Protective effects of carnosine and homocarnosine on ferritin and hydrogen peroxide-mediated DNA damage

Previous studies have shown that one of the primary causes of increased iron content in the brain may be the release of excess iron from intracellular iron storage molecules such as ferritin. Free iron generates ROS that cause oxidative cell damage. Carnosine and related compounds such as endogenous histidine dipetides have antioxidant activities. We have investigated the protective effects of carnosine and homocarnosine against oxidative damage of DNA induced by reaction of ferritin with H(2)O(2). The results show that carnosine and homocarnosine prevented ferritin/H(2)O(2)-mediated DNA strand breakage. These compounds effectively inhibited ferritin/H(2)O(2)-mediated hydroxyl radical generation and decreased the mutagenicity of DNA induced by the ferritin÷H(2)O(2) reaction. Our results suggest that carnosine and related compounds might have antioxidant effects on DNA under pathophysiological conditions leading to degenerative damage such as neurodegenerative disorders.     

Iron-overload induces oxidative DNA damage in the human colon carcinoma cell line HT29 clone 19A

Dietary iron may contribute to colon cancer risk via production of reactive oxygen species (ROS). The aim of the study was to determine whether physiological ferric/ferrous iron induces oxidative DNA damage in human colon cells. Therefore, differentiated human colon tumour cells (HT29 clone 19A) were incubated with ferric-nitrilotriacetate (Fe-NTA) or with haemoglobin and DNA breaks and oxidised bases were determined by microgelelectrophoresis. The effects of Fe-NTA were measured with additional H(2)O(2) (75microM) and quercetin (25-100microM) treatment. Analytic detection of iron in cell cultures, treated with 250microM Fe-NTA for 15 min to 24h, showed that 48.02+/-5.14 to 68.31+/-2.11% were rapidly absorbed and then detectable in the cellular fraction. Fe-NTA (250-1000microM) induced DNA breaks and oxidised bases, which were enhanced by subsequent H(2)O(2) exposure. Simultaneous incubation of HT29 clone 19A cells with Fe-NTA and H(2)O(2) for 15 min, 37 degrees C did not change the effect of H(2)O(2) alone. The impact of Fe-NTA and H(2)O(2)-induced oxidative damage is reduced by the antioxidant quercetin (75-67% of H(2)O(2)-control). Haemoglobin was as effective as Fe-NTA in inducing DNA damage. From these results we can conclude that iron is taken up by human colon cells and participates in the induction of oxidative DNA damage. Thus, iron or its capacity to catalyse ROS-formation, is an important colon cancer risk factor. Inhibition of damage by quercetin reflects the potential of antioxidative compounds to influence this risk factor. Quantitative data on the genotoxic impact of ferrous iron (e.g. from red meat) relative to the concentrations of antioxidants (from plant foods) in the gut are now needed to determine the optimal balance of food intake that will reduce exposure to this type of colon cancer risk factor.     

H2O2致WB-F344细胞内活性氧的产生及机理

以双氢罗丹明123（DHR123）作为荧光探针,采用激光共聚焦扫描显微镜研究小剂量（800nmol/L)H2O2诱导大鼠肝卵细胞株WB－F344细胞内活性氧产生的动态变化过程及其机理。结果发现：（1）小剂量H2O2的一次作用可以引起胞内活性氧的产生;（2）胞内活性氧清除剂N－乙酰－L－半胱氨酸（NAC）处理2h时后,再加入小剂量H2O2,发现胞内活性氧的产生明显减少;（3）用广谱的蛋白激酶抑制剂2－氨基嘌呤（2－AP）、Ca^2 依赖性蛋白激酶（PKC）抑制剂Bisindolylmaleimide Ⅰ、酷氨酸蛋白激酶（TPK）抑制剂Tyrphostin25分别预处理15min后,H2O2诱导的胞内活性氧的产生现象均消失;（4）细胞在无外钙环境下,小剂量H2O2诱导的胞内活性氧的产生明显减少;（5）细胞在无外钙环境下用NAC预处理后,H2O2诱导的胞内活性氧的产生现象消失。结果表明,H2O2可以通过胞内信号转导系统诱使WB细胞胞内活性氧产生,这可能与小剂量H2O2调控细胞生物学功能（如增殖、转化）相关。     

