Endogenous Oxidative Damage Research Articles

Tamoxifen reduces endogenous and UV light-induced oxidative damage to DNA, lipid and protein in vitro and in vivo.

We have investigated the effect of tamoxifen (TAM) on endogenous or ultraviolet radiation (UVR)-induced oxidative damage to macromolecules in vitro and in vivo. In a system containing calf thymus DNA exposed to a germicidal UV lamp, both TAM and 4-hydroxytamoxifen (4-OH-TAM) inhibited UVR-induced the formation of 8-hydroxy-2'-deoxyguanosine (8-OHdG) in DNA in a dose-dependent manner. At low concentrations, 4-OH-TAM quenched 8-OHdG more potently than TAM. However, the reduction of 8-OHdG by TAM and 4-OH-TAM became similar at a concentration of 10 microM. In contrast, ascorbic acid had the similar effect to TAM, whereas glutathione exhibited little effect on UVR-induced 8-OHdG. The order of quenching efficacy was: 4-OH-TAM > TAM approximately = ascorbic acid > glutathione. We have further determined the effect of TAM on endogenous 8-OHdG formation, lipid peroxidation, and protein oxidation in the skin of SENCAR mice. Topical application of 5 micromol TAM significantly reduced the level of 8-OHdG in mouse epidermis by approximately 27% (P < 0.05). Endogenous lipid peroxidation and protein oxidation, measured as malondialdehyde (MDA) and carbonyl groups, were also substantially reduced by topical TAM. Further study was conducted to evaluate the effect of TAM on UVR-induced 8-OHdG and MDA in skin of hairless mice. In mice subacutely exposed to low dose (3.4 kJ/m2 x six doses) and high dose (16.8 kJ/m2 x three doses) of UVB irradiation, TAM significantly blocked the formation of 8-OHdG in mouse epidermis by 57-81% and MDA by 37-65%, respectively. Our studies suggest that reduction of oxidative damages to biological macromolecules in vitro and in vivo may at least in part explain the anti-carcinogenic and chemopreventive actions of tamoxifen.

Comparison of Oxidative Base Damage in Mitochondrial and Nuclear DNA

The levels of endogenous pig liver cells mitochondrial DNA oxidative base damage have been investigated using isotope dilution gas chromatography mass spectrometry (GC/MS). Higher levels of five measured bases were found in mtDNA in relation to nuclear DNA. We have also detected large differences in the modified base ratios of mitochondrial versus nuclear DNA. These ratios for the bases with promutagenic properties as 8OHGua and 5OHCyt are much lower then for other bases (5OHHyd, 5OHMeHyd, 5OHMeUra).

Mapping frequencies of endogenous oxidative damage and the kinetic response to oxidative stress in a region of rat mtDNA.

Genomic DNA is constantly being damaged and repaired and our genomes exist at lesion equilibrium for damage created by endogenous mutagens. Mitochondrial DNA (mtDNA) has the highest lesion equilibrium frequency recorded; presumably due to damage by H2O2 and free radicals generated during oxidative phosphorylation processes. We measured the frequencies of single strand breaks and oxidative base damage in mtDNA by ligation-mediated PCR and a quantitative Southern blot technique coupled with digestion by the enzymes endonuclease III and formamidopyrimidine DNA glycosylase. Addition of 5 mM alloxan to cultured rat cells increased the rate of oxidative base damage and, by several fold, the lesion frequency in mtDNA. After removal of this DNA damaging agent from culture, the single strand breaks and oxidative base damage frequency decreased to levels slightly below normal at 4 h and returned to normal levels at 8 h, the overshoot at 4 h being attributed to an adaptive up-regulation of mitochondrial excision repair activity. Guanine positions showed the highest endogenous lesion frequencies and were the most responsive positions to alloxan-induced oxidative stress. Although specific bases were consistently hot spots for damage, there was no evidence that removal of these lesions occurred in a strand-specific manner. The data reveal non-random oxidative damage to several nucleotides in mtDNA and an apparent adaptive, non-strand selective response for removal of such damage. These are the first studies to characterize oxidative damage and its subsequent removal at the nucleotide level in mtDNA.

Transcriptional regulation of the Escherichia coli oxyR gene as a function of cell growth.

The oxyR regulon plays a central role in the defense of Escherichia coli against the endogenous oxidative damage associated with active aerobic growth. Here we have studied the transcriptional regulation of oxyR in E. coli growing aerobically in rich medium. Expression of a single-copy oxyR'::lacZ reporter construct varied sixfold along the growth curve, with the highest value at 4 to 6 h of growth (approximately 14 x 10(8) cells x ml(-1)). Direct measurements of oxyR mRNA by primer extension showed the same biphasic expression but with a peak somewhat earlier in cell growth (2 to 3 h; approximately 3.5 x 10(8) cells x ml(-1)). The results of immunoblotting experiments demonstrated that the level of OxyR protein exhibits the same biphasic expression. Mutant strains lacking adenylate cyclase (cya) or Crp protein (crp) failed to increase oxyR expression during exponential growth. On the other hand, an rpoS mutation allowed oxyR expression to continue increasing as the cells entered stationary phase. Consistent with a biological role for increased levels of OxyR during exponential growth, the crp cya strain had lower activities of catalase hydroperoxidase I and glutathione reductase and an increased sensitivity to exogenously added hydrogen peroxide. These results suggest that the Crp-dependent upregulation of oxyR in exponential phase is a component of a multistep strategy to counteract endogenous oxidative stress in actively growing E. coli cells.

Inactivation of OGG1 increases the incidence of G · C→T · A transversions in Saccharomyces cerevisiae : evidence for endogenous oxidative damage to DNA in eukaryotic cells

The OGG1 gene of Saccharomyces cerevisiae encodes a DNA glycosylase that excises 7,8-dihydro-8-oxoguanine (8-OxoG) and 2,6-diamino-4-hydroxy-5-N-methylformamidopyrimidine. To investigate the biological role of the OGG1 gene, mutants were constructed by partial deletion of the coding sequence and insertion of marker genes, yielding ogg1::TRP1 and ogg1::URA3 mutant strains. The disruption of the OGG1 gene does not compromise the viability of haploid cells, therefore it is not an essential gene. The capacity to repair 8-OxoG has been measured in cell-free extracts of wild-type and ogg1 strains using a 34mer DNA fragment containing a single 8-OxoG residue paired with a cytosine (8-OxoG/C) as a substrate. Cell-free extracts of the wild-type strain efficiently cleave the 8-OxoG-containing strand of the 8-OxoG/C duplex. In contrast, cell-free extracts of the Ogg1-deficient strain have no detectable activity that can cleave the 8-OxoG/C duplex. The biological properties of the ogg1 mutant have also been investigated. The results show that the ogg1 disruptant is not hypersensitive to DNA-damaging agents such as ultraviolet light at 254 nm, hydrogen peroxide or methyl methanesulfonate. However, the ogg1 mutant exhibits a mutator phenotype. When compared to those of a wild-type strain, the frequencies of mutation to canavanine resistance (CanR) and reversion to Lys+ are sevenfold and tenfold higher for the ogg1 mutant strain, respectively. Moreover, using a specific tester system, we show that the Ogg1-deficient strain displays a 50-fold increase in spontaneously occurring G x C-->T x A transversions compared to the wild-type strain. The five other base substitution events are not affected by the disruption of the OGG1 gene. These results strongly suggest that endogeneous reactive oxygen species cause DNA damage and that the excision of 8-OxoG catalyzed by the Ogg1 protein contributes to the maintenance of genetic stability in S. cerevisiae.

Oxidative damage to DNA: do we have a reliable biomarker?

