Methylene blue plus light mediates 8-hydroxy 2''-deoxyguanosine formation in DNA preferentially over strand breakage.

Methylene blue (MB) plus light, in the presence of oxygen, mediates formation of 8-hydroxyguanine in DNA. The yield of 8-hydroxyguanine may be as much as from 2 to 4% of the guanines present. The results presented here show that treatment of supercoiled plasmid DNA with methylene blue plus light causes single-stranded nicks. However, single-stranded nicking occurs approximately 17-fold less frequently than does formation of 8-hydroxyguanine. The nicking rate is reduced in the presence of Mg ion but is not prevented by inhibitors of the iron-catalyzed Fenton reaction or by scavengers of hydroxyl free radicals. Extensive exposure of DNA to light in the presence of MB produces no detectable thiobarbital reactive material thus implicating that single strand nicking does not occur by hydroxyl free radical attack on deoxyribose. Formation of 8-hydroxyguanine is apparently not dependent upon intercalative binding of MB to DNA, since it is formed in polydeoxyguanylic acid.     

Hydroxyl free radical mediated formation of 8-hydroxyguanine in isolated DNA

Formation of 8-hydroxyguanine within calf thymus DNA has been studied after exposure to uv-H2O2 as a hydroxyl free radical generating system. Using high-pressure liquid chromatography with electrochemical detection, we measured the amount of 8-hydroxy-2-deoxyguanosine (8-OHdG) in the enzymatically digested DNA. The 8-OHdG content of uv-exposed DNA increased linearly with increasing H2O2 levels up to 0.03%, above which the rate of increase was less than linear. All hydroxyl free radical scavengers studied (mannitol, ethanol, thiourea, and salicylate), if present in the system when DNA was exposed to uv-H2O2, caused a decrease in the amount of 8-OHdG formed. Thiourea when incubated with damaged DNA caused a loss of 8-OHdG when it was an integral part of DNA. In contrast, thiourea did not react with the nucleoside free in solution. Reduced glutathione did not cause a decrease of 8-OHdG, either when it was an integral part of DNA, or, as the free nucleoside in solution.     

Mediation of 8-hydroxy-guanine formation in DNA by thiazin dyes plus light

We have discovered that methylene blue plus light mediates the formation of 8-OHdG in DNA. Methylene blue is one of several thiazin dyes and we report here that the other thiazin dyes tested, in combination with white light, are effective in mediating 8-OHdG formation in DNA. The effectiveness of light plus the thiazin dyes in forming 8-OHdG in DNA were as follows: methylene blue greater than azure B greater than azure A greater than toluidine blue greater than thionin. Two other compounds tested; riboflavin and fuschin acid, in combination with light, caused formation of very little, if any, 8-OHdG in DNA. Thiazin dye mediated formation of 8-OHdG in DNA was not inhibited by the spin trap alpha-phenyl-t-butyl nitrone, which supports our previous observations that oxygen free radical scavengers did not inhibit methylene blue plus light mediated 8-OHdG formation in DNA. Ascorbate addition to methylene blue plus DNA, in the absence of light, was ineffective in mediating 8-OHdG formation in DNA.     

Photosensitized formation of 8-hydroxyguanine (7,8-dihydro-8-oxoguanine) in DNA by riboflavin.

Potosensitized formation of 8-hydroxyguanine in DNA by riboflavin was observed. A reaction mechanism involving guanine radical cation and hydration reaction was proposed. This hypothesis was confirmed by the incorporation of [18O]-atom within guanine moiety in isotopic experiments using [18O]-H2O. Photosensitized formation of oh8Gua by riboflavin was also observed in cellular DNA.     

DNA strand break and 8-hydroxyguanine formation induced by 2-hydroxyestradiol dispersed in liposomes

