Photosensitized formation of 8-hydroxy-2'-deoxyguanosine and DNA strand breakage by a cationic meso-substituted porphyrin

Cationic porphyrins, known to have a high affinity for DNA, are useful tools with which to probe a variety of interactions with DNA. In this study we have examined both DNA strand scission and oxidative DNA base damage, measured by 8-hydroxy-2'-deoxyguanosine (8-OHdG) formation, using a photoactivated cis-dicationic porphyrin. The data demonstrated a dose-dependent formation for each type of DNA damage. Inhibition of strand scission and 8-OHdG formation with the singlet oxygen scavenger 1,3-diphenylisobenzofuran and with MgCl2 and no apparent effect by D2O suggests that a singlet oxygen mechanism generated in close proximity to the DNA may be responsible for the damage. However, a nearly complete inhibition of 8-hydroxy-2'-deoxyguanosine formation in 75% D2O and the substantial enhancement of 8-hydroxy-2'-deoxyguanosine formation in a helium atmosphere by photoactivated porphyrin rules out singlet oxygen as a primary mechanism for this process. These data indicate that distinct mechanisms lead to 8-OHdG formation and strand scission activity.     

The effects of oestrogen and progesterone on insulin sensitivity in female rats

Several reactive oxygen species, including singlet oxygen (1O2) and hydroxyl free radical (.OH), may potentially be involved in the photoinactivation of viruses by agents such as methylene blue (MB) and rose bengal (RB). Both 1O2 and .OH also mediate the formation of 8-oxoguanine (8-oxoGua) in DNA and RNA. Evidence that MB-or RB-induced bacteriophage (R17 or Q beta) inactivation and 8-oxoGua formation in RNA result from 1O2 rather than .OH was obtained utilizing complementary experimental approaches which show that: (i) the rate of phage photoinactivation by MB was unchanged by the presence of iron chelators or by different temperatures in the 13-37 degrees C range; (ii) MB- and RB-mediated rates of 8-oxoGua formation in isolated RNA have very little, if any, temperature dependence, in contrast to a significant temperature dependence of 8-oxoGua formation by a .OH generating system, the ultraviolet light irradiation of H2O2; and (iii) deuterium oxide (D2O) enhanced the RB-mediated rate of phage photoinactivation and 8-oxoGua formation in isolated RNA. The presence of superoxide dismutase in the RB photoinactivation reaction did not alter the rate of phage inactivation. The data suggest that 8-oxoGua serves as a marker that correlates qualitatively with 1O2-mediated lethal lesions in RNA bacteriophages.     

Induction of 8-hydroxydeoxyguanosine in isolated DNA and HeLa cells exposed to fecapentaene-12: evidence for the involvement of prostaglandin H synthase and iron

The genotoxic/mutagenic mechanism(s) of action of fecapentaene-12 (fec-12) is complex but there is evidence to suggest that the generation of active oxygen species (AOS) may be involved. This has been assessed by measuring the formation of 8-hydroxydeoxyguanosine (8-OHdG) in isolated DNA and HeLa cells exposed in vitro to fec-12. The possibility that fec-12 may form AOS via peroxidative 'activation' by prostaglandin H synthase (PHS) has been investigated by measuring 8-OHdG in HeLa cells exposed to fec-12 in the absence or presence of PHS inhibitors. The role of iron as a catalyst in this pathway has also been investigated. A 4-fold increase in the level of 8-OHdG in isolated DNA was seen after exposure to fec-12 (1 mM) alone. This increase was enhanced synergistically by ferrous iron. Fec-12 exposure of HeLa cells at 50 and 100 microM induced 2- and 3-fold increases (P < 0.001) respectively in the level of 8-OHdG in cellular DNA. No increase was seen at 10 microM fec-12. The PHS inhibitors indomethacin and acetylsalicylate blocked the formation of 8-OHdG induced by fec-12 (50 microM) but did not inhibit the formation of 8-OHdG in these cells after exposure to H2O2 and Fe2+. Addition of the iron chelating agent o-phenanthroline to cells prior to fec-12 exposure blocked the increase in 8-OHdG induced by fec-12 (50 microM). Addition of the radical scavenging agent DMSO (10%) to cells prior to fec-12 exposure reduced the level of 8-OHdG to within 10% of control. Specific inhibition of fec-12 induced 8-OHdG formation in HeLa cells by PHS inhibitors suggests that this enzyme may be involved in 'activating' fec-12 to form AOS in cells. Inhibition of fec-12 induced 8-OHdG formation in cells by o-phenanthroline suggests a role for intracellular iron as a catalyst in this process.     

