A novel method for quantitation of favism-inducing agents in legumes

Peas, beans, and the Pythagorean theorem - the relevance of glucose-6-phosphate dehydrogenase deficiency in dermatology

Glucose-6-phosphate (G6PD) deficiency is a common disease characterized by acute hemolysis induced by oxidative stress. More than 400 million subjects throughout the world carry the hereditary enzyme defect with the highest prevalences in Africa, Asia, and the Mediterranean region. In individuals affected by the erythrocytic enzymatic disorder, besides infectious diseases and diet, acute hemolytic crisis can be triggered by numerous drugs frequently used for the treatment of dermatoses. Taking into account the increasing number of immigrants from geographic regions with high prevalences of G6PD deficiency, dermatologists should be alert to the presence of disease.

Cardioprotective and antioxidant effects of apomorphine

Apomorphine is a potent antioxidant that infiltrates through biological membranes. We studied the effect of apomorphine (2 microM) on myocardial ischemic-reperfusion injury in the isolated rat heart. Since iron and copper ions (mediators in formation of oxygen-derived free radicals) are released during myocardial reperfusion, apomorphine interaction with iron and copper and its ability to prevent copper-induced ascorbate oxidation were studied. Apomorphine perfused before ischemia or at the commencement of reperfusion demonstrated enhanced restoration of hemodynamic function (i.e. recovery of the work index (LVDP x HR) was 69.2 +/- 4.0% with apomorphine pre-ischemic regimen vs. 43.4 +/- 9.01% in control hearts, p < 0.01, and 76.3 +/- 8.0% with apomorphine reperfusion regimen vs. 30.4 +/- 11.1% in controls, p < 0.001). This was accompanied by decreased release of proteins in the effluent and improved coronary flow recovery in hearts treated with apomorphine after the ischemia. Apomorphine forms stable complexes with copper and with iron, and inhibits the copper-induced ascorbate oxidation. It is suggested that these iron and copper chelating properties and the redox-inactive chelates formed by transition metals and apomorphine play an essential role in post-ischemic cardioprotection.

Evaluation of plasma low molecular weight antioxidant capacity by cyclic voltammetry

The low molecular weight antioxidants (LMWA) of biological samples include many compounds and contribute to the total antioxidant capacity of the system. They act as direct chemical scavengers neutralizing, reactive oxygen-derived species (ROS), and contribute to the ability of the sample to cope with oxidative stress. We propose cyclic voltammetry (CV) as a new method for evaluating the antioxidant capacity of plasma-LMWA and the severity of oxidative stress exerted on the plasma. It is based on the reducing properties of these molecules. CV has been proven to be a simple, sensitive and reliable method. Its tracing does not change during storage of frozen plasma for up to six months. We analyzed the CV tracings by the oxidation potential E1/2, and the current heights Ia of its anodic wave(s). E1/2 indicates the specific component of the LMWA and its ability to donate electron(s); Ia indicates the concentration of this component. Two anodic waves have been identified in human plasma, at E1/2 = 420 +/- 25 and 920 +/- 25 mV. Ascorbate (AA) and urate (UA) were identified as major LMWA components of the first anodic wave, and were confirmed by HPLC-electrochemical detection. Ia was shown to depend linearly on the concentration of either of these LMWA, both in buffer and in plasma. Oxidative stress exerted by exposure to peroxyl radicals, copper ions and ionizing irradiation caused marked changes in the CV tracing. These changes represent corresponding alterations particularly in la, rather than in E1/2. The Ia and E1/2 values reflect the antioxidant capacity of the plasma, while the change of Ia value represents the severity of the oxidative stress induced.

Interaction between allopurinol and copper: possible role in myocardial protection

Allopurinol, a potent inhibitor of xanthine oxidase, is known to effectively protect the heart against damage in patients undergoing cardiac bypass surgery. There is still an ambiguity concerning the presence of xanthine oxidase in the human heart. Thus, the mechanism underlying the protective effect of allopurinol is unclear. Transition metal ions, such as iron and copper, can participate in single-electron reactions and mediate the formation of oxygen-derived free radicals. In this study the interaction between allopurinol and Cu(II) was investigated. Spectrophotometric investigation shows that allopurinol (0-0.8 mM) form a 1:1 complex with Cu(II) ions (0-0.8 mM) with a specific absorbance peak at 364 nm. Also, the rate constant (k) for the copper-catalyzed aerobic oxidation of ascorbate was markedly decreased in the presence of allopurinol (from 0.068 min-1 to 0.014 min-1). Allopurinol substantially reduced the copper-mediated and ascorbate-driven DNA breakage. Spectrophotometric measurements did not indicate a specific interaction between iron ions and allopurinol. It is suggested that the beneficial effects of allopurinol during reperfusion of the heart could stem from its chelation of copper, yielding a complex with low redox activity.

Is hemin responsible for the susceptibility of Plasmodia to oxidant stress?

Based on the unusually high and stage-dependent susceptibility of Plasmodia to oxidant stress it has been proposed that during parasite development, increasing levels of redox-active forms of iron are gradually released. The purpose of this study was to examine this proposal by using an assay monitoring the levels of available forms of iron for redox reactions. Ascorbate-driven and iron-mediated degradation of adventitious DNA served as the basis for this functional assay. Incubation of DNA with lysate from infected RBC caused massive degradation, which was dose, time- and parasite-stage dependent. In contrast, lysate from non-infected RBC did not induce DNA degradation. Likewise, lysate only from infected RBC enhanced the aerobic oxidation of ascorbate. These effects on both reaction, DNA degradation and ascorbate oxidation, could be reconstructed with hemin, instead of lysate. Also, chelators exerted similar effects on both reactions. The results suggest that increased levels of redox-active forms of iron are liberated during parasite development. We propose that hemin or hemin-like structures are the appropriate candidates which could catalyze oxidative stress and deregulate the delicate redox balance of the host-parasite system.

Ascorbic acid oxidation and DNA scission catalyzed by iron and copper chelates

The asorbic acid (AH-) auto-oxidation rates catalyzed by copper chelates of 1,10-phenanthroline (OP) or by iron chelates of bleomycin (BLM) are only slightly higher than the oxidation rates catalyzed by the metal ions. AH- oxidation in the presence of DNA is accompanied by degradation of the DNA. The rates of DNA scission by the metal chelates are markedly higher than the rates induced by the free metal ions. AH- oxidation is slowed down in the presence of DNA which forms ternary complexes with the chelates. The ternary complexes react slowly with AH- but induce DNA double strand breaks more efficiently than the free metal chelates. With OP, DNA is degraded by the reaction of the ternary complex, DNA-(OP)2Cu(I), with H2O2. AH- oxidation in the presence of DNA was biphasic, showing a marked rate increase after DNA was cleaved. We suggest that this sigmoidal pattern of the oxidation curves reflects the low initial oxidative activity of the ternary complexes, accelerating as DNA is degraded. Using O2- produced by pulse radiolysis as a reductant, we found that AH- oxidation with (OP)2Cu(II) induced more DNA double strand breaks per single strand break than bipyridine-copper. The site specific DNA damaging reactions indicated by these results are relevant to the mechanism of cytotoxic activities of bleomycin and similar antibiotics or cytotoxic agents.

Membrane cross bonding in red cells in favic crisis: a missing link in the mechanism of extravascular haemolysis

Red cells of G6PD (D-glucose-6-phosphate:NADP+ 1-oxidoreductase; G6PD) deficient (Mediterranean variant) subjects were studied during a fava bean haemolytic crisis. Two representative cases are described. In Case 1, haemolysis was still going on. In more than 50% of the red cells the Hb was confined to one part of the cell, leaving the other part as transparent as a Hb-free ghost. In this part the membranes appeared tightly bonded because swelling did not peel apart the bonded membrane areas. This feature is defined as membrane cross bonding (MCB). In Case 2, haemolysis had terminated and MCB-cells were less than 1%. MCB was reproduced in vitro by incubating G6PD-deficient whole blood with 1 mM divicine for up to 10 h. Subsequent shrinkage of red cells in hypertonic plasma (400 mOsm) resulted in the rapid formation of MCB. Membrane modifications by divicine, contained in fava beans, followed by osmotic shrinkage in the kidney and/or squeezing in the microcirculation are proposed as the cause of MCB during the favic crisis. MCB reduces the effective surface area of red cells. This is a plausible cause for sequestration by the reticulo-endothelial system. Intravascular haemolysis observed in favic crisis cannot be explained by mechanical forces, but it is possible that the effective surface area is reduced by MCB to such an extent that red cells lyse osmotically.

Haemolysis in a G6PD-deficient child induced by eating unripe peaches

A child suffering from G6PD deficiency developed a severe haemolytic crisis without an apparent trigger. The possible pathogenetic role of the ingestion of unripe peaches was studied biochemically in this anaemia. We show that an extract from the unripe peach exerts an oxidative challenge on normal as well as on asymptomatic G6PD-deficient erythrocytes. This effect is analogous to that of the favism-inducing agents. The effect of the extract on the patient's red blood cells was more pronounced than on other asymptomatic G6PD-deficient erythrocytes, particularly during his haemolytic crisis. The chemical nature of the deleterious component was not identified. It is suggested that unripe peaches be added to the list of hazards for G6PD-deficient subjects in combination with other factors.

Mechanism of action of divicine in a cell-free system and in glucose-6-phosphate dehydrogenase-deficient red cells

Favism is an acute hemolysis occurring in glucose-6-phosphate dehydrogenase (G6PD)-deficient (Mediterranean variant) individuals after intake of fava beans. Divicine (D), 2,6-diamino-4,5-dihydroxypyrimidine, is present in high amounts in the beans, and is suspected to play a role in hemolysis. Its mechanism of action was studied in a cell-free system and in G6PD (Mediterranean variant)-deficient red cells (RBC). Upon hydrolysis of the inactive beta-glucoside vicine, reduced divicine is formed. Oxygen acts as a one- or two-electron acceptor; superoxide anion and hydrogen peroxide are formed, respectively, together with the semiquinoid free-radical form of D. This free radical gives an electron spin resonance (ESR) signal, which is similar to that of the alloxan free radical. Added reduced glutathione (GSH) is rapidly oxidized with a stoichiometry of one to one, and the ESR signal is abolished. Additional GSH is oxidized by hydrogen peroxide and by a slow redox cycle which continuously regenerates oxidized D. The fast-direct and the slow-indirect oxidation result in nonstoichiometric oxidation of GSH. D added to G6PD-deficient RBC rapidly oxidizes GSH with an end point kinetics and a stoichiometry of one to one. Hydrogen peroxide and superoxide anion are scavenged in the RBC and no redox cycling is taking place. No GSH is regenerated even after long incubation periods. After the primary event, i.e., oxidation of GSH and--SH groups, a number of metabolic, rheologic, and membrane modifications, together with increased erythrophagocytosis take place in G6PD-deficient, D-treated RBC only.(ABSTRACT TRUNCATED AT 250 WORDS)

Dietary carcinogens and anticarcinogens. Oxygen radicals and degenerative diseases

The human diet contains a great variety of natural mutagens and carcinogens, as well as many natural antimutagens and anticarcinogens. Many of these mutagens and carcinogens may act through the generation of oxygen radicals. Oxygen radicals may also play a major role as endogenous initiators of degenerative processes, such as DNA damage and mutation (and promotion), that may be related to cancer, heart disease, and aging. Dietary intake of natural antioxidants could be an important aspect of the body's defense mechanism against these agents. Many antioxidants are being identified as anticarcinogens. Characterizing and optimizing such defense systems may be an important part of a strategy of minimizing cancer and other age-related diseases.