Ceruloplasmin as low-density lipoprotein oxidase: activation by ascorbate and dehydroascorbate.

The ability of ceruloplasmin (Cp) to oxidize low-density lipoproteins (LDL) in the presence of water-soluble antioxidants was investigated and a reaction mechanism proposed. Ascorbate strongly enhanced LDL oxidation, but only after its rapid consumption. Dehydroascorbate enhanced Cp-mediated LDL oxidation even more strongly. Lipid-soluble antioxidants and water-soluble peroxides did not show noticeable activation. However, loading of LDL with lipid hydroperoxides increased the initial oxidation rate. We conclude that Cp mediates a localized redox cycle, where reduction of Cp-Cu2+ is effected by water-soluble reductants and reoxidation by liposoluble hydroperoxides.

Hypochlorite induces the formation of LDL(-), a potentially atherogenic low density lipoprotein subspecies.

Oxidation of low density lipoprotein (LDL) induced by hypochlorous acid (HOCl) leading to LDL(-), a minimally oxidized subspecies of LDL, was investigated. LDL(-) is characterized by its greater electronegativity and oxidative status, and is found in plasma in vivo. Its concentration was found to be elevated under conditions that predispose humans to atherosclerosis. We found that HOCl also converts LDL rapidly to an even more oxidized state, identified as LDL(2-), which is more electronegative than LDL(-). After milder oxidation for short durations, formation of LDL(-) takes place while less LDL(2-) is formed. Under these conditions, addition of methionine not only suppressed further oxidation of LDL but also favored the formation of LDL(-) over LDL(2-), possibly by removing chloramines at lysyl residues of LDL. The presence of lipoprotein-deficient plasma did not prevent HOCl-mediated conversion of LDL to more electronegative species. It is concluded that the HOCl-mediated conversion of LDL into more electronegative species might be physiologically relevant.

Blood polymorphonuclear leukocyte activation in atherosclerosis: effects of aspirin.

The aim of the study was to demonstrate an activation of polymorpho-nuclear leukocytes (PMNs) in chronic progressive atherosclerosis (ATH). A group of patients with ATH, and a group of ATH patients under aspirin (ASA) therapy were compared with control persons without atherosclerotic alterations (healthy controls). Each group comprised 15 male age-matched subjects. The following inflammatory parameters related to PMN activities were measured: the polymorphonuclear leukocyte (PMN) blood count; blood PMN migration and reactive oxygen species release in vitro; the blood levels of PMN elastase, malondialdehyde, antibodies to oxidized LDL and soluble ICAM-1. In ATH patients, the PMN blood counts and the share of blood PMNs migrating upon platelet activating factor and leukotriene B4 stimulation were significnatly above the values of the healthy controls, while the other parameters were not significantly altered. ASA treatment attenuated the inflammatory response and reduced the differences between ATH and the healthy controls. It can be concluded that, in patients with chronic progressive atherosclerosis, PMNs are involved in the inflammatory process underlying the disease.

Kinetics of chlorination of monochlorodimedone by myeloperoxidase.

The phagocyte-derived enzyme myeloperoxidase has been recently implicated in the pathogenesis of atherosclerosis, because it catalyzes the reaction of hydrogen peroxide with chloride ions to give the highly toxic oxidant hypochlorous acid. The aim of this study was to determine the dependence of this reaction on the concentration of hydrogen peroxide and of the enzyme by means of the photometric monochlorodimedone assay. The initial rate of hypochlorous acid formation increased less than proportionally with increasing myeloperoxidase concentrations. Variation of the concentration of hydrogen peroxide had a biphasic effect, with an optimal concentration of hydrogen peroxide. Above this concentration enzyme destruction is apparently predominant. The progress curves of hypochlorous acid formation showed two distinct maxima. It was concluded that hypochlorous acid not only reacts with monochlorodimedone but also with the amino groups of myeloperoxidase to form intermediary chloramines that may further chlorinate monochlorodimedone. This was supported by the kinetics in the presence of the amino compound glycine, a competitive substrate for chlorination by hypochlorous acid. In the presence of high concentrations of glycine the progress curve rises continuously, yielding a greatly increased concentration of chlorinating species, either hypochlorous acid or chloramines. We concluded that glycine protects myeloperoxidase against hypochlorous acid-induced self-destruction.

Nitrogen dioxide radical generated by the myeloperoxidase-hydrogen peroxide-nitrite system promotes lipid peroxidation of low density lipoprotein.

Myeloperoxidase, a heme protein secreted by activated phagocytes, is present and enzymatically active in human atherosclerotic lesions. In the current studies, we explored the possibility that reactive nitrogen species generated by myeloperoxidase promote lipid peroxidation of low density lipoprotein (LDL) -- a modification that may render the lipoprotein atherogenic. We found that myeloperoxidase, an H2O2-generating system and nitrite (NO2-) peroxidized LDL lipids. The process required NO2- and each component of the enzymatic system; it was inhibited by catalase, cyanide and ascorbate, a potent scavenger of aqueous phase radicals. LDL peroxidation did not require chloride ion, and it was little affected by the hypochlorous acid scavenger taurine. Collectively, these results suggest that lipid peroxidation is promoted by a nitrogen dioxide radical-like species. These observations indicate that myeloperoxidase, by virtue of its ability to form reactive nitrogen intermediates, may promote lipid peroxidation and atherogenesis.