Hydroxyl radical scavengers inhibit TNF-alpha production in mononuclear cells but not in polymorphonuclear leukocytes

The hydroxyl radical (HO*) scavengers dimethylthiourea (DMTU), tetramethylthiourea (TMTU), dimethylsulfoxide (DMSO) and deferoxamine (DFX), the latter being an iron chelator which prevents HO* formation by blocking the Fenton reaction, were found to inhibit TNF-alpha production in LPS-stimulated human PBMC but not in PMN. Furthermore, this effect was not LPS-specific, as TNF-alpha production was reduced by HO* radical scavengers to a similar extent upon stimulation of PBMC with immune complexes (IC), concanavalin A (Con A) and phorbol myristate acetate (PMA). Other scavengers such as glutathione (GSH), N-acetylcysteine (NAC), ascorbic acid (ASC) and mannitol (MAN) do not have effect on the production of TNF-alpha either in PBMC or PMN. These results provide evidence that the participation of ROI in the regulation of TNF-alpha production differ in different cell types. Particularly, the data presented in this work indicate that HO* radicals have a central role in the production of this inflammatory cytokine by human PBMC.     

Active oxygen generation as a possible mechanism of selenium toxicity

Selenium plays an important role in scavenging active oxygen (AO) species as an essential constituent of glutathione peroxidase. On the other hand, several reports proposed a possible induction of toxic AO by selenium compounds in vitro. However, some of these experiments including ours, were revealed to conclude on the basis of experimental artifacts, and to have problems in the interpretation of data. Methods or principles so far used for the detection of AO species generated by selenium compound were measurement of chemiluminescence from lucigenin or luminol by AO species, the spectrophotometric analysis of reduction of ferricytochrome c or nitroblue tetrazolium (NBT) by superoxide anion (O2-), electron spin resonance (ESR) spectra using dimethylpyrroline oxide (DMPO) as a spin trapping agent, the deoxyribose decomposition by hydroxyl radical (HO.), the salicylate hydroxylation by HO., and the strand breakage of DNA by AO. Many of these methods together with their principles seem to have some defects which prevent clear conclusion as stated below. (i) Lucigenin was found to mediate the formation of O2- in the presence of selenite and reduced glutathione (GSH). Therefore, lucigenin is not a suitable reagent. (ii) Luminol may also mediate O2- generation in the presence of HO.. (iii) ferricytochrome c can be reduced to ferrocytochrome c in the mixture of selenite and GSH in the absence of oxygen. Moreover, the spectrophotometric method is interfered by turbidity of elemental selenium formed under some conditions in the reaction mixture containing selenite and GSH. (iv) NBT is also reduced by selenium compounds in the absence of O2. (v) ESR signals of AO species were obtained in the reaction mixture containing selenite and GSH, or in the solution of hydrogen selenide in the presence of O2. However, selenide decomposed spin adduct of DMPO with HO. (DMPO-OH). Therefore, the intensity of the signals is not quantitative. (vi) CuZn-SOD is not necessarily a good tool to prove the involvement of O2- because it enhanced HO. generation in the reaction mixture containing selenite and GSH. Thus, we would like to emphasize that carefully designed experiments are required to further identify the molecular species of active oxygen induced by selenium compounds.     

