Effect of Physiological Concentrations of Vitamin C on the Inhibitation of Hydroxyl Radical Induced Light Emission from Fe2+-EGTA-H2O2 and Fe3+-EGTA-H2O2 Systems In Vitro.

Ascorbic acid (AA) has antioxidant properties. However, in the presence of Fe2+/Fe3+ ions and H2O2, it may behave as a pro-oxidant by accelerating and enhancing the formation of hydroxyl radicals (•OH). Therefore, in this study we evaluated the effect of AA at concentrations of 1 to 200 µmol/L on •OH-induced light emission (at a pH of 7.4 and temperature of 37 °C) from 92.6 µmol/L Fe2+-185.2 µmol/L EGTA (ethylene glycol-bis (ß-aminoethyl ether)-N,N,N',N'-tetraacetic acid)-2.6 mmol/L H2O2, and 92.6 µmol/L Fe3+-185.2 µmol/L EGTA-2.6 mmol/L H2O2 systems. Dehydroascorbic acid (DHAA) at the same range of concentrations served as the reference compound. Light emission was measured with multitube luminometer (AutoLumat Plus LB 953) for 120 s after automatic injection of H2O2. AA at concentrations of 1 to 50 µmol/L and of 1 to 75 µmol/L completely inhibited light emission from Fe2+-EGTA-H2O2 and Fe3+-EGTA-H2O2, respectively. Concentrations of 100 and 200 µmol/L did not affect chemiluminescence of Fe3+-EGTA-H2O2 but tended to increase light emission from Fe2+-EGTA-H2O2. DHAA at concentrations of 1 to 100 µmol/L had no effect on chemiluminescence of both systems. These results indicate that AA at physiological concentrations exhibits strong antioxidant activity in the presence of chelated iron and H2O2.

Protective Effects of Dihydromyricetin against •OH-Induced Mesenchymal Stem Cells Damage and Mechanistic Chemistry.

As a natural flavonoid in Ampelopsis grossedentata, dihydromyricetin (DHM, 2R,3R-3,5,7,3',4',5'-hexahydroxy-2,3-dihydroflavonol) was observed to increase the viability of •OH-treated mesenchymal stem cells using a MTT [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl] assay and flow cytometry analysis. This protective effect indicates DHM may be a beneficial agent for cell transplantation therapy. Mechanistic chemistry studies indicated that compared with myricetin, DHM was less effective at ABTS⁺• (2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid radical) scavenging and reducing Cu(2+), and had higher •O2(-) and DPPH• (1,1-diphenyl-2-picrylhydrazyl radical) scavenging activities. Additionally, DHM could also chelate Fe(2+) to give an absorption maximum at 589 nm. Hence, such protective effect of DHM may arise from its antioxidant activities which are thought to occur via direct radical-scavenging and Fe(2+)-chelation. Direct radical-scavenging involves an electron transfer (ET) pathway. The hydrogenation of the 2,3-double bond is hypothesized to reduce the ET process by blocking the formation of a larger π-π conjugative system. The glycosidation of the 3-OH in myricitrin is assumed to sterically hinder atom transfer in the •O2(-) and DPPH• radical-scavenging processes. In DHM, the Fe(2+)-chelating effect can actually be attributed to the 5,3',4',5'-OH and 4-C=O groups, and the 3-OH group itself can neither scavenge radicals nor chelate metal.

Excess processing of oxidative damaged bases causes hypersensitivity to oxidative stress and low dose rate irradiation.

