Identification of 4-hydroxynonenal as a cytotoxic product originating from the peroxidation of liver microsomal lipids

During the NADPH-Fe induced peroxidation of liver microsomal lipids, products are formed which show various cytopathological effects including inhibition of microsomal glucose-6-phosphatase. The major cytotoxic substance has been isolated and identified as 4-hydroxy-2,3-trans-nonenal. The structure was ascertained by means of ultraviolet, infrared and mass spectrometry and high-pressure liquid chromatographic analysis. Moreover, 4-hydroxynonenal, prepared by chemical synthesis, was found to reproduce the biological effects brought about by the biogenic aldehyde. Preliminary investigations suggest that as compared to 4-hydroxynonenal very low amounts of other 4-hydroxyalkenals, namely 4-hydroxyoctenal, 4-hydroxydecenal and 4-hydroxyundecenal are also formed by actively peroxidizing liver microsomes. In the absence of NADPH-Fe liver microsomes produced only minute amounts of 4-hydroxyalkenals. The biochemical and biological effects of synthetic 4-hydroxyalkenals have been studied in great detail in the past. The results of these investigations together with the finding that 4-hydroxyalkenals, in particular 4-hydroxynonenal, are formed during NADPH-Fe stimulated peroxidation of liver microsomal lipids, may help to elucidate the mechanism by which lipid peroxidation causes deleterious effects on cells and cell constituents.     

Action of 2-nonenal and 4-hydroxynonenal on phosphoinositide-specific phosopholipase C in undifferentiated and DMSO-differentiated HL-60 cells

The promyelocytic cell line HL-60 has been used as an in vitro model to study the mechanism of action of two chemotactic aldehydes, 2-nonenal and 4-hydroxynonenal. Increasing aldehyde concentrations have been added to undifferentiated and DMSO-differentiated cells incubated at 37 degrees C and their effect on phosphoinositide-specific phospholipase C has been analysed by using a specific inositol-1,4,5-tris-phosphate assay system. Concentrations of 2-nonenal between 10(-9) and 10(-7) M significantly increased the enzymatic-activity in DMSO-differentiated HL-60 cells, while 10(-9) and 10(-8) M concentrations were active in the undifferentiated cells. 4-Hydroxynonenal was able to activate phospholipase C both in undifferentiated and DMSO-differentiated cells at concentrations ranging from 10(-8) to 10(-6) M. The concentrations of both compounds active on phospholipase C displayed a good correspondence with those which had been reported to be chemotactic towards rat neutrophils. In the case of 4-hydroxynonenal, the present results confirm its ability to activate phospholipase C, which we had previously shown in isolated neutrophil plasma membranes. The comparison of the effects of 2-nonenal and 4-hydroxynonenal on chemotaxis and phospholipase C activation suggests a common mechanism of action for both aldehydes, for which the presence of the double bond seems to be required.     

Inhibition of calcium sequestration activity of liver microsomes by 4-hydroxyalkenals originating from the peroxidation of liver microsomal lipids

Aldehydes released during peroxidation of liver microsomal lipids and identified as 4-hydroxyalkenals (4-hydroxynonenal being quantitatively the most significant) strongly inhibited the calcium sequestration activity of liver microsomes. The ID50 for 4-hydroxynonenal was 42 microM. The inhibition appeared to be correlated with the amount of the aldehyde bound to the microsomal protein. In rats intoxicated with BrCCl3 significant amounts of protein-bound aldehydes were formed at only 5 min after poisoning, a time at which the calcium sequestring capacity is markedly inhibited.     

