Phagocytes, O2 reduction, and hydroxyl radical

The formation of O2 reduction products by human neutrophils is critical to their elimination of potential pathogens. Hydroxyl radical is a potent oxidizing agent that may be formed by neutrophils through the iron-catalyzed reaction of superoxide and its dismutation product, hydrogen peroxide. Although indirect evidence has implicated hydroxyl radical in a variety of neutrophil-mediated processes, recent studies have not demonstrated hydroxyl radical formation by neutrophils unless an exogenous iron source and chelator were available, and even then neutrophils appear to limit formation of hydroxyl radical. By consuming hydrogen peroxide, the release of myeloperoxidase limits the magnitude of hydroxyl radical production. Lactoferrin released during neutrophil stimulation binds iron in a form incapable of catalyzing hydroxyl radical generation, thereby limiting both the magnitude and the duration of hydroxyl radical formation. Hydroxyl radical resulting from neutrophil superoxide production is likely to occur either in vitro or in vivo only when the target cell (or microenvironment) provides iron in an oxidation state and form capable of catalyzing the formation of hydroxyl radical and when neutrophil prevention systems are overwhelmed.     

5-hydroxytryptophan is a more potent in vitro hydroxyl radical scavenger than melatonin or vitamin C

Hydroxyl radicals are involved in direct damage of important biomolecules. Potent radical scavengers such as vitamin C and indoles of the tryptophan family can avert the potential damage. Melatonin and its precursor 5-hydroxytryptophan (5-HTP) were compared with water-soluble vitamin C. Different scavenger concentrations were measured in a steady-state luminol chemiluminescence system (SLCL-system) with combined Fe(II) chloride (0.1 mm) and hydrogen peroxide (1.0 mm) as hydroxyl radical generators. 5-HTP showed highest hydroxyl radical scavenging effects with a 50% inhibition concentration (IC50) of 1.8 microm. For vitamin C an IC50 of 12.7 microm was measured, whereas melatonin in pure demineralized water was much less efficient (IC50=724 microm). A comparison between melatonin in aqueous solution and melatonin in ethanol solution revealed that melatonin was significantly more effective in pure demineralized water.     

Menadione-Induced Oxidative Stress in Bovine Heart Microvascular Endothelial Cellsa

Objective: Oxidative stress from increased production of reactive oxygen species or decreased efficiency of inhibitory and scavenger systems may contribute to vascular injury. In this study, we developed an in vitro model of vascular injury by menadione-induced oxidative stress in bovine heart microvascular endothelial cells. Methods: Oxidative stress was induced by exposure to menadione. Superoxide, hydrogen peroxide and hydroxyl radical formation was measured by superoxide dismutase-inhibitable cytochrome c reduction, the dichlorofluorescin technique and the salicylate method, respectively. Electron paramagnetic-spin resonance spectroscopy employing 5–5′-dimethyl-1-pyrroline-N-oxide for superoxide trapping was used. Endothelial cell cytotoxicity was assessed by lactate dehydrogenase release. Results: Superoxide and hydroxyl radical were produced in a time- and concentration-dependent fashion. Fluorescence in the presence of dichlorofluorescin confirmed hydrogen peroxide formation. Endothelial cell cytotoxicity became evident after 5 h of menadione treatment at concentrations of 100 μM. 3-Aminobenzamide, a poly(ADP-ribose)polymerase inhibitor, and dimethylthiourea, a hydrogen peroxide and hydroxyl radical scavenger, decreased menadione cytotoxicity, whereas deferoxamine, an inhibitor of hydroxyl radical formation, did not. Conclusions: The results suggest that menadione toxicity is mediated by poly(ADP-ribose)polymerase activation via hydrogen peroxide formation and that menadione-treated bovine heart microvessel endothelial cells provide a suitable in vitro model to study oxidative stress in endothelial cells.     

Evidence for superoxide radical-dependent coronary vasospasm after angioplasty in intact dogs.