Ionizing radiations such as X-ray and γ-ray can directly or indirectly produce clustered or multiple damages in DNA. Previous studies have reported that overexpression of DNA glycosylases in Escherichia coli (E. coli) and human lymphoblast cells caused increased sensitivity to γ-ray and X-ray irradiation. However, the effects and the mechanisms of other radiation, such as low dose rate radiation, heavy-ion beams, or hydrogen peroxide (H2O2), are still poorly understood. In the present study, we constructed a stable HeLaS3 cell line overexpressing human 8-oxoguanine DNA N-glycosylase 1 (hOGG1) protein. We determined the survival of HeLaS3 and HeLaS3/hOGG1 cells exposed to UV, heavy-ion beams, γ-rays, and H2O2. The results showed that HeLaS3 cells overexpressing hOGG1 were more sensitive to γ-rays, OH(•), and H2O2, but not to UV or heavy-ion beams, than control HeLaS3. We further determined the levels of 8-oxoG foci and of chromosomal double-strand breaks (DSBs) by detecting γ-H2AX foci formation in DNA. The results demonstrated that both γ-rays and H2O2 induced 8-oxoguanine (8-oxoG) foci formation in HeLaS3 cells. hOGG1-overexpressing cells had increased amounts of γ-H2AX foci and decreased amounts of 8-oxoG foci compared with HeLaS3 control cells. These results suggest that excess hOGG1 removes the oxidatively damaged 8-oxoG in DNA more efficiently and therefore generates more DSBs. Micronucleus formation also supported this conclusion. Low dose-rate γ-ray effects were also investigated. We first found that overexpression of hOGG1 also caused increased sensitivity to low dose rate γ-ray irradiation. The rate of micronucleus formation supported the notion that low dose rate irradiation increased genome instability.

Effect of intense, ultrashort laser pulses on DNA plasmids in their native state: strand breakages induced by in situ electrons and radicals.

Single strand breaks are induced in DNA plasmids, pBR322 and pUC19, in aqueous media exposed to strong fields generated using ultrashort laser pulses (820 nm wavelength, 45 fs pulse duration, 1 kHz repetition rate) at intensities of 1-12 TW cm(-2). The strong fields generate, in situ, electrons and radicals that induce transformation of supercoiled DNA into relaxed DNA, the extent of which is quantified. Introduction of electron and radical scavengers inhibits DNA damage; results indicate that OH radicals are the primary (but not sole) cause of DNA damage.

Protective effects against H2O2-induced damage by enzymatic hydrolysates of an edible brown seaweed, sea tangle (Laminaria japonica).

Enzymatic hydrolysates of Laminaria japonica were evaluated for antioxidative activities using hydroxyl radical scavenging activity and protective effects against H(2)O(2)-induced DNA and cell damage. In addition, activities of antioxidative enzymes, including catalase, glutathione peroxidase, and glutathione S-transferase, of the enzymatic hydrolysates from L. japonica were also estimated. L. japonica was first enzymatically hydrolyzed by seven carbohydrases (Dextrozyme, AMG, Promozyme, Maltogenase, Termamyl, Viscozyme, and Celluclast [all from Novo Co., Novozyme Nordisk, Bagsvaerd, Denmark]) and five proteinases (Flavourzyme, Neutrase, Protamex, Alcalase [all from Novo Co.], and pancreatic trypsin). The hydroxyl radical scavenging activities of Promozyme and pancreatic trypsin hydrolysates from L. japonica were the highest as compared to those of the other carbohydrases and proteinases, and their 50% inhibitory concentration values were 1.67 and 317.49 mug/mL, respectively. The pancreatic trypsin hydrolysates of L. japonica exerted a protective effect on H(2)O(2)-induced DNA damage. We also evaluated the protective effect on hydroxyl radical-induced oxidative damage in PC12 cells via propidium iodide staining using a flow cytometer. The AMG and pancreatic trypsin hydrolysates of L. japonica dose-dependently protected PC12 cells against cell death caused by hydroxyl radical-induced oxidative damage. Additionally, we analyzed the activity of antioxidative enzymes such as catalase, glutathione peroxidase, and the phase II biotransformation enzyme glutathione S-transferase in L. japonica-treated cells. The activity of all antioxidative enzymes was higher in L. japonica-treated cells compared with the nontreated cells. These results indicate that enzymatic hydrolysates of L. japonica possess antioxidative activity.

