Predominance of the 1,N2-propano 2'-deoxyguanosine adduct among 4-hydroxy-2-nonenal-induced DNA lesions

4-Hydroxy-2-nonenal (HNE), one of the main aldehydic compounds released during lipid peroxidation, has been proposed to react with DNA bases in cells. Several classes of DNA lesions involving addition of either HNE or its 2,3-epoxide (epox-HNE) have been identified. In the present work, HPLC associated with tandem mass spectrometry was used to determine the pattern of HNE-induced DNA lesions. First, adducts were quantified within isolated DNA treated with HNE under peroxidizing conditions. The 1,N2-propano-2'-deoxyguanosine adduct of HNE (HNE-dGuo) was found to be the major lesion under all conditions studied. 1,N6-Ethenoadenine and 1,N2-ethenoguanine together with their (1,2-dihydroxyheptyl)-substituted derivatives, which all arise from the reaction of epox-HNE with DNA, were produced in significantly lower yields, even in the presence of 20 mM H2O2. The pyrimidopurinone malondialdehyde-2'-deoxyguanosine adduct was also found to be produced, although in very low yield. Similar results were obtained in cultured human monocytes incubated with HNE, because the HNE-dGuo adduct represented more than 95% of the overall adducts to DNA. In addition, the former lesion was poorly repaired, in contrast to 1,N2-ethenoguanine and, to a lesser extent, 1,N6-ethenoadenine. Altogether, these results suggest than HNE-dGuo may represent the best biomarker of the genotoxic effects of HNE.     

Glutathione conjugates of 4-hydroxy-2(E)-nonenal as biomarkers of hepatic oxidative stress-induced lipid peroxidation in rats

Here we present a simple, specific, and sensitive liquid chromatography/mass spectrometry method to measure 4-hydroxy-2(E)-nonenal-glutathione (HNE-GSH), the major stable hepatic metabolite of HNE after GSH conjugation, as a marker of oxidative stress in rat liver and hepatocytes. Commonly employed methods for the measurement of lipid peroxidation-derived free aldehydes or modified proteins suffer from the artificial formation of HNE or HNE adducts to cellular molecules during sample preparation and derivatization, resulting in an overestimation of background levels. Basal levels of HNE-GSH in liver tissue from untreated rats were detected in amounts of 20 pmol/g liver. Rats exposed to a single dose of iron nitrilotriacetate (Fe(III)NTA; 15 mg Fe/kg bw, ip), a model compound for the induction of oxidative stress, revealed a fivefold increase in the hepatic HNE-GSH levels compared to controls 5 h after dosing. Moreover, a significant increase in HNE-mercapturic acid (HNE-MA) and its reduced metabolite DHN-MA was evident at 5 or 24 h after treatment, which was also reflected in increased plasma concentrations of these secondary HNE-GSH metabolites. In agreement with the in vivo data, a time-dependent increase in the levels of HNE-GSH from <1 to 123 +/- 16 pmol/10(6) cells over 5 h was detected in rat hepatocytes treated with Fe(III)NTA (150 microM). An increase in cellular HNE-GSH from <1.0 to 7.2 +/- 0.3 pmol/10(6) cells could be observed in rat hepatocytes treated with allyl alcohol (500 microM, 3 h), known for generation of HNE in hepatocytes. These data suggest that the direct measurement of the stable GSH conjugation product of cellular HNE in rat primary hepatocytes or its secondary metabolites may represent a reliable biomarker of oxidative stress-induced lipid peroxidation in rat liver in vivo.     

