R. J. Schaur

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.

Pathways of phospholipid oxidation by HOCl in human LDL detected by LC-MS.

A wealth of evidence now indicates that low-density lipoprotein (LDL) must be modified to promote atherosclerosis, and that this may involve oxidants released by phagocytes. Many studies of oxidative damage in atherosclerosis previously have concentrated on damage by nonhalogenated oxidants, but HOCl is a highly toxic oxidant produced by myeloperoxidase in phagocytes, which is also likely to be important in the disease pathogenesis. Currently some controversy exists over the products resulting from reaction of HOCl with LDL lipids, in particular regarding whether predominantly chlorohydrins or lipid peroxides are formed. In this study LC-MS of phosphatidylcholines in human LDL treated either with HOCl or the myeloperoxidase system was used as a specific method to detect chlorohydrin and peroxide formation simultaneously, and with comparable sensitivity. Chlorohydrin products from lipids containing oleic, linoleic and arachidonic acids were detected, but no hydroperoxides of linoleoyl or arachidonoyl lipids could be observed. This study provides the first direct evidence that lipid chlorohydrins rather than peroxides are the major products of HOCl- or myeloperoxidase-treated LDL phospholipids. This in turn provides important information required for the study of oxidative damage in vivo which will allow the type and source of oxidants involved in the pathology of atherosclerosis to be investigated.

Possible involvement of myeloperoxidase in lipid peroxidation

1. Exposure of liposomes to the MPO-H2O2-Cl- system results in oxidation of lipids. Malondialdehyde and 4-hydroxynonenal are formed. 2. Oxidation of liposomes by stimulated rat neutrophils, assessed by malondialdehyde formation, is inhibited by KCN. This indicates involvement of MPO in the process. 3. The MPO-H2O2 system oxidizes mildly LDL but in the presence of chloride a propagation phase, with a rapid increase of conjugated diene formation, was observed.

Detection of phospholipid oxidation in oxidatively stressed cells by reversed-phase HPLC coupled with positive-ionization electrospray MS

Measurement of lipid peroxidation is a commonly used method of detecting oxidative damage to biological tissues, but the most frequently used methods, including MS, measure breakdown products and are therefore indirect. We have coupled reversed-phase HPLC with positive-ionization electrospray MS (LC-MS) to provide a method for separating and detecting intact oxidized phospholipids in oxidatively stressed mammalian cells without extensive sample preparation. The elution profile of phospholipid hydroperoxides and chlorohydrins was first characterized using individual phospholipids or a defined phospholipid mixture as a model system. The facility of detection of the oxidized species in complex mixtures was greatly improved compared with direct-injection MS analysis, as they eluted earlier than the native lipids, owing to the decrease in hydrophobicity. In U937 and HL60 cells treated in vitro with t-butylhydroperoxide plus Fe2+, lipid oxidation could not be observed by direct injection, but LC-MS allowed the detection of monohydroperoxides of palmitoyl-linoleoyl and stearoyl-linoleoyl phosphatidylcholines. The levels of hydroperoxides observed in U937 cells were found to depend on the duration and severity of the oxidative stress. In cells treated with HOCl, chlorohydrins of palmitoyloleoyl phosphatidylcholine were observed by LC-MS. The method was able to detect very small amounts of oxidized lipids compared with the levels of native lipids present. The membrane-lipid profiles of these cells were found to be quite resistant to damage until high concentrations of oxidants were used. This is the first report of direct detection by LC-MS of intact oxidized phospholipids induced in cultured cells subjected to oxidative stress.

4-Hydroxynonenal modifies the effects of serum growth factors on the expression of the c-fos proto-oncogene and the proliferation of HeLa carcinoma cells

In this study, the effect of 4-hydroxynonenal (HNE), a peroxidation product of omega-6-poly-unsaturated fatty acids, on the expression of the c-fos proto-oncogene and growth factor-induced proliferation of HeLa carcinoma cells in vitro was investigated. The Fos protein forms the heterodimer AP-1 with the Jun protein and regulates the cell cycle by inducing cyclin D1. Agents that are able to induce c-fos include serum, platelet-derived growth factor (PDGF), and epidermal growth factor (EGF), all of which were used in this study. The proliferation rate was determined by cell counting (viable and dead cells according to trypan blue exclusion) and the BrdU assay. The c-fos mRNA level was monitored by the reverse transcriptase/polymerase chain reaction. In the absence of HNE, serum-deprived cells responded to serum stimulation with a more than 10-fold increase of the c-fos mRNA level as well as with an increased rate of DNA synthesis and cell multiplication. Both EGF and PDGF (applied in combination with insulin) were able to substitute for FCS and induced rapid growth of the tumor cells preincubated in serum-deprived medium. In the absence of growth factors a negative correlation between the HNE concentration (range: 1-250 microM) and the c-fos mRNA level was observed. We suppose that HNE interferes in this case with the basal activity of the c-fos promoter. EGF, when applied after the HNE treatment, induced rapid growth of the tumor cells preincubated in serum-free medium, if HNE was used in a physiological concentration (1 microM). No difference was observed compared to the HNE-free control. c-fos mRNA level was nearly unchanged. In contrast, a cytotoxic concentration of the aldehyde (100 microM) caused a complete inhibition of proliferation, although a twofold increase of the c-fos mRNA level immediately after the aldehyde treatment was observed. A similar effect of HNE in cytotoxic concentration on c-fos expression was observed when cells were grown in presence of PDGF instead of EGF. Hence, in both cases HNE possibly interferes with the signal transduction pathway, which is initiated by external growth factors. The increased c-fos expression might be part of an abortive attempt to overcome the stressful condition raised by a cytotoxic concentration of HNE.