Hydroxyl radical damaged immunoglobulin G in patients with rheumatoid arthritis: biochemical and immunological studies.

OBJECTIVES: The role of hydroxyl radical (OH) damaged Immunoglobulin G (IgG) in rheumatoid arthritis (RA) has been investigated. DESIGN AND METHODS: The study was hypothesized that oxidative by-products, like OH-damage IgG, help to initiate autoimmunity in RA. To test this hypothesis, IgG was modified by OH. Immunogenicity of native and modified IgG was probed by inducing polyclonal antibodies in rabbits. Autoantibodies from 77 RA sera were screened by direct binding and competition ELISA. RESULTS: The OH caused extensive damage to IgG. The OH-IgG was found to be highly immunogenic in rabbits as compare to native IgG. High degree of specific binding by 72.7% RA sera autoantibodies towards OH-IgG was observed, in comparison to its native analogue (p<0.05). CONCLUSION: The OH modification of IgG causes perturbations, resulting in the generation of neo-epitopes, and making it a potential immunogen. The IgG modified with the .OH may be one of the factors for the induction of circulating RA autoantibodies.

SERCA overexpression reduces hydroxyl radical injury in murine myocardium.

Hydroxyl radicals (*OH) are involved in the pathogenesis of ischemia-reperfusion injury and are observed in clinical situations, including acute heart failure, stroke, and myocardial infarction. Acute transient exposure to *OH causes an intracellular Ca(2+) overload and leads to impaired contractility. We investigated whether upregulation of sarcoplasmic reticulum Ca(2+)-ATPase function (SERCA) can attenuate *OH-induced dysfunction. Small, contracting right ventricular papillary muscles from wild-type (WT) SERCA1a-overexpressing (transgenic, TG) and SERCA2a heterogeneous knockout (HET) mice were directly exposed to *OH. This brief 2-min exposure led to a transient elevation of diastolic force (F(dia)) and depression of developed force (F(dev)). In WT mice, F(dia) increased to 485 +/- 49% and F(dev) decreased to 11 +/- 3%. In sharp contrast, in TG mice F(dia) increased only to 241 +/- 17%, whereas F(dev) decreased only to 51 +/- 5% (P < 0.05 vs. WT). In HET mice, F(dia) rose more than WT (to 597 +/- 20%, P < 0.05), whereas F(dev) was reduced in a similar amount. After approximately 45 min after *OH exposure, a new steady state was reached: F(dev) returned to 37 +/- 6% and 32 +/- 6%, whereas F(dia) came back to 238 +/- 28% and 292 +/- 17% in WT and HET mice, respectively. In contrast, the sustained dysfunction was significantly less in TG mice: F(dia) and F(dev) returned to 144 +/- 20% and 67 +/- 6%, respectively. Before exposure to *OH, there is decrease in phospholamban (PLB) phosphorylation at Ser16 (pPLBSer16) and PLB phosphorylation at Thr17 (pPLBThr17) in TG mice and an increase in pPLBSer16 and pPLBThr17 in HET mice versus WT. After exposure to *OH there is decrease in pPLBSer16 in WT, TG, and HET mice but no significant change in the level of pPLBThr17 in any group. The results indicate that SERCA overexpression can reduce the *OH-induced contractile dysfunction in murine myocardium, whereas a reduced SR Ca(2+)-ATPase activity aggravates this injury. Loss of pPLB levels at Ser16 likely amplifies the differences observed in injury response.

Differential DNA strand breaking abilities of *OH and ROS generating radiomimetic chemicals and gamma-rays: study of plasmid DNA, pMTa4, in vitro.

Reactive oxygen species (ROS) interact with components of a living cell. Among them *OH is known to cause major oxidative damage to living cells and is proposed to be involved in pathogenesis including carcinogenesis. Proper understanding of consequences of such damage is, therefore, medically relevant. In this report, aqueous solution of plasmid DNA, pMTa4, has been exposed to Fenton oxidant and Haber-Weiss oxidant mediated free radical generating chemical systems, and 60Co gamma-rays in vitro either alone or in combination to study their strand breaking abilities. The exposed pMTa4 was analyzed by agarose gel electrophoresis. The results show qualitative differences in the induction of strand breaks on the plasmid pMTa4 molecule by the iron (Fe2+), copper (Cu2+) or gamma-rays mediated *OH and other ROS.

Free radical development in phacoemulsification cataract surgery.

Phacoemulsification and aspiration (PEA) has become the most popular cataract surgery, due to the establishment of safe surgical techniques and development of associated instruments. However, corneal endothelial damage still represents a serious complication, as excessive damage can lead to irreversible bullous keratopathy. In addition to causes such as mechanical or heat injuries, free radical formation due to ultrasound has been posited as another cause of corneal endothelium damage in PEA. Ultrasound in aqueous solution induces cavitation, directly causing water molecule disintegration and resulting in the formation of hydroxylradicals, the most potent of the reactive oxygen species. Considering the oxidative insult to endothelial cells caused by free radicals, their presence in the anterior chamber may represent one of the most harmful factors during these procedures. Indeed, some researchers have recently started to evaluate PEA from the perspective of oxidative stress. Conversely, the major ingredient in ophthalmic viscosurgical devices (OVDs), which are indispensable for maintaining the anterior chamber in PEA surgery, is sodium hyaluronate, a known free radical scavenger. OVDs can thus be expected to provide some anti-free radical effect during PEA procedures. In addition, since commercially available OVDs display different properties regarding retention in the anterior chamber during PEA, the anti-free radical effect of OVDs is likely to depend on behavior during irrigation and aspiration. The present study followed standard PEA procedures in an eye model and measured hydroxylradicals in the anterior chamber using electron spin resonance. The kinetics of free radical intensity and effects of several OVDs during clinical PEA were also demonstrated. These studies may be of significance in re-evaluating OVDs as a chemical protectant for corneal endothelium, since the OVD has thus far only been regarded as a physical barrier. In addition, many reports about corneal endothelium damage during PEA have been published, but objective evaluation of various damaging factors has been difficult. The present assay of free radicals in a simulation of clinical PEA offers the first method to quantitatively assess stress on the corneal endothelium.

Enhanced conversion of DNA radical damage to double strand breaks by 1,2,4-benzotriazine 1,4-dioxides linked to a DNA binder compared to tirapazamine.

Targeting the anticancer compound tirapazamine (3-amino-1,2,4-benzotriazine 1,4-dioxide; TPZ) to DNA by appended binding units has been found to greatly increase the free radical-induced production of both single and double strand breaks under hypoxia compared to TPZ itself. The (*)OH radical, produced upon the radiolysis of aqueous solutions, was used to damage plasmid DNA, and both types of strand breaks were quantified in the absence and presence of TPZ and analogues. Targeted analogues of TPZ show increases of 12-18-fold in single strand breaks, and 60-110-fold in double strand breaks, as compared with TPZ itself. The observed increased formation of double strand breaks under hypoxia is the likely mechanism for the large increase in potency previously demonstrated for a similarly targeted analogue of TPZ as a bioreductive drug (Delahoussaye et al. (2003) Biochem. Pharmacol. 65, 1807-1815). The one-electron reduction potential of the two-electron reduced metabolite of TPZ (the 1-oxide, SR 4317) has been measured as -568 +/- 9 mV, which is sufficiently high to oxidize carbon-centered radicals such as those formed on the sugar moiety of DNA. Targeting the 1-oxide moiety to DNA resulted in a ca. 50% increase in single strand breaks over that seen for TPZ without the dramatic increase in double strand breaks seen for the similarly targeted benzotriazine 1,4-dioxides. These studies support the mechanism by which the reduction of TPZ to an oxidizing radical leads to free radical damage on DNA that can be further oxidized by TPZ or SR4317 (and especially well by DNA-targeted analogues) to yield lesions resulting in strand breakage. The targeting of benzotriazine 1,4-dioxide analogues to DNA by appending binding units to the compounds thus represents an efficient system for inducing strand breaks in DNA.

[Mechanism of antioxidant protection of an organism from oxidative stress]. / Mekhanizmy antioksidantnoi zashchity organizma pri deistvii aktivnykh form kisloroda.

The analysis of the literature and authors' data concerning the mechanism of antioxidant protection of the organism under conditions of "oxygen stress" is submitted. Possible mechanisms of initiation of free radical reactions with participation of oxygen and the role of hydroxyl radicals, being one of the basic factors, determining toxic action of oxygen, are considered. The methods of estimation of antiradical activity of biologically active compounds are characterized.

Quinacrine acts as an antioxidant and reduces the toxicity of the prion peptide PrP106-126.

The accumulation of protein aggregates in the brain is a central feature of several different neurodegenerative diseases. We have recently shown that Abeta and alpha-synuclein, associated with Alzheimer's disease, Parkinson's disease and related disorders, can both induce the formation of hydroxyl radicals following incubation in solution, upon addition of Fe(II). PrP106-126, a model peptide for the study of prion protein-mediated cell death, shares the same property. In this study we show that quinacrine (an anti-malarial drug and inhibitor of prion replication) acts as an effective antioxidant, readily scavenging hydroxyl radicals formed from hydrogen peroxide via the Fenton reaction or generated during incubation of the PrP106-126 peptide. Furthermore, the toxicity of PrP106-126 to cultured cells was significantly inhibited by quinacrine.

Direct evidence for increased hydroxyl radicals in angiotensin II-induced cardiac hypertrophy through angiotensin II type 1a receptor.

Oxidative stress is known to contribute to numerous cardiac disease processes. However, the contribution of reactive oxygen species to cardiac hypertrophy has not yet been fully investigated. The aim of the present study was therefore to determine whether levels of reactive oxygen species were increased in angiotensin II-induced cardiac hypertrophy. We continuously administered angiotensin II (1.1 mg/kg per day) into wild-type and angiotensin II type-1a receptor knockout mice for 2 weeks. The angiotensin II treatment increased blood pressure and heart weight/body weight ratio in wild-type mice but not in knockout mice. The generation of hydroxyl radicals in heart tissue homogenate was directly assessed with electron spin resonance spectroscopy using a spin trapping agent, alpha-phenyl-N-tert butylnitrone. Angiotensin II significantly increased hydroxyl radical production 2.2-fold (p < 0.01) in the hearts of wildtype mice but not in knockout mice. The present study provided direct evidence for increased production of hydroxyl radicals in angiotensin II-induced cardiac hypertrophy through angiotensin II type-1a receptor. These findings in this study may provide important insights into the development of hypertrophy and the transition of hypertrophy to heart failure.

Possible involvement of copper(II) in Alzheimer disease.

The beta-amyloid (Abeta) peptide is a principal component of insoluble amyloid plaques that are characteristic neuropathological features of Alzheimer disease (AD). The amyloid peptide also exists as a normal soluble protein that undergoes a pathogenic transition to an aggregated, fibrous form. This transition can be affected by extraneous proteinaceous elements and nonproteinaceous elements such as copper ions, which may promote aggregation and/or stabilization of the fibrils. Copper has been found in abnormally high concentrations in amyloid plaques and AD-affected neuropil, and copper-selective chelators have been shown to dissolve Abeta peptide from postmortem brain specimens. Although Cu(2+) is an essential element for life and the function of numerous enzymes is basic to neurobiology, free or incorrectly bound Cu(2+) can also catalyze generation of the most damaging radicals, such as hydroxyl radical, giving a chemical modification of the protein, alternations in protein structure and solubility, and oxidative damage to surrounding tissue.