Inhibition by reactive aldehydes of superoxide anion radical production in stimulated human neutrophils

alpha,beta-Unsaturated aldehydes were investigated in vitro for their ability to inhibit superoxide anion radical (O2-.) production in stimulated human polymorphonuclear leukocytes (PMN). The aldehydes investigated were (i) trans-4-hydroxynonenal and malonaldehyde (MDA), two toxic lipid peroxidation products; (ii) acrolein and crotonaldehyde, two air pollutants derived from fossil fuel combustion; (iii) trans,trans-muconaldehyde, a putative hematotoxic benzene metabolite. Preincubation of PMN with reactive aldehydes followed by stimulation with the oxygen burst initiator phorbol myristate acetate (PMA) resulted in a dose-dependent inhibition of O2-. production. The concentration at which 50% inhibition (IC50) was observed was 21 microM for acrolein, 23 microM for trans,trans-muconaldehyde, 27 microM for trans-4-hydroxynonenal and 330 microM for crotonaldehyde. A similar inhibitory effect by these aldehydes was observed in digitonin- and concanavalin A-stimulated PMN. MDA inhibited O2-. production in PMA-stimulated PMN by 100% at 10(-2) M but gave no inhibition at 10(-3) M. The standard aldehyde propionaldehyde did not inhibit O2-. production at 10(-3)-10(-6) M. Preincubation of PMN with acrolein in the presence of cysteine completely protected against the inhibitory effect of this reactive aldehyde. The results indicate that the ability of toxic aldehydes to inhibit O2-. production in stimulated PMN correlates directly with their alkylation potential which is a function of the electrophilicity of the beta carbon.     

Interaction Between Neutrophils and 4-Hydroxyalkenals and Consequences on Neutrophil Motility

The lipid peroxidation product 4-hydroxynonenal (HNE) and homologous aldehydes have been found to possess chemotactic activity for rat neutrophil leukocytes in the micromolar to picomolar range, depending on the compound. Such an activity is displayed only in the presence of albumin. The mechanisms by which aldehydes could interact with neutrophils are discussed. II is proposed that albumin acts as a carrier for the aldehyde and releases them to a neutrophil receptor. At concentrations around 10^?4M, 4-hydroxyal-kenals have been found to exert toxic effects on a number of cells, including a strong depression of neutrophil motility. Finally, HNE has been found at chemotactic concentrations in the inflammatory site. The possibility that HNE is involved in the neutrophil influx into the inflammatory site is considered.     

Chemistry and biochemistry of 4-hydroxynonenal, malonaldehyde and related aldehydes

Lipid peroxidation often occurs in response to oxidative stress, and a great diversity of aldehydes are formed when lipid hydroperoxides break down in biological systems. Some of these aldehydes are highly reactive and may be considered as second toxic messengers which disseminate and augment initial free radical events. The aldehydes most intensively studied so far are 4-hydroxynonenal, 4-hydroxyhexenal, and malonaldehyde. The purpose of this review is to provide a comprehensive summary on the chemical properties of these aldehydes, the mechanisms of their formation and their occurrence in biological systems and methods for their determination. We will also review the reactions of 4-hydroxyalkenals and malonaldehyde with biomolecules (amino acids, proteins, nucleic acid bases), their metabolism in isolated cells and excretion in whole animals, as well as the many types of biological activities described so far, including cytotoxicity, genotoxicity, chemotactic activity, and effects on cell proliferation and gene expression. Structurally related compounds, such as acrolein, crotonaldehyde, and other 2-alkenals are also briefly discussed, since they have some properties in common with 4-hydroxyalkenals.     

Cytotoxicity, DNA fragmentation and sister-chromatid exchange in Chinese hamster ovary cells exposed to the lipid peroxidation product 4-hydroxynonenal and homologous aldehydes

The cytotoxic and genotoxic activities of 4-hydroxypentenal (HPE), 4-hydroxyhexenal (HHE), 4-hydroxyoctenal (HOE), 4-hydroxynonenal (HNE) and 4-hydroxyundecenal (HUE) were investigated in Chinese hamster ovary (CHO) cells. All five 4-hydroxyalkenals reduced plating efficiency in a concentration (ranging from 7 to 170 microM) lower than that producing a parallel reduction of trypan blue-excluding cells, but with both methods the increase in molarity needed to obtain a lethal effect was constantly rather small. With all five 4-hydroxyalkenals a significant amount of DNA fragmentation, as revealed either by the alkaline elution assay or by alkaline denaturation followed by chromatographic partition of single- and double-stranded DNA, was detected only after cell exposure to a cytotoxic concentration. HPE, HHE and HOE induced a clear-cut increase of sister-chromatid exchange (SCE) frequency, while that displayed by cells treated with HNE and HUE was minimal, even if dose-dependent and statistically significant. Since 4-hydroxyalkenals have been shown to originate from biomembrane lipids peroxidation, these findings should be taken into consideration in the assessment of the genotoxic role of lipoperoxidation in humans.     

Monoclonal Antibodies for Detection of 4-Hydroxynonenal Modified Proteins

A promising approach to study lipid peroxidation pathology is antibodies recognizing aldehydes which react with and became bound to amino acid side chains of proteins. We present in this study the characterization of several monoclonal antibodies which recognize 4-hydroxynonenal (HNE) modified proteins. Six out of 20 antibodies recognizing HNE modified BSA were able to detect HNE-protein adducts in peroxidized liver microsomes. Two of these antibodies were selected and characterized. Both antibodies could also detect HNE-protein adducts in oxidized low density lipoprotein. They exhibit no detectable cross reaction with proteins modified by malonaldehyde, nonanal, nonenal and 4-hydroxyhexenal. Protein bound 4-hydroxyoctenal and 4-hydroxydecenal were recognized to some extent. Further characterization revealed that the two antibodies are highly selective for HNE bound to histidine with only some cross reaction to HNE bound to lysine and cysteine. Preliminary quantitative ELISA-analysis showed that oxidized microsomes and oxidized LDL contain 12 nmol and 3 nmol HNE-histidine per mg protein respectively.     

Interaction Between Neutrophils and 4-Hydroxyalkenals and Consequences on Neutrophil Motility

The lipid peroxidation product 4-hydroxynonenal (HNE) and homologous aldehydes have been found to possess chemotactic activity for rat neutrophil leukocytes in the micromolar to picomolar range, depending on the compound. Such an activity is displayed only in the presence of albumin. The mechanisms by which aldehydes could interact with neutrophils are discussed. II is proposed that albumin acts as a carrier for the aldehyde and releases them to a neutrophil receptor. At concentrations around 10^-4M, 4-hydroxyal-kenals have been found to exert toxic effects on a number of cells, including a strong depression of neutrophil motility. Finally, HNE has been found at chemotactic concentrations in the inflammatory site. The possibility that HNE is involved in the neutrophil influx into the inflammatory site is considered.     

Reactive aldehydes – second messengers of free radicals in diabetes mellitus

Abstract

Elevated levels of pro-oxidants and various markers of oxidative tissue damage were found in diabetic patients, indicating involvement of oxidative stress in the pathogenesis of diabetes mellitus (DM). On one side, physiological levels of reactive oxygen species (ROS) play an important role in redox signaling of various cells, while on the other, excessive ROS production can jeopardize the integrity and physiological functions of cellular macromolecules, in particular proteins, thus contributing to the pathogenesis of DM. Reactive aldehydes, especially 4-hydroxynonenal (HNE), are considered as second messengers of free radicals that act both as signaling molecules and as cytotoxic products of lipid peroxidation causing long-lasting biological consequences, in particular by covalent modification of macromolecules. Accordingly, the HNE and related reactive aldehydes may play important roles in the pathophysiology of DM, both in the development of the disease and in its progression and complications due to the following: (i) exposure of cells to supraphysiological levels of 4-hydroxyalkenals, (ii) persistent and sustained generation of 4-hydroxyalkenals that progressively affect vulnerable cells that lack an efficient bioactive aldehyde neutralization system, (iii) altered redox signaling influenced by reactive aldehydes, in particular by HNE, and (iv) induction of extracellular generation of similar aldehydes under secondary pathological conditions, such as low-grade inflammation.     