H2O2-driven reduction of the Fe3+-quin2 chelate and the subsequent formation of oxidizing species

The objective of this study was to compare effects of quin2 and EDTA in iron-driven Fenton-type reactions. Seven different assays for detection of strong oxidants were used: the DMSO, deoxyribose, benzoate hydroxylation, and plasmid DNA strand breakage assays, detection of 8-oxo-deoxyguanosine in deoxyguanosine mononucleosides and calf thymus DNA, and electron spin resonance with the spin-trap (4-pyridyl-1-oxide)-N-tert-butylnitrone (4-POBN) in the presence of ethanol or DMSO. With H2O2 and Fe3+, quin2 generally strongly increased the formation of reactive species in all assays, whereas with EDTA the results varied between the assays from barely detectable to highly significant increases compared to H2O2 and unchelated Fe3+. We found that the species produced in the reaction between Fe3+-quin2 and H2O2 behaved like the hydroxyl radical in all assays, whereas with Fe3+-EDTA no clear conclusion could be drawn about the nature of the oxidant. The effect of quin2 on the formation of oxidants on Fe2+ autoxidation, varied from generally inhibiting to slightly promoting, depending on the assay used. EDTA had a promoting effect on the amount of oxidant detected by all but one assay. None of the autoxidation systems produced DMSO or ethanol radical adducts with 4-POBN. In the presence of either chelator, H2O2, and Fe2+ DMSO and ethanol radical adducts of 4-POBN were produced. Using the Fe2+ indicator ferrozine, evidence for direct reduction of Fe3+-quin2 by H2O2 was found. Superoxide anion radical appeared to be less efficient than H2O2 as reductant of Fe3+-quin2 as addition of superoxide dismutase in the ferrozine experiments only decreased the amount of Fe2+ available for Fenton reaction by 10-20%. The main conclusions from our study are that the reduction of Fe3+-quin2 can be driven by H2O2 and that Fe2+ in the following oxidation step produces a species indistinguishable from free hydroxyl radical.     

Formation of 8-hydroxydeoxyguanosine from 2'-deoxyguanosine and its decomposition by active oxygen

8-hydroxydeoxyguanosine (8-OHdG) was formed from dG and isolated DNA by photosensitization with rose bengal (RB) and methylene blue (MB). 8-OHdG formed from dG was decomposed by the photosensitization with these dyes. Singlet oxygen was concerned with the formation and decomposition of 8-OHdG by photosensitization. Fe++ oxidized dG to 8-OHdG, which was decomposed by the addition of H2O2. 8-OHdG was formed and decomposed by the treatment of dG with Fe++, EDTA and ascorbic acid. Hydroxy radical (.OH) participated in the formation and decomposition of 8-OHdG by Fe++.     

Quantification of singlet oxygen from hematoporphyrin derivative by electron spin resonance

The mechanism of the generation and the quantitative analysis of singlet oxygen (1O2) formed by the exposure of a hematoporphyrin derivative (HpD) to light was re-evaluated by electron spin resonance (ESR) combined with 2,2,6,6,-tetramethyl-4-piperidine (TMPD). The change from TMPD to 2,2,6,6,-tetramethyl-4-piperidine-N-oxide (TAN) has been reported to depend on singlet oxygen. However, we confirmed that this reagent also react with superoxide anion (O2-) and hydroxyl radicals (OH). Therefore, the reactions between TMPD and 1O2, O2- and OH were re-examined using a kinetic approach. We found that the generation of TAN was proportional to the concentration of TMPD and HpD, as well as to the duration and strength of the illumination. The generation of TAN was not inhibited by dimethyl-sulfoxide (DMSO) or superoxide dismutase (SOD). The reaction rate between TMPD and 1O2 was determined to be 5.0 x 10(-7) M min-1. The generation of 1O2 from HpD was 2.7 x 10(-7) M min-1 under our conditions. The competitive reaction observed between 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) and TMPD for O2- or OH shows that TMPD reacts with both forms of active oxygen, but gave no ESR signal. The second-order reaction rate constant of TMPD between O2- and OH was calculated as 73 M-1 s-1 and 1.5 x 10(9) M-1 s-1, respectively. The photochemical generation of 1O2 from methylene blue, another sensitizer, was also demonstrated by this method. These results show that ESR signal of TAN can be used for the highly selective monitoring of 1O2.     

Effect of shikonin and alkannin on hydroxyl radical generation system concerned with iron ion

The effects of shikonnin (SK) and its optical isomer alkannin (AK) on the hydroxyl radical (HO.) generation system including iron ions were evaluated using the spin trap method by ESR spectroscopy. 5,5-Dimethyl-1-pyrroline-1-oxide (DMPO) was used as a spin trap agent and HO. was generated by a reaction between an iron ion and hydrogen peroxide, which is called Fenton reaction system. SK inhibited the HO. spin adduct (DMPO-OH) yielded in a dose-dependent manner. In this effect no difference was observed between SK and AK. When different concentrations of DMPO were used for the confirmation of its competitive reaction, no difference was also observed in the concentration of SK required to reduce the amount of the DMPO-OH by 50% (ID50). These findings suggested that the inhibitory effect of SK against the thus yielded DMPO-OH was not generated by the scavenging for HO., but by the inhibition on the Fenton reaction system. The mechanism of the inhibition on this system may be based on the formation of a complex between SK and the iron ion. The molar ratio of SK to the iron ion in the complex was considered 2 to 1 (2:1), because the concentrations of the observed ID50 and the used iron ion exhibited the same value. In addition, the same result was also obtained from the study using spectroscopic analysis.     

The origin of the hydroxyl radical oxygen in the Fenton reaction

There is an ongoing discussion in the chemical literature regarding the nature of the highly reactive hydroxyl radical formed from the reaction between ferrous iron and hydrogen peroxide (the Fenton reaction). However, the fundamental experiment of directly determining the source of the hydroxyl radicals formed in the reaction has not yet been carried out. In this study, we have used both hydrogen peroxide and water labeled with 17O, together with ESR spin trapping, to detect the hydroxyl radicals formed in the reaction. ESR experiments were run in phosphate buffer with 5,5-dimethyl-1-pyrroline N-oxide (DMPO) as a spin trap, and either H2O2 or H2O labeled with 17O. The hydroxyl radical was generated by addition of Fe2+ ion to H2O2, or as a control, by photolysis of H2O2 in the ESR cavity. Observed ESR spectra were the sum of DMPO/.16OH and DMPO/.17OH radical adduct spectra. Within experimental accuracy, the percentage of 17O-labeled hydroxyl radical trapped by the DMPO was the same as in the original hydrogen peroxide, for either method of hydroxyl radical generation, indicating that the trapped hydroxyl radical was derived exclusively from hydrogen peroxide and that there was no exchange of oxygen atoms between H2O2 and solvent water. Likewise, the complementary reaction with ordinary H2O2 and 17O-labeled water also showed that none of the hydroxyl radical was derived from water. Our results do not preclude the ferryl intermediate, [Fe = O]2+ reacting with DMPO to form DMPO/.OH if the ferryl oxygen is derived from H2O2 rather than from a water ligand.     

Tyrosine hydroxylase: mechanisms of oxygen radical formation

A new mechanism of oxygen radical formation in dopaminergic neurons is proposed, based on the oxidative mechanism of tyrosine hydroxylase. The cofactor (6R,6S)-5,6,7,8-tetrahydrobiopterin can rearrange in solution which allows an autoxidation reaction producing O2.-, H2O2 and HO.. The combination of tyrosine hydroxylase and the cofactor produces more oxygen radicals than does the autoxidation of the cofactor. This production of oxygen radicals could be damaging to dopaminergic neurons. In the presence of tyrosine, the enzyme produces less radicals than it does in the absence of tyrosine. Mechanisms are proposed for the generation of reactive oxygen species during the autoxidation of the cofactor and during enzymatic catalysis. The generation, by tyrosine hydroxylase, of very small amounts of oxygen radicals over the period of 65 years could contribute to the oxidative stress that causes Parkinson's disease.     

A role for oxygen radicals in rat monocytic leukemia cell differentiation under stimulation with platelet-activating factor

Combined stimulation, by superoxide ions generated by the xanthine-xanthine oxidase reaction, and platelet-activating factor (PAF), induced cell differentiation of rat monocytic leukemia cells (c-WRT-LR) to macrophage-like mature cells. Monitoring of cytochrome c reduction revealed that PAF stimulation induced the release of superoxide ions from c-WRT-LR. To further investigate the effect of superoxide ions in the autocrine or paracrine mechanism in cell differentiation, molecular species of the oxygen radicals under PAF stimulation were examined using the EPR spin trap, 5,5'-dimethyl-1-pyrroline N-oxide (DMPO). PAF and/or phorbol myristate acetate caused the formation of EPR spectra, a combination of DMPO/.OOH and DMPO/.OH. Since both spectra were diminished in the presence of superoxide dismutase, it was concluded that DMPO/.OH was derived from superoxide ions. Mannitol and catalase suppressed cell differentiation induced by combined stimulation with PAF and oxygen radicals generated by the xanthine-xanthine oxidase reaction. Taken together, these results suggest that hydroxyl radicals generated by Fenton reaction from H2O2 may be involved in the mechanism of cell differentiation in rat monocytic leukemia cells.     

Action of phenolic antioxidants on various active oxygen species

The action of phenolic antioxidants, such as probucol, on various active oxygen species was investigated using luminol chemiluminescence and spin trapping with 5,5-dimethyl-1-pyrroline-N-oxide (DMPO). The various active oxygen species, including hydroxyl radicals (Fenton reaction), superoxide anions, singlet oxygen and hypochlorite ions were examined with phenolic antioxidants under aqueous and nonaqueous conditions. Probucol showed a quenching effect on both superoxide anions and hypochlorite ions in nonaqueous solution. However, it had no effect on hydroxyl radicals. alpha-Tocopherol, a natural phenolic antioxidant, showed a stronger quenching effect on superoxide anions and hypochlorite ions than probucol, and quenched hydroxyl radicals in nonaqueous solution. Furthermore, Trolox showed a quenching effect on all active oxygen species in both aqueous and nonaqueous solution. The antioxidants were studied under comparable conditions in a series of test systems and the reactivity profiles depicted as 'radar charts' which are helpful for characterizing antioxidant action.     

Perceived physical and emotional trauma as precipitating events in fibromyalgia. Associations with health care seeking and disability status but not pain severity

The spectrophotometry and photofluorescence techniques were used in the studies on photochemical transformations of lactate dehydrogenase exposed to UV irradiation with a dose of 2.25 kJ/m2, in the native state and in the presence of exogenous modifiers: sodium azide, beta-carotene, histidine, D-mannitol, and tret-butanol. It was shown that UV irradiation of the mixtures of lactate dehydrogenase with sodium azide, beta-carotene, and histidine results in restoration (by 99, 65, and 63%, respectively) of the level of catalytic activity of the enzyme as compared to that observed after irradiating it in the absence of the protectors. The protective effect provided by mannitol during UV irradiation of the lactate dehydrogenase was 23%. Thus, it was shown that active oxygen species--singlet molecular oxygen and hydroxyl radical--make significant contributions to photomodification of lactate dehydrogenase.     

Cervical spine abnormalities in professional singers

BACKGROUND AND OBJECTIVE: The purpose of this study was to determine irradiation parameters of a 780 nm low power CW diode laser (6.5 mW) leading to enhanced proliferation of cultured normal human keratinocytes (NHK). The possible role of reactive oxygen species (ROS) in this response was evaluated. STUDY DESIGN/MATERIALS AND METHODS: NHK were exposed to a single dose of 0 to 3.6 J/cm2 (0-180 sec) of irradiation. Proliferation parameters studied were: incorporation of 3H-thymidine during 6-24 hr following irradiation; percentage of dividing cells and number of cells, 24 hr and 48 hr following irradiation, respectively. RESULTS: Proliferation of NHK exposed to 0.45-0.95 J/cm2 was significantly enhanced by 1.3-1.9-folds relative to sham-irradiated controls, as inferred from parameters studied. Exposure to other energy densities was considerably less effective in enhancing proliferation parameters. Added enzymatic antioxidants, superoxide dismutase or catalase, scavenging superoxide anions and H2O2, suppressed this enhanced proliferation. Added scavengers (alpha-tocopherol acetate, scavenging lipid peroxidation, or sodium azide, histidine, mannitol, scavenging singlet oxygen, superoxide anions, and hydroxyl radicals, respectively), or N-acetyl cysteine, the thiol-reducing agent, suppressed the response, but to different extents. CONCLUSIONS: The results indicate that 780 nm low power diode laser irradiation enhanced keratinocytes proliferation in vitro, with an apparent involvement of ROS in this response, and comparably, might be used to promote their proliferation in vivo to enhance wound healing.     

Relationship of oxidative events and DNA oxidation in SENCAR mice to in vivo promoting activity of phorbol ester-type tumor promoters

Reactive oxygen species (ROS) have been implicated as being involved in tumor promotion processes. However, the mechanism by which ROS modulate tumor promotion has not as yet been elucidated. In this report, we show that phorbol ester-type tumor promoters (12-O-tetradecanoylphorbol-13-acetate [TPA], mezerein and 12-O-retinoylphorbol-13-acetate [RPA]), which vary in their in vivo potencies, also differ in their effect on formation of hydrogen peroxide (H2O2) and oxidation of normal bases to 5-hydroxymethyl-2'-deoxyuridine [HMdU] and 8-hydroxyl-2'-deoxyguanosine [8-OHdG] in the DNA of SENCAR mouse epidermis, though they are equipotent in causing infiltration of polymorphonuclear leukocytes (PMNs). Treatment of SENCAR mice with the chemopreventive agents (-)-epigallocatechin gallate or tamoxifen (6.5 nmol) prior to application of TPA (6.5 nmol) diminished PMN infiltration, and formation of H2O2, HMdU and 8-OHdG. These results strengthen the evidence that ROS are involved in tumor promotion, and that generation of ROS and the subsequent oxidative DNA modification are related to the tumor-promoting potencies of the different phorbol ester-type promoters.     

Selective pituitary resistance to thyroid hormone produced by expression of a mutant thyroid hormone receptor beta gene in the pituitary gland of transgenic mice

Phosphine (PH3), from hydrolysis of metal phosphides, is an important insecticide (aluminum phosphide) and rodenticide (zinc phosphide) and is considered genotoxic and cytotoxic in mammals. This study tests the hypothesis that PH3-induced genotoxicity and cytotoxicity are associated with oxidative stress by examining liver (Hepa 1c1c7) cells for possible relationships among cell death, increases in reactive oxygen species (ROS) and lipid peroxidation, and elevated 8-hydroxyguanine (8-OH-Gua) in DNA. PH3 was generated from 0.5 mM magnesium phosphide (Mg3P2) to give 1 mM PH3 as the nominal and maximal concentration. This level causes 31% cell death at 6 h, measured by lactate dehydrogenase leakage, with appropriate dependence on concentration and time. The intracellular ROS level is elevated within 0.5 h following exposure to PH3, peaking at 235% of the control by about 1 h. Lipid peroxidation (measured as malondialdehyde plus 4-hydroxyalkenals) is increased up to 504% by PH3 at 6 h in a time-dependent manner. The level of 8-OH-Gua in DNA, a biomarker of mutagenic oxidative DNA damage analyzed by GC/MS, increases to 259% at 6 h after PH3 treatment. Antioxidants significantly attenuate the PH3-induced ROS formation, lipid peroxidation, 8-OH-Gua formation in DNA, and cell death, with the general order for effectiveness of GSH (5 mM) and D-mannitol (10 mM) (hydroxyl radical scavengers), then Tempol (2.5 mM) and sodium azide (3 mM) (superoxide anion and singlet oxygen scavengers, respectively). These studies support the hypothesis that PH3-induced mutagenic and cytotoxic effects are due to increased ROS levels, probably hydroxyl radicals, initiating oxidative damage.     

Spin trapping of azidyl and hydroxyl radicals in azide-inhibited rat brain submitochondrial particles

Succinate-driven respiration in azide-inhibited rat brain submitochondrial particles (smps) produces azidyl and hydroxyl radicals that were detected by spin trapping with 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO). Production of radicals required succinate and oxygen and was eliminated by heat denaturation, which indicates that radical production is a result of respiration. The concentrations of both DMPO/.OH and DMPO/.N3 were decreased by addition of catalase to the smps, which indicates that H2O2 is involved in radical production. In the absence of azide anion, DMPO/.OH was not detected in the same system, even after five additions of succinate over a period of 24 h. It is proposed that azide inhibition of cytochrome c oxidase results in increased production of superoxide, which is efficiently converted to hydrogen peroxide by membrane-bound superoxide dismutase. Hydrogen peroxide activates endogenous peroxidase to react with azide anion forming azidyl radical, which damages the peroxidase, resulting in decreased production of azidyl radical with successive additions of succinate. Hydroxyl radical is produced from the hydrogen peroxide that is not removed by peroxidase. The increased production of superoxide in the azide-inhibited system suggests that loss of cytochrome c oxidase activity can lead to increased radical production if other proteins in the respiratory chain remain active. In the azide-inhibited system, reaction of azide anion with H2O2-activated endogenous peroxidase and spin-trapping of the resulting azidyl radical is a convenient monitor of H2O2 production.     

Hypochlorite reacts with an organic hydroperoxide forming free radicals, but not singlet oxygen, and thus initiates lipid peroxidation

The mechanism of the reaction of hypochlorite with t-butyl hydroperoxide as a model organic hydroperoxide was studied. The reaction produces chemiluminescence with rate constant 13 +/- 2 mM-1.sec-1. The chemiluminescence of this reaction was compared with that of the hypochlorite reaction with H2O2 where singlet oxygen (1O2) is formed. In the hypochlorite reaction with H2O2, the effect of hypochlorite concentration on the integrated chemiluminescence intensity is quadratic: a red filter with transmission > 600 nm did not significantly decrease the chemiluminescence intensity: substitution of D2O for H2O increased the luminescence intensity 10-fold; infrared monomol emission was observed at 1270 nm. These results confirm the formation of 1O2 during the hypochlorite reaction with H2O2. However, when t-butyl hydroperoxide was used instead of H2O2, the concentration effect significantly differed from quadratic, and the red filter decreased the luminescence intensity by approximately 99%; D2O slightly decreased the luminescence intensity. Finally, addition of t-butyl hydroperoxide to hypochlorite was not associated with monomol emission of 1O2 in the infrared region. The data exclude the possibility of singlet oxygen formation in the hypochlorite reaction with the organic hydroperoxide. According to 1H-NMR spectroscopy, di-t-butyl peroxide is the main product of the hypochlorite reaction with t-butyl hydroperoxide; its production can be explained by radical formation, i.e., by generation of t-butyloxy radical. t-Butyl hydroperoxide and cumene hydroperoxide promoted hypochlorite-induced lipid peroxidation of phospholipid liposomes. The free radical scavenger butylated hydroxytoluene completely inhibited this effect. The data suggest that organic hydroperoxides, always present in certain amounts in vivo, may be the intermediates that interact with hypochlorite-forming free radicals which are initiators of lipid peroxidation.