Direct demonstration that ferrous ion complexes of di- and triphosphate nucleotides catalyze hydroxyl free radical formation from hydrogen peroxide

Utilizing an electron paramagnetic resonance (EPR) spin-trapping technique it was demonstrated that the di- and triphosphate nucleotides of adenosine, cytidine, thymidine, and guanosine in the presence of Fe(II) catalyze hydroxyl free radical formation from H₂O₂. The triphosphate nucleotides in general were about 20% more effective than the diphosphate nucleotides. The amount of ?H produced from H₂O₂ as a function of nucleotide level tended to increase in a sigmoidal fashion beginning at a nucleotide/Fe(II) ratio of 2 but then rose rapidly up to a ratio of 5 at which point the increase became more gradual. The monophosphate nucleotides did not cause an increase in the amount of hydroxyl free radical produced from H₂O₂ over the low level obtained in the buffer system only. The cations, Mg²⁺ and Ca²⁺, even at much higher than physiological levels and much higher than the level of added Fe(II), did not cause a substantial diminution of the Fe(II)-nucleotide-catalyzed breakdown of H₂O₂ to yield ?H. A study of the time course of the effectiveness of Fe(II)-nucleotide-mediated ?H formation from H₂O₂ demonstrated that Fe(II) in the presence of nucleotides remained in an effective catalytic state with a halftime of about 160 s whereas in the absence of the nucleotides the halftime was 7.5 s. All observations indicate that Fe(II) ligates with di- and triphosphate nucleotides and remains in the ferrous state which is then capable of catalyzing ?H formation from H₂O₂; but with time, oxidation of the metal ion to the ferric state occurs, which either ligated to the nucleotide or to buffer ions, is ineffective in H₂O₂ catalysis to yield ?H. Iron-nucleotide complexes may be of importance in mediating oxygen free radical damage to biological systems. The observations presented here indicate that hydroxyl free radicals will be produced when H₂O₂ is present with ferrous-nucleotide complexes.     

The hemoglobin of the crossopterygian fish, Latimeria chalumnae (Smith). Subunit structure and oxygen equilibria

There are five oxidation-reduction states of horseradish peroxidase which are interconvertible. These states are ferrous, ferric, Compound II (ferryl), Compound I (primary compound of peroxidase and H₂O₂), and Compound III (oxy-ferrous). The presence of heme-linked ionization groups was confirmed in the ferrous enzyme by spectrophotometric and pH stat titration experiments. The values of pK were 5.87 for isoenzyme A and 7.17 for isoenzymes (B + C). The proton was released when the ferrous enzyme was oxidized to the ferric enzyme while the uptake of the proton occurred when the ferrous enzyme reacted with oxygen to form Compound III. The results could be explained by assuming that the heme-linked ionization group is in the vicinity of the sixth ligand and forms a stable hydrogen bond with the ligand.The measurements of uptake and release of protons in various reactions also yielded the following stoichiometries: Ferric peroxidase + H₂O₂ → Compound I, Compound I + e^? + H⁺ → Compound II, Compound II + e^? + H⁺ → ferric peroxidase, Compound II + H₂O₂ → Compound III, Compound III + 3e^? + 3H⁺ → ferric peroxidase.Based on the above stoichiometries and assuming the interaction between the sixth ligand and heme-linked ionization group of the protein, it was possible to picture simple models showing structural relations between five oxidation-reduction states of peroxidase. Tentative formulae are as follows: [Pr·Po·Fe-(II) $\text{\$}\text{?}$PrH⁺·Po·Fe(II)] is for the ferrous enzyme, Pr·Po·Fe(III)OH₂ for the ferric one, Pr·Po·Fe(IV)OH^? for Compound II, Pr(OH^?)·Po⁺·Fe(IV)OH^? for Compound I, and PrH⁺·Po·Fe(III)O₂^? for Compound III, in which Pr stands for protein and Po for porphyrin. And by Fe(IV)OH^?, for instance, is meant that OH^? is coordinated at the sixth position of the heme iron and the formal oxidation state of the iron is four.     

Acyl-CoA oxidase of rat liver: A new enzyme for fatty acid oxidation

Acyl-CoA oxidase was purified from rat liver based on the palmitoyl-CoA-dependent H₂O₂-forming activity. Enoyl-CoA formation from palmitoyl-CoA by this enzyme was shown by the following observations; first, palmitoyl-CoA-dependent NAD⁺ reduction in the presence of this enzyme, crotonase, and 3-hydroxyacyl-CoA dehydrogenase, and, second, palmitoyl-CoA-dependent increase in absorbance at 263 nm. Same amounts of enoyl-CoA and H₂O₂ were formed during the reaction. It is concluded that this enzyme catalyzes the following reaction: Palmitoyl-CoA + O₂ → $\text{transm}$-2-Hexadecenoyl-CoA + H₂O₂. It was most active toward C₁₂-C₁₈ acyl-CoAs. C₂₀ and C₂₂ acyl-CoAs were also oxidized, but C₄ and C₆ acyl-CoAs were hardly oxidized at all.     