Repair kinetics of trans-4-hydroxynonenal-induced cyclic 1,N2-propanodeoxyguanine DNA adducts by human cell nuclear extracts

trans-4-Hydroxynonenal (HNE) is a major peroxidation product of omega-6 polyunsaturated fatty acids. The reaction of HNE with DNA produces four diastereomeric 1,N(2)-gamma-hydroxypropano adducts of deoxyguanosine (HNE-dG); background levels of these adducts have been detected in tissues of animals and humans. There is evidence to suggest that these adducts are mutagenic and involved in liver carcinogenesis in patients with Wilson's disease and in other human cancers. Here, we present biochemical evidence that in human cell nuclear extracts the HNE-dG adducts are repaired by the nucleotide excision repair (NER) pathway. To investigate the recognition and repair of HNE-dG adducts in human cell extracts, we prepared plasmid DNA substrates modified by HNE. [(32)P]-Postlabeling/HPLC determined that the HNE-dG adduct levels were approximately 1200/10(6) dG of plasmid DNA substrate. We used this substrate in an in vitro repair-synthesis assay to study the complete repair of HNE-induced DNA adducts in cell-free extracts. We observed that nuclear extracts from HeLa cells incorporated a significant amount of alpha[(32)P]dCTP in DNA that contained HNE-dG adducts by comparison with UV-irradiated DNA as the positive control. Such repair synthesis for UV damage or HNE-dG adducts did not occur in XPA cell nuclear extracts that lack the capacity for NER. However, XPA cells complemented with XPA protein restored repair synthesis for both of these adducts. To verify that HNE-dG adducts in DNA were indeed repaired, we measured HNE-dG adducts in the post-repaired DNA substrates by the [(32)P]-postlabeling/HPLC method, showing that 50-60% of HNE-dG adducts were removed from the HeLa cell nuclear extracts after 3 h at 30 degrees C. The repair kinetics indicated that the excision rate is faster than the rate of gap-filling/DNA synthesis. Furthermore, the HNE-dG adduct isomers 2 and 4 appeared to be repaired more efficiently at early time points than isomers 1 and 3.     

Post-translational Modification of Serine/Threonine Kinase LKB1 via Adduction of the Reactive Lipid Species 4-Hydroxy-trans-2-nonenal (HNE) at Lysine Residue 97 Directly Inhibits Kinase Activity

Oxidative stress is pathogenic in a variety of diseases, but the mechanism by which cellular signaling is affected by oxidative species has yet to be fully characterized. Lipid peroxidation, a secondary process that occurs during instances of free radical production, may play an important role in modulating cellular signaling under conditions of oxidative stress. 4-Hydroxy-trans-2-nonenal (HNE) is an electrophilic aldehyde produced during lipid peroxidation that forms covalent adducts on proteins, altering their activity and function. One such target, LKB1, has been reported to be inhibited by HNE adduction. We tested the hypothesis that HNE inhibits LKB1 activity through adduct formation on a specific reactive residue of the protein. To elucidate the mechanism of the inhibitory effect, HEK293T cells expressing LKB1 were treated with HNE (10 μm for 1 h) and assayed for HNE-LKB1 adduct formation and changes in LKB1 kinase activity. HNE treatment resulted in the formation of HNE-LKB1 adducts and decreased LKB1 kinase activity by 31 ± 9% (S.E.) but had no effect on the association of LKB1 with its adaptor proteins sterile-20-related adaptor and mouse protein 25. Mutation of LKB1 lysine residue 97 reduced HNE adduct formation and attenuated the effect of HNE on LKB1 activity. Taken together, our results suggest that adduction of LKB1 Lys-97 mediates the inhibitory effect of HNE.     

Enhanced glutathione depletion, protein adduct formation, and cytotoxicity following exposure to 4-hydroxy-2-nonenal (HNE) in cells expressing human multidrug resistance protein-1 (MRP1) together with human glutathione S-transferase-M1 (GSTM1)

4-Hydroxy-2-nonenal (HNE) is one of the most reactive products of lipid peroxidation and has both cytotoxic and genotoxic effects in cells. Several enzymatic pathways have been reported to detoxify HNE, including conjugation by glutathione-S-transferases (GSTs). Removal of the resulting HNE-glutathione conjugate (HNE-SG) by an efflux transporter may be required for complete detoxification. We investigated the effect of expression of GSTM1 and/or the ABC efflux transporter protein, multidrug-resistance protein-1 (MRP1), on HNE-induced cellular toxicity. Stably transfected MCF7 cell lines were used to examine the effect of GSTM1 and/or MRP1 expression on HNE-induced cytotoxicity, GSH depletion, and HNE-protein adduct formation. Co-expression in the MCF7 cell line of GSTM1 with MRP1 resulted in a 2.3-fold sensitization to HNE cytotoxicity (0.44-fold IC(50) value relative to control) rather than the expected protection. Expression of either GSTM1 or MRP1 alone also resulted in slight sensitization to HNE cytotoxicity (0.79-fold and 0.71-fold decreases in IC(50) values, respectively). Co-expression of GSTM1 and MRP1 strongly enhanced the formation of HNE-protein adducts relative to the non-expressing control cell line, whereas expression of either MRP1 alone or GSTM1 alone yielded similarly low levels of HNE-protein adducts to that of the control cell line. Glutathione (GSH) levels were reduced by 10-20% in either the control cell line or the MCF7/GSTM1 cell line with the same HNE exposure for 60min. However, HNE induced >80% depletion of GSH in cells expressing MRP1 alone. Co-expression of both MRP1 and GSTM1 caused slightly greater GSH depletion, consistent with the greater protein adduct formation and cytotoxicity in this cell line. Since expression of GSTM1 or MRP1 alone did not strongly sensitize cells to HNE, or result in greater HNE-protein adducts than in the control cell line, these results indicate that MRP1 and GSTM1 collaborate to enhance HNE-protein adduct formation and HNE cytotoxicity, facilitated by GSH depletion mediated by both MRP1 and GSTM1.     

Lipid peroxidation product 4-hydroxy-2-nonenal modulates base excision repair in human cells

Oxidative-stress-driven lipid peroxidation (LPO) is involved in the pathogenesis of several human diseases, including cancer. LPO products react with cellular proteins changing their properties, and with DNA bases to form mutagenic etheno-DNA adducts, removed from DNA mainly by the base excision repair (BER) pathway.One of the major reactive aldehydes generated by LPO is 4-hydroxy-2-nonenal (HNE). We investigated the effect of HNE on BER enzymes in human cells and in vitro. K21 cells pretreated with physiological HNE concentrations were more sensitive to oxidative and alkylating agents, H₂O₂ and MMS, than were untreated cells. Detailed examination of the effects of HNE on particular stages of BER in K21 cells revealed that HNE decreases the rate of excision of 1,N⁶-ethenoadenine (ɛA) and 3,N⁴-ethenocytosine (ɛC), but not of 8-oxoguanine. Simultaneously HNE increased the rate of AP-site incision and blocked the re-ligation step after the gap-filling by DNA polymerases. This suggested that HNE increases the number of unrepaired single-strand breaks (SSBs) in cells treated with oxidizing or methylating agents. Indeed, preincubation of cells with HNE and their subsequent treatment with H₂O₂ or MMS increased the number of nuclear poly(ADP-ribose) foci, known to appear in cells in response to SSBs. However, when purified BER enzymes were exposed to HNE, only ANPG and TDG glycosylases excising ɛA and ɛC from DNA were inhibited, and only at high HNE concentrations. APE1 endonuclease and 8-oxoG-DNA glycosylase 1 (OGG1) were not inhibited. These results indicate that LPO products exert their promutagenic action not only by forming DNA adducts, but in part also by compromising the BER pathway.     

Long-chain adducts of trans-4-hydroxy-2-nonenal to DNA bases cause recombination, base substitutions and frameshift mutations in M13 phage

Oxidative stress enhances lipid peroxidation (LPO) implicated in the promotion and progression of carcinogenesis. One of the major LPO products is trans-4-hydroxy-2-nonenal (HNE), which was shown to react with guanosine and under peroxidizing conditions also with adenosine. We show here that all four DNA bases are targets for HNE, although displaying different reactivity: dG > dC > dA approximately equal to dT. HPLC and mass spectrometry analyses of HNE reactions with deoxynucleosides showed in each case the formation of several products, with mass peaks corresponding to HNE-dN adducts at a 1:1 and also 2:1 and 3:1 ratios. In the dA, dC and dG reactions, mass peaks corresponding to heptyl-substituted etheno-adducts were also detected, indicating HNE oxidation to its epoxide by air oxygen. In DNA pretreated with HNE, DNA synthesis by T7 DNA polymerase was stopped in a sequence-dependent manner at G > or = C > A and T sites. HNE increased the mutation rates in the lac Z gene of M13 phage transfected into wild type Escherichia coli. The most frequent event was the recombination between lacZ gene sequences in M13 and the E. coli F' factor DNA. Base substitutions and frameshifts were also observed in approximately similar numbers. Over 50% of base substitutions were the C-->T transitions, followed by the G-->C and A-->C transversions. In the E. coli recA strain recombination was not observed, although one mutational G-->T hot-spot appeared within the DNA fragment undergoing recombination in the wild type E. coli. We conclude that long chain HNE adducts to DNA bases arrest DNA synthesis and cause recombination, base substitutions and frameshift mutations in ssDNA.     

Glutathione transferase A4-4 resists adduction by 4-hydroxynonenal

4-Hydroxy-2-trans-nonenal (HNE) is a lipid peroxidation product that contributes to the pathophysiology of several diseases with components of oxidative stress. The electrophilic nature of HNE results in covalent adduct formation with proteins, fatty acids and DNA. However, it remains unclear whether enzymes that metabolize HNE avoid inactivation by it. Glutathione transferase A4-4 (GST A4-4) plays a significant role in the elimination of HNE by conjugating it with glutathione (GSH), with catalytic activity toward HNE that is dramatically higher than the homologous GST A1-1 or distantly related GSTs. To determine whether enzymes that metabolize HNE resist its covalent adduction, the rates of adduction of these GST isoforms were compared and the functional effects of adduction on catalytic properties were determined. Although GST A4-4 and GST A1-1 have striking structural similarity, GST A4-4 was insensitive to adduction by HNE under conditions that yield modest adduction of GST A1-1 and extensive adduction of GST P1-1. Furthermore, adduction of GST P1-1 by HNE eliminated its activity toward the substrates 1-chloro-2,4-dinitrobenzene (CDNB) and toward HNE itself. HNE effects on GST A4-4 and A1-1 were less significant. The results indicate that enzymes that metabolize HNE may have evolved structurally to resist covalent adduction by it.     

Reactions of malonaldehyde and acetaldehyde with calf thymus DNA: formation of conjugate adducts

Our previous work has shown that treatment of nucleosides with malonaldehyde simultaneously with acetaldehyde affords stable conjugate adducts. In the present study we demonstrate that conjugate adducts are also formed in calf thymus DNA when incubated with the aldehydes. The adducts were identified in the DNA hydrolysates by their positive ion electrospray MS/MS spectra, by coelution with the 2'-deoxynucleoside standards, and, in the case of adducts exhibiting fluorescent properties, also by LC using a fluorescence detector. In the hydrolysates of double-stranded DNA (ds DNA), two deoxyguanosine and two deoxyadenosine conjugate adducts were detected and in single-stranded DNA (ss DNA) also, the deoxycytidine conjugate adduct was observed. The guanine base was the major target for the malonaldehyde-acetaldehyde conjugates and 2'-deoxyguanosine adducts were produced in ds DNA at levels of 100-500 adducts/10(5) nucleotides (0.7-3 nmol/mg DNA).     

The covalent modification of spectrin in red cell membranes by the lipid peroxidation product 4-hydroxy-2-nonenal

Spectrin strengthens the red cell membrane through its direct association with membrane lipids and through protein-protein interactions. Spectrin loss reduces the membrane stability and results in various types of hereditary spherocytosis. However, less is known about acquired spectrin damage. Here, we showed that α- and β-spectrin in human red cells are the primary targets of the lipid peroxidation product 4-hydroxy-2-nonenal (HNE) by immunoblotting and mass spectrometry analyses. The level of HNE adducts in spectrin (particularly α-spectrin) and several other membrane proteins was increased following the HNE treatment of red cell membrane ghosts prepared in the absence of MgATP. In contrast, ghost preparation in the presence of MgATP reduced HNE adduct formation, with preferential β-spectrin modification and increased cross-linking of the HNE-modified spectrins. Exposure of intact red cells to HNE resulted in selective HNE-spectrin adduct formation with a similar preponderance of HNE-β-spectrin modifications. These findings indicate that HNE adduction occurs preferentially in spectrin at the interface between the skeletal proteins and lipid bilayer in red cells and suggest that HNE-spectrin adduct aggregation results in the extrusion of damaged spectrin and membrane lipids under physiological and disease conditions.     