Oxidative damage of DNA induced by the cytochrome C and hydrogen peroxide system

To elaborate the peroxidase activity of cytochrome c in the generation of free radicals from H2O2, the mechanism of DNA cleavage mediated by the cytochrome c/H2O2 system was investigated. When plasmid DNA was incubated with cytochrome c and H2O2, the cleavage of DNA was proportional to the cytochrome c and H2O2 concentrations.Radical scavengers, such as azide, mannitol, and ethanol, significantly inhibited the cytochrome c/H2O2 system-mediated DNA cleavage. These results indicated that free radicals might participate in the DNA cleavage by the cytochrome c and H2O2 system. Incubation of cytochrome c with H2O2 resulted in a time-dependent release of iron ions from the cytochrome c molecule. During the incubation of deoxyribose with cytochrome c and H2O2, the damage to deoxyribose increased in a time-dependent manner, suggesting that the released iron ions may participate in a Fenton-like reaction to produce dOH radicals that may cause the DNA cleavage. Evidence that the iron-specific chelator, desferoxamine (DFX), prevented the DNA cleavage induced by the cytochrome c/H2O2 system supports this mechanism. Thus we suggest that DNA cleavage is mediated via the generation of dOH by a combination of the peroxidase reaction of cytochrome c and the Fenton-like reaction of free iron ions released from oxidatively damaged cytochrome c in the cytochrome c/H2O2 system.     

In vivo formation of single-strand breaks in DNA by hydrogen peroxide is mediated by the Haber-Weiss reaction

Phenanthroline and bipyridine, strong chelators of iron, protect DNA from single-strand break formation by H2O2 in human fibroblasts. This fact strongly supports the concept that these DNA single-strand breaks are produced by hydroxyl radicals generated by a Fenton-like reaction between intracellular Fe2+ and H2O2: H2O2 + Fe2+----Fe3+ + OH- + OH: Corroborating this idea is the fact that thiourea, an effective OH radical scavenger, prevents the formation of DNA single-strand breaks by H2O2 in nuclei from human fibroblasts. The copper chelator diethyldithiocarbamate, a strong inhibitor of superoxide dismutase, greatly enhances the in vivo production of DNA single-strand breaks by H2O in fibroblasts. This supports the idea that Fe3+ is reduced to Fe2+ by superoxide ion: O divided by 2 + Fe3+----O2 + Fe2+; and therefore that the sum of this reaction and the Fenton reaction, namely the so-called Haber-Weiss reaction, H2O2 + O divided by 2----O2 + OH- + OH; represents the mode whereby OH radical is produced from H2O2 in the cell. EDTA completely protects DNA from single-strand break formation in nuclei. The chelator therefore removes iron from the chromatin, and although the Fe-EDTA complex formed is capable of reacting with H2O2, the OH radical generated under these conditions is not close enough to hit DNA. Therefore iron complexed to chromatin functions as catalyst for the Haber-Weiss reaction in vivo, similarly to the role played by Fe-chelates in vitro.     

Superoxide and the production of oxidative DNA damage.

The conventional model of oxidative DNA damage posits a role for superoxide (O2-) as a reductant for iron, which subsequently generates a hydroxyl radical by transferring the electron to H2O2. The hydroxyl radical then attacks DNA. Indeed, mutants of Escherichia coli that lack superoxide dismutase (SOD) were 10-fold more vulnerable to DNA oxidation by H2O2 than were wild-type cells. Even the pace of DNA damage by endogenous oxidants was great enough that the SOD mutants could not tolerate air if enzymes that repair oxidative DNA lesions were inactive. However, DNA oxidation proceeds in SOD-proficient cells without the involvement of O2-, as evidenced by the failure of SOD overproduction or anaerobiosis to suppress damage by H2O2. Furthermore, the mechanism by which excess O2- causes damage was called into question when the hypersensitivity of SOD mutants to DNA damage persisted for at least 20 min after O2- had been dispelled through the imposition of anaerobiosis. That behavior contradicted the standard model, which requires that O2- be present to rereduce cellular iron during the period of exposure to H2O2. Evidently, DNA oxidation is driven by a reductant other than O2-, which leaves the mechanism of damage promotion by O2- unsettled. One possibility is that, through its well-established ability to leach iron from iron-sulfur clusters, O2- increases the amount of free iron that is available to catalyze hydroxyl radical production. Experiments with iron transport mutants confirmed that increases in free-iron concentration have the effect of accelerating DNA oxidation. Thus, O2- may be genotoxic only in doses that exceed those found in SOD-proficient cells, and in those limited circumstances it may promote DNA damage by increasing the amount of DNA-bound iron.     