Nitric oxide alleviates Fe deficiency-induced stress in Solanum nigrum

The possible involvement of nitric oxide in response of Solanum nigrum seedlings to Fe deficiency was investigated. Iron deficiency resulted in decreased shoot height and chlorophyll content and increased proliferation of root hairs and H₂O₂, K⁺ and Ca²⁺ content. NO donor S-nitrosoglutathione (GSNO) was effective in preventing Fe deficiency-induced increase in content of H₂O₂ and the ion uptake. The protective effects of GSNO were reversed by cPTIO, an NO scavenger, and tungstate, a nitrate reductase (NR) inhibitor.     

A chemiluminescent method for measurement of activated oxygen forms in biological fluids and homogenates

A chemiluminescent method for measuring the concentration of activated oxygen species (O₂² and H₂O₂) is described. Its main features are: high sensitivity (10^?9 M H₂O₂), its applicability to systems with high optical absorbance in the visible spectral region, a wide linear dynamic range, and the possibility for recording the kinetics of the processes, in which activated oxygen species are involved.     

Factors affecting the determination of total mercury in biological samples by continuous-flow cold vapor atomic absorption spectrophotometry

The acidic reduction of Hg using a continuous-flow analytical system was evaluated. With 25% SnCl₂ as the reductant, characteristic concentrations (sensitivities) of 0.44 μg/L (open cell) and 0.29 μg/L (flow-through cell) were obtained using inorganic Hg²⁺ standards in 1.5% HCl. When CH₃Hg⁺ standards were used, absorption signals were an order of magnitude lower, indicating that Sn(II) is incapable of producing Hg° from organic Hg in this acidic reduction system. Addition of CdCl₂ to the SnCl₂ reductant, as suggested by Magos (1) for the reduction of organomercurials under alkaline conditions, was without beneficial effect. Similarly, combining Sn, with another reducing agent (hydroxylamine hydrochloride), or a strong alkaline solution (40% NaOH), in the reaction coil of the flow-through system did not significantly enhance the Hg absorption signal for either inorganic or organic Hg. Recovery of Hg from spiked liver homogenates digested at 70–80°C using a HNO₃/H₂SO₄/HCl procedure and stabilized with 0.5 mM K₂Cr₂O₇ was >85%, using either inorganic Hg²⁺ or CH₃Hg⁺, indicating that this digestion procedure successfully breaks the C-Hg bond to form readily reducible Hg species. Usingl-cysteine to stabilize standards of inorganic Hg²⁺ in HCl caused significant depressions of the Hg absorption signal atl-cysteine concentrations >0.001% (≈0.5 mM); 0.1%l-cysteine caused total suppression of the Hg signal. These results indicate that: (1) acidic reduction of Hg by Sn in this continuous-flow system requires breakdown of organomercurials prior to analysis; (2) tissue digestion using HNO₃/H₂SO₄/HCl followed by the addition of K₂Cr₂O₇ to stabilize Hg²⁺ achieves this breakdown and allows good recovery of total Hg; and (3) use ofl-cysteine to complex and prevent losses of Hg should be avoided in systems using acidic reduction of Hg. Concentrations of endogenous tissue sulfhydryls are generally lower than those associated with depressed absorbance signals during the acidic reduction of Hg.     

Impact of hydrogen peroxide-driven Fenton reaction on mouse oocyte quality

Here we show that hydroxyl radical ^(•OH) generated through the Fenton reaction alters metaphase-II mouse oocyte microtubules (MT) and chromosomal alignment (CH). Metaphase-II mouse oocytes, obtained commercially, were grouped as follows: control, hydrogen peroxide (H₂O₂), Fe(II), and combined (Fe(II) +H₂O₂) treatments. After 7–10 min of incubation at 37 °C, MT and CH were evaluated on fixed and stained oocytes and scored by two blinded observers. Pearson χ² test and Fisher exact test were used to compare outcomes between controls and treated groups and also among the treated groups. Our results showed that poor scores for MT and CH increased significantly in oocytes treated with a combination of H₂O₂ and Fe(II) (p<0.001); oocytes treated with H₂O₂ alone or Fe(II) alone showed no or few changes compared to control. Comparison of oocyte groups that received increasing concentrations of H₂O₂ and a fixed amount of Fe(II) showed that 70–80% demonstrated poor scores in both MT and CH when pretreated with 5 μM H₂O₂, and this increased up to 90–100% when treated with 10–20 μM H₂O₂. Hydroxyl radical generated by H₂O₂-driven Fenton reaction deteriorates the metaphase-II mouse oocyte spindle and CH alignment, which is thought to be a potential cause of poor oocyte quality. Thus, free iron and/or ROS scavengers could attenuate the ^•OH-mediated spindle and chromosomal damage, thereby serving as a possible approach for further examination as a therapeutic option in inflammatory states.     

Generation of active oxygen species during enzymic isolation of protoplasts from oat leaves

Summary Protoplasts were isolated from oat (Avena sativa L.) leaves by the combination of highly purified preparations of pectin lyase, xylanase, and cellulase C₁. During the enzymic isolation, superoxide radical (O ₋ ² ) was generated from the tissues. Both the protoplasts themselves and the cell walls, exposed to enzyme treatment, produced O ₋ ² . Hydrogen peroxide (H₂O₂) apparