The use of Zn-desferrioxamine for radioprotection in mice, tissue culture, and isolated DNA.

Redox-active metals mediate oxidative injury and might also potentiate radiation damage. The iron chelator desferrioxamine (DFO), which diminishes oxidative damage in many chemical and biological systems as well as in human subjects, has a controversial role in radiobiology and reportedly acts both as a radiosensitizer and a radioprotector. The present research focused on the radioprotective activity of its zinc complex. Zn-DFO was studied using three test systems differing by their complexities: isolated DNA from pUC 19 plasmid, cultured V79 Chinese hamster cells, and C3H mice. Zn-DFO (0.5-2 mM) protected isolated DNA against gamma-radiation better than each of its components alone; however, neither Zn-DFO nor DFO (50-100 microM) alone affected the radiation sensitivity of cultured cells. With total body irradiation, Zn-DFO, but not DFO alone at 100 micromol/kg body weight, administered to mice 30 min before irradiation provided significant radioprotection (P < 0.01). Zn-DFO had an LD(50/30) of 10.3 Gy, whereas DFO and vehicle alone had LD(50/30) of 8.03 Gy and 7.91 Gy, respectively. The effect of Zn-DFO on the hemodynamic parameters in mice did not differ from that of the vehicle (saline) alone. This excludes the explanation that the radioprotective activity of Zn-DFO results from its effect on oxygen levels. In addition to the possible direct effect of Zn, other potential modes of action underlying the radioprotective activity of Zn-DFO might involve a displacement of iron and its substitution by zinc, a greater proximity of the drug to DNA, and less likely an improved penetration of the drug into cells because of its structure. The failure of Zn-DFO to protect cells in tissue cultures indicates that it has some systemic role in the whole animal, possibly due to a prolonged half-life in the animal's circulation.

Membrane studies of Streptococcus pyogenes and its L-form growing in hypertonic and physiologically isotonic media. An electron spin resonance spectroscopy approach.

Electron spin resonance spectroscopy (ESR) was used to compare the lipid organization, thermal stability and the physical state of the membrane of a human pathogen, Streptococcus pyogenes and its osmotically fragile L-form with this same L-form now adapted to grow under physiologically isotonic conditions (physiological L-form). Comparison of the hyperfine splittings of a derivative of 5-ketostearic acid spin label, I(12, 3), after incorporation into the membrane, revealed that the lipid chain rigidity of these membranes is in the order physiological L-form greater than osmotically fragile L-form greater than streptococcus. The signal intensity (of the center magnetic field line) versus temperature analysis showed two transitions for these membranes. The first with melting points of 45, 26 and 36 degrees C and second transition at 70, 63 and 60 degrees C for the physiological L-form, osmotically fragile L-form and streptococcal membranes, respectively. This same order of membrane lipid chain rigidity was seen from the cooperativities obtained for each of these systems from analysis based on the expression for an n-order reaction. The I(12, 3) and other probes with the paramagnetic group close to the methyl end of the molecule suggested that this difference in lipid chain rigidity between these organisms resides in the environment closer to the lipid head group region rather than in the hydrophobic lipid core. Another major finding was the binding of I(12, 3) at two or more different sites in each of the membranes examined. This change in lipid chain rigidity now provides an explanation to account for the survival of a previously osmotically fragile L-form in physiologically isotonic media by focusing on changes in the physical nature of its membrane. In so doing, it adds to and reinforces the speculation of the potential survival in vivo and involvement in pathogenesis of osmotically fragile aberrant forms of bacteria.

High resolution EPR studies of the fine structure of heme proteins. Third harmonic detection approach.

When third harmonic detection is applied in EPR studies of the superhyperfine structure of nitrosyl derivatives of a number of human hemoglobin variants, significant resoltuion enhancement is obtained. This has allowed a detailed analysis of the number of superhyperfine lines, their g-values and their splittings, and has led to a more complete understanding of the interaction between the axial ligands of the heme iron. Sudies of the effect of the modulation amplitude on EPR line-shapes revealed that the amplitude required to resolve fine structure in the third harmonic mode is 3-10 times larger than that used to record an undistorted first derivative spectrum. The application of this approach for other systems is discussed, and practical guidelines for its use are given.