Mitochondrial DNA damage is sensitive to exogenous H(2)O(2) but independent of cellular ROS production in prostate cancer cells

Intrinsic oxidative stress through enhanced production of reactive oxygen species (ROS) in prostate and other cancers may contribute to cancer progression due to its stimulating effect on cancer growth. In this study, we investigate differential responses to exogenous oxidative stimuli between aggressive prostate cancer and normal cell lines and explore potential mechanisms through interactions between cytotoxicity, cellular ROS production and oxidative DNA damage. The circular, multi-copy mitochondrial DNA (mtDNA) is used as a sensitive surrogate to oxidative DNA damage. We demonstrate that exogenous H(2)O(2) induces preferential cytotoxicity in aggressive prostate cancer than normal cells; a cascade production of cellular ROS, composed mainly of superoxide (O(2)(-)), is shown to be a critical determinant of H(2)O(2)-induced selective toxicity in cancer cells. In contrast, mtDNA damage and copy number depletion, as measured by a novel two-phase strategy of the supercoiling-sensitive qPCR method, are very sensitive to exogenous H(2)O(2) exposure in both cancer and normal cell lines. Moreover, we demonstrate for the first time that the sensitive mtDNA damage response to exogenous H(2)O(2) is independent of secondary cellular ROS production triggered by several ROS modulators regardless of cell phenotypes. These new findings suggest different mechanisms underpinning cytotoxicity and DNA damage induced by oxidative stress and a susceptible phenotype to oxidative injury associated with aggressive prostate cancer cells in vitro.     

Nucleosomal histone protein protects DNA from iron-mediated damage.

Iron promotes DNA damage by catalyzing hydroxyl radical formation. We examined the effect of chromatin structure on DNA susceptibility to oxidant damage. Oxygen radicals generated by H2O2, ascorbate and iron-ADP (1:2 ratio of Fe2+:ADP) extensively and randomly fragmented protein-free DNA, with double-strand breaks demonstrable even at 1 microM iron. In contrast, polynucleosomes from chicken erythrocytes were converted to nucleosome-sized fragments by iron-ADP even up to 250 microM iron. Cleavage occurred only in bare areas where DNA is unassociated with histone. In confirmation, reassembly of nucleosomes from calf thymus DNA and chicken erythrocyte histone also yielded nucleosomes resistant to fragmentation. Protection of DNA by histone was dependent on nucleosome assembly and did not simply reflect presence of scavenging protein. In contrast to this specific cleavage of internucleosomal linker DNA by iron-ADP, iron-EDTA cleaved polynucleosomes indiscriminately at all sites. The hydroxyl radical scavenger thiourea completely inhibited the random cleavage of polynucleosomes by iron-EDTA but inhibited the nonrandom cleavage of polynucleosomes by iron-ADP less completely, suggesting the possibility that the lower affinity iron-ADP chelate may allow association of free iron with DNA. Thus, oxygen radicals generated by iron-ADP indiscriminately cleaved naked DNA but cleaved chromatin preferentially at internucleosomal bare linker sites, perhaps because of nonrandom iron binding by DNA. These findings suggest that the DNA-damaging effects of iron may be nonrandom, site-directed and modified by histone protein.     

Effect of lipophilic chelators on oxyradical-induced DNA strand breaks in human granulocytes: paradoxical effect of 1,10-phenanthroline.

Strand breaks can be produced in the DNA of intact granulocytes by a flux of oxyradicals (O2- and H2O2) generated by tetradecanoylphorbol acetate (TPA) or by a flux of H2O2 generated by glucose oxidase. The mechanism by which such breaks are induced is still uncertain. Lipophilic chelators such as dipyridyl and 1,10-phenanthroline (OP) strongly inhibit strand breaks induced by H2O2, presumably because of their ability to chelate intracellular iron. We now report that dipyridyl also partially inhibits strand breaks in TPA-stimulated granulocytes while a "copper-specific" lipophilic chelator, neocuproine, has no effect. As opposed to these effects, OP increases the number of strand breaks in TPA-stimulated granulocytes. Superoxide dismutase (SOD) (but not catalase) partially blocks this increase. Both the cell-impermeable chelator, EDTA, and neocuproine strongly block the increase also. In fact, in the presence of EDTA, OP behaves like dipyridyl and inhibits strand breaks. Preformed OP2-copper(II) complex causes DNA breaks in TPA-stimulated granulocytes. The paradoxical effect of OP may be explained by assuming that OP may form two different metal complexes, a DNA-damaging complex with copper or an inhibitory complex with iron. If copper(II) and O2- are present, the first complex may form and the net effect may be an increase in strand breaks. If the formation of this complex is prevented by SOD, EDTA, or neocuproine, then OP may complex iron and the net effect may be (like dipyridyl) an inhibition of strand breaks. The source of the copper responsible for the formation of OP2-copper complex is unknown.     