Inactivation of NADP+-dependent isocitrate dehydrogenase by lipid peroxidation products

Membrane lipid peroxidation processes yield products that may react with proteins to cause oxidative modification. Recently, we demonstrated that the control of cytosolic and mitochondrial redox balance and oxidative damage is one of the primary functions of NADP₊-dependent isocitrate dehydrogenase (ICDH) through to supply NADPH for antioxidant systems. When exposed to lipid peroxidation products, such as malondialdehyde (MDA), 4-hydroxynonenal (HNE) and lipid hydroperoxide, ICDH was susceptible to oxidative damage, which was indicated by the loss of activity and the formation of carbonyl groups. The structural alterations of modified enzymes were indicated by the change in thermal stability, intrinsic tryptophan fluorescence and binding of the hydrophobic probe 8-anilino 1-napthalene sulfonic acid. Upon exposure to 2,2'-azobis(2-amidinopropane) hydrochloride (AAPH), which induces lipid peroxidation in membrane, a significant decrease in both cytosolic and mitochondrial ICDH activities were observed in U937 cells. Using immunoprecipitation and immunoblotting, we were able to isolate and positively identify HNE adduct in mitochondrial ICDH from AAPH-treated U937 cells. The lipid peroxidation-mediated damage to ICDH may result in the perturbation of the cellular antioxidant defense mechanisms and subsequently lead to a pro-oxidant condition.     

Comparative study of hydrogen peroxide- and 4-hydroxy-2-nonenal-induced cell death in HT22 cells

Several studies have indicated that lipid peroxidation often occurs in response to oxidative stress, and that many aldehydic products including 4-hydroxy-2-nonenal (HNE) are formed when lipid hydroperoxides break down. In order to clarify the mechanism of oxidative stress-induced neuronal death in the nervous system, we investigated H(2)O(2)- and HNE-induced cell death pathways in HT22 cells, a mouse hippocampal cell line, under the same experimental conditions. Treatment with H(2)O(2) and HNE decreased the viability of these cells in a time- and concentration-dependent manner. In the cells treated with H(2)O(2), significant increases in the immunoreactivities of DJ-1 and nuclear factor-kappaB (NF-kappaB) subunits (p65 and p50) were observed in the nuclear fraction. H(2)O(2) also induced an increase in the intracellular concentration of Ca(2+), and cobalt chloride (CoCl(2)), a Ca(2+) channel inhibitor, suppressed the H(2)O(2)-induced cell death. In HNE-treated cells, none of these phenomena were observed; however, HNE adduct proteins were formed after exposure to HNE, but not to H(2)O(2). N-Acetyl-L-cysteine (NAC) suppressed both HNE-induced cell death and HNE-induced expression of HNE adduct proteins, whereas H(2)O(2)-induced cell death was not affected. These findings suggest that the mechanisms of cell death induced by H(2)O(2) different from those induced by HNE in HT22 cells, and that HNE adduct proteins play an important role in HNE-induced cell death. It is also suggested that the pathway for H(2)O(2)-induced cell death in HT22 cells does not involve HNE production.     