DNA damage induced by estrogens dispersed in liposomes was investigated. 2-Hydroxyestradiol (2HOE(2)) and 4-hydroxyestradiol (4HOE(2)), but not estrone, estradiol-17beta or estriol, caused strand break of plasmid DNA damage in the presence of ADP-Fe(3+). The catechol structure may be necessary for DNA damage. When DNA was incubated with 2HOE(2) for a long time (24 h), DNA damage was induced even at very low concentrations. Adding hydrogen peroxide markedly enhanced the sensitivity of DNA to the attack by 2HOE(2). Hydroxyl radical (HO.) scavengers strongly inhibited the 2HOE(2)-induced DNA damage, and EDTA partially inhibited DNA damage. However, 2HOE(2) caused 8-hydroxyguanine formation from calf thymus DNA only in the presence of EDTA-Fe(3+), but not ADP-Fe(3+). In addition, deoxyribose, which is a detective molecule of HO(.), was not degraded by 2HOE(2) in the presence of ADP-Fe(3+). Upon adding EDTA 2HOE(2) rapidly degraded deoxyribose. These results suggest that DNA strand break caused by 2HOE(2) in the presence of ADP-Fe(3+) was due to ferryl ion rather than HO(.), whereas 8-hydroxyguanine (8HOG) induced by 2HOE(2) in the presence of EDTA-Fe(3+) was due to HO(.).     

细胞氧化损伤时8-羟基鸟嘌呤的测定

利用H₂O₂易通过细胞膜而到达核这一特点,初步探讨了不同浓度H₂O₂对HL-60细胞DNA的氧化损伤程度.发现H₂O₂浓度在0.4 mmol/L以上时,作用8～24 h可以用气相色谱/火焰离子检测器(GC/FID)检测到氧化损伤标志产物——8-羟基鸟嘌呤(8-oh-G),并观测到在0.4～0.8 mmol/L H₂O₂作用一定时间时,8-羟基鸟嘌呤含量随H₂O₂浓度升高而升高.     

Reduction of 8-hydroxyguanine in human leukocyte DNA by physical exercise

We investigated the effect of physical exercise on the level of 8-hydroxyguanine (8-OH-Gua), a form of oxidative DNA damage, and its repair activity in human peripheral leukocytes. Whole blood samples were collected by venipuncture from 21 healthy male volunteers (10 trained athletes and 13 untrained men), aged 19-50 years, both before and after physical exercise. Trained athletes showed a lower level of 8-OH-Gua (2.4 ± 0.5/10⁶ Gua, p = 0.0032) before exercise when compared to that of untrained men (6.2 ± 3.5). The mean levels of 8-OH-Gua of untrained subjects decreased significantly (p = 0.0057) from 6.2 ± 3.5/10⁶ Gua (mean ± SD/10⁶ Gua) to 3.3 ± 1.4/10⁶ Gua after physical exercise. On the other hand, the mean levels of repair activity of untrained subjects significantly increased after exercise (p = 0.0093) from 0.037 ± 0.024 (mean DNA cleavage ratio ± SD) to 0.056 ± 0.036. In the trained athletes 8-OH-Gua level and its repair activity were not changed before and after the exercise. We also observed inter-individual differences in 8-OH-Gua levels and its repair activities. These results suggest that physical exercise causes both rapid and long-range reduction of oxidative DNA damage in human leukocytes, with individually different efficiencies.     

Increased 8-hydroxyguanine content of chloroplast DNA from ozone-treated plants

The mechanism of ozone-mediated plant injury is not known but has been postulated to involve oxygen free radicals. Hydroxyl free radicals react with DNA causing formation of many products, one of which is 8-hydroxyguanine. By using high performance liquid chromatography with electrochemical detection, the 8-hydroxy-2′-deoxyguanosine (8-OHdG) content of a DNA enzymatic digest can be sensitively quantitated. Beans (Phaseolus vulgaris L.) and peas (Pisum sativum L.) were treated with an ozone regime that caused acute injury. Chloroplast DNA was obtained from plants harvested either immediately after ozone treatment or 24 hours later. Ozone-exposed plants in general had nearly two-fold higher levels of 8-OHdG as compared to control plants. In vitro treatment of DNA in buffer solution with ozone did not cause formation of 8-OHdG in DNA, even though ozone did react directly with the macromolecule per se. Exposure of isolated, illuminated chloroplasts to ozone caused nearly a seven-fold increase in the amount of 8-OHdG in the chloroplast DNA as compared to none-ozone-exposed chloroplasts. These results suggest that ozone exposure to plants causes formation of enhanced levels of oxygen free radicals, thus mediating formation of 8-OHdG in chloroplast DNA. The reaction of ozone with DNA per se did not cause formation of 8-OHdG. Therefore, it is the interaction of ozone with plant cells and isolated chloroplasts which mediates oxygen free radical formation.     