Chlorella virus pyrimidine dimer glycosylase excises ultraviolet radiation- and hydroxyl radical-induced products 4,6-diamino-5-formamidopyrimidine and 2,6-diamino-4-hydroxy-5-formamidopyrimidine from DNA.

A DNA glycosylase specific for UV radiation-induced pyrimidine dimers has been identified from the Chlorella virus Paramecium Bursaria Chlorella virus-1. This enzyme (Chlorella virus pyrimidine dimer glycosylase [cv-pdg]) exhibits a 41% amino acid identity with endonuclease V from bacteriophage T4 (T4 pyrimidine dimer glycosylase [T4-pdg]), which is also specific for pyrimidine dimers. However, cv-pdg possesses a higher catalytic efficiency and broader substrate specificity than T4-pdg. The latter excises 4,6-diamino-5-formamidopyrimidine (FapyAde), a UV radiation- and hydroxyl radical-induced monomeric product of adenine in DNA. Using gas chromatography-isotope-dilution mass spectrometry and y-irradiated DNA, we show in this work that cv-pdg also displays a catalytic activity for excision of FapyAde and, in addition, it excises 2,6-diamino-4-hydroxy-5-formamidopyrimidine (FapyGua). Kinetic data show that FapyAde is a better substrate for cv-pdg than FapyGua. On the other hand, cv-pdg possesses a greater efficiency for the extension of FapyAde than T4-pdg. These two enzymes exhibit different substrate specificities despite substantial structural similarities.

Formation of copper oxychloride and reactive oxygen species as causes of uterine injury during copper oxidation of Cu-IUD.

The lining of the uterus and cervix might be injured by a variety of oxidation products of Cu in a Cu-IUD, including cuprous ions, dissolved and precipitated cupric ions, and reactive oxygen species such as superoxide radicals, hydrogen peroxide, and hydroxyl radicals. In this study, the human amnious WISH cell line was employed as a model of uterine cells in the presence of copper. The cell viability was decreased by elemental copper, which was alleviated up to 70% by the addition of catalase. The addition of copper oxychloride caused cell death in a dose-dependent manner. Hydroxyl radicals in the presence of copper were determined by the formation of malondialdehyde. Soluble cuprous chloride complexes are formed in the uterus by slowly entering oxygen. The complexes are partly oxidized to insoluble copper oxychloride. which damages the endometrium. Unoxidized cuprous ions migrate to the oxygen-rich cervix and are oxidized to copper oxychloride, causing cervix damage.

[Free oxygen radiacals and kidney diseases--part I]. / Kiseonikovi slobodni radikali i oboljenja bubrega--I deo.

ADVERSE EFFECTS OF OXYGEN: Adverse effect of oxygen on anaerobes implies oxidation of the basic cell constituents NAD(P)H, thiols, iron-sulphur proteins, pteridines and others) and inactivation of the essential components of the active site of enzymes. Oxygen can also adversely affect the aerobes, especially if long-term influence is taken into consideration, while exposition to high-pressure oxygen causes considerable damages. Direct influence of oxygen on aerobes due to slow and limited enzyme inactivation (for example glutamate decarboxylase) and small number of affected "targets" is not responsible for total adverse effects of oxygen. Even in 1954 it was supposed that oxygen free radicals are the most responsible for the adverse effects of oxygen. ATMOSPHERIC (TRIPLET) OXYGEN: Electron configuration of triplet oxygen explains its reactivity since it is a biradical. The reactions of oxygen with non-radicals are possible with participation of transition metals (except zinc), while its reactivity is much more expressed in case of reactions with other radical species. ACTIVE OXYGEN: More reactive forms of oxygen, known as singlet oxygen, can be generated by an input of energy to triplet oxygen. Singlet-oxygen is obtained mainly by photoexcitation in the presence of initiators (methylene blue, chlorophyll etc.) and as a product of reactions of ozone with certain biomolecules. REDUCED FORMS OF OXYGEN: If a single electron is added to the triplet oxygen, it must enter one of the antibonding molecular orbitals and produce the superoxide radical--(O2.-). Addition of one more electron produces peroxide ion--O2(2-), which forms hydro peroxide in presence of H+, the most common two-electron reduction product of oxygen in biological systems. The four-reduction product of oxygen in biological systems is water. SUPEROXIDE RADICAL: The in vivo production of superoxide radical is possible in many different ways mentioned in this paper. This radical species is unstable in water solutions because of dismutation reaction leading to non-enzymic generation of hydroperoxide. The most reactive radical species--hydroxyl radical is produced from hydro peroxide by Fenton or Haber-Weiss reactions in the presence of catalytic transition metals (iron or copper). HYDROXYL RADICAL: Hydroxyl radicals are the most reactive radical species. The way of their generation has been shown in detail in this paper with special emphasis given to Fenton and Haber-Weiss reactions, that is, transition metals (iron and copper) as catalizators for these reactions. The reactivity of hydroxyl radical can be recognized by monitoring the second-order rate constants for reactions of the hydroxyl radical with some organic compounds in aqueous solution presented in this paper. Although the number of compounds that can be affected and damaged by hydroxyl radicals is great, until now, attention has been paid mostly to investigation of attacks of these radical species on lipids, proteins and DNA. LIPID PEROXIDATION: Radicals react with lipids and cause oxidative destruction of unsaturated, that is, polyunsaturated fatty acids, known as lipid peroxidation. Both lipids in biological systems and lipids as food constituents are submitted to this process. Lipid peroxidation is a chain reaction and its mechanism has been shown in detail in this paper. Lipid peroxidation in cells leads to direct damage of cell membranes with indirect damages of other cell constituents, caused by reactivity of secondary products of this reaction, aldehydes. This complex reaction is responsible for damages of many tissues and progress of some diseases (atherosclerosis). OXIDATIVE STRESS: Protection of an organism from oxygen free radicals implies activity of enzymatic (catalase, SOD, glutathione peroxidase, glutathione reductase etc.) and nonenzymatic (vitamin E. vitamin C. glutathione, uric acid etc.) systems of protection. Disturbance of the balance between production of oxygen free radicals (or some other radical species) and activity of antioxidative system of protection causes the so called oxidative stress. An organism can tolerate a mild oxidative stress but a higher disturbance between the production of free radicals and the activity of the antioxidative protection results in lipid protein and DNA as well as numerous diseases.

Genotoxidade do íon estanoso e sua associação ao DNA / Stannous ion genotoxic and ist association of DNA

O estanho é um agente químico de uso amplamente difundido nos mais diferentes setores da atividade humana, podendo ser encontrado, por exemplo, em preparações biocidas; como conservante em refrigerantes; na composição de cremes dentais e enxagüantes orais (como veiculador de flúor); como agente anticorrosivo na cobertura de outros metais em embalagens metálicas contendo alimentos e na pigmentação de tintas especiais. Na forma de cloreto estanoso (SnCl2), este agente é utilizado como agente redutor do Tecnécio 99m para a obtenção de radiofármacos e outras moléculas de interesse biológico. Uma vez que a literatura apresenta vários efeitos biológicos indesejáveis atribuídos ao SnCl2, este trabalho teve por objetivo avaliar a sua atividade genotóxica, bem como a ação antioxidante de algumas substâncias naturais (cartilagem e boldina), através do bloqueio das lesões produzidas por este sal em plasmídeos e células bacterianas, com o fim de estudar a ação do íon estanoso sobre o DNA. O emprego das técnicas de análise de sobrevivência bacteriana, capacidade transformante, eletroforese em gel de agarose, espectrofotometria de luz ultravioleta e de absorção atômica, reveram que: i) O cloreto estanoso provoca lesões, mediadas pela produção de espécies reativas de oxigênio, tanto in vivo quanto in vitro; ii) os danos induzidos pelo SnCl2 provocam diminuição da capacidade transformante do plamídeo pUC9.1; iii) o número de lesões formadas no DNS é diretamente proporcional ao tempo de incubação com SnCl2; iv)o íon estanoso é capaz de se associar à molécula de DNA, induzindo a geração de espécies reativas de oxigênio próximo ao local de ligação, promovendo modificações na estrutura da macromolécula; v) essa associação parece acarretar um ataque preferencial às bases nitrogenadas, fato que poderia estar associado a uma potencialidade mutagênica do estanho

Astrocytes prevent neuronal death induced by reactive oxygen and nitrogen species.