Advanced glycation end product-induced activation of NF-kappaB is suppressed by alpha-lipoic acid in cultured endothelial cells.

Depletion of cellular antioxidant defense mechanisms and the generation of oxygen free radicals by advanced glycation end products (AGEs) have been proposed to play a major role in the pathogenesis of diabetic vascular complications. Here we demonstrate that incubation of cultured bovine aortic endothelial cells (BAECs) with AGE albumin (500 nmol/l) resulted in the impairment of reduced glutathione (GSH) and ascorbic acid levels. As a consequence, increased cellular oxidative stress led to the activation of the transcription factor NF-kappaB and thus promoted the upregulation of various NF-kappaB-controlled genes, including endothelial tissue factor. Supplementation of the cellular antioxidative defense with the natural occurring antioxidant alpha-lipoic acid before AGE albumin induction completely prevented the AGE albumin-dependent depletion of reduced glutathione and ascorbic acid. Electrophoretic mobility shift assays (EMSAs) revealed that AGE albumin-mediated NF-kappaB activation was also reduced in a time- and dose-dependent manner as long as alpha-lipoic acid was added at least 30 min before AGE albumin stimulation. Inhibition was not due to physical interactions with protein DNA binding, since alpha-lipoic acid, directly included into the binding reaction, did not prevent binding activity of recombinant NF-kappaB. Western blots further demonstrated that alpha-lipoic acid inhibited the release and translocation of NF-kappaB from the cytoplasm into the nucleus. As a consequence, alpha-lipoic acid reduced AGE albumin-induced NF-kappaB mediated transcription and expression of endothelial genes relevant in diabetes, such as tissue factor and endothelin-1. Thus, supplementation of cellular antioxidative defense mechanisms by extracellularly administered alpha-lipoic acid reduces AGE albumin-induced endothelial dysfunction in vitro.

A site-specific mechanism for free radical induced biological damage: the essential role of redox-active transition metals.

The metal-mediated site-specific mechanism for free radical-induced biological damage is reviewed. According to this mechanism, cooper- or iron-binding sites on macromolecules serve as centers for repeated production of hydroxyl radicals that are generated via the Fenton reaction. The aberrations induced by superoxide, ascorbate, isouramil, and paraquat are summarized. An illustrative example is the enhancement of double-strand breaks by ascorbate/copper. Prevention of the site-specific free radical damage can be accomplished by using selective chelators for iron and copper, by displacing these redox-active metals with other redox-inactive metals such as zinc, by introducing high concentrations of hydroxyl radicals scavengers and spin trapping agents, and by applying protective enzymes that remove superoxide or hydrogen peroxide. Histidine is a special agent that can intervene in free radical reactions in variety of modes. In biological systems, there are traces of copper and iron that are at high enough levels to catalyze free-radical reactions, and account for such deleterious processes. In the human body Fe/Cu = 80/1 (w/w). Nevertheless, both (free) copper and iron are soluble enough, and the rate constants of their reduced forms with hydrogen peroxide are sufficiently high to suggest that they might be important mediators of free radical toxicity.

The use of cyclic voltammetry for the evaluation of antioxidant capacity.

Low-molecular weight antioxidants (LMWAs) play a major role in protecting biological systems against reactive oxygen-derived species and reflect the antioxidant capacity of the system. Cyclic voltammetry (CV), shown to be convenient methodology, has been validated for quantitation of the LMWA capacity of blood plasma, tissue homogenates, and plant extracts. Analysis of the CV tracing yields the values of (i) the biological oxidation potential, E and E(1/2), which relate to the nature of the specific molecule(s); (ii) the intensity (Ia) of the anodic current; and (iii) the area of the anodic wave (S). Both Ia and S relate to the concentration of the molecule(s). LMWA components of human plasma and animal tissues were identified and further validated by reconstruction of the CV tracing and by high-performance liquid chromatography-electrochemical detection. To reflect the oxidative stress status, the use of an additional parameter, R, has been proposed. R represents the level (%) of oxidized ascorbate (compared with total ascorbate) and is measured by high-performance liquid chromatography-electrochemical detection. All these parameters were monitored in healthy human subjects as well as in chronic (diabetes mellitus) and acute care patients (subjected to total body irradiation before bone marrow transplantation). The electroanalytical methodologies presented here could be widely employed for rapid evaluation of the status of subjects (in health and disease) for monitoring of their response to treatment and/or nutritional supplementation as well as for screening of specific populations.

The effect of zinc on reperfusion arrhythmias in the isolated perfused rat heart.

Considerable evidence suggests that free radicals engendered by redox-active metals, particularly iron and copper, are causative agents in reperfusion injury following ischemia. This study demonstrates that perfusion of the isolated rat heart with a buffer containing zinc, a non-redox active metal similar to copper in its coordination chemistry, inhibits the development of ventricular arrhythmias during reperfusion. Zinc was employed as the bishistidine complex, Zn--His2, to maintain solubility and permeability. Zn--His2 exerted an antiarrhythmic activity as hearts spent a longer time in normal sinus rhythm and a shorter time in ventricular fibrillation during reperfusion following 10 min of regional ischemia. However, Zn--His2 also produced a negative inotropic and chronotropic effect, evident during equilibration and ischemia. In the course of experiments which began in Israel and continued in the U.S. it was necessary to use two different sources of rats. Hearts from the two sources manifested different sensitivities to the concentrations of Zn--His2, although their physiological effects were similar. Differential activity responses were noted for antiarrhythmic activity, negative inotropic and chronotropic properties, and toxicity. In both groups of untreated hearts the incidence of ventricular fibrillation after ischemia was 100%. Ventricular fibrillation was reduced to 17% at 37.5 microM Zn--His2 in the U.S.-bred rat hearts and to 9% at 200 microM Zn--His2 in those from Israel. These changes in Zn--His2 treated animals were accompanied by a decrease in lactate dehydrogenase release from the myocardium during reperfusion. None of the protective effects was due to histidine alone. These results indicate that zinc prevents ventricular arrhythmias during reperfusion following regional ischemia and may prevent membrane damage, possibly, by reduction of free radical formation.

Salicylate as an in vivo free radical trap: studies on ischemic insult to the rat intestine.

Ischemia of rat intestine was induced in vivo by occlusion of the superior mesenteric artery (SMA) for 15 min. Sodium salicylate, 100 mg/kg, given IP, 30 min prior to the ischemic event served as a specific trap for hydroxyl radicals. Portions of the bowel were sequentially isolated and removed--2 min prior to ischemia, 2 min prior to declamping of the SMA, and 10 min following reperfusion. The bowel segments were homogenized in 3% TCA. The homogenate was centrifuged and filtrated through a 0.22 mu filter. The hydroxylation products of salicylate, dihydroxybenzoic acid (DHBA) derivatives, were isolated, identified, and quantified by HPLC coupled with electrochemical detection (ECD). The level of 2,5-DHBA (M +/- SE, ng/g tissue) in the preischemic bowel (N = 21) was 241.8 +/- 10.0. In the ischemic specimen the level of 2,5-DHBA increased significantly to 313.3 +/- 15.5 (p = 0.0129), and remained unchanged in the reperfusion period (322.8 +/- 15.5). The histological examination correlated well with these levels: mild villi damage in the ischemic period with no further exacerbation during the reperfusion period. This study in an in vivo animal model of intestinal ischemia-reperfusion provides direct evidence for the involvement of free radicals during the ischemic insult.

Inverse correlation between resistance towards copper and towards the redox-cycling compound paraquat: a study in copper-tolerant hepatocytes in tissue culture.

The essential mediatory role of copper or iron in the manifestation of paraquat toxicity has been demonstrated (Kohen and Chevion (1985) Free Rad. Res. Commun. 1, 79-88; Korbashi, P. et al. (1986) J. Biol. Chem. 261, 12472-12476). Several liver cell lines, characterized by their resistance to copper, were challenged with paraquat and their cross-resistance to paraquat and copper was studied. Cell growth and survival data showed that copper-resistant cells, containing elevated copper, are more sensitive towards paraquat than wild type cells. Copper-deprived resistant cells did not have this sensitivity. Paraquat was also shown to cause a marked degradation of cellular glutathione in all cell lines. Albeit the fact that the basal glutathione levels are higher in copper-resistant than in wild type cells, there is more paraquat-induced degradation of cellular glutathione (GSH + GSSG) in resistant cells. It is suggested that in copper-resistant cells which contain elevated levels of copper, paraquat-induced cellular injury is potentiated even where glutathione levels are elevated. Additionally, in vitro experiments are presented that support the in vivo findings demonstrating a role for copper in glutathione degradation.