Methylene blue directly oxidizes glutathione without the intermediate formation of hydrogen peroxide

Methylene blue stimulates the oxidation of glutathione in red blood cells in vitro and in vivo. This oxidation has been attributed to hydrogen peroxide that is generated from the autooxidation of leucomethylene blue arising from the reduction of methylene blue by NADPH. In this report we present evidence that methylene blue directly oxidizes glutathione and that oxidation of glutathione by hydrogen peroxide is a secondary reaction. Moreover, superoxide dismutase has no effect on the oxidation. Under aerobic conditions, methylene blue oxidizes glutathione 30 times faster than the spontaneous autooxidation of glutathione. Under anaerobic conditions the stoichiometry of the reaction of methylene blue with glutathione supports a direct chemical reaction. The reaction rates between glutathione and methylene blue suggest a second order reaction over the conditions tested. That neither oxygen radical formation nor significant amounts of hydrogen peroxide are produced by methylene blue, even in the presence of added glucose, is further confirmed by the failure to detect significant amounts of lipid peroxidation products, or hemolysis, in red blood cells incubated with the dye.     

Quirks of dye nomenclature. 8. Methylene blue,azure and violet

Methylene blue was synthesized in 1877 and soon found application in medicine, staining for microscopy and as an industrial dye and pigment. An enormous literature has accumulated since its introduction. Early on, it was known that methylene blue could be degraded easily by demethylation; consequently, the purity of commercial samples often was low. Therefore, demethylation products, such as azures and methylene violet, also are considered here. The names and identity of the components, their varying modes of manufacture, analytical methods and their contribution to biological staining are discussed.     

An endonuclease activity in human polymorphonuclear neutrophils that removes 8-hydroxyguanine residues from DNA+

An endonuclease that specifically removes 8-hydroxyguanine (oh8Gua) from DNA has been isolated from Escherichia coli. As the amount of oh8Gua produced in DNA of X-ray-irradiated mice is known to decrease with time after irradiation, an attempt was made to find a similar activity in human polymorphonuclear neutrophils (PMNs) using a synthetic dsDNA containing oh8Gua as a substrate. The PMN enzyme was isolated free of other DNases, and found to cleave the substrate DNA simultaneously at 2 sites, the phosphodiester bonds 5' and 3' to oh8Gua, producing free hydroxyl and phosphate groups, respectively. The enzyme showed almost no activity on DNAs containing other kinds of modified base tested or mismatched DNA. Thus human cells also contain an endonuclease that specifically removes oh8Gua residues from DNA.     

Role of red light in hair-whorl formation induced by blue light in Acetabularia mediterranea

After a pre-treatment with red light, hair formation at the growing tip of the siphonaceous green alga Acetabularia mediterranea Lamour. (= A. acetabulum (L.) Silva) can be induced by a pulse of blue light. Red light is needed again after the inductive blue-light pulse if the new whorl of hairs is to develop within the next 24 h. In order to investigate the role of this red light, the duration of the red irradiation was varied and combined with periods of darkness. The response of hair-whorl formation was dependent on the total amount of red light, regardless of whether the red irradiation followed the blue pulse immediately or was separated from it by a period of darkness. Furthermore, periods of exposure to the photosynthesis inhibitor 3-(3,4-dichlorophenyl)-1-1dimethylurea had a similar effect to darkness. Both observations indicate that this red irradiation acts as a light source for photosynthesis. Whether or not the red light had an additional effect via phytochrome was tested in another type of experiment. The dependence of hair-whorl formation on red-light irradiance in the presence of simultaneous far-red irradiation was determined for the pre-irradiation period as well as for the irradiation period after the blue pulse. In both experiments, far-red light caused a small promotion of hair-whorl formation when low irradiances of red light were used. However, these differences were attributable to a low level of photosynthetic activity (which in fact was measurable) caused by red light reflected in the growth chamber. Furthermore, lowering the proportion of active phytochrome by far-red light would be expected to suppress hair-whorl formation. The influence of far-red light was also tested in a strain of Acetabularia mediterranea that developed hair whorls in about 20% of cells even when kept in complete darkness after the blue-light pulse. Far-red irradiation had no effect. These results strongly indicate that phytochrome is not involved in hair-whorl formation. Rather it is concluded that the effects of red light are caused by photosynthesis.Abbreviation DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea     

SOS-independent mutagenesis in lacZ induced by methylene blue plus visible light

Summary In vitro photosensitization by visible light in the presence of methylene blue (MB-light) produces lesions in M13mpl8 lacZ phage DNA, the lethal and mutagenic potential of which was analyzed after transfection into various bacterial hosts. Mutagenesis was determined with a forward mutation assay using the lacZ gene of M13mp18 as a target. When, MB-light-treated double-stranded (ds) M13mp18 DNA was used to transfect wild-type cells which were not induced for SOS functions, a fivefold increase in mutation frequency was observed at 10% survival compared to that observed with untreated DNA. Mutation frequency obtained with MB-light-treated ds M13mp18 DNA was greater when transfected into the uvrA fpg-1 double mutant than that seen in uvrA, fpg-1, or umuC single mutants or in the wild-type. Sequence analysis shows that in the wild-type strain, MB-light treatment of ds M13mp18 DNA results mostly in single base substitutions. The most frequent base change is the GCTA transversion. MB-light treatment of single-stranded (ss) M13mp18 DNA also results in an increased mutation frequency after transfection into the wild-type strain, yielding mostly GT transversions. Our results show that MB-light-induced mutagenesis is at least partially independent of the induction of SOS functions in Escherichia coli. The mutation spectra suggest that 8-oxo-7,8-dihydroguanine is the major promutagenic lesion in DNA.     

Thermolabile 8-hydroxyguanine DNA glycosylase with low activity in senescence-accelerated mice due to a single-base mutation.

8-hydroxyguanine (8-oxoguanine; oh8Gua) DNA glycosylase (OGG1) repairs oh8Gua, a highly mutagenic oxidative DNA damage. In the present study, we compared two strains of senescence-accelerated mouse (SAM) expressing senescence-prone phenotypes, SAMP1 and SAMP8, with one strain of SAM expressing senescence-resistant phenotype, SAMR1. We found three distinct characteristics of OGG1 in SAMPs: (i) low activity (10-40% of the SAMRI enzyme in all organs and ages observed), (ii) thermolability, and (iii) mutation from Arg (CGG) in SAMR1 to Trp (TGG) at codon 304. There was no difference in the levels of mRNA and protein. As expected, oh8Gua level in tissues was higher in the SAMPs. In contrast, O6-methylguanine-DNA methyltransferase, which repairs alkylated DNA, showed no difference in its activity. The impairment of oh8Gua repair activity caused by the 304 mutation in OGG1 may be one of the factors contributing to the high somatic mutation rate and the accelerated senescence observed in these strains.     

Involvement of mammalian OGG1(MMH) in excision of the 8-hydroxyguanine residue in DNA

8-Hydroxyguanine (7,8-dihydro-8-oxoguanine, abbreviated as 8-OH-G or 8-oxoG) is the site of a frequent mutagenic DNA lesion produced by oxidative damage. MutM of E. coli and OGG1 of Saccharomyces cervisiae are known to possess 8-OH-G glycosylase and apurinic (AP) site lyase activity. cDNA clones of four isoforms (types 1a, 1b, 1c, and 2) of human OGG1 homologs (hMMH) were isolated. In order to examine whether expression of hMMH (hOGG1) protein actually occurs in human cells, we prepared type 1a specific antibody, and by using this antibody, we showed that type 1a protein isolated from HeLaS3 has 8-OH-G glycosylase/lyase activity. Furthermore, we showed that type 1a protein is a major enzyme for repair of the 8-OH-G lesion in human cells. In our second study, we generated a mouse line carrying an inactivated mutant Mmh allele by targeted gene disruption. Liver extracts of Mmh homozygous mutant mice were found to have loss of the nicking activity for the 8-OH-G site. In addition, the amount of endogenous 8-OH-G in liver DNA of the homozygous mice increased linearly with age, reaching 7-fold increase in 14 week old mice, over that of wild-type or heterozygous mice. Furthermore, when homozygous mice were fed the oxygen radical-forming agent KBrO3, to provide oxidative stress, the level of 8-OH-G in kidney DNA was tremendously increased: more than 200-fold as that of control mice without oxidative stress after 12 weeks of age. These results indicate that Ogg1/Mmh plays an essential role in the repair of the 8-OH-G residue in DNA produced by oxidative stress.