Stereospecificity of leukotriene B4 and structure-function relationships for chemotaxis of human neutrophils

The chemotactic activity of leukotriene B4 (5S, 12R Dihydroxy 6, 14 cis, 8, 10 trans eicosatetraenoic acid) (LTB4) was examined by using a sensitive Boyden-chamber assay. The activity of LTB4 was compared to other biosynthetic stereoisomers: 5S, 12R Dihydroxy 6, 8, 10 trans 14 cis eicosatetraenoic acid (6-trans LTB4); 5S, 12S Dihydroxy 6, 8, 10 trans 14 cis eicosatetraenoic acid (12-epi-6-trans LTB4), 5S, 12S DiHETE; the metabolic product 20-Hydroxy LTB4 (20-OH LTB4); methylated LTB4 (Methyl-LTB4), and the related monoHETE 5-HETE and 12-HETE. The compounds were purified by several steps of reverse phase and straight phase HPLC. The LTB4 exhibits measurable chemotactic activity at 10(-9) M with maximal activity at 10(-7) M and an ED50 of 10(-8) M. The LTB4 isomers and monoHETE were less chemotactic than previously reported. The monoHETE (5-HETE and 12-HETE), the isomer 12-epi-6-trans LTB4, and 5S, 12S DiHETE fail to attract neutrophils at levels between 10(-6) and 10(-5) M. If these compounds are chemotactic, then activity is at least four orders of magnitude less than that of LTB4. The isomer 6-trans LTB4 at 10(-6) to 10(-5) M induced chemotaxis with an extrapolated ED50 value of 10(-5) M, indicating that a trans for cis change in configuration at position 6 reduces the chemotactic activity of LTB4 by 1000-fold. Conversely, the metabolic product 20-OH LTB4 is at least as active as the native compound LTB4. Methylation of the carboxyl group of LTB4 reduces its chemotactic activity by two orders of magnitude. These results indicate a high degree of stereospecificity for the LTB4 receptor with strict dependence on hydroxyl group, and triene configuration and considerable dependence on the carboxyl group. Modification at the aliphatic omega end of the LTB4 molecule has a minimal effect on function, suggesting that the hydrophobicity of this portion of the molecule is not important for optimal activity. Furthermore, we propose that metabolic products of LTB4 may be of greater importance than LTB4 as physiologic inflammatory mediators in vivo.     

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

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.     

Kinetics of membrane-bound aldehyde dehydrogenase from Acinetobacter calcoaceticus

In recent investigations we were able to demonstrate that the NADP-dependent aldehyde dehydrogenase of Acinetobacter calcoaceticus is an inducible enzyme localized in intracytoplasmic membranes limiting alkane inclusions. Long-chain aliphatic hydrocarbons and alkanols are inducers of the enzyme. It was purified by us and now kinetically characterized using the enzyme-micelle form, which contains bacterial phospholipids and a detergent (sodium cholate), too. The pH optimum of aldehyde dehydrogenase was determined to be at pH 10. The enzyme showed substrate inhibition (by aldehyde excess). The Ks and Km values of the leading substrate NADP+ were found to be 8.6 X 10(-5) and 10.3 X 10(-5)M independent of the chain-length of the aldehydes. The Km values of the aldehydes decreased depending on increasing chain-length (butanal: 1.6 X 10(-3), decanal: 1.5 X 10(-6)M). The Ki values (for inhibition by aldehyde excess) showed a similar behaviour (butanal: 7.5 X 10(-3), decanal: 3.5 X 10(-5)M) as well as the optimal aldehyde concentrations inducing the "maximal" reaction velocity (butanal: 5mM, decanal: 6 microM). The number of inhibiting aldehyde molecules per enzyme-substrate complex was determined to be n = 1. NADPH showed product inhibition kinetics (Ki(NADPH) = 2.2 X 10(-4)M), fatty acids did not. We were unable to measure a reverse reaction. The following ions and organic compounds were non-competitive inhibitors of the enzyme: Sn2+, Fe2+, Cu2+, BO3(3-), CN-, EDTA, o-phenanthroline, p-chloromercuri-benzoate, mercaptoethanol, phenylmethylsulfonyl fluoride, and diisopropylfluorophosphate; iodoacetate did not influence enzyme activity. Chloral hydrate was a competitive inhibitor of the aldehydes. Ethyl butyrate activates the enzyme, dependent on the chain-length of the aldehyde substrates.     