Regulation of 4-hydroxynonenal-mediated signaling by glutathione S-transferases

4-Hydroxynonenal (HNE), one of the major end products of lipid peroxidation, has been shown to be involved in signal transduction and available evidence suggests that it can affect cell cycle events in a concentration-dependent manner. Glutathione S-transferases (GSTs) can modulate the intracellular concentrations of HNE by affecting its generation during lipid peroxidation by reducing hydroperoxides and also by converting it into a glutathione conjugate. We have recently demonstrated that overexpression of the Alpha class GSTs in cells leads to lower steady-state levels of HNE, and these cells acquire resistance to apoptosis induced by lipid peroxidation-causing agents such as H(2)O(2), UVA, superoxide anion, and pro-oxidant xenobiotics, suggesting that signaling for apoptosis by these agents is transduced through HNE. Cells with the capacity to exclude HNE from the intracellular environment at a faster rate are relatively more resistant to apoptosis caused by H(2)O(2), UVA, superoxide anion, and pro-oxidant xenobiotics as well as by HNE, suggesting that HNE may be a common denominator in mechanisms of apoptosis caused by oxidative stress. We have also shown that transfection of adherent cells with HNE-metabolizing GSTs leads to transformation of these cells due to depletion of HNE. These recent studies from our laboratories, which strongly suggest that HNE is a key signaling molecule and that GSTs, being determinants of its intracellular concentrations, can regulate stress-mediated signaling, are reviewed in this article.     

Mitogenic responses of vascular smooth muscle cells to lipid peroxidation-derived aldehyde 4-hydroxy-trans-2-nonenal (HNE): role of aldose reductase-catalyzed reduction of the HNE-glutathione conjugates in regulating cell growth

Products of lipid peroxidation such as 4-hydroxy-trans-2-nonenal (HNE) trigger multiple signaling cascades that variably affect cell growth, differentiation, and apoptosis. Because glutathiolation is a significant metabolic fate of these aldehydes, we tested the possibility that the bioactivity of HNE depends upon its conjugation with glutathione. Addition of HNE or the cell-permeable esters of glutathionyl-4-hydroxynonenal (GS-HNE) or glutathionyl-1,4-dihydroxynonene (GS-DHN) to cultures of rat aortic smooth muscle cells stimulated protein kinase C, NF-kappaB, and AP-1, and increased cell growth. The mitogenic effects of HNE, but not GS-HNE or GS-DHN, were abolished by glutathione depletion. Pharmacological inhibition or antisense ablation of aldose reductase (which catalyzes the reduction of GS-HNE to GS-DHN) prevented protein kinase C, NF-kappaB, and AP-1 stimulation and the increase in cell growth caused by HNE and GS-HNE, but not GS-DHN. The growth stimulating effect of GS-DHN was enhanced in cells treated with antibodies directed against the glutathione conjugate transporters RLIP76 (Ral-binding protein) or the multidrug resistance protein-2. Overexpression of RLIP76 abolished the mitogenic effects of HNE and its glutathione conjugates, whereas ablation of RLIP76 using RNA interference promoted the mitogenic effects. Collectively, our findings suggest that the mitogenic effects of HNE are mediated by its glutathione conjugate, which has to be reduced by aldose reductase to stimulate cell growth. These results raise the possibility that the glutathione conjugates of lipid peroxidation products are novel mediators of cell signaling and growth.     

Glutathione Cycle Impairment Mediates Aβ-induced Cell Toxicity

Membrane lipid peroxidation processes yield products that may react with proteins to cause oxidative modification. Recently, we demonstrated that the control of cytosolic and mitochondrial redox balance and oxidative damage is one of the primary functions of NADP⁺-dependent isocitrate dehydrogenase (ICDH) through to supply NADPH for antioxidant systems. When exposed to lipid peroxidation products, such as malondialdehyde (MDA), 4-hydroxynonenal (HNE) and lipid hydroperoxide, ICDH was susceptible to oxidative damage, which was indicated by the loss of activity and the formation of carbonyl groups. The structural alterations of modified enzymes were indicated by the change in thermal stability, intrinsic tryptophan fluorescence and binding of the hydrophobic probe 8-anilino 1-napthalene sulfonic acid. Upon exposure to 2,2′-azobis(2-amidinopropane) hydrochloride (AAPH), which induces lipid peroxidation in membrane, a significant decrease in both cytosolic and mitochondrial ICDH activities were observed in U937 cells. Using immunoprecipitation and immunoblotting, we were able to isolate and positively identify HNE adduct in mitochondrial ICDH from AAPH-treated U937 cells. The lipid peroxidation-mediated damage to ICDH may result in the perturbation of the cellular antioxidant defense mechanisms and subsequently lead to a pro-oxidant condition.     

Mechanism of destruction of microtubule structures by 4-hydroxy-2-nonenal

A major end product of lipid peroxidation, 4-hydroxy-2-nonenal (HNE), is an electrophilic alkenal and produces Michael adducts with cellular proteins. It is known that exposure of cultured cells to HNE causes rapid disappearance of microtubule networks. In this study we addressed the mechanism. Immunochemical studies revealed that HNE preferentially modified alpha-tubulin in rat primary neuronal cells, PC12 cells, and rat fibroblast cell line 3Y1 cells. This was morphologically associated with the disappearance of microtubule structures in those cells. In a purified rat brain microtubule fraction, HNE modified unpolymerized tubulin and impaired its polymerizability, with a concomitant increase in insolubilized tubulin. Nevertheless, HNE had a marginal effect on the stability of pre-polymerized microtubules. These results suggest that disruption of microtubule assembly as a result of HNE modification of unpolymerized tubulin, rather than destruction of assembled microtubules, is responsible for the disappearance of microtubule structures in cells exposed to HNE.     

Metabolism of 4-hydroxy-2-nonenal in human polymorphonuclear leukocytes

Intracellular metabolism of 4-hydroxy-2-nonenal (HNE), a major product and mediator of oxidative stress and inflammation, is analyzed in resting and fMLP-stimulated human polymorphonuclear leukocytes (PMNL), where this compound is generated during activation of the respiratory burst. HNE consumption rate in PMNL is very low, if compared to other cell types (rat hepatocytes, rabbit fibroblasts), where HNE metabolism is always an important part of secondary antioxidative defense mechanisms. More than 98% of HNE metabolites are identified. The pattern of HNE intermediates is quite similar in stimulated and resting PMNL - except for higher water formation in resting PMNL - while the initial velocity of HNE degradation is somewhat higher in resting cells, 0.44 instead of 0.28 nmol/(min × 10⁶ cells). The main products of HNE metabolism are 4-hydroxynonenoic acid (HNA), 1,4-dihydroxynonene (DHN) and the glutathione adducts with HNE, HNA, and DHN. Protein-bound HNE and water account for about 3-4% of the total HNE derivatives in stimulated cells, while in resting cells protein-bound HNE and water are 4% and 20%, respectively. Cysteinyl-glycine-HNE adduct and mercapturic acids contribute to about 5%.     

The modulation of topoisomerase I-mediated DNA cleavage and the induction of DNA-topoisomerase I crosslinks by crotonaldehyde-derived DNA adducts

Crotonaldehyde is a representative alpha,beta-unsaturated aldehyde endowed of mutagenic and carcinogenic properties related to its propensity to react with DNA. Cyclic crotonaldehyde-derived deoxyguanosine (CrA-PdG) adducts can undergo ring opening in duplex DNA to yield a highly reactive aldehydic moiety. Here, we demonstrate that site-specifically modified DNA oligonucleotides containing a single CrA-PdG adduct can form crosslinks with topoisomerase I (Top1), both directly and indirectly. Direct covalent complex formation between the CrA-PdG adduct and Top1 is detectable after reduction with sodium cyanoborohydride, which is consistent with the formation of a Schiff base between Top1 and the ring open aldehyde form of the adduct. In addition, we show that the CrA-PdG adduct alters the cleavage and religation activities of Top1. It suppresses Top1 cleavage complexes at the adduct site and induces both reversible and irreversible cleavage complexes adjacent to the CrA-PdG adduct. The formation of stable DNA-Top1 crosslinks and the induction of Top1 cleavage complexes by CrA-PdG are mutually exclusive. Lastly, we found that crotonaldehyde induces the formation of DNA-Top1 complexes in mammalian cells, which suggests a potential relationship between formation of DNA-Top1 crosslinks and the mutagenic and carcinogenic properties of crotonaldehyde.