BACKGROUND. Active oxygen species can influence vascular tone and platelet activation through a variety of mechanisms. This study assessed the role of the superoxide anion, the hydroxyl radical, and hydrogen peroxide in vasoconstriction and mural thrombosis after coronary artery angioplasty in intact dogs. METHODS AND RESULTS. Injury was induced by inflation of a balloon catheter 50 +/- 6% above baseline arterial diameter; dogs were followed for 2 hours before death. Epicardial coronary diameters at arteriography and extent of thrombus deposition at serial histological sections were analyzed in controls (n = 20) and in dogs pretreated with superoxide dismutase (SOD, a superoxide radical scavenger, n = 10); other dogs were pretreated with the hydrogen peroxide scavenger catalase (n = 8), the iron chelator deferoxamine (n = 6), or the hydroxyl radical scavenger 1,3-dimethyl-2-thiourea (n = 9). Angioplasty-induced injury was similar among groups. After angioplasty, control dogs exhibited localized and persistent vessel constriction, which was maximal at the initial 5 minutes (28.9 +/- 6.3% diameter decrease versus baseline). Corresponding arterial diameters of SOD-treated dogs were 24-69% larger (95% confidence interval, p less than 0.001) than controls at 5 minutes and, on average, 32% larger than controls thereafter (p less than 0.01). Vasoconstriction was not prevented by the other treatments. The SOD dose used accounted for inhibition of zymosan-stimulated blood cytochrome c reduction versus baseline (7 +/- 3 versus 30 +/- 6 nmol/min/10(6) cells, respectively, p = 0.003); such inhibition occurred in no other group. Prevalence of mural thrombosis was similar among all groups, but large thrombi (greater than 15% of lumen area) were absent in SOD-treated dogs, contrary to control group (p = 0.028); other groups were similar to control. In the absence of injury, SOD alone induced no change in coronary diameter, coronary blood flow, or platelet aggregation. CONCLUSIONS. These data provide evidence implicating the superoxide radical in the genesis of vasoconstriction after coronary angioplasty in vivo. Such effects seem to be independent of its conversion to hydroxyl radicals and availability of hydrogen peroxide or catalytic iron complexes.     

Histamine release during intestinal ischemia-reperfusion: role of iron ions and hydrogen peroxide.

Reactive oxygen intermediates (ROI) play a major role in the mucosal damage developing during the reperfusion period following intestinal ischemia. We have shown previously that histamine (H) release is related to the ROI generated by xanthine oxidase during intestinal ischemia-reperfusion. The present study sought to determine the possible chain of events leading to H liberation. The artery supplying a segment of the ileum was occluded for 2 hr in 51 anesthetized dogs, and plasma levels of H were determined radioenzymatically in the venous effluent. Catalase was applied to scavenge hydrogen peroxide; dimethylsulfoxide and mannitol were used as hydroxyl radical scavengers; the role of catalytically active iron was assessed by using desferrioxamine. Pretreatment with either catalase or desferrioxamine, but not with dimethyl sulfoxide or mannitol, was effective in reducing the postocclusive H release. The results provide further in vivo evidence that ROI are causative agents in H liberation during reperfusion of the ischemic gut. Hydrogen peroxide can interact with catalytically active iron and generate highly reactive oxidants, which in turn are responsible for H release. The exact nature of these oxidants is still uncertain.     

Alloxan cytotoxicity is highly potentiated by plasma membrane- and lysosomal-associated iron — a study on a model system of cultured J-774 cells

Summary Pancreatic islet beta cells, and some other cell types, are sensitive to the damaging effects of alloxan. The mechanisms behind the cytotoxicity have not been fully elucidated, although they are considered to be mediated by the formation and effects of reactive oxygen metabolites. In the present study, the cytotoxic effects of alloxan/cysteine at high and low concentrations were investigated on a model system of cultured J-774 cells. Viability was estimated by the trypan blue dye exclusion test, plasma membrane permeability by a modified microfluometric fluorescein diacetate technique and lysosomal membrane stability by a microfluorometric acridine orange method. The results showed: (a) hydrogen peroxide, readily diffusing through cellular membranes and produced extracellularly in large amounts by alloxan/cysteine at high concentrations, enters the secondary lysosomes if not previously degraded by cellular anti-oxidant systems. Intralysosomal Fenton reactions, with the formation of hydroxyl radicals, may be induced provided catalytically active lysosomal iron is present. This would result in lysosomal membrane damage followed by leakage of lysosomal contents to the cell sap and cell degeneration. (b) Alloxan/cysteine at low concentrations induced production of superoxide and hydrogen peroxide in low amounts which caused almost no lysosomal damage and appeared to be non-toxic unless there was some plasma membrane-associated iron. Consequently, cells initially allowed to endocytose iron during culture, or briefly exposed to iron just before exposure to alloxan and cysteine, showed greatly enhanced sensitivity. In this case iron, in combination with superoxide and hydrogen peroxide, is believed to give rise to plasma membrane-associated hydroxyl radical production (Fenton reaction) with resultant loss of membrane integrity. We thus propose that reasons for pronounced alloxan sensitivity may include lysosomal damage to cells with weak anti-oxidative defense systems or especially vulnerable secondary lysosomes or ironcatalysed plasma membrane damage following exocytosis of this transition metal.     