Specific binding of leukotriene B4 to receptors on human polymorphonuclear leukocytes

Leukotriene B4 (5(S),12(R)-di-hydroxy-eicosa-6,14-cis-8,10-trans-tetraenoic acid [LTB4]) is a product of the 5-lipoxygenation of arachidonic acid, which elicits human PMN leukocyte chemotactic responses in vitro that are 50% of the maximal level at concentrations of 3 X 10(-9) M to 10(-8) M and are maximal at 2 X 10(-8) M to 10(-7) M. The specific binding of highly purified [3H]LTB4 to human PMN leukocytes was assessed both by extracting the unbound and weakly bound [3H]LTB4 with acetone at -78 degrees C and by centrifuging the PMN leukocytes through cushions of phthalate oil to separate the unbound from bound [3H]LTB4. The levels of total binding of [3H]LTB4 and of nonspecific binding of [3H]LTB4, in the presence of a 1500-fold molar excess of nonradioactive LTB4, were approximately two times higher with the phthalate oil method. Scatchard plots of the concentration dependence of the specific binding (total - nonspecific binding) of [3H]LTB4 to PMN leukocytes were linear for the acetone extraction and phthalate oil methods and revealed dissociation constants of 10.8 X 10(-9) M and 13.9 X 10(-9) M, respectively, and mean of 2.6 X 10(4) and 4.0 X 10(4) receptors per PMN leukocyte. The 5(S),12(S)-all-trans-di-HETE analog of LTB4 and 5-HETE competitively inhibited by 50% the binding of [3H]LTB4 to PMN leukocytes at respective concentrations that evoked half-maximal chemotactic responses, whereas neither N-formyl-methionyl-leucyl-phenylalanine nor chemotactic fragments of C5 inhibited the binding. Human erythrocytes exhibited no specific binding sites for [3H]LTB4. Human PMN leukocytes possess a subset of receptors for LTB4 that are distinct from those specific for peptide chemotactic factors.     

Autoxidation of human low density lipoprotein: loss of polyunsaturated fatty acids and vitamin E and generation of aldehydes

The alteration of structural and biological properties of human plasma low density lipoprotein (LDL) exposed to oxidative conditions is in part ascribed to lipid peroxidation. The objective of this investigation was to measure quantitatively several parameters in oxidizing LDL indicative for lipid peroxidation. Exposure of freshly prepared EDTA-free LDL to an oxygen-saturated buffer led to a complete depletion of alpha- and gamma-tocopherol within 6 hr, thereafter lipid peroxidation commenced as indicated by the kinetics of the loss of linoleic (18:2) and arachidonic (20:4) acids, the formation of aldehydic lipid peroxidation products and fluorescent apoB. Within 24 hr of oxidation, on average 79 nmol of 18:2 (initial 345) and 12.8 nmol of 20.4 (initial 25.6) were oxidized per mg of LDL and the sample contained in total 7.1 nmol of aldehydes with the following molar distribution: 36.6% malonaldehyde, 25% hexanal, 8.9% propanal, 8.2% 4-hydroxynonenal, 7.6% butanal, 4.1% 2.4-heptadienal, 3.4% pentanal, 3.4% 4-hydroxyhexenal, and 2.5% 4-hydroxyoctenal. Malonaldehyde was predominantly (93%) in the aqueous phase, whereas the other aldehydes remained mostly (34-98%) within the LDL particle, where the total aldehyde concentration was in the range of 12 mM. Oxidized LDL exhibited a 1.6-fold enhanced electrophoretic mobility. Similarily, native LDL incubated for 5 hr with aldehydes showed increased electrophoretic mobility. At equal concentrations (5 mM) 4-hydroxynonenal was most effective, followed by 2,4-heptadienal, hexanal, and malonaldehyde. This study reports for the first time the rate and extent of the change of LDL constituents occurring during lipid peroxidation.     