Oxidized bases in DNA can be measured directly by high-performance liquid chromatography (HPLC). 7,8-Dihydro-8-oxo-guanine (8-OHgua), as the most abundant oxidation product, is often regarded as an indicator of oxidative stress. Estimates of endogenous 8-OHgua levels in human lymphocyte DNA are between 2 and 8 for every 10(5) unaltered bases--a high frequency in view of the potential mutagenicity of this base alteration and of the presence of an effective base excision repair pathway in eukaryotic cells. An alternative approach to the measurement of oxidized bases makes use of repair endonucleases with appropriate lesion specificities--endonuclease III, for oxidized pyrimidines and formamidopyrimidine glycosylase for 8-OHgua. These enzymes introduce breaks at sites of damage in DNA. The comet assay (single cell gel electrophoresis) can then be used to detect the DNA breaks. This modified comet assay, like other enzyme-linked DNA breakage assays, gives a value for endogenous oxidative base damage that is more than 10-fold lower than most estimated from HPLC. It is possible that HPLC-based estimates are artificially high because oxidation of guanine occurs during isolation, storage, or hydrolysis of DNA. Using a revised DNA isolation procedure designed to decrease in vitro oxidation, we have obtained results for 8-OHgua concentrations in human lymphocytes that are closure to the figures obtained by the comet assay. It is still an open question whether 8-OHgua, measured by HPLC or by the comet assay, is a valid marker for oxidative damage.

The causes and prevention of cancer.

Epidemiological evidence indicates that avoidance of smoking, increased consumption of fruits and vegetables, and control of infections will have a major effect on reducing rates of cancer. Other factors include avoidance of intense sun exposure, increases in physical activity, and reduction of alcohol consumption and possibly red meat. A substantial reduction in breast cancer is likely to require modification of sex hormone levels, and development of practical methods for doing so is a high research priority. Resolution of the potential protective roles of specific antioxidants and other constituents of fruits and vegetables deserves major attention. Mechanistic studies of carcinogenesis indicate an important role of endogenous oxidative damage to DNA that is balanced by elaborate defense and repair processes. Also key is the rate of cell division, which is influenced by hormones, growth, cytotoxicity, and inflammation, as this determines the probability of converting DNA lesions to mutations. These mechanisms may underlie many epidemiologic observations.

Oxidative modification of DNA bases in rat liver and lung during chemical carcinogenesis and aging

The extent of DNA modification in cancerous rat liver and lung tissues was investigated and compared to their respective normal tissues. Liver tumors were induced by 2-fluorenyl-acetamide (2-FAA) or N-nitroso- N-2-fluorenylacetamide (N-NO-2-FAA), and lung tumors were induced by sodium nitrite plus trimethylamine. In the DNA samples isolated from these tissues, two pyrimidine-derived and four purine-derived modified DNA bases were identified and quantified by gas chromatography/mass spectrometry with selected-ion monitoring. These compounds were characterized as 5-hydroxyuracil (5-OHUra), thymine glycol (TG), 4,6-diamino-5-formamidopyrimidine (FapyAde), 2,6-diamino-4-hydroxy-5-formamidopyrimidine (FapyGua), 8-hydroxyadenine (8-OHAde), and 8-hydroxyguanine (8-OHGua). Elevated amounts of modified DNA bases were found in most cancerous tissues when compared to the controls. Chemicals used for tumor induction were responsible for inducing DNA lesions that could be promutagenic in vivo and could lead to various types of mutations. When endogenous oxidative damage to DNA during aging was examined, a roughly 2-fold increase of thymine glycol, 8-OHAde and 8-OHGua was found in aged (12 months) rat liver tissues compared to young tissues (1 month). The same results were also found in lung tissues, except that the amount of thymine glycol exhibited more than a 10-fold increase in aged tissues when compared to young tissues. The association of the modified bases with the processes of aging and carcinogenesis deserves further investigation.

Dietary vitamin C decreases endogenous protein oxidative damage, malondialdehyde, and lipid peroxidation and maintains fatty acid unsaturation in the guinea pig liver

Guinea pigs were fed during 5 weeks with three different levels of vitamin C in the diet: 33 (marginal deficiency), 660, or 13,200 mg of vitamin C per kg of diet. The group fed 660 mg of vitamin C/kg of diet showed strongly reduced levels of protein carbonyls (46% decrease), malondialdehyde (HPLC; 72% decrease), and in vitro production of TBARS (both stimulated with ascorbate-Fe 2+ and with NADPH-ADP-Fe 2+; 68% and 71% decrease), increased glutathione reductase activity, and increased vitamin C content (48 times higher) in the liver in relation to the group fed 33 mg/kg. The treatment with 660 mg of vitamin C/kg did not decrease any of the antioxidant defences studied: superoxide dismutase, catalase, glutathione peroxidase, glutathione reductase, GSH, vitamin E, or uric acid. Further supplementation with 13,200 mg vitamin C/kg also reduced protein and lipid peroxidation, but decreased hepatic glutathione reductase and uric acid and resulted in a lower body weight of the animals. Both low (33 mg/kg) and very high (13,200 mg/kg) levels of vitamin C decreased body weight, glutathione reductase, and unsaturation of fatty acids in membrane lipids. The results show that a diet supplying an amount of vitamin C 40 times higher than the minimum daily requirement to avoid scurvy increases the global antioxidant capacity and is of protective value against endogenous lipid and protein oxidation in the liver under normal nonstressful conditions.

Effect of diet and vitamin C on DNA strand breakage in freshly-isolated human white blood cells.

We have measured DNA strand breaks induced by ionising radiation in nucleated cells from freshly isolated whole blood from normal human subjects. Samples were taken after subjects had fasted overnight and again 1 h after they had eaten breakfast in combination with approximately 35 mg/kg vitamin C. Damage was measured by single cell gel electrophoresis (the 'comet' assay), in which DNA single strand breaks generate a comet tail streaming from the nucleus. In repeat experiments on 6 subjects a reduction in DNA damage, as indicated by a highly significant decrease in overall comet length, was observed following vitamin C ingestion, both in the unirradiated control blood samples and in the dose response to ionising radiation damage. In addition, consistent differences in dose response between individual subjects were found. The peak effect was 4 h after intake of food and vitamin C. An effect was also seen with vitamin C alone and after breakfast without additional vitamin C. Protection against strand breakage was also seen in Ficoll-separated mononuclear cells but evidence was not obtained for protection of separated, mitogen stimulated T-lymphocytes either against ionising radiation cell killing in a clonal assay, or against clastogenicity assessed by micronucleus formation following one cell division. Exposure of separated lymphocytes in vitro to vitamin C, at doses greater than 200 microM, did not offer protection but induced strand breakage. Our results raise the possibility that variation in normal diet may not only affect susceptibility to endogenous oxidative damage, but may affect some responses of the individual to radiation.

Effect of dietary vitamin C and catalase inhibition of antioxidants and molecular markers of oxidative damage in guinea pigs.

Guinea pigs were fed for five weeks with two diets with different levels of vitamin C, low (33 mg of Vit C/Kg diet) and high (13,200 mg of Vit C/Kg of diet). Catalase was inhibited with 3-amino-1,2,4-triazole (AT) in half of the animals from each dietary group. AT caused an almost complete depletion of liver catalase activity (90%) in both dietary groups. Vitamin C supplementation increased total glutathione peroxidase activity and tissue vitamin C level and decreased levels of protein carbonyls and malondialdehyde (MDA) in both treated and non-treated animals. This vitamin C supplementation did not change any of the other antioxidant defences studied. Our results show that dietary vitamin C supplementation increases global antioxidant capacity and decreases endogenous oxidative damage in the guinea pig liver under normal non-stressful conditions. This supports the protective value of dietary antioxidant supplementation.

DNA excision-repair defect of xeroderma pigmentosum prevents removal of a class of oxygen free radical-induced base lesions.

Plasmid DNA was gamma-irradiated or treated with H2O2 in the presence of Cu2+ to generate oxygen free radical-induced lesions. Open circular DNA molecules were removed by ethidium bromide/CsCl density gradient centrifugation. The closed circular DNA fraction was treated with the Escherichia coli reagent enzymes endonuclease III (Nth protein) and Fpg protein. This treatment converted DNA molecules containing the major base lesions pyrimidine hydrates and 8-hydroxyguanine to a nicked form. Remaining closed circular DNA containing other oxygen radical-induced base lesions was used as a substrate for nucleotide excision-repair in a cell-free system. Extracts from normal human cells, but not extracts from xeroderma pigmentosum cells, catalyzed repair synthesis in this DNA. The repair defect in the latter extracts could be specifically corrected by in vitro complementation. The data suggest that accumulation of endogenous oxidative damage in cellular DNA from xeroderma pigmentosum patients contributes to the increased frequency of internal cancers and the neural degeneration occurring in serious cases of the syndrome.

