Paradoxical protective effect of aminoguanidine toward low-density lipoprotein oxidation: inhibition of apolipoprotein B fragmentation without preventing its carbonylation. Mechanism of action of aminoguanidine.

Oxidative modification of low-density lipoproteins (LDLs) is an important feature in the initiation and progression of atherosclerosis. Aminoguanidine (AMG), classically described as an inhibitor of advanced glycation end products, turned out to be also efficient in animal models as an antioxidant against lipid peroxidation. The originality of the present study was based on the simultaneous assessment of the oxidation of LDL lipid and protein moieties in order to characterize the molecular sites of AMG protection. Oxidation of the LDL lipid moiety was monitored by measuring conjugated dienes (CD) and hydroperoxide molecular species from cholesteryl esters (CEOOH) and phosphatidylcholines (PCOOH). LDL protein oxidative modifications were assessed by evaluating apoB carbonylation and fragmentation. The LDL oxidation was mediated by water gamma radiolysis, which has the advantage of being quantitative and highly selective with regard to the free radicals produced. Here, we reported that AMG resulted in a protection of LDLs against lipid peroxidation (both in the lag phase and in the propagation phase) and against apoB fragmentation in a concentration-dependent manner, due to the scavenging effect of AMG toward lipid peroxyl radicals. Paradoxically, AMG was poorly efficient against apoB carbonylation that began during the lag phase. We hypothesize that, even in the presence of AMG, a nonnegligible proportion of (*)OH radicals remained able to initiate oxidation of the LDL protein moiety, leading to apoB carbonylation.

In vitro low-density lipoprotein oxidation by copper or *OH/O*(2)(-): new features on carbonylation and fragmentation of apolipoprotein B during the lag phase.

The aim of our study was to evaluate the carbonylation and the carbonylated fragmentation of apolipoprotein B upon low-density lipoprotein (LDL) oxidation induced in vitro by copper and *OH/O*(2)(-) free radicals generated by gamma-radiolysis. Therefore, we developed a very sensitive Western blot immunoassay using 2,4-dinitrophenylhydrazine which allows the revelation of the apolipoprotein B carbonylation and its carbonylated fragmentation. The main results of this study show that (i) apolipoprotein B carbonylation is present during the lag phase of LDL oxidation in the two oxidative processes and (ii) apolipoprotein B carbonylated fragmentation was not detected during the lag phase of copper-oxidized LDL but was detected during the propagation phase. By contrast, apolipoprotein B carbonylated fragmentation was detected in the lag phase of *OH/O*(2)(-) oxidized LDL.

Human apo-lipoprotein B from normal plasma contains oxidised peptides.

Oxidation of low density lipoprotein (LDL) may be atherogenic, but radical-initiated oxidation of its apoprotein B-100 (apoB) has been little studied. Transition metal ions iron and copper are candidates for mediating radical oxidation of LDL in vivo. Therefore, we studied the copper-ion-induced oxidation of apoB in human LDL. Using HPLC methods developed in our recent work, we studied the destruction of native and the generation of six oxidised amino acids; we also assessed the release of peptides from the LDL particle by FPLC. We observed time-dependent losses of apoB histidine, lysine and glycine. Long-lived reactive species, the reductant DOPA, and the oxidant hydroperoxides of valine and leucine (measured as hydroxides after reduction), were generated. Their relative abundance (mol/mol of parent amino acid) was DOPA > o- and m-tyrosine > dityrosine, valine-hydroxides, leucine hydroxides. Low molecular weight fragments were also released from the LDL in a time-dependent manner, contained hydroperoxides sensitive to GSH peroxidase, and generated radicals on reaction with iron-EDTA. The fragments contained peptides active in the quinone redox cycling procedure, comprising 0.25% of the supplied LDL amino acids. Characteristic peptides were present in each FPLC fraction containing the fragments, as judged by further HPLC fractionation. Some fragments were present in the unoxidised LDL preparations, and when these were largely removed by FPLC, copper oxidation could still generate fragments, suggesting that those present in the starting material might indicate prior oxidation. Concordantly, we found that fresh plasma LDL apoB contained 43% of total plasma protein-bound oxidised amino acids, and with the same relative abundance. We conclude that plasma proteins including apoB are subject to physiological oxidation, similar to that inflicted by copper ions; the latter may contribute to intimal LDL oxidation, which could be the source of oxidised plasma apoB.

Alteration of lipoproteins of suction blister fluid by UV radiation.

Suction blister fluid is a good representative of the interstitial fluid feeding the epidermal cells. Lipoproteins contained in the suction blister fluid of healthy volunteers are readily photo-oxidized by UV radiation in the wavelength range 290-385 nm. Absorbed light doses equivalent to one minimal erythemal dose absorbed by skin exposed to UVB (e.g. 290-320 nm) are sufficient to induce lipid peroxidation and modification of apolipoproteins A-I, A-II and B. Albumin, which is known to protect serum fully from oxidative stresses, is not so effective against photo-oxidation. Although tryptophan (Trp) residues of proteins contained in the suction blister fluid are photo-oxidized, apolipoprotein A-II, which does not contain any chromophoric Trp residue, is also altered by the UV radiation. With regard to results obtained with a model reconstituted fluid, it is suggested that the radical chain reaction of the lipid peroxidation can transfer the initial photodamage at sites not directly susceptible to photo-oxidation. The biological implications of these results are discussed.

Elucidation of antioxidant activity of alpha-lipoic acid toward hydroxyl radical.

The photosensitive organic hydroperoxide, NP-III, which produces hydroxyl radicals on illumination by UVA light, was used to examine the antioxidant activity of alpha-lipoic acid and its derivatives toward hydroxyl radical. Apolipoprotein (apo-B) of human low density lipoprotein (LDL) and bovine serum alubumin (BSA) were irradiated with UVA in the presence of NP-III and alpha-lipoic acid. The oxidation of BSA and the apo-B protein of LDL by NP-III was completely suppressed by alpha-lipoic acid. ESR studies using dimethylpyrroline oxide (DMPO) as a spin trapping reagent also revealed that in the presence of alpha-lipoic acid, the DMPO-OH adduct produced from the irradiation of NP-III and DMPO completely disappeared. DMPO-OH quenching experiments were performed in the presence or absence of desferoxamine but no change in the signal intensity was found. Hence, the quenching activity of alpha-lipoic acid is not due to its chelating activity toward transition metals (ferrous ions). The results lead us to conclude that alpha-lipoic acid is an efficient hydroxyl radical quencher owing to the disulfide bond in the dithiolane ring.