Purification and immunochemical studies of pyruvate dehydrogenase complex from rat heart, and cell-free synthesis of lipoamide dehydrogenase, a component of the complex

A mixture of NADPH and ferredoxin reductase is a convenient way of reducing adriamycin in vitro. Under aerobic conditions the adriamycin semiquinone reacts rapidly with O2 and superoxide radical is produced. Superoxide generated either by adriamycin:ferredoxin reductase or by hypoxanthine:xanthine oxidase can promote the formation of hydroxyl radicals in the presence of soluble iron chelates. Hydroxyl radicals produced by a hypoxanthine:xanthine oxidase system in the presence of an iron chelate cause extensive fragmentation in double-stranded DNA. Protection is offered by catalase, superoxide dismutase or desferrioxamine. Addition of double-stranded DNA to a mixture of adriamycin, ferredoxin reductase, NADPH and iron chelate inhibits formation of both superoxide and hydroxyl radicals. This is not due to direct inhibition of ferredoxin reductase and single-stranded DNA has a much weaker inhibitory effect. It is concluded that adriamycin intercalated into DNA cannot be reduced.     

Copper + zinc and manganese superoxide dismutases inhibit deoxyribose degradation by the superoxide-driven Fenton reaction at two different stages. Implications for the redox states of copper and manganese.

When OH. radicals are formed in a superoxide-driven Fenton reaction, in which O2.- is generated enzymically, deoxyribose degradation is effectively inhibited by CuZn- and Mn-superoxide dismutases. The products of this reaction are H2O2 and a Fe3+-EDTA chelate. The mixing of H2O2 and a Fe3+-EDTA chelate also generates OH. radicals able to degrade deoxyribose with the release of thiobarbituric acid-reactive material. This reaction too is inhibited by CuZn- and Mn-superoxide dismutases, suggesting that most of the OH. is formed by a non-enzymic O2.--dependent reduction of the Fe3+-EDTA chelate. Since the reaction between the Fe3+-EDTA chelate and H2O2 leads to a superoxide dismutase-inhibitable formation of OH. radicals, it could suggest a much wider protective role for the superoxide dismutase enzymes in biological systems. Urate produced during the reaction of xanthine oxidase and hypoxanthine limits deoxyribose degradation as well as the effectiveness of the superoxide dismutase enzymes to inhibit damage to deoxyribose by H2O2 and the Fe3+-EDTA chelate. Some of this damage may result from an O2.--independent pathway to OH. formation in which urate reduces the ferric complex.     

Protecting or promoting effects of spermine on DNA strand breakage induced by iron or copper ions as a function of metal concentration

Polyamines are ubiquitous polycations that participate in cellular processes such as growth, differentiation and cell death. Among the different functions ascribed to these organic cations, the polyamine spermine is known to protect DNA from the damage produced by reactive oxygen species (ROS) generated by different agents including copper ions. We have found that spermine exerts opposite effects on DNA strand breakage induced by Fenton reaction depending on metal concentration. Whereas at low concentration of the transition metals, 10 microM copper or 50 microM Fe(II), 1 mM spermine exerted a protective role, at metal concentrations higher than 25 microM copper or 100 microM Fe(II), spermine stimulated DNA strand breakage. The promotion of the damage induced by spermine was independent of DNA sequence but decreased by increasing the ionic concentration of the media or by the presence of metal-chelating agents. Moreover, spermine did not increase the oxidation of 2-deoxyribose by metal/H2O2 when DNA was substituted by 2-deoxyribose as a target for damage. Our results corroborate that spermine may protect DNA and 2-deoxyribose from the damage induced by ROS but also demonstrate that under certain conditions spermine may promote DNA strand breakage. The fact that this promoting effect of spermine on ROS-induced damage was observed only in the presence of DNA suggests that this polyamine under certain conditions may facilitate the interaction of copper and iron ions with DNA leading to the formation of ROS in close proximity to DNA.     