Hydroxyl radical generation in beta-thalassemic red blood cells.

To provide more experimental evidence for the proposed role of oxygen free radicals in red blood cell (RBC) damage in beta-thalassemia, hydroxyl radical generation was studied in thalassemic (Th) vs. normal (N) RBC. .OH fluxes were quantified by the conversion of salicylic acid (SA) into its hydroxylated products, 2,3- and 2,5-dihydroxybenzoic acids (DHBA) and catechol, assayed with HPLC coupled to electrochemical detection. No significant difference in spontaneous .OH generation between N-RBC and Th-RBC was found. Ascorbic acid (0.5-3.0 mM) induced many-fold increases in SA hydroxylation in a dose-dependent manner in both types of cells. In the presence of ascorbate (1.0 mM), the SA hydroxylated products were determined in Th-RBC vs. N-RBC as follows (nmol/ml): 2,5-DHBA, 1.45 +/- 0.06 vs. 1.81 +/- 0.05 (p = 0.001); 2,3-DHBA, 1.89 +/- 0.21 vs. 1.15 +/- 0.08 (p = 0.008) and catechol, 0.87 +/- 0.13 vs. 0.38 +/- 0.05 (p = 0.006). The results showed significant increase in the total SA hydroxylation in Th-RBC as compared to N-RBC with a tendency to form 2,3-DHBA and catechol at the expanse of 2,5-DHBA. The excessive .OH generation in Th-RBC is attributed to the abnormally high content of redox active iron in the cytosolic and/or membrane compartments of these cells.

New modes of action of desferrioxamine: scavenging of semiquinone radical and stimulation of hydrolysis of tetrachlorohydroquinone.

Desferrioxamine (DFO) is a common drug used in the treatment of iron overload. In addition to its iron-chelation, other properties have been identified. Alas, DFO has demonstrable effects which cannot be explained by its classically established properties; i.e., DFO protects against DNA single strand breaks induced by tetrachlorohydroquinone (TCHQ), while other iron chelators such as DTPA (diethylenetriaminepentaacetic acid) do not. The autooxidation process of TCHQ yielding the tetrachlorosemiquinone radical (TCSQ.) intermediate, was studied here in the presence of chelators. DFO led to a marked reduction in both concentration and life span of TCSQ. via formation of DFO-nitroxide radical (DFO.). In contrast, DTPA had no detectable effect on TCHQ autooxidation. Present studies indicate that the protective effects of DFO on TCHQ-induced DNA damage were not due to the binding of iron, but rather to scavenging of the reactive TCSQ. and the formation of the less reactive DFO.. An additional mode of action of DFO was identified, via stimulation of the hydrolysis (dechlorination) of tetrachloro-1,4-benzoquinone (chloranil), which is the oxidation product of TCHQ, to form 2,5-dichloro-3,6-dihydroxy-1,4-benzoquinone (chloranilic acid). The results of this study demonstrate two new modes of action for DFO: the scavenging of deleterious semiquinone radical, and the stimulation of the hydrolysis of halogenated substituents on the quinone structure. Both modes might prove highly relevant to the biological activities of DFO.

Gallium-desferrioxamine protects the cat retina against injury after ischemia and reperfusion.