Reactive oxygen and nitrogen species (RO/NS) such as nitric oxide (NO), hydroxyl radical (OH.), and superoxide anion (O(2)(-)) are generated in a variety of neuropathological processes and damage neurons. In the present study, we investigated the neuroprotective effects of rat astrocytes against RO/NS-induced damage using neuron-glia cocultures, and the effects were compared to those of microglial cells. Sodium nitroprusside (SNP), 3-morpholinosydnonimine (SIN-1), and FeSO(4) were used to generate NO, O(2)(-) and NO, and OH., respectively. Solely cultured neurons, which were transiently exposed to these agents, degenerated, possibly through apoptotic mechanisms as revealed by in situ detection of DNA fragmentation, whereas neurons cocultured with either astrocytes or microglial cells were viable even after exposure to RO/NS. In contrast, most neurons cocultured with meningeal fibroblasts degenerated. Astrocyte-conditioned medium partially attenuated RO/NS-induced neuronal damage. When neurons were cultured on astrocyte-derived extracellular matrix (AsECM), neuronal death induced by SNP and FeSO(4) was almost completely inhibited. AsECM contained significant amounts of laminin and fibronectin, and pure fibronectin and laminin also protected neurons against RO/NS-induced damage in the same manner as AsECM. These results suggest that astrocytes can protect neurons against RO/NS-induced damage by secreting soluble and insoluble factors.

SOS-dependent A-->G transitions induced by hydroxyl radical generating system hypoxanthine/xanthine oxidase/Fe3+/EDTA are accompanied by the increase of Fapy-adenine content in M13 mp18 phage DNA.

Gas chromatography/isotope dilution-mass spectrometry with selected ion monitoring (GC/IDMS-SIM) was used to measure oxidised bases in hypoxanthine/xanthine oxidase/Fe3+/EDTA modified ss M13 mp18 phage DNA. A dose-dependent increase of oxidised bases content in DNA was observed with the biggest augmentation of FapyGua, thymine glycol and FapyAde. The amount of 8-OH-Gua was relatively high both in non-oxidised and oxidised DNA, and increased to the same extent as FapyAde and ThyGly. DNA oxidation caused a dramatic decrease in phage survival after transfection to E. coli. Survival was improved 2.8-fold after induction of the SOS system by UV irradiation of bacteria and mutation frequency of the lacZ gene in SOS conditions increased 7-fold over that in non-irradiated bacteria. Spectrum of mutations was different from those reported previously and mutations were distributed rather randomly within M13 lacZ sequence, which was in contrast to previous findings, where with non-chelated metal ions other types of mutations were found in several clusters. Thus, conditions of DNA oxidation and accessibility of metal ions for DNA bases might be important factors for generating different DNA damages and mutations. Major base substitutions found both in SOS-induced and non-induced E. coli but with higher mutation frequency in SOS-induced cells were C-->A (approximately 20-fold increase in SOS-conditions), G-->A (9-fold increase) and G-->C (4.5-fold increase). Very few G-->T transitions were found. A particularly large group of A-->G transitions appeared only in SOS-induced bacteria and was accompanied by augmentation of FapyAde content in the phage DNA with undetectable 2-OH-Ade. It is then possible that imidazole ring-opened adenine mimics guanine during DNA replication and pairs with cytosine yielding A-->G transitions in SOS-induced bacteria.