Ethanol Oxidation by Hydroxyl Radicals: Role of Iron Chelates, Superoxide, and Hydrogen Peroxide

Oxygen-derived free radicals such as the hydroxyl radical (.OH) have been shown to mediate the oxidation of ethanol by a variety of oxy radical-generating systems. Among these are microsomal electron transport systems (both intact and purified, reconstituted systems), the coupled oxidation of hypoxanthine or xanthine by xanthine oxidase, and the model iron-ascorbate system. The sequence of reactions leading to the oxy radical-dependent oxidation of ethanol as well as other hydroxyl radical-scavenging agents by these various systems is believed to proceed through the formation of a common intermediate, namely, hydrogen peroxide (H2O2), after dismutation of the superoxide anion radical (O2-.). The presence of iron, especially chelated iron, greatly enhances the production of .OH by serving as an oxidant for O2-. or a reductant for H2O2. Experiments were carried out to evaluate the role of iron, the chelating agent, O2-., and H2O2 in the oxidation of ethanol by a variety of in vitro systems (chemical, enzymatic, and intact membrane bound) that can produce oxy radicals via different mechanisms. The generation of .OH by all the systems studied was sensitive to catalase, which indicates that H2O2 is the precursor of .OH. Superoxide radical appears to be the reducing agent in the hypoxanthine-xanthine oxidase system, indicating an iron-catalyzed Haber-Weiss reaction. In the ascorbate, reductase, and microsomal systems, superoxide radical does not appear to be the reducing agent. However, superoxide radical probably is the precursor of H2O2. While iron plays an important role in the production of .OH by the various systems, the effect of iron depends on the nature of the iron chelate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hydroxyl radical "footprinting": high-resolution information about DNA-protein contacts and application to lambda repressor and Cro protein.

A method has been developed for making "footprints" of proteins bound to DNA. The hydroxyl radical, generated by reduction of hydrogen peroxide by iron(II), is the reagent used to cut the DNA. Hydroxyl radical breaks the backbone of DNA with almost no sequence dependence, so all backbone positions may be monitored for contact with protein. In addition to defining the DNA sequence in contact with the protein, hydroxyl radical footprints embody structural information about the DNA-protein complex. For example, hydroxyl radical footprints of the bacteriophage lambda repressor and Cro protein show directly that these proteins are bound to only one side of the DNA helix. Additional contacts of lambda repressor and Cro protein with DNA, not observed by other chemical footprinting methods, are revealed by hydroxyl radical footprinting.     

Phagocyte-derived free radicals stimulated by ingestion of iron-rich Staphylococcus aureus: a spin-trapping study.

Phagocytic cells generate superoxide (O2-) and hydrogen peroxide (H2O2), creating the substrates for hydroxyl radical (HO.) in the presence of redox active metals. Previously it was shown that HO. is not a physiologic product of human neutrophils or monocytes but can be generated in the presence of high concentrations of iron. This study was undertaken to determine whether bacterial iron could be used for the generation of HO. The growth of Staphylococcus aureus under iron-rich conditions increased bacterial iron concentration and phagocytosis of iron-rich bacteria allowed neutrophils to accumulate threefold more iron than ingestion of iron-starved organisms. Neither neutrophils nor monocytes ingesting iron-rich S. aureus generated iron-catalyzed HO. at levels detectable by spin-trapping techniques. No differences in the killing of iron-rich organisms by neutrophils was noted. The results suggest that HO. does not play a role in the killing of S. aureus by human neutrophils, regardless of their ability to deliver iron to the cell.     

