A possible role of superoxide anion radical in the process of blastocyst implantation in Mus musculus

Superoxide anion radical and superoxide dismutase, the enzyme responsible for dismutating it, are both present in the ovary and uterus of Mus musculus during early pregnancy. The detectable, stable levels of superoxide radical and the constant high levels of superoxide dismutase in the ovary during early pregnancy suggests that these may be involved in the regulation of extended luteal steroidogenesis for the maintenance of pregnancy. An inverse correlation between the levels of superoxide anion radical and superoxide dismutase in the uterus is shown. The high levels of superoxide anion radical in the uterus on the early morning of Day 5 of pregnancy point towards a probable role for this radical in the act of implantation and in mediating the increased vascular permeability at the initiation of implantation.     

Changes in the levels of superoxide anion radical and superoxide dismutase during the estrous cycle of Rattus norvegicus and induction of superoxide dismutase in rat ovary by lutropin

Superoxide dismutase, which has been shown to be present in a number of tissues, exhibits cyclic changes during the reproductive cycle of rats. An inverse correlation is seen between the levels of superoxide dismutase and superoxide radical. In immature, pseudopregnant rats, primed with human Chorionic Gonadotropin, lutropin seemed to induce ovarian superoxide dismutase, which could be blocked significantly by the introduction of anti-LH serum. These results point out the specific induction of superoxide dismutase by lutropin. It is reasonable to postulate that during luteal functioning, luteinizing hormone induces superoxide dismutase which in turn seems to play a central role generating hydrogen peroxide from superoxide anion radicals. Hydrogen peroxide, thus formed, drives the peroxidase-ascorbate system, responsible for production of progesterone.     

Cancer chemopreventive oltipraz generates superoxide anion radical

The cancer chemopreventive actions of oltipraz, a member of a class of 1,2-dithiolethiones, have been primarily associated with the induction of phase 2 enzymes mediated by a 41bp enhancer element known as the anti-oxidant response element in the promoter regions of many phase 2 genes. It has been suggested that oxygen radical formation by oltipraz may be a critical mechanism by which it exerts chemoprevention. Therefore, in the present work, studies were performed to directly determine if oltipraz generates oxygen free radicals. Electron paramagnetic resonance (EPR) spin trapping demonstrated that oltipraz slowly reacts in the presence of oxygen to generate the superoxide anion radical. This formation of superoxide by oltipraz was concentration- and time-dependent. EPR oximetry studies showed that oxygen was also slowly consumed paralleling the process of superoxide formation. Thus, oltipraz induced superoxide formation occurs and could be involved in the mechanism by which it exerts chemoprotection.     

Comparison of different methods for measuring the superoxide radical by EPR spectroscopy in buffer,cell lysates and cells

Abstract

As superoxide anion is of keen interest in biomedical research, it is highly desirable to have a technique allowing its detection sensitively and specifically in biological media. If electron paramagnetic resonance (EPR) techniques and probes have been individually described in the literature, there is actually no comparison of these techniques in the same conditions that may help guiding researchers for selecting the most appropriate approach. The aim of the present study was to compare different EPR strategies in terms of sensitivity and specificity to detect superoxide (vs. hydroxyl radical). Three main classes of EPR probes were used, including paramagnetic superoxide scavengers (such as nitroxides TEMPOL and mitoTEMPO as well as trityl CT-03), a spin trap (DIPPMPO), and diamagnetic superoxide scavengers (such as cyclic hydroxylamines CMH and mitoTEMPO-H). We analysed the reactivity of the different probes in the presence of a constant production of superoxide or hydroxyl radical in buffers and in cell lysates. We also assessed the performances of the different probes to detect superoxide produced by RAW264.7 macrophages stimulated by phorbol 12-myristate 13-acetate. In our conditions and models, we found that nitroxides were not specific for superoxide. CT-03 was specific, but the sensitivity of detection was low. Comparatively, we found that nitrone DIPPMPO and cyclic hydroxylamine CMH were good candidates to sensitively and specifically detect superoxide in complex biological media, CMH offering the best sensitivity.     

Role of the superoxide free radical ion in photosynthetic ascorbate oxidation and ascorbate-mediated photophosphorylation

The mechanism of ascorbate photooxidation in isolated chloroplasts has been studied. The enzyme superoxide dismutase has been used as a tool to show that ascorbate is oxidized by the superoxide free radical ion, which is formed during the autooxidation of a low-potential electron acceptor.

In the absence of an artificial, low-potential electron acceptor, addition of ascorbate stimulates photophosphorylation in isolated chloroplasts. This effect of ascorbate is abolished by superoxide dismutase, indicating that both the superoxide free radical ion and ascorbate are responsible for the stimulation of photophosphorylation. In this case, the superoxide free radical ion seems to be formed during the autooxidation of an endogenous electron acceptor.

In the presence of ferredoxin and NADP⁺, photophosphorylation in isolated chloroplasts stops as soon as the available NADP⁺ is fully reduced. If ascorbate is present in this system, however, a linear rate of photophosphorylation is maintained in spite of the fact, that NADP⁺ is fully reduced. This ascorbate-mediated photophosphorylation again is abolished by superoxide dismutase.

During the catalysis of this oxygen-dependent photophosphorylation, ascorbate consumption is not observed. These findings support the idea, that in chloroplasts ascorbate together with the superoxide free radical ion may function in providing additional ATP by an oxygen-dependent photophosphorylation.     

Generation of superoxide free radical by neocarzinostatin and its possible role in DNA damage

Spectroscopic analysis of the reduction of both nitro blue tetrazolium and ferricytochrome c induced by neocarzinostatin shows that superoxide free radical is produced during the spontaneous degradation of the antibiotic. The amount of superoxide free radical produced from neocarzinostatin is not affected by the presence of thiol, although earlier work has shown that DNA damage is stimulated at least 1000-fold by thiol. Transition metals are not involved in this reaction. Although superoxide dismutase inhibits the reduction of nitro blue tetrazolium and cytochrome c induced by neocarzinostatin, neither it nor catalase interferes with the action of neocarzinostatin on DNA, whether or not drug has been activated by thiol. The pH profiles for spontaneous base release and alkali-labile base release (a measure of nucleoside 5'-aldehyde formation at a strand break) do not correspond with that for the generation of superoxide free radical from neocarzinostatin. The same holds for supercoiled DNA cutting by neocarzinostatin chromophore in the absence of a thiol, which is an acid-favored reaction. These results indicate that the generation of superoxide free radical by the drug does not correlate with DNA damage activity, whether or not thiol is present. Furthermore, the failure of hydroxyl free-radical scavengers to inhibit drug-induced single-strand breaks in supercoiled DNA in the absence of thiol also indicates that a diffusible hydroxyl free radical is most probably not involved in this reaction.     

Effects of 50-Hz magnetic field exposure on superoxide radical anion formation and HSP70 induction in human K562 cells

Epidemiological studies suggest a correlation between exposure to low-level extremely low-frequency (ELF) magnetic fields (MF) and certain cancers and neurodegenerative diseases. Experimental studies have not provided any mechanism for such effects, although at flux density levels significantly higher than the ones encountered in epidemiological studies, radical homoeostasis and levels of stress response proteins can be affected. Here, we report on the influence of MF exposure (50-Hz sine wave; 1 h; 0.025–0.10 mT; vertical or horizontal MF exposure direction) on different cellular parameters (proliferation, cell cycle distribution, superoxide radical anion, and HSP70 protein levels) in the human leukaemia cell line K562. The positive control heat treatment (42°C, 1 h) did not affect either cell proliferation or superoxide radical anion production but caused accumulation of cells in the G2 phase and increased the stress protein HSP70. MF exposure (0.10 mT, 1 h) did not affect either cell cycle kinetics or proliferation. Both vertical and horizontal MF exposures for 1 h caused significantly and transiently increased HSP70 levels (>twofold), at several flux densities, compared to sham controls and also compared to heat treatment. This exposure also increased (30–40%) the levels of the superoxide radical anion, comparable to the positive control PMA. Addition of free radical scavengers (melatonin or 1,10-phenantroline) inhibited the MF-induced increase in HSP70. In conclusion, an early response to ELF MF in K562 cells seems to be an increased amount of oxygen radicals, leading to HSP70 induction. Furthermore, the results suggest that there is a flux density threshold where 50-Hz MF exerts its effects on K562 cells, at or below 0.025 mT, and also that it is the MF, and not the induced electric field, which is the active parameter.     

Production of superoxide radical in reductive metabolism of a synthetic food-coloring agent, indigocarmine, and related compounds

Indigocarmine, which is widely used as a synthetic colouring agent for foods and cosmetics in many countries, was reduced to its leuco form and decolorized by rat liver microsomes with NADPH under anaerobic conditions. The reductase activity was enhanced in liver microsomes of phenobarbital-treated rats, and inhibited by diphenyliodonium chloride, a NADPH-cytochrome P450 reductase (P450 reductase) inhibitor, but was not inhibited by SKF 525-A or carbon monoxide. Indigocarmine reductase activity was exhibited by purified rat P450 reductase. In contrast, when indigocarmine was incubated with rat liver microsomes and NADPH under aerobic conditions, superoxide radical was produced and its production was inhibited by superoxide dismutase and diphenyliodonium chloride. When indigocarmine was incubated with purified rat P450 reductase in the presence of NADPH, superoxide radical production was enhanced 17.7-fold (similar to the enhancement of indigocarmine-reducing ability) as compared with that of rat liver microsomes. A decrease of one molecule of NADPH was accompanied with formation of about two molecules of superoxide radical. P450 reductase exhibited little reductase activity towards indigo and tetrabromoindigo, which also afforded little superoxide radical under aerobic conditions. These results indicate that indigocarmine is reduced by P450 reductase to its leuco form, and superoxide radical is produced by autoxidation of the leuco form, through a mechanism known as futile redox cycling.     

Superoxide radical production in plasma membrane samples from regressing rat corpora lutea

Plasma membrane samples prepared from regressing rat corpora lutea were examined for production of the superoxide radical. A procedure was developed to purify membrane samples that were enriched approximately 15-fold with the plasma membrane marker enzyme, and superoxide radical levels were determined using electron spin resonance to measure Tiron semiquinone. During prostaglandin F2 alpha-induced and spontaneous regression, there was a significant increase in formation of superoxide radical that was not observed in plasma membrane samples from nonregressing corpora lutea. Plasma membrane incubation experiments indicated that the increase in production was temperature sensitive and reduced with inhibitors of phospholipase A2 and cyclooxygenase. Addition of superoxide dismutase or vitamin E abolished superoxide radical formation in vitro. Following the rise in superoxide radical levels during regression, there was also a significant decrease in the activity of the plasma membrane enzyme, Na+-K+ ATPase. These results indicate that the production of superoxide radical increases in plasma membrane samples prepared from regressing rat corpora lutea and that this increase is mainly due to the products of phospholipase A2 and cyclooxygenase activity.     

拟南芥叶片超氧自由基的组织化学定位

拟南芥叶小不易进行超氧自由基的组织化学定位,本方法使拟南芥叶片超氧自由基的检测方便易行。     

Changes in cholinergic and noradrenergic nerves in the pregnant and postpartum uterus of the albino rat and guinea pig

The present study was undertaken to investigate the structural changes in both cholinesterase (ChE)-positive nerve fibers and adrenergic nerves with formaldehyde-induced fluorescence in pregnant and postpartum uteri of both the albino rat and guinea pig. Particular attention was directed to the relationship between these changes and the local factors associated with the growing fetus. ChE reaction was absent in the control and pregnant uterus of the guinea pig. In the albino rat, there were signs of degeneration in pregnancy. These were evidenced by vacuolation of large nerve trunks and the presence of focal segments with very faint reaction along the course of the nerve bundles. Myometrial segments from fetus-containing horns showed some fragmented nerve fibers, but at the same time some other normal ones. Most of the fine nerve bundles gave a weak reaction. Three weeks after delivery, multiple ChE fibers were found in the uterus of the albino rat. The normal appearance was, however, not regained and some nerve fibers were still fragmented. Noradrenergic (NA) nerve fibers were disintegrated and markedly reduced in number in the myometrium of the pregnant uterus of both the guinea pig and albino rat, particularly in the uterine horns that were distended by fetuses. The number of NA fibers was not significantly reduced in the tubal ends of the albino rat uterus. Three weeks after delivery, normal NA fibers were seen in the myometrium of both the albino rat and guinea pig uterus. Nerves with reduced fluorescence reaction were observed less frequently.     

Studies on the mechanism of toxicity of the mycotoxin, sporidesmin. I. Generation of superoxide radical by sporidesmin

Sporidesmin (SDMS2), the mycotoxin responsible for 'facial eczema' in ruminants, contains a disulphide group which appears to be intimately involved in its toxic action. The reduced (dithiol) form of sporidesmin has been shown readily to undergo autoxidation in vitro in a reaction which generates superoxide radical (O2-). The autoxidation reaction, which takes place over a wide pH range, is strongly catalysed by trace amounts of copper, although the reaction was inhibited at high concentrations of this metal. Inhibition of the autooxidation of reduced sporidesmin (SDM(SH)2) was also observed in the presence of nickel, cobalt and manganese. Superoxide radical is also generated from SDMS2 itself in a cyclic reduction/autoxidation reaction with glutathione and other thiols; in view of the known toxicity of superoxide and its derivatives, it is suggested that oxygen-free-radicals may be involved in the initiation of the deleterious effects of the mycotoxin.     

Biochemical changes associated with the mechanism controlling superoxide radical formation in the aging rotifer

Levels of the superoxide radical (SOR) and lipid peroxides were measured and found to increase during aging in the short-lived rotifer, Asplanchna brightwelli. Life-span was altered by changes in environmental temperature, absence of light, diet restriction, exposure to ultraviolet radiation, and addition of vitamin E to the diet. Each of the conditions that lengthened life-span decreased SOR and lipid peroxide levels, and each condition that shortened life-span increased levels of SOR and lipid peroxides. Additional experiments indicated that on the third day of age, there was a significant increase in Ca2+ uptake and phospholipase A2 activity in membrane samples and an elevation in superoxide dismutase and catalase activity in rotifer homogenates. In addition, SOR concentration was inhibited by the addition of bromophenacyl bromide and indomethacin to membrane samples. By day 5 there was also a significant increase in the lysosomal enzyme, alpha-mannosidase. The results of this study indicate that levels of the SOR and lipid peroxides are coupled to rotifer life-span and that activation of phospholipase A2 may contribute to the elevation of these agents in older animals.     

Biphasic regulation of superoxide radical levels in Mn-depleted and photoactivated photosystem II

In the past decades, it has become clear that superoxide radical (O₂ ^·?) can be generated from photosystem II (PSII) during photosynthesis. Depending on the extent of its accumulation, O₂ ^·? plays an important role in plant physiology and pathology. The photoinhibition/repair cycle is a typical process in PSII which is mainly responsible for the survival of plants under the photoinihibition condition. It is therefore of significant importance to determine O₂ ^·? production in this cycle, and then explore how O₂ ^·? is controlled by PSII within a normal physiological level. With this in mind, we herein investigate the variation of the O₂ ^·? levels in PSII under Mn-depleted and photoactivated conditions mimicking the photoinhibition/repair cycle in vitro. The effect of intrinsic SOD-like component on the O₂ ^·? levels was also studied. Results show that PSII has the ability to regulate the O₂ ^·? levels in these two processes by simultaneously modulating the O₂ ^·? generation activity and intrinsic SOD-like activity. This finding could shed new lights on the photoprotective property of PSII against O₂ ^·? and other reactive oxygen species.     

Generation of superoxide radical, hydrogen peroxide and hydroxyl radical during the autoxidation of N,N,N',N'-tetramethyl-p-phenylenediamine

The autoxidation of N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) at neutral pH has been shown to generate superoxide radical and hydrogen peroxide. The rate of formation of these species was increased in the presence of certain iron and copper compounds; in the presence of iron complexed with EDTA, hydroxyl radical was also produced. Hydrogen peroxide was detected in erythrocytes incubated with TMPD and these cells suffered oxidative damage as reflected by methaemoglobin formation and glutathione depletion; the one-electron oxidation product of TMPD, Wurster's Blue, was equally effective in producing such changes in erythrocytes. N-Methylated p-phenylenediamines are known to be mutagenic and myotoxic, and it is suggested that 'active oxygen' species may be involved in the initiation of these harmful effects.     

Disorder in human myelin induced by superoxide radical: an in vitro investigation

Potassium superoxide (KO.2), applied as a source of superoxide radical directly in vitro to white matter from young adult human brain, caused the lipid phase of the myelin to change from a crystalline (ordered) state to a liquid crystalline (disordered) state. The myelin transition temperature decreased from 65 degrees C to 37 degrees C. This alteration was accompanied by a dramatic increase in the levels of lipid peroxidation products--malondialdehyde, a conjugated diene, and ethane. These changes in human myelin, induced by direct application of O2-. radical, simulated myelin deterioration that occurs in the course of natural aging, thus, providing further substantiation for the notion that O2-. might be a major toxic agent associated with the aging process.     

Ascorbic acid, metal ions and the superoxide radical.

1. No evidence could be found for production of the superoxide radical, O2-, during autoxidation of ascorbic acid at alkaline pH values. Indeed, ascorbate may be important in protection against O2- genat-d in vivo. 2. Oxidation of ascorbate at pH 10.2 was stimulated by metal ions. Stimulation by Fe2+ was abolished by superoxide dismutase, probably because of generation of O2-- during reduction of O2 by Fe2+, followed by reaction of O2-- with ascorbate. EDTA changed the mechanism of Fe2+-stimulated ascorbate oxidation. 3. Stimulation of ascorbate oxidation by Cu2+ was also decreased by superoxide dismutase, but this appears to be an artifact, since apoenzyme or bovine serum albumin showed similar effects.     

The function of superoxide dismutase during the enzymatic formation of the free radical of ribonucleotide reductase

An enzyme system from Escherichia coli activates an inactive form of ribonucleotide reductase by transforming a tyrosine residue of the enzyme into a cationic free radical. The process requires NAD(P)H, a flavin, dithiothreitol, and oxygen and at least three proteins. After purification to near homogeneity two of the proteins were identified as superoxide dismutase and NAD(P)H:flavin oxidoreductase (Fontecave, M., Eliasson, R., and Reichard, P. (1987) J. Biol. Chem. 262, 12325-12331). The nature of the third protein, provisionally named Fraction b, is unknown. The flavin reductase is believed to reduce the ferric iron center of the ribonucleotide reductase as a prerequisite for radical generation. Here we demonstrate that the flavin reductase under aerobic conditions generates superoxide anions which inactivate ribonucleotide reductase. Superoxide dismutase protects the enzyme or a sensitive intermediate formed during the generation of the tyrosyl radical from the harmful effects of superoxide. Hydrogen peroxide, formed by superoxide dismutase, is also harmful. In this case, catalase present in Fraction b might protect the system. Fraction b has, however, an additional unknown function in the overall process of radical generation.     

Studies of the role of ischemia/reperfusion and superoxide anion radical production in the teratogenicity of cocaine.

The administration of multiple doses of cocaine on a single day during late gestation is teratogenic in rats in which hind limb ectrodactyly is a major finding (Webster and Brown-Woodman, '90). We have previously hypothesized that these limb malformations result from the generation of reactive oxygen species during the process of ischemia/reperfusion in vivo. In order to study the direct effects of cocaine versus the aberrant oxygenation it may induce, we have developed a system for culturing rat embryos between days 14 and 15 of gestation. Growth and development of cultured embryos are comparable to that of in vivo controls. Exposure to normoxia (95% O2) with or without cocaine failed to induce limb malformations and exposure to a single long period of hypoxia (20% O2) only reduced limb growth in the anterior-posterior axis. By contrast, embryos receiving multiple brief exposures to hypoxia developed a significant incidence of hind limb ectrodactyly that appeared indistinguishable from that induced by cocaine in vivo. By incubating day 14 embryos in a nitroblue tetrazolium derivative, 1-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide (MTT), it was shown that superoxide anion radical appears in the digital rays following two episodes of reperfusion. Little reaction product was seen under the other conditions. Finally, mitochondrial electron transport particles prepared from teratogenically sensitive limb buds spontaneously "leak" electrons to form superoxide anion radical whereas those from insensitive heart fail to do so. We propose that cocaine and other exposures that can transiently reduce conceptual oxygenation during late gestation are teratogenic by virtue of their capacity to induce ischemia/reperfusion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dietary flavonoid iron complexes as cytoprotective superoxide radical scavengers

Superoxide radicals have been implicated in the pathogenesis of ischemia/reperfusion, aging, and inflammatory diseases. In the present work, we have shown that the Fe(3+) complexes of flavonoids (polyphenols) were much more effective than the uncomplexed flavonoids in protecting isolated rat hepatocytes against hypoxia-reoxygenation injury. The 2:1 flavonoid-metal complexes of Cu(2+), Fe(2+), or Fe(3+) were more effective than the parent compounds in scavenging superoxide radicals generated by xanthine oxidase/hypoxanthine (an enzymatic superoxide-generating system). The 2:1 [flavonoid:Fe(3+)] complexes but not the [deferoxamine:Fe(3+)] complex readily scavenged superoxide radicals. These results suggest that the initial step in superoxide radical scavenging (SRS) activity involves a redox-active flavonoid:Fe(3+) complex. Flavonoid:Fe(3+) complexes should, therefore, be tested as a therapy for the treatment of ischemia/reperfusion injury.