[The role of oxidative processes in augmentation of atherogenity of low density lipoprotein particles].

We investigated action of natural dicarbonyl compounds which are formed in atherosclerosis and diabetes on properties of low density lipoproteins (LDL) such as surface charge, conformational changes of apoB100, susceptibility to oxidation. and aggregation rate. It was found that malonic dialdehyde (MDA) compared with glyoxal and methylglyoxal is more effective modificating agent of protein part of LDL particle. Nevertheless glyoxal and methylglyoxal-dependent modification of LDL can accelerate processes of further free radical peroxidation increasing atherogenity of LDL particles.

Macrophages actively accumulate malonyldialdehyde-modified but not enzymatically oxidized low density lipoprotein.

In this study, we show that low density lipoproteins (LDL) from human blood plasma which was oxidized by animal C-15 lipoxygenase is taken up by cultivated human macrophages with the same effectiveness as with non-oxidized (native) LDL. At the same time malonyldialdehyde-modified LDL is captured by cultivated macrophages very actively. Based on differences in catabolism of LDL with various levels of primary and secondary products of free-radical oxidation, it was offered to discriminate between the oxidized LDL itself (lipohydroperoxide-rich LDL) and the LDL that was chemically modified by free-radical oxidation secondary products of aldehyde nature. In this respect, aldehyde-modified but not oxidized (lipohydroperoxide-containing) LDL is atherogenic.

Interrelation between malonyl dialdehyde-dependent modification and cholesterol content in low-density lipoproteins.

Epidemiological study of an independent representative sample of population revealed a strong positive correlation between the content of oxidized (MDA-modified) LDL and concentration of atherosclerosis biomarkers (total cholesterol and LDL cholesterol) in blood plasma from 348 probands. The correlation between these parameters was more significant in atherosclerotic patients, but was less pronounced in probands with diabetes mellitus. The correlation between the concentration of atherosclerosis markers and content of MDA was absent in probands with diabetes mellitus. These data attest to the presence of LDL-modifying agents differing from MDA (e.g., glyoxal and methylglyoxal) in the blood of diabetes mellitus patients. We conclude that the content of MDA-modified LDL can serve as an additional biomarker of atherosclerosis.

Superoxide formation as a result of interaction of L-lysine with dicarbonyl compounds and its possible mechanism.

The EPR signal recorded in reaction medium containing L-lysine and methylglyoxal is supposed to come from the anion radical (semidione) of methylglyoxal and cation radical of methylglyoxal dialkylimine. These free-radical intermediates might be formed as a result of electron transfer from dialkylimine to methylglyoxal. The EPR signal was observed in a nitrogen atmosphere, whereas only trace amounts of free radicals were registered under aerobic conditions. It has been established that the decay of methylglyoxal anion radical on aeration of the medium is inhibited by superoxide dismutase. Using the methods of EPR spectroscopy and lucigenin-dependent chemiluminescence, it has been shown that nonenzymatic generation of free radicals including superoxide anion radical takes place during the interaction of L-lysine with methylglyoxal--an intermediate of carbonyl stress--at different (including physiological) pH values. In the course of analogous reaction of L-lysine with malondialdehyde (the secondary product of the free radical derived oxidation of lipids), the formation of organic free radicals or superoxide radical was not observed.

Effect of colchicine on sensitivity of duck salt gland Na,K-ATPase to Na+.

Low molecular mass proteins of the FXYD family that affect the sensitivity of Na,K-ATPase to Na+ and K+ are known to be present in Na,K-ATPases in various tissues. In particular, in Na,K-ATPase from kidney a gamma-subunit (with electrophoretic mobility corresponding to molecular mass of about 10 kD) is present, and Na,K-ATPase preparations from heart contain phospholemman (electrophoretic mobility of this protein corresponds to molecular mass of 13-14 kD), which provides for the interaction of heart Na,K-ATPase with cytoskeletal microtubules. Disruption of microtubules by colchicine removes phospholemman from heart Na,K-ATPase preparations. The goal of the present study was to reveal a low molecular mass protein (probably a member of FXYD family) in preparation of Na,K-ATPase from duck salt glands. Immunoprecipitation of solubilized duck salt gland Na,K-ATPase using antibodies against alpha1-subunit results in the coprecipitation of a 13 kD protein with the Na,K-ATPase complex. Treatment of homogenate from duck salt glands with colchicine removes this protein from the purified preparation of Na,K-ATPase. Simultaneously, we observed a decrease in the sensitivity of Na,K-ATPase to Na+ at pH 6.5. However, colchicine treatment of homogenate from rabbit kidney does not affect either the sensitivity of Na,K-ATPase obtained from this homogenate to Na+ or the content of 10 kD protein (presumably gamma-subunit). The data suggest that phospholemman (or a similar member of the FXYD family) tightly interacts with Na,K-ATPase from duck salt glands and binds it to microtubules, simultaneously participating in the regulation of the sensitivity of Na,K-ATPase to Na+.