Correlation of low-density lipoprotein modification by myeloperoxidase with hypochlorous acid formation.

Myeloperoxidase is an enzyme in phagocytes which catalyzes several redox reactions. A major product is hypochlorous acid which appears to be important in inflammatory processes such as atherosclerosis. The aim of this study was to investigate whether the kinetics of low-density lipoprotein modification by the myeloperoxidase/hydrogen peroxide/chloride system in vitro conform to the established kinetics of hypochlorous acid formation and to compare the results with known in vivo data. The absorbance at 234 nm was applied to study the kinetics of the modification of low-density lipoprotein. Variation of the concentration of low-density lipoprotein, hydrogen peroxide, and chloride, respectively, had a biphasic effect on the maximal rate of low-density lipoprotein modification. Increasing the substrates up to certain threshold levels resulted in increased modification, however, further increases caused inhibition of low-density lipoprotein modification. The inhibitory effect of higher low-density lipoprotein concentrations might be relevant, since these concentrations occur in the human aortic intima. Furthermore, a positive correlation was found between the maximal rate of low-density lipoprotein modification and the acidity of the medium. In summary, low-density lipoprotein modification is affected by the myeloperoxidase/hydrogen peroxide/chloride system in a similar manner to hypochlorous acid production. We conclude that myeloperoxidase, which has been detected in atherosclerotic lesions, is able to modify low-density lipoprotein into the form which is taken up by macrophages in an uncontrolled manner.

Human low density lipoprotein as a target of hypochlorite generated by myeloperoxidase.

The aim of this study was to further clarify which part of human low density lipoprotein (LDL) is attacked by the MPO/H2O2/Cl- -system and which reactive oxygen species is responsible for the attack. Therefore the influence of this system on the modification of the lipid and protein moiety of LDL was studied in vitro. Using the monochlorodimedone assay it was found that HOCl is produced in micromolar quantities in the absence of LDL and is rapidly consumed by LDL in a concentration dependent manner. The consumption of HOCl was reflected in the formation of HOCl-specific epitopes on apo B-100 as determined by an antibody raised against HOCl-modified LDL. The absorbency at 234 nm was applied to measure continuously the extent of modification of LDL. The general kinetic pattern of the absorbency measurement consisted of a lag phase where no LDL modification was observed, followed by a rapid increase of absorbency and a plateau phase. Finally the absorbency decreased due to LDL precipitation. Time dependent absorption spectra indicated that this kinetic pattern is mainly caused by light scattering due to particle aggregation rather than by a specific absorption at 234 nm due to conjugated diene formation. In agreement with this finding a low rate of thiobarbituric acid reactive substances (TBArS) formation was observed after a lag phase. The aggregation of LDL occurs most likely by modification of apo B-100, which was determined fluorimetrically in terms of LDL-tryptophan destruction in presence of the MPO/H2O2/Cl(-)-system. The kinetic course of tryptophan fluorescence generally consisted of a rapid decrease leveling off into a low plateau phase. Gas chromatographic determinations of linoleic acid in LDL in presence of the MPO system showed that this polyunsaturated fatty acid (PUFA) is easily attacked by HOCl. Consistent with this finding NMR spectra of HOCl modified LDL indicated a complete disappearance of bis-allylic methylene groups. Since lipid peroxidation products only partially account for this loss of PUFAs, other reactions of HOCl with unsaturated lipids--probably chlorohydrin formation--must be involved. Summarizing, although the rate of lipid peroxidation is low, both the lipid and the protein moiety of LDL are readily modified by the MPO system. It appears that the immediate consequence of apo B-100 modification is its aggregation. It is concluded that MPO, which has been detected in atherosclerotic lesions, is able to contribute to the modification of LDL into a form recognizable for uncontrolled uptake by macrophages.

Changes in the polymorphonuclear leukocyte function of blood samples induced by storage time, temperature and agitation.

We have investigated changes in polymorphonuclear leukocyte (PMN) functions of blood samples caused by such typical elements of laboratory handling as storage time, temperature and agitation. The blood of five healthy subjects was stored upright in test tubes at 4, 22 and 37 degrees C over periods of 20 min, one, two, six and 24 h. Controlled agitation was performed on a shaker. The following PMN functional parameters were measured: the white blood cell count (WBC), migration, elastase (EL) release, reactive oxygen species (ROS) production and lipid peroxidation. Migration was determined in a whole-blood membrane filter assay; ROS production by latex-stimulated, luminol-enhanced chemiluminescence (CL) in a whole-blood assay; EL as EL alpha 1-antitrypsin complex; and lipid peroxidation by malondialdehyde (MDA) generation. The reactions after handling were compared with the values measured immediately after blood withdrawal which served as reference values of 'genuine' PMN reactivity. The outstanding result was the marked scatter between the individual reactions. Overall, the proportion of migrating PMNs in the blood total decreased, while CL, correlating positively with MDA, increased with the time of storage. EL increased considerably in some of the samples. Agitation raised CL and MDA. The effect of temperature was apparent only after 24 h at 37 degrees C. There was evidence that inhomogeneities in the blood samples were another interfering factor, since resuspension of sedimented blood after storage can be incomplete. In order to obtain reliable results from PMN functional tests, whole-blood assays and processing of blood samples within 20 min after blood withdrawal are recommended.