Direct enzymic detection of endogenous oxidative base damage in human lymphocyte DNA.

The endogenous production of oxidative damage in DNA by free radicals released as a by-product of respiration is a likely cause of mutations which, if they occur in appropriate genes, may lead to cancer. Using an endonuclease specific for oxidized pyrimidines, in conjunction with the highly sensitive method of single cell gel electrophoresis, we have detected significant oxidative damage in untreated, freshly isolated lymphocytes from normal, healthy individuals.

Endogenous oxidative damage of deoxycytidine in DNA.

Three major oxidation products of 2'-deoxycytidine (dC)--5-hydroxy-2'-deoxycytidine (oh5dC), 5-hydroxy-2'-deoxyuridine (oh5dU), and 5,6-dihydroxy-5,6-dihydro-2'-deoxyuridine (dUg)--were analyzed from enzymatically hydrolyzed DNA with reversed-phase high-performance liquid chromatography coupled to electrochemical detection. oh5dC and oh5dU can be detected with high sensitivity (50 fmol) and selectivity (0-0.2 V) from hydrolyzed DNA. dUg is not electrochemically active but can be measured by dehydrating it into oh5dU. The quantities of oh5dC, dUg, and oh5dU in untreated commercial-grade calf thymus DNA are 10, 10, and 0.75 fmol/micrograms of DNA, respectively. These levels increased substantially when calf thymus DNA was exposed to ionizing radiation, H2O2 alone, H2O2 and combinations of Fe3+ or Cu2+ and ascorbate, near-UV light (365 nm), near-UV light in the presence of menadione, and OsO4, indicating that oh5dC, oh5dU, and dUg are major oxidative DNA damage products. The steady-state levels of these products were determined from freshly extracted rat tissues and ranged from less than 0.5 fmol/micrograms of DNA for oh5dU to about 10 fmol/micrograms of DNA for oh5dC and dUg in liver and kidney and 22 fmol/micrograms of DNA for oh5dC in brain. The levels of oxo8dG were also determined and in general were somewhat lower than the levels of oh5dC. These findings reinforce the link between DNA damage induced by oxidative metabolism and spontaneous mutagenesis leading to cancer and aging.

Improved Erythrocyte Survival with High-Dose Vitamin E in Chronic Hemolyzing G6PD and Glutathione Synthetase Deficiencies

Brief Reports1 January 1979Improved Erythrocyte Survival with High-Dose Vitamin E in Chronic Hemolyzing G6PD and Glutathione Synthetase DeficienciesS. P. SPIELBERG, M.D., Ph.D., L. A. BOXER, M.D., L. M. CORASH, M.D., J. D. SCHULMAN, M.D.S. P. SPIELBERG, M.D., Ph.D.Search for more papers by this author, L. A. BOXER, M.D.Search for more papers by this author, L. M. CORASH, M.D.Search for more papers by this author, J. D. SCHULMAN, M.D.Search for more papers by this authorAuthor, Article, and Disclosure Informationhttps://doi.org/10.7326/0003-4819-90-1-53 SectionsAboutPDF ToolsAdd to favoritesDownload CitationsTrack CitationsPermissions ShareFacebookTwitterLinkedInRedditEmail ExcerptGlutathione (GSH) and vitamin E both play vital roles in the protection of cells from oxidative stress (1). Decreased reduced erythrocyte GSH resulting from inborn errors of metabolism is associated with hemolytic anemia (2). Hemolysis may be caused by endogenous or drug-induced oxidative damage to erythrocytes. Pharmacologic levels of vitamin E partially protect cells experimentally rendered GSH deficient in tissue culture and in vivo (3, 4). Therefore, we have examined the effects of chronic administration of high doses of vitamin E on erythrocyte survival in two patients with inherited disorders of GSH metabolism. Both patients have chronic hemolytic anemia, one...