Influence of Age on the Release of Reactive Oxygen Species by Phagocytes as Measured by a Whole Blood Chemiluminescence Assay

Polymorphonuclear and mononuclear phagocytes play an important role in host defense, but may also cause tissue injury through excessive inflammation. Reactive oxygen species (ROS) are not only directly ore indirectly involved in a wide variety of clinical disorders, such as atherosclerosis, reperfusion injury, pulmonary toxicity and cancer, but they are also important in the aging process. This process is associated with increasing susceptibility to infection. In this study we investigated the influence of age and sex on phagocyte activation by means of a whole blood chemiluminescence (CL) assay. Circulating phagocyte activity was measured in 55 healthy volunteers (24 females, 31 males) aged from 6 to 92 years. Using an automated luminescence system, phagocytes were stimulated by polystyrene beads and Luminol-enhanced CL was determined in terms of peak height and peak time in freshly withdrawn, peripheral venous whole blood. An extremely significant positive correlation (p < 0.0001) between the maximum of light emission after stimulation and increasing age was found. This finding is true for the total population of blood phagocytes as well as for a single cell. In contrast the time of the appearance of the maximum of light emission showed an extremely significant inverse correlation (p < 0.0003) with increasing age. The influence of sex on the CL-parameters showed no significant difference between women and men. It is concluded that the increased susceptibility of circulating phagocytes to oxidative burst in elderly subjects may be the consequence of several biological events. Senescent cells express more and also have new antigens on their surfaces that trigger an autoimmune response. Cellular senescence appears earlier in old organisms. Therefore phagocytes in aging individuals may be increasingly involved in their scavenger tasks that grow with the catabolic bias in cell turnover. Moreover, atherosclerotic alterations in the intima and endothelial lesions are physiologic concomitants of age and may lead to a stimulation of circulating phagocytes.

Detection of 4-hydroxynonenal as a product of lipid peroxidation in native Ehrlich ascites tumor cells

4-Hydroxynonenal, which is a major product of lipid peroxidation in rat liver microsomes, was detected in native Ehrlich ascites tumor cells. Its formation was stimulated either by ferrous ions or by Fe(II)-histidinate. The identification was based on chromatographic (TLC/HPLC) and ultraviolet-spectroscopic evidence using synthetic 4-hydroxynonenal as reference. Highest values of 4-hydroxynonenal concentration (about 0.1 microM in the cell suspension) after 30 min of incubation were observed with Fe(II)-histidinate as stimulant. Saturation was already reached after an incubation period of 10 min. The results confirm the expectation by Schauenstein and Esterbauer (in Submolecular Biology and Cancer, Ciba Foundation Series 67 (1979) pp. 225-244, Excerpta Medica, Amsterdam) that endogenous lipid peroxidation gives rise to a distinct intracellular level of alpha, beta-unsaturated aldehydes. A simple hypothetical mechanism for the formation of 4-hydroxynonenal from n-6-polyunsaturated fatty acids is presented.

Effect of Oxidative Stress by Iron on 4-Hydroxynonenal Formation and Proliferative Activity In Hepatomas of Different Degrees of Differentiation