The role of metals in site-specific DNA damage with reference to carcinogenesis

We reviewed the mechanism of oxidative DNA damage with reference to metal carcinogenesis and metal-mediated chemical carcinogenesis. On the basis of the finding that chromium (VI) induced oxidative DNA damage in the presence of hydrogen peroxide (H2O2), we proposed the hypothesis that endogenous reactive oxygen species play a role in metal carcinogenesis. Since then, we have reported that various metal compounds, such as cobalt, nickel, and ferric nitrilotriacetate, directly cause site-specific DNA damage in the presence of H2O2. We also found that carcinogenic metals could cause DNA damage through indirect mechanisms. Certain nickel compounds induced oxidative DNA damage in rat lungs through inflammation. Endogenous metals, copper and iron, catalyzed ROS generation from various organic carcinogens, resulting in oxidative DNA damage. Polynuclear compounds, such as 4-aminobiphenyl and heterocyclic amines, appear to induce cancer mainly through DNA adduct formation, although their N-hydroxy and nitroso metabolites can also cause oxidative DNA damage. On the other hand, mononuclear compounds, such as benzene metabolites, caffeic acid, and o-toluidine, should express their carcionogenicity through oxidative DNA damage. Metabolites of certain carcinogens efficiently caused oxidative DNA damage by forming NADH-dependent redox cycles. These findings suggest that metal-mediated oxidative DNA damage plays important roles in chemical carcinogenesis.     

Mechanisms underlying the cytotoxic effects of Tachpyr--a novel metal chelator

Tachpyr (N,N'N"-tris(2-pyridylmethyl)-cis,cis-1,3,5-triaminocyclohexane), a novel metal chelator, was previously shown to deplete intracellular iron and exert a cytotoxic effect on cultured bladder cancer cells. Tachpyr binds Fe(II) and readily reduces Fe(III). The iron(II)-Tachpyr chelate undergoes intramolecular oxidative dehydrogenation resulting in mono- and diimino Fe(II) complexes. The present study investigates the redox-activity of the Tachpyr-iron complex to better define the mechanism of Tachpyr's cytotoxicity. Tachpyr's mechanism of cytotoxicity was studied using cell-free solutions, isolated DNA, and cultured mammalian cells by employing UV-VIS spectrophotometry, oximetry, spin-trapping technique, and electron paramagnetic resonance (EPR) spectrometry. The results show that: (1) Tachpyr by itself after 24 h of incubation had a cytotoxic effect on cultured cells; (2) fully oxidized Tachpyr had no cytotoxic effects on cultured cells even after 24 h of incubation; (3) Tachpyr protected isolated DNA against H(2)O(2)-induced damage, but not against HX/XO-induced damage; and (4) Tachpyr-Fe(II) chelate slows down but does not block oxidation of Fe(II), allows O*(-)(2)-induced or Tachpyr-induced reduction of Fe(III), and consequently promotes production of *OH through the Haber-Weiss reaction cycle. The results indicate that Tachpyr can protect cells against short-term, metal-mediated damage. However, upon prolonged incubation, Tachpyr exerts cytotoxic effects. Therefore, in addition to iron depletion, low-level oxidative stress, which in part occurs because of redox cycling of the coordinated iron ion, may contribute to the cytotoxic effects of Tachpyr.     

Effects of metal ion chelators on DNA strand breaks and inactivation produced by hydrogen peroxide in Escherichia coli: detection of iron-independent lesions.

In order to study the role of metallic ions in the H2O2 inactivation of Escherichia coli cells, H2O2-sensitive mutants were treated with metal ion chelators and then submitted to H2O2 treatment. o-Phenanthroline, dipyridyl, desferrioxamine, and neocuproine were used as metal chelators. Cell sensitivity to H2O2 treatment was not modified by neocuproine, suggesting that copper has a minor role in OH production in E. coli. On the other hand, prior treatment with iron chelators protected the cells against the H2O2 lethal effect, indicating that iron participates in the production of OH. However, analysis of DNA sedimentation profiles and DNA degradation studies indicated that these chelators did not completely block the formation of DNA single-strand breaks by H2O2 treatment. Thiourea, a scavenger of OH, caused a reduction in both H2O2 sensitivity and DNA single-strand break production. The breaks observed after treatment with metal chelators and H2O2 were repaired 60 min after H2O2 elimination in xthA but not polA mutant cells. Therefore, we propose that there are at least two pathways for H2O2-induced DNA lesions: one produced by H2O2 through iron oxidation and OH production, in which lesions are repaired by the products of the xthA and polA genes, and the other produced by an iron-independent pathway in which DNA repair requires polA gene products but not those of the xthA gene.     