Assessment of growth inhibition by aldehydic lipid peroxidation products and related aldehydes by Saccharomyces cerevisiae

The effect of pretreatment with aldehydes on the subsequent colony forming efficiency (CFE) of Saccharomyces cerevisiae was investigated. All 21 aldehydes tested inhibited CFE in a dose-dependent manner. The effective doses, however, differed markedly from 300 mM to 0·07 mM depending on the functional groups and chain length of the aldehydes. Amongst the nine representatives of n-alkanals, formaldehyde was the most potent inhibitor, reducing CFE to 50 per cent at a dose of 0·3 mM (IC₅₀). In the series of 2-trans-alkenals, acrolein was most effective with an IC₅₀ of 0·08 mM and amongst the 4-hydroxy 2-trans-alkenals, 4-hydroxynonenal was most effective with IC₅₀ of 0·07 mM . In general, effectiveness decreased in the order: 4-hydroxyalkenals > 2-alkenals ? n-alkenals. It is proposed that S. cerevisiae is a promising target cell to elucidate further the molecular mechanisms by which aldehydes, particularly the lipid peroxidation product 4-hydroxynonenal, inhibits cell proliferation.     

LH-RH antagonist inhibits gonadal steroid secretion in vitro

This investigation was aimed at studying the direct action of LH-RH derivatives on gonadal function. Modulation by LH-RH antagonist (Ac-[D-beta-Nal1, D-p-Cl-Phe2, D-Trp3, D-Arg6, D-Ala10]-LH-RH) and agonist of LH-RH (D-Ser(TBU)6, AzaGly10-LH-RH) and native LH-RH of HCG-stimulated steroidogenesis in testicular Leydig cells and luteal cells was studied in vitro. The LH-RH antagonist (3.2 X 10(-8) M) was found to change ED50 of HCG from 2 X 10(-11) M to 5.5 X 10(-11) M in the Leydig cell culture system. In addition, the antagonist was noted to override the stimulatory action of native LH-RH in Leydig cells. Furthermore, the agonist was found to augment HCG-provoked testosterone secretion. Similarly, the LH-RH antagonist at 10(-9) M blunted HCG-stimulated progesterone secretion in the luteal cell culture system and increased the ED50 of HCG from 8.7 X 10(-13) to 7.7 X 10(-12) M. In contrast to the Leydig cell culture system native LH-RH (10(-8) M) and the agonist (10(-8) M) increased the ED50 of HCG in luteal cells from 8.7 X 10(-13) M to 3 X 10(-12) M and 2.3 X 10(-12) M, respectively. Present data combine to suggest that LH-RH antagonists act at least partially at the gonadal level and may be clinically useful to inhibit Leydig cell and ovarian function.     

Lipid Peroxidation and Biogenic Aldehydes: From the Identification of 4-Hydroxynonenal to Further Achievements in Biopathology

The formation, reactivity and toxicity of aldehydes originating from lipid peroxidation of cellular membranes are reviewed. Very reactive aldehydes, namely 4-hydroxyalkenals, were first shown to be formed in autoxidizing chemical systems. It was subsequently shown that 4-hydroxyalkenals are formed in biological conditions, i.e. during lipid peroxidation of liver microsomes incubated in the NADPH-Fe systems. Our studies carried out in collaboration with Hermann Esterbauer which led to the identification of 4-hydroxynonenal (4-HNE) are reported. 4-HNE was the most cytotoxic aldehyde and was then assumed as a model molecule of oxidative stress. Many other aldehydes (alkanals, alk-2-enals and dicarbonyl compounds) were then identified in peroxidizing liver microsomes or hepatocytes. The in vivo formation of aldehydes in liver of animals intoxicated with agents that promote lipid peroxidation was shown in further studies. In a first study, evidence was forwarded for aldehydes (very likely alkenals) bound to liver micro-somal proteins of CCl₄ or BrCCl₃-intoxicated rats. In a second study, 4-HNE and a number of other aldehydes (alkanals and alkenals) were identified in the free (non-protein bound) form in liver extracts from bromoben-zene or ally-1 alcohol-poisoned mice. The detection of free 4-HNE in the liver of CCl₄ or BrCCl₃-poisoned animals was obtained with the use of an electrochemical detector, which greatly increased the sensitivity of the HPLC method. Furthermore, membrane phospho-lipids bearing carbonyl groups were demonstrated in both in vitro (incubation of microsomes with NADPH-Fe) and in vivo (CCl₄ or BrCCl₃ intoxication) conditions. Finally, the results concerned with the histochemical detection of lipid peroxidation are reported. The methods used were based on the detection of lipid peroxidation-derived carbonyls. Very good results were obtained with the use of fluorescent reagents for carbonyls, in particular with 3-hydroxy-2-naphtoic acid hydrazide (NAH) and analysis with confocal scanning fluorescence microscopy with image video analysis. The significance of formation of toxic aldehydes in biological membranes is discussed.     

Lipid peroxidation of poly-unsaturated fatty acids in normal and obese adipose tissues

Adipose tissues function as the primary storage compartment of fatty acids and as an endocrine organ that affects peripheral tissues. Many of adipose tissue-derived factors, often termed adipokines, have been discovered in recent years. The synthesis and secretion of these factors vary in different depots of adipose tissues. Excessive lipid accumulation in adipocytes induces inflammatory processes by up-regulating the expression and release of pro-inflammatory cytokines. In addition, activated macrophages in the obese adipose tissue release inflammatory cytokines. Adipose tissue inflammation has also been linked to an enhanced metabolism of polyunsaturated fatty acids (PUFAs). The non-enzymatic peroxidation of PUFAs and of their 12/15-lipoxygenase-derived hydroperoxy metabolites leads to the generation of the reactive aldehyde species 4-hydroxyalkenals. This review shows that 4-hydroxyalkenals, in particular 4-hydroxynonenal, play a key role in lipid storage homeostasis in normal adipocytes. Nonetheless, in the obese adipose tissue an increased production of 4-hydroxyalkenals contributes to the inflamed phenotype.     

Occurrence of 4-hydroxyalkenals in rat tissues determined as pentafluorobenzyl oxime derivatives by gas chromatography-mass spectrometry

Malondialdehyde measurements have been the major tool for studying relationships between lipid peroxidation and tissue pathology. Recently, we presented a novel gas chromatography-mass spectrometry method for direct detection of phospholipid peroxides with picogram sensitivity based on transesterification of phospholipids or triglycerides to form pentafluorobenzyl esters. Under some circumstances the reactive primary oxidation products break down. Therefore, we developed a convenient, high sensitivity method to detect more stable secondary lipid oxidation products, the 4-hydroxyalkenals. The method accomplishes a facile extraction of 4-hydroxynonenal from tissues by forming pentafluorobenzyl oxime derivatives to displace aldehydes from Schiff base linkages. 4-hydroxynonenal was found in heart, liver, adrenal, and testis from rats and was detected to the 10-100 pg level by the current method.