It has been shown previously that oxidative stress by ferrous iron in vitro leads to an inhibition of proliferation of murine ascites tumour cells in vivo. This effect is associated with increased lipid peroxidation in terms of formation of the highly reactive aldehyde 4-hydroxynonenal (HNE), which has been shown to inhibit the proliferation of numerous tumours and to induce differentiation. It was the purpose of this article to study the occurrence and metabolism of HNE and its inducibility by oxidative stress in hepatomas of different degrees of differentiation to find further evidence for a possible role of HNE in proliferation and/or differentiation, because it is known that in hepatoma cells with a very low degree of differentiation basal lipid peroxidation is hardly detectable, while in normal hepatocytes the basal level of thiobarbituric acid reactive substances (TBArS) is rather high. MH1C1 hepatoma cells and Yoshida AH-130 hepatoma cells were chosen as highly differentiated and poorly differentiated tumour cells, respectively, and rat hepatocytes served as a control for normal liver phenotype. Ferrous histidinate (Fe/His) did not have a cytotoxic effect on Yoshida and MH1C1 cells, as measured by the LDH release test. In cell culture studies Fe/His revealed a dose dependent inhibition of the proliferation of Yoshida cells. The incorporation of 3H-thymidine into DNA of these cells was also inhibited by Fe/His in a dose-dependent manner, while the precursor uptake into the cytoplasm was unaffected. The basal levels of HNE were in the order: hepatocytes > MH1C1 cells > Yoshida cells. Both hepatocytes and Yoshida cells responded to the presence of Fe/His with increased formation of TBArS. Compared with hepatocytes the response of the Yoshida cells was greatly reduced. The response of cells to Fe/His with respect to HNE formation was decreased in the order: hepatocytes > MH1C1 cells > Yoshida cells, but in this case the differences were not very pronounced. The metabolic capacity of the cells to consume HNE was also decreased in the order: hepatocytes > MH1C1 cells > Yoshida cells. In this case the differences were very pronounced. These findings support the view that Yoshida cells with a low degree of differentiation and a low basal level of HNE are released from an inhibitory effect of HNE operative in hepatocytes and that HNE is causally involved in the iron induced inhibition of proliferation of poorly differentiated hepatoma cells.

Selective promotion of ferrous ion-dependent lipid peroxidation in Ehrlich ascites tumor cells by histidine as compared with other amino acids

Among tumors in general, Ehrlich ascites tumor cells are particularly resistant to lipid peroxidation. In this study lipid peroxidation was measured in terms of the formation of malondialdehyde-equivalent material in Ehrlich tumor cells during incubation in vitro. It was shown that the high antioxidant potential of these cells could be overcome by a strong radical-promoting agent like ferrous ion. Various amino acids were tested for their capability to augment the effect of Fe(II). Histidine and its 3-methyl-derivative turned out to be the most effective pro-oxidants, whose action could be ascribed to the presence of the imidazole group. From studies with homogenized and denatured cells it was concluded that lipid peroxidation stimulated by Fe(II)-histidinate is an autoxidation process and that no carrier effect of iron by histidine is predominating. The stimulatory action of Fe(II)-histidinate could be completely suppressed by vitamin C, which was shown to be a potent anti-oxidant under the conditions used. The combined application of Fe(II)-histidinate and vitamin C may offer a means to study lipid peroxidation of Ehrlich tumor cells in a controlled manner.

Iron-induced lipid peroxidation and inhibition of proliferation in Ehrlich ascites tumor cells

SummaryThe purpose of this study was to find further experimental evidence for the postulated negative association between the extent of lipid peroxidation in tumor cells and their proliferative behavior. After incubation of Ehrlich ascites tumor cells at 37°C for 30 min with increasing concentrations of Fe(II) histidinate (Fe/His) the following parameters were determined: the formation of lipid hydroperoxides was measured fluorimetrically after reaction with dichlorofluorescein; 4-hydroxynonenal was determined by reversed-phase high-pressure chromatography after derivatization with dinitrophenylhydrazine; as a third parameter of lipid peroxidation the formation of 2-thiobarbituric-acid-reactive substances was determined. The proliferative activity was determined by measuring the growth rate in vivo after reimplantation i.p. of the tumor cells into mice. Trypan-blue exclusion tests for viability were performed before reimplantation. The reliability of the trypan-blue exclusion tests was checked by comparing the results with another parameter of viability, the release of the cytosolic enzyme lactate dehydrogenase. The concentration both of lipid hydroperoxides and of 2-thiobarbituric-acid-reactive substances showed a biphasic dependence on the concentration of Fe/His with maximal increase at iron concentrations of 0.25 mM and 0.1mM respectively. 4-Hydroxynonenal, in contrast, showed a continuous increase up to 41.1 nM (corresponding to 0.58 pmol/109 cells) with increasing iron concentration in the range from 0.1 mM to 0.6 mM. The total number of tumor cells, when determined 5 days after reimplantation, continuously decreased with increasing iron concentration, showing half-maximal inhibition at about 0.22 mM Fe. The exclusion of the trypan-blue dye was unaffected by the presence of iron at any concentration used. Similarly, iron had no influence on the release of lactate dehydrogenase. The results support the hypothesis that 4-hydroxynonenal may act as an inhibiting messenger between endogenic lipid peroxidation and proliferation.