Complex-formation and reduction of ferric iron by 2-oxo-4-thiomethylbutyric acid, and the production of hydroxyl radicals.

2-Oxo-4-thiomethylbutyric acid (OMBA) is a widely used oxygen-radical-scavenging agent and has been used for the detection of .OH-like species in a variety of systems. This scavenger reacts with other radicals and is therefore not specific for .OH. Since iron is required in most systems for the generation of OH-like species, studies were carried out to investigate the possible interaction of OMBA with iron. Fe3+ reacted with OMBA to produce complexes that gave rise to discrete spectra. Intense purple complexes, with broad absorbance maxima of 525-550 nm, were found at OMBA/Fe3+ ratios of up to 1:1, whereas red complexes with a prominent shoulder between 440 and 480 nm were found at higher OMBA/Fe3+ ratios. OMBA caused reduction of ferric iron to the ferrous state, as detected with 2,2'-bipyridyl as the indicator. This reduction occurs in the dark, can be photo-accelerated especially by light with wavelengths near the absorbance maximum of the respective complexes, and is increased as the OMBA/Fe3+ ratio is elevated. The presence of phosphate buffer quenches the purple and red ferric-ion-OMBA complexes and lowers the rate of reduction of Fe3+ by OMBA about 10-fold. The resulting ferrous-ion-OMBA-phosphate complex is very stable against autoxidation. Both the ferrous-ion-OMBA and ferric-ion-OMBA complexes reacted with H2O2, with the subsequent production of ethylene gas from OMBA. The interaction with H2O2 resulted in discrete spectral changes of both the ferrous-ion-OMBA and ferric-ion-OMBA complexes. The ferrous-ion-OMBA/H2O2 or ferric-ion-OMBA/H2O2 system appeared to produce .OH free radicals via a Fenton-type of reaction since ethylene production was inhibited by competitive OH scavengers. Ferrous-ion-OMBA complex reacted with H2O2 not only to produce ethylene from the OMBA, but also to promote the oxidation of another scavenger, ethanol. The ability of OMBA to chelate iron, to promote reduction of ferric iron and to react with H2O2 to produce potent oxidizing radicals may play a role in the lack of specificity of OMBA as a scavenger of oxygen radicals.     

Pyruvate secreted by human lymphoid cell lines protects cells from hydrogen peroxide mediated cell death

Reactive oxygen species (ROS) released from polymorphonuclear leukocytes and macrophages could cause DNA damage, but also induce cell death. Therefore inhibition of cell death must be an important issue for accumulation of genetic changes in lymphoid cells in inflammatory foci. Scavengers in the post culture medium of four lymphoid cell lines, lymphoblastoid cell lines (LCL), Raji, BJAB and Jurkat cells, were examined. Over 80% of cultured cells showed cell death 24 h after xanthine (X)/xanthine oxidase (XOD) treatment, which was suppressed by addition of post culture medium from four cell lines in a dose-dependent manner. H2O2 but not O2*- produced by the X/XOD reaction was responsible for the cytotoxity, thus we used H2O2 as ROS stress thereafter. The H2O2-scavenging activity of post culture media from four cell lines increased rapidly at the first day and continued to increase in the following 2-3 days for LCL, Raji and BJAB cells. The scavenging substance was shown to be pyruvate, with various concentrations in the cultured medium among cell lines. Over 99% of total pyruvate was present in the extracellular media and less than 1% in cells. alpha-Cyano-4-hydroxycinnamate, a specific inhibitor of the H+-monocarbohydrate transporter, increased the H2O2-scavenging activity in the media from all four cell lines via inhibition of pyruvate re-uptake by cultured cells from the media. These findings suggest that lymphoid cells in inflammatory foci could survive even under ROS by producing pyruvate, so that accumulation of lymphoid cells with DNA damage is possible.