H. Esterbauer scite author profile

The metabolism of the lipid peroxidation product 4-hydroxynonenal and of several other related aldehydes by isolated hepatocytes and rat liver subcellular fractions has been investigated. Hepatocytes rapidly metabolize 4-hydroxynonenal in an oxygen-independent process with a maximum rate (depending on cell preparation) ranging from 130 to 230 nmol/min per 10(6) cells (average 193 +/- 50). The aldehyde is also rapidly utilized by whole rat liver homogenate and the cytosolic fraction (140 000 g supernatant) supplemented with NADH, whereas purified nuclei, mitochondria and microsomes supplemented with NADH show no noteworthy consumption of the aldehyde. In cytosol, the NADH-mediated metabolism of the aldehyde exhibits a 1:1 stoichiometry, i.e. 1 mol of NADH oxidized/mol of hydroxynonenal consumed, and the apparent Km value for the aldehyde is 0.1 mM. Addition of pyrazole (10 mM) or heat inactivation of the cytosol completely abolishes aldehyde metabolism. The various findings strongly suggest that hepatocytes and rat liver cytosol respectively convert 4-hydroxynonenal enzymically is the corresponding alcohol, non-2-ene-1,4-diol, according to the equation: CH3-[CH2]4-CH(OH)-CH = CH-CHO + NADH + H+----CH3-[CH2]4-CH(OH)-CH = CH-CH2OH + NAD+. The alcohol non-2-ene-1,4-diol has not yet been isolated from incubations with hepatocytes and liver cytosolic fractions, but was isolated in pure form from an incubation mixture containing 4-hydroxynonenal, isolated liver alcohol dehydrogenase and NADH and its chemical structure was confirmed by mass spectroscopy. Compared with liver, all other tissues possess only little ability to metabolize 4-hydroxynonenal, ranging from 0% (fat pads) to a maximal 10% (kidney) of the activity present in liver. The structure of the aldehyde has a strong influence on the rate and extent of its enzymic NADH-dependent reduction to the alcohol. The saturated analogue nonanal is a poor substrate and only a small proportion of it is converted to the alcohol. Similarly, nonenal is much less readily utilized as compared with 4-hydroxynonenal. The effective conversion of the cytotoxic 4-hydroxynonenal and other reactive aldehydes to alcohols, which are probably less toxic, could play a role in the general defence system of the liver against toxic products arising from radical-induced lipid peroxidation.

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Estimation of Peroxidative Damage

Esterbauer¹

1993

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Structure-activity relationships of 4-hydroxyalkenals in the conjugation catalysed by mammalian glutathione transferases

1987

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The substrate specificities of 15 cytosolic glutathione transferases from rat, mouse and man have been explored by use of a homologous series of 4-hydroxyalkenals, extending from 4-hydroxypentenal to 4-hydroxypentadecenal. Rat glutathione transferase 8-8 is exceptionally active with the whole range of 4-hydroxyalkenals, from C5 to C15. Rat transferase 1-1, although more than 10-fold less efficient than transferase 8-8, is the second most active transferase with the longest chain length substrates. Other enzyme forms showing high activities with these substrates are rat transferase 4-4 and human transferase mu. The specificity constants, kcat./Km, for the various enzymes have been determined with the 4-hydroxyalkenals. From these constants the incremental Gibbs free energy of binding to the enzyme has been calculated for the homologous substrates. The enzymes responded differently to changes in the length of the hydrocarbon side chain and could be divided into three groups. All glutathione transferases displayed increased binding energy in response to increased hydrophobicity of the substrate. For some of the enzymes, steric limitations of the active site appear to counteract the increase in binding strength afforded by increased chain length of the substrate. Comparison of the activities with 4-hydroxyalkenals and other activated alkenes provides information about the active-site properties of certain glutathione transferases. The results show that the ensemble of glutathione transferases in a given species may serve an important physiological role in the conjugation of the whole range of 4-hydroxyalkenals. In view of its high catalytic efficiency with all the homologues, rat glutathione transferase 8-8 appears to have evolved specifically to serve in the detoxication of these reactive compounds of oxidative metabolism.

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Hydroxyl-radical-induced iron-catalysed degradation of 2-deoxyribose. Quantitative determination of malondialdehyde

1988

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The degradation of 2-deoxyribose to thiobarbituric acid-reactive material was investigated with two hydroxyl-radical-generating systems: (i) a defined gamma-radiolysis method and (ii) incubation with FeSO4 in phosphate buffer. In each case the thiobarbituric acid-reactive material can be accounted for by malondialdehyde, as measured by an h.p.l.c. method for free malondialdehyde. In the radiolysis system there is a large post-irradiation increase in free malondialdehyde if iron ions are added to the samples. It is proposed that this is due to iron ions catalysing the formation of hydroxyl radicals from radiolytically generated H2O2 as well as stimulating the breakdown of an intermediate deoxyribose degradation product. A mechanism for the formation of malondialdehyde during deoxyribose degradation is proposed.

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A spectrophotometric assay for lipid peroxides in serum lipoproteins using a commercially available reagent.

ElSaadani

Esterbauer

El‐Sayed

et al. 1989

Journal of Lipid Research

569

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H. Esterbauer

Metabolism of the lipid peroxidation product 4-hydroxynonenal by isolated hepatocytes and by liver cytosolic fractions

Estimation of Peroxidative Damage

Structure-activity relationships of 4-hydroxyalkenals in the conjugation catalysed by mammalian glutathione transferases

Hydroxyl-radical-induced iron-catalysed degradation of 2-deoxyribose. Quantitative determination of malondialdehyde

A spectrophotometric assay for lipid peroxides in serum lipoproteins using a commercially available reagent.

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