydroperoxides depend on the ratio of bound copper to LDL as computed under the assumption that each LDL particle has 17 equivalent copper binding sites characterized by a dissociation constant K = 1 microM. (b) Peroxidation is initiated by copper-catalyzed decomposition of hydroperoxides (LOOH) into peroxy radicals (LOO.) and other products, including dienals. Under these assumptions, the rate of accumulation of LOOH can be computed from the equation (equation in text). The agreement between the simulated and experimentally-observed kinetics supports the assumptions used for simulations. The close agreement between the values of lipid oxidizability (kp/square root 2kt) obtained for LDL (0.035 (Ms)[-1/2]) and previously published data on the oxidizability of linoleates (0.02-0.11 (Ms)[-1/2]) lends further support for these assumptions.

Inhibition of oxidation of low-density lipoprotein by a novel antioxidant, BO-653, prepared by theoretical design

2,3-Dihydro-5-hydroxy-2,2-dipentyl-4,6-di-tert-butyl-benzofuran (BO-653) is a novel antioxidant synthesized by theoretical designing based on the previous experimental findings and consideration. The antioxidant activities of BO-653 against the oxidative modification of low-density lipoprotein (LDL) induced by free radicals were studied. BO-653 was consumed faster than endogenous alpha-tocopherol and inhibited the formation of lipid hydroperoxides, which was observed during the consumption of alpha-tocopherol. Doxyl stearic acids incorporated into LDL as spin probes competed with the antioxidants in scavenging radicals. It was found that the efficacy of radical scavenging by alpha-tocopherol became smaller as the radical went deeper into the interior of LDL particle, whereas that by BO-653 did not change. Ascorbic acid in the aqueous phase spared alpha-tocopherol efficiently during oxidation. On the other hand, the sparing effect of ascorbic acid for BO-653 was not remarkable, unlike that for alpha-tocopherol, which implied different locations of radicals derived from BO-653 and alpha-tocopherol within the LDL particle. It was concluded that BO-653 protected LDL from oxidative modification efficiently by scavenging peroxyl radicals and by reducing alpha-tocopheroxyl radicals and that this novel antioxidant might act as a potent inhibitor of development of atherosclerosis.

Antioxidant role of melatonin in lipid peroxidation of human LDL

The antioxidant effect of melatonin on LDL oxidation was studied in vitro using either a thermolabile initiator or copper ions to induce lipid peroxidation. Loading of LDL with melatonin showed only weak protection against oxidative damage as compared to alpha-tocopherol. In the presence of high concentrations of melatonin (1000 mol/mol LDL) in the medium a clear protective effect was found during lag- and propagation phase, albeit weaker than after loading with alpha-tocopherol. It is concluded that melatonin is not incorporated into LDL in sufficient concentrations to prevent lipid peroxidation effectively. When melatonin is present in the incubation medium during oxidation, a partitioning equilibrium between aqueous and lipid phase is established. Only under these conditions can melatonin act as a chain breaking antioxidant. The concentrations required, however, are far beyond those found in human plasma. Therefore, the data in this study do not support a direct physiological relevance of melatonin as an antioxidant in lipid peroxidation processes.

Impact of concentrations of glycated hemoglobin, alpha-tocopherol, copper, and manganese on oxidation of low-density lipoproteins in patients with type I diabetes, type II diabetes and control subjects

The late organ complications in diabetic patients are associated with enhanced oxidation of low-density lipoproteins (LDL). The role of vitamin and trace metal concentrations in this process is not clear. Therefore, we compared the oxidative susceptibility and alpha-tocopherol concentration of LDL with the levels of glycated hemoglobin (HbA1c), copper and manganese. Sixty-three diabetic patients (23 female and 40 male; 53 of type II, 10 of type I) and 35 control subjects (17 female and 18 male) were investigated. The in vitro-formation of conjugated dienes in purified LDL preparations in the presence of copper was followed as absorbance at 234 nm. LDL exhibited a shorter lagtime (44.5 +/- 10.1 vs. 67.8 +/- 16.0 and 50.1 +/- 14.3 vs. 68.8 +/- 14.6 min) for type I and type II diabetic patients vs. sex and age-matched controls, P < 0.001. For all subjects together the lagtime was inversely correlated to HbA1c (r = -0.230, P = 0.023) and positively correlated to LDL alpha-tocopherol/LDL (mol/mol). This ratio was lower in diabetic patients (P < 0.01 for type II) than in control subjects. The copper and manganese plasma levels were not different between diabetic and nondiabetic groups. However, parameters of LDL oxidizability (amount and rate of oxidation) were positively correlated with both copper and manganese concentrations. We conclude that in diabetes the resistance of LDL against oxidation is diminished in relation to the quality of glucose control.

Inhibition of copper- and peroxyl radical-induced LDL lipid oxidation by ebselen: antioxidant actions in addition to hydroperoxide-reducing activity

The effects of ebselen (2-phenyl-1,2-benzisoselenazol-3(2H)-one) on human LDL lipid oxidation induced by different fluxes of aqueous peroxyl radicals and cupric ion (at a Cu2+:LDL ratio of 17:1) were investigated. Addition of ebselen to LDL oxidised with Cu2+ prolonged the duration of the lag-phase typical for this oxidising condition, with the increase being proportional to the square of the ebselen concentration. Ebselen also prevented the formation of lipid hydroperoxides and inhibited the consumption of endogenous antioxidants during the early period of Cu(2+)-induced oxidation, during which time the drug was converted stoichiometrically into ebselen oxide (2-phenyl-1,2-benzisoselenazol-3(2H)-one-Se-oxide). Ebselen oxide itself was antioxidant inactive. Ebselen also inhibited formation of lipid-hydroperoxides and spared alpha-tocopherol during the initial stages of LDL oxidation mediated by low-flux of aqueous peroxyl radicals, where a lag-phase was not observed. When a higher flux of aqueous peroxyl radicals was used, ebselen increased the observed inhibited phase of peroxidation in a dose-dependent manner, though less pronounced than its prolongating effect on the lag-phase of Cu(2+)-induced LDL lipid oxidation. Ebselen was also able to directly interact with Cu1+, alkyl peroxyl radicals and alpha-tocopheroxyl radicals, demonstrating that the drug has a number of potential antioxidant activities in addition to its well-known hydroperoxide-reducing activity. We conclude that the antioxidant activities of ebselen are complex and that their relative importance likely vary depending on the experimental system used.