This study sought to determine whether gallium-desferrioxamine (Ga/DFO) can curb free radical formation and mitigate biochemical and electrophysiological parameters of injury in the cat retina subjected to ischemia followed by reperfusion. For the biochemical studies, cat eyes were subjected to 90 min of retinal ischemia followed by 5 min of reperfusion, and enucleation of one eye of each cat was used to measure retinal reperfusion injury. Before enucleation of fellow eyes, 2.5 mg/kg Ga/DFO was injected intravenously 5 min before reperfusion. The flux of hydroxyl radicals, as measured directly by conversion of salicylate to 2,3- and 2,5-dihydroxybenzoic acid (2,3- and 2,5-DHBA), was significantly lower in Ga/DFO-treated eyes. The mean normalized level of 2,3-DHBA (considered a specific marker of hydroxyl radicals) was 3.5 times higher in untreated eyes. Ga/DFO caused a significant reduction, by 2.56-fold, in lipid peroxidation, as reflected by levels of malondialdehyde. Ascorbic acid, a natural antioxidant present in the retina, is severely depleted in untreated eyes. In contrast, in Ga/DFO-treated eyes, levels were 10 times higher than the control. Energy charge was 2.38 times higher in treated eyes. Levels of purine catabolites (hypoxanthine, xanthine, and uric acid) that reflect excessive metabolism of purine nucleotides were approximately twice higher in untreated retinas. Electroretionographic studies, performed on a different subset of animals, substantiated the biochemical results. In Ga/DFO-treated eyes the amplitude of the mixed cone-rod response b-wave (as compared with fellow nonischemic eyes) fully recovered within 24 h after ischemia (b-wave ratio 1.04 +/- 0.09, [mean +/- SEM]) whereas ischemic/reperfused and nontreated eyes recovered to only 0.33 +/- 0. 05. The results show that severe biochemical and functional retinal injury occurs in cat eyes subjected to ischemia and reperfusion. These severe changes were significantly reduced by a single administration of Ga/DFO just before reperfusion. We hypothesize that the protection afforded by Ga/DFO is due to a combined effect of "Push-Pull" mechanisms interfering with transition metal-dependent and free radical-mediated injurious processes.

Protection by desferrioxamine and other hydroxamic acids against tetrachlorohydroquinone-induced cyto- and genotoxicity in human fibroblasts.

Tetrachlorohydroquinone (TCHQ) has been identified as a major toxic metabolite of the widely used wood preservative pentachlorophenol and has also been implicated in its genotoxicity. We have recently demonstrated that protection by the trihydroxamate iron chelator desferrioxamine (DFO) on TCHQ-induced single-strand breaks in isolated DNA was not the result of its chelation of iron but rather of its efficient scavenging of the reactive tetrachlorosemiquinone (TCSQ) radical. In this study, we extended our research from isolated DNA to human fibroblasts. We found that DFO provided marked protection against both the cyto- and genotoxicity induced by TCHQ in human fibroblasts when it was incubated simultaneously with TCHQ. Pretreatment of the cells with DFO followed by washing also provided marked protection, although less efficiently compared with the simultaneous treatment. Similar patterns of protection were also observed for three other hydroxamic acids (HAs): aceto-, benzo-, and salicylhydroxamic acid. Dimethyl sulfoxide, an efficient hydroxyl radical scavenger, provided only partial protection even at high concentrations. In vitro studies showed that the HAs tested effectively scavenged the reactive TCSQ radical and enhanced the formation of the less reactive and less toxic 2,5-dichloro-3, 6-dihydroxy-1,4-benzoquinone (chloranilic acid). The results of this study demonstrated that the protection provided by DFO and other HAs against TCHQ-induced cyto- and genotoxicity in human fibroblasts is mainly through scavenging of the observed reactive TCSQ radical and not through prevention of the Fenton reaction by the binding of iron in a redox-inactive form.

The protective role of neocuproine against cardiac damage in isolated perfused rat hearts.

The effect of neocuproine on cardiac injury was studied using retrogradely perfused isolated rat hearts in two experimental systems. In the first system, where hydrogen peroxide-induced damage was studied, neocuproine at the range of 40-175 microM provided protection at the level of 70-85%, as demonstrated by the reduced loss in the peak systolic pressure (P), in +dP/dt and in -dP/dt. In the second system, where ischemia/reperfusion-induced arrhythmias were studied, neocuproine (42 microM) provided a marked protection against cardiac injury as demonstrated by the lowering of the incidence in irreversible ventricular fibrillation, by decreasing the duration of ventricular fibrillation and by the concomitant increase of the duration of normal sinus rhythm, and by improving the post-ischemic recovery of P, +dP/dt and -dP/dt. Free radicals have already been implicated as causative agents in cardiac injury resulting from either hydrogen peroxide or ischemia followed by reperfusion. Additionally, iron and copper have already been shown to drastically exacerbate the injurious effects of free radicals. Thus, the results reported here with neocuproine, a highly effective chelator for both iron and copper, as well as with adventitious copper and with the combination of neocuproine and copper, are in accord with the mediatory role of transition metals in enhancing the deleterious effects induced by free radicals.