Oxygen derived free radicals and synovial fluid hyaluronate.

High performance liquid chromatography with TSK 5000 PW or TSK 6000 PW size exclusion columns combined with a 125I labelled hyaluronic acid binding protein assay was used to study the effects of oxygen derived free radicals on synovial fluid hyaluronate. A continuous flux of free radicals was generated by the xanthine oxidase/hypoxanthine system. When the free radical flux was generated with xanthine oxidase/hypoxanthine in the presence of the iron chelator desferrioxamine and the hydroxyl radical scavenger mannitol a 30-50% decrease in hyaluronate peak was detected, but the molecular weight of synovial fluid hyaluronate remained almost unchanged as a result of reaction with superoxide radicals and hydrogen peroxide. When trace amounts of iron and EDTA were present in the reaction mixture depolymerisation of synovial fluid hyaluronate occurred, and it reached a final molecular weight of about 13,500 daltons. These results suggest that superoxide and hydroxyl radicals may have a different mode of action on synovial fluid hyaluronate. Superoxide radicals and hydrogen peroxide do not induce depolymerisation but, rather, change the molecular configuration of synovial fluid hyaluronate.     

Oxygen radicals, inflammation, and arthritis: pathophysiological considerations and implications for treatment

A vast amount of circumstantial evidence implicates oxygen-derived free radicals, especially superoxide and hydroxyl radical (and to lesser extent, hydrogen peroxide), as mediators of inflammation and/or tissue destruction in inflammatory and arthritic disorders. The substrates for radical generation, namely properly stimulated phagocytic cells, transition metal catalysts, and (to a limited extent) ischemia, are all amply present, although there is no particular rheumatic disease in which a consistent abnormality of radical generation has been identified. These radical species can clearly degrade hyaluronic acid, modify collagen and perhaps proteoglycan structure and/or synthesis, alter and interact with immunoglobulins, activate enzymes and inactivate their inhibitors, and possibly participate in chemotaxis. In most situations, however, there is ample scavenging ability to detoxify these radicals before they hit their target, and many rheumatic disease drugs can decrease their production and/or effects. Despite the apparent sufficiency of natural scavengers and the lack of direct evidence that oxygen radicals are pathogenetically important, substantial pharmaceutical effort is still being made to develop free radical scavengers as therapeutic agents. Although individual free radicals die out quickly, rheumatologic interest in them has been sustained for nearly two decades.     

Metal-independent decomposition of hydroperoxides by halogenated quinones: Detection and identification of a quinone ketoxy radical

We have shown recently that halogenated quinones could enhance the decomposition of hydroperoxides and formation of alkoxyl/hydroxyl radicals through a metal-independent mechanism. However, neither the proposed quinone enoxy radical intermediate, nor the major reaction products were unambiguously identified. In the present study, one of the major reaction products between 2,5-dichloro-1,4-benzoquinone (DCBQ) and t-butylhydroperoxide (t-BuOOH) was isolated and purified by semipreparative HPLC, and identified as 2-hydroxy-3-t-butoxy-5-chloro-1,4-benzoquinone [CBQ(OH)-O-t-Bu], which is the rearranged isomer of the postulated quinone-peroxide reaction intermediate. The formation of CBQ(OH)-O-t-Bu was found to be inhibited by the spin trapping agent 5,5-dimethyl-1-pyrroline N-oxide (DMPO), and concurrently, a new DMPO adduct with 1-chlorine isotope peak clusters at m/z 268 was observed. Further electron spin resonance (ESR) spin-trapping, ¹H-NMR and HPLC/Fourier transform ion cyclotron resonance (FTICR) mass spectrometric studies with oxygen-17-labeled and unlabeled hydrogen peroxide strongly suggest that the radical trapped by DMPO is a carbon-centered quinone ketoxy radical, which is the spin isomer of the proposed oxygen-centered quinone enoxy radical. Analogous results were observed when DCBQ was substituted by other halogenated quinones. This study represents the first detection and identification of an unusual carbon-centered quinone ketoxy radical, which provides direct experimental evidence to further support and expand our previously proposed mechanism for metal-independent decomposition of hydroperoxides by halogenated quinones.     

Doxorubicin represses CARP gene transcription through the generation of oxidative stress in neonatal rat cardiac myocytes: possible role of serine/threonine kinase-dependent pathways

Doxorubicin (Dox), an anthracyclin antineoplastic agent, causes dilated cardiomyopathy. CARP has been identified as a nuclear protein whose mRNA levels are exquisitely sensitive to Dox. In this study we investigated the molecular mechanisms underlying the repression of CARP expression by Dox in cultured neonatal rat cardiac myocytes. Dox (1 micromol/l)-mediated decrease in CARP mRNA levels was strongly correlated with BNP but not with ANP mRNA levels. Hydrogen peroxide scavenger catalase (1 mg/ml) but not hydroxyl radical scavengers dimethylthiourea (10 mmol/l) or mannitol (10 mmol/l) blunted the Dox-mediated decrease in CARP and BNP expression. Superoxide dismutase inhibitor diethyldithiocarbamic acid (10 mmol/l), which inhibits the generation of hydrogen peroxide from superoxide metabolism, attenuated the repression. PD98059 (MEK1 inhibitor, 50 micromol/l), SB203580 (p38 MAP kinase inhibitor, 10 micromol/l), calphostin C (protein kinase C (PKC) inhibitor, 1 micromol/l), non-selective protein tyrosine kinase inhibitors genistein (50 micromol/l) or herbimycin A (1 micromol/l) failed to abrogate the downregulation of CARP and BNP expression by Dox. In contrast, H7 (30 micromol/l), a potent inhibitor of serine/threonine kinase, significantly blocked Dox-mediated downregulation of CARP and BNP expression. Transient transfection of a series of 5'-deletion and site-specific mutation constructs revealed that M-CAT element located at -37 of the human CARP promoter mediates Dox-induced repression of CARP promoter activity. These results suggest that a genetic response to Dox is mediated through the generation of hydrogen peroxide, which is selectively linked to the activation of H7-sensitive serine/threonine kinase distinct from PKC and well characterized mitogen-activated protein (MAP) kinases (ERK and p38MAP kinase). Furthermore, our data implicated M-CAT element as a Dox-response element within the CARP promoter in cardiac myocytes.     

Oxidative mechanisms of monocyte-mediated cytotoxicity.

Human monocytes stimulated with phorbol myristate acetate were able to rapidly destroy autologous erythrocyte targets. Monocyte-mediated cytotoxicity was related to phorbol myristate acetate concentration and monocyte number. Purified preparations of lymphocytes were incapable of mediating erythrocyte lysis in this system. The ability of phorbol myristate acetate-stimulated monocytes to lyse erythrocyte targets was markedly impaired by catalase or superoxide dismutase but not by heat-inactivated enzymes or albumin. Despite a simultaneous requirement for superoxide anion and hydrogen peroxide in the cytotoxic event, a variety of hydroxyl radical and singlet oxygen scavengers did not effect cytolysis. However, tryptophan significantly inhibited cytotoxicity. The myeloperoxidase inhibitor cyanide enhanced erythrocyte destruction, whereas azide reduced it modestly. The inability of cyanide to reduce cytotoxicity coupled with the protective effect of superoxide dismutase suggests that cytotoxicity is independent of the classic myeloperoxidase system. We conclude that monocytes, stimulated with phorbol myristate acetate, generate superoxide anion and hydrogen peroxide, which together play an integral role in this cytotoxic mechanism.     

Insulinoma cells in culture show pronounced sensitivity to alloxan-induced oxidative stress

Summary In a model system of cultured J-774 cells we have previously shown that alloxan in moderate concentrations is toxic only in the presence of a reducing agent with the production of hydrogen peroxide. The cytotoxicity was found to involve lysosomal destabilization. In the present study the cytotoxic effects of (i) alloxan alone, (ii) a combination of alloxan and cysteine or (iii) hydrogen peroxide were investigated in two established insulinoma cell lines (HIT-T15 and RINm5F), and compared with the effects on J-774 cells. The protective effects of desferrioxamine and catalase, and the intracellular levels of reduced glutathione and activities of the enzymes glutathione peroxidase, glutathione reductase and catalase were also studied. HIT and RIN cells showed about 10 times greater sensitivity than J-774 cells against exposure to either alloxan and cysteine, or hydrogen peroxide. All cell types were relatively insensitive to alloxan alone. Preincubation with desferrioxamine and addition of catalase provided efficient protection against cytotoxicity and lysosomal destabilization. HIT and RIN cells had less capacity to degrade hydrogen peroxide and lower levels of glutathione peroxidase than J-774 cells. The lysosomal stability in all three cell lines was directly correlated to their viability. We conclude that HIT and RIN cells have weak antioxidative defence systems resulting in enhanced lysosomal vulnerability when they are exposed to alloxan and cysteine, which produce hydrogen peroxide extracellularly. The degree of cytotoxicity seems to be dependent on cellular capacity to degrade hydrogen peroxide and the lysosomal content of reactive iron.Abbreviations AO Acridine orange - Des desferrioxamine - GSH reduced glutathione - GSHPx glutathione peroxidase - GSHRed glutathione reductase - GSSG oxidized glutathione - HIT-T15 (HIT) an established hamster insulinoma cell line - HO^. hydroxyl radical - H₂O₂ hydrogen peroxide - HPLC high performance liquid chromatography - LD₅₀ median lethal dose - O₂ ^— superoxide anion radical - PBS Dulbecco's phosphate-buffered saline, pH 7.4 without Ca²⁺ and Mg²⁺ - RINm5F (RIN) an established rat insulinoma cell line     

Characterisation of oxidative injury to an intestinal cell line (HT-29) by hydrogen peroxide.

Reactive oxygen metabolites have been implicated in causing epithelial cell injury in colonic inflammation. A model of oxidant injury in intestinal epithelial cells has been developed in which HT-29-18-C1 cells are injured with graded concentrations of hydrogen peroxide and characterised by the MTT test. The MTT test was validated as a cytotoxicity assay and has a similar sensitivity to hydrogen peroxide induced injury as the assay of intracellular adenosine triphosphate. Exposure to a range of hydrogen peroxide concentrations (0.05-20 mM) for varying duration (5-120 min) showed that injury was dependent on time and concentration. The median lethal dose (LD50) for one hour exposure to hydrogen peroxide was approximately 0.1 mM. Injury from hydrogen peroxide was only partially reversible as determined by the MTT test and assay of cellular proliferation by crystal violet staining. There was an exponential loss of hydrogen peroxide when incubated with HT-29-18-C1 cells (t1/2 35 min). Experiments with 0.5 mg/ml aminotriazole and 0.5-2 mM buthionine sulphoximine suggested hydrogen peroxide breakdown was predominantly caused by catalase rather than glutathione peroxidase. Injury resulting from 1 mM hydrogen peroxide could be reduced by either coincubation of cells with 1,10-phenanthroline, an Fe2+ chelator, or preincubation with deferoxamine, and Fe3+ chelator, suggesting the participation of Fe2+ and Fe3+ in hydrogen peroxide induced injury. In conclusion, hydrogen peroxide induces injury in HT-29-18-C1 cells both directly and by generation of the hydroxyl radical.     

Hydroxyl radical scavengers inhibit lymphocyte mitogenesis.

Agents that are known to be scavengers of hydroxyl radicals inhibit lymphocyte mitogenesis induced by phorbol myristate acetate (PMA) to a greater extent than they inhibit mitogenesis induced by concanavalin A or phytohemagglutinin. These agents include dimethyl sulfoxide, benzoate, thiourea, dimethylurea, tetramethylurea, L-tryptophan, mannitol, and several other alcohols. Their inhibitory effect is not associated with cytotoxicity. The hydroxyl radical scavengers do not inhibit PMA-dependent amino acid transport in T cells or PMA-induced superoxide production by monocytes. Thus, they do not inhibit the primary interaction of PMA with responding cells. Treatment of peripheral blood mononuclear cells with PMA increased cellular guanylate cyclase in most experiments, and dimethyl sulfoxide tended to inhibit this increase. In addition to inhibition of PMA-induced mitogenesis, hydroxyl radical scavengers markedly inhibited the activity of lymphocyte activating factor (interleukin 1). The differential inhibition of lymphocyte mitogenesis induced by different mitogens appears to be related to the differential macrophage requirements of the mitogens. The data suggest that hydroxyl radicals may be involved in mediating the triggering signal for lymphocyte activation. Some of the hydroxyl radical scavengers are inducers of cellular differentiation,. nd it is possible that their differentiating activity is related to their ability to scavenge free radicals.     

A Holliday recombination intermediate is twofold symmetric.

Four-arm Holliday structures are ephemeral intermediates in genetic recombination. We have used an oligodeoxynucleotide system to form immobile DNA junctions, which are stable analogs of Holliday structures. We have probed the equilibrium structure of a junction by means of hydroxyl radicals generated by the reaction of iron(II)EDTA with hydrogen peroxide. The hydroxyl radical cleavage pattern shows twofold symmetry throughout the molecule. Strong protection from hydroxyl radical attack is evident on two strands near the branch site, and weaker protection may be seen four or five residues 3' to the branch site on the other two strands. No other position appears significantly distinct from double-helical DNA controls. From these data, we conclude that the Holliday junction is a twofold symmetric complex whose four arms form two stacking domains.     

Hemoglobin potentiates the production of reactive oxygen species by alveolar macrophages

The objectives of this investigation were (1) to determine the effects of hemoglobin on the production of reactive oxygen species by activated rat alveolar macrophages, (2) to determine a possible mechanism for these effects, and (3) to determine which part of the hemoglobin molecule is responsible for these effects. Production of reactive oxygen species by phorbol myristate acetate (PMA)-stimulated cells was assessed by measuring luminol-enhanced chemiluminescence (CL). Hemoglobin enhances PMA-stimulated CL in a dose-dependent manner. The effect is maximal at 0.5-1.0 microM hemoglobin where PMA-induced CL is increased by approximately 20-fold. Superoxide anion release from PMA-stimulated cells is not affected by hemoglobin. However, the hemoglobin-induced enhancement of PMA-stimulated CL is inhibited by superoxide dismutase, catalase, dimethylthiourea, or deferoxamine. These results suggest that hydroxyl radical may be formed from hydrogen peroxide which is derived from superoxide anion. Measurements of electron spin resonance spectra following spin trapping of radicals verify that hydroxyl radicals are produced by the cells in the presence of PMA and hemoglobin. The hemoglobin effects appear to require iron in a protoporphyrin complex, because hemin stimulates PMA-induced CL, whereas neither ferrous nor ferric iron has any effect. These findings taken together suggest that hemoglobin can act as a biological Fenton reagent to enhance the production of reactive oxygen species from alveolar macrophages and potentially contribute to lung damage during leakage of blood into the alveolar spaces.     

Superoxide anions produced by inflammatory cells play an important part in the pathogenesis of acid and pepsin induced oesophagitis in rabbits.

BACKGROUND: Reactive oxygen metabolites have been associated with gastrointestinal injury. OBJECTIVE: To investigate whether mucosal reactive oxygen metabolites are involved in acid and pepsin induced oesophagitis, and if so, which specific metabolites. METHODS: The effects of free radical scavengers and the anti-inflammatory drug ketotifen on rabbit oesophagitis induced by acidified pepsin were studied. Isolated oesophageal cells were obtained before and after oesophageal injury and the generation of superoxide anion and hydrogen peroxide was analysed by flow cytometry. The presence of inflammatory cells was determined by indirect immunofluorescence with a mouse antirabbit CD11b antibody. RESULTS: Of the free radical scavengers tested, superoxide dismutase, which reacts with the superoxide anion, significantly reduced oesophagitis, whereas catalase, which reacts with hydrogen peroxide, had only a mild effect and dimethylsulphoxide had no effect. Ketotifen significantly reduced the inflammation and also prevented the induction of oesophagitis. Isolated cells obtained from the oesophageal mucosa after acidified pepsin exposure generated increased amounts of superoxide anions, which were mainly produced by CD11b positive cells. CONCLUSIONS: Reactive oxygen metabolites, especially superoxide anion, produced by inflammatory cells play a significant part in the genesis of oesophagitis induced by acid and pepsin in rabbits and might be a target for future medical therapy.