Redox-active iron mediates amyloid-beta toxicity.

While amyloid-beta toxicity is mediated by oxidative stress and can be attenuated by antioxidants, the actual biochemical mechanism underlying neurotoxicity remains to be established. However, since aggregated amyloid-beta can interact with transition metals, such as iron, both in vitro and in vivo, we suspected that bound iron might be the mediator of toxicity such that holo- and apo-amyloid would have differential effects on cellular viability. Here we demonstrate that when amyloid-beta is pretreated with the iron chelator deferoxamine, neuronal toxicity is significantly attenuated while conversely, incubation of holo-amyloid-beta with excess free iron restores toxicity to original levels. These data, taken together with the known sequelae of amyloid-beta, suggest that the toxicity of amyloid-beta is mediated, at least in part, via redox-active iron that precipitates lipid peroxidation and cellular oxidative stress.

Mechanistic aspects of paraquat toxicity in E. coli. A spin trapping study.

Mechanistic aspects of paraquat monocation radical (PQ.+) and copper involvement in paraquat toxicity have been examined using E. coli B cells. Electron spin resonance (ESR) spectrometry combined with cell survival studies were used to explore the correlation between radical production and biological damage. The line broadening agent oxalato-chromiate (CrOx) was used to characterize the anoxic partition of PQ.+ inside and outside the cell. In the presence of CrOx the ESR signal was totally eliminated, indicating that intracellular species were undetectable and that, contrary to previous reports, PQ.+ exclusively accumulates outside the cell. The PQ.+ radical does not react with H2O2 but disappears in the presence of H2O2 when catalytic traces of Cu(II) are present. Spin-trapping studies using DMPO showed that in aerobic environment paraquat-induced O2 radicals are detectable exclusively in the extracellular compartment. The correlation between PQ.+ appearance and the biological damage is not simple. PQ.+ non-toxically accumulates, in the absence of oxygen and either Cu(II) or H2O2. By contrast, with both H2O2 and Cu(II) the cells are rapidly killed but PQ.+ was undetectable. These results reconfirm the key catalytic mediatory function of transition metals in paraquat toxicity.

Inhibition of purified soluble guanylyl cyclase by copper ions.

The aim of the present study was to investigate the effect of Cu(II) ions on soluble guanylyl cyclase [GTP pyrophosphate-lyase (cyclizing), EC 4.6.1.2; sGC] and to test for a possible physiological role of this putative cofactor of the enzyme [Gerzer et al., FEBS Lett. 132: 71-74, 1981]. CuSO4 was found to inhibit NO-stimulated 5GC with an IC50 of 2.2 +/- 0.3 microM. Virtually complete inhibition of guanosine-3',5'-cyclic monophosphate (cGMP) formation was observed at 10 microM of the copper salt. Presence of CuSO4 (2 microM) did not significantly affect the potency of 2,2-diethyl-1-nitroso-oxyhydrazine (DEA/NO) but did markedly decrease maximal cyclase activity from 3.71 +/- 0.2 mumol cGMP x mg-1 x min-1 to 1.75 +/- 0.2 mumol cGMP x mg-1 x min-1. The nonstimulated enzyme was also sensitive to CuSO4 (IC50 of 6.2 +/- 1.2 microM). Addition of glutathione, which potently complexes Cu(I) ions, induced a pronounced rightward shift of the concentration-response curves for inhibition by CuSO4 of both DEA/NO-stimulated and nonstimulated guanylyl cyclase. The inhibitory effect of CuSO4 was completely antagonized by the specific Cu(I) chelator neocuproine, with a half-maximal effect at 5.9 +/- 0.2 microM. In contrast, the Cu(II) chelator cuprizone and several thiols, which do not form stable Cu(I) complexes, were far less protective. Our results suggest that inhibition of soluble guanylyl cyclase by CuSO4 is unrelated to heme-mediated enzyme stimulation and may arise from the reversible high affinity binding of Cu(I) ions to a site of the protein that is critically involved in enzyme catalysis.

Protective effects of tea polyphenols against oxidative damage to red blood cells.

Tea polyphenols (TPP) from black and green teas were evaluated for their antioxidant effects on normal red blood cells (RBC) and beta-thalassemic RBC membranes challenged with exogenous oxidants in vitro. The TPP of both types protected RBC against primaquine-induced lysis; they also protected the whole cells and the membranes against H2O2-induced lipid peroxidation so that about 80% protection was reached at [TPP] = 10 microg/mL. TPP from black tea at the same concentration protected normal RBC from morphological alterations caused by the peroxide treatment. The mechanism of the effects of TPP was investigated using a chemical system generating .OH (iron + ascorbic acid). TPP from both black and green teas inhibited the .OH fluxes in a concentration-dependent manner, indicating the possibility of iron chelation by TPP. Spectrophotometric titration revealed that TPP could stoichiometrically bind ferric iron to form a redox-inactive Fe-TPP complex. Quantitative analysis suggests that one or more major catechins from the TPP preparations are the likely iron-binding compounds accounting for the antioxidant effects of TPP on RBC.

Deleterious synergistic effects of ascorbate and copper on the development of Plasmodium falciparum: an in vitro study in normal and in G6PD-deficient erythrocytes.

The effects of ascorbate and copper on the development of Plasmodium falciparum were studied in two modes: pretreatment of uninfected erythrocytes followed by infection by P. falciparum and treatment of parasitized erythrocytes. Pretreatment of G6PD(+) cells with ascorbate caused a slight enhancement in parasite development, while in G6PD(-) cells a suppressive effect on the plasmodia was demonstrated. Copper alone interfered with parasite growth in both cell types. The combination of copper and ascorbate arrested parasite maturation, an effect which was more pronounced in G6PD(-) cells. Synergism between copper and ascorbate was better demonstrated following the treatment of infected erythrocytes: while ascorbate alone supported parasite development and copper alone had only a marginal suppressive effect, the combination of copper and ascorbate yielded a marked inhibition of parasite growth. Ascorbate proved destructive to the parasites in the presence of adventitious copper, or on the second day of the parasite life cycle. In these cases it acted as a pro-oxidant, while in other systems, in particular in the presence of a chelator, ascorbate acted as an antioxidant and promoted parasite growth. The understanding of the role of transition metals and free radicals in parasite development and injury could shed light on novel approaches to fight malaria.

The push-and-pull mechanism to scavenge redox-active transition metals: a novel concept in myocardial protection.

OBJECTIVE: Traces of redox-active transition metals such as iron and copper play an important role in free radical formation during postischemic reperfusion of the heart. Two studies were conducted to assess the efficacy of the complexes of desferrioxamine with zinc or gallium to prevent this aspect of reperfusion injury. METHODS: In study I, isolated working rat hearts (n = 96) were subjected to 2 hours of hypothermic arrest at 10 degrees C induced by use of St Thomas' Hospital cardioplegic solution II supplemented with desferrioxamine, zinc-histidinate, zinc-desferrioxamine, gallium-nitrate, or gallium-desferrioxamine. In study II, isolated nonworking rat hearts (n = 23) were subjected to normothermic regional (10 minutes) or global (35 minutes) unprotected ischemia. In this study, the perfusate was supplemented with gallium-desferrioxamine during preischemic and postischemic periods. RESULTS: In study I, the addition of desferrioxamine, zinc-histidinate, or gallium-nitrate to St Thomas' Hospital solution II improved postischemic aortic flow recovery. When the binary complexes zinc-desferrioxamine or gallium-desferrioxamine were added, however, functional recovery was further enhanced significantly. In study II, high-performance liquid chromatography analyses of tissue from postischemic hearts exposed to unsupplemented perfusate revealed a marked increase of malondialdehydes. In hearts perfused with perfusate supplemented with gallium-desferrioxamine, however, tissue malondialdehyde concentrations were significantly smaller, indicating reduced free radical formation. CONCLUSIONS: The data suggest synergistic protection by the complexes of the iron chelator desferrioxamine with zinc or gallium. The single components neutralize transition metals by 2 different but complementary push-and-pull mechanisms, thereby leading to an inhibition of metal-mediated site-specific free radical formation and improvement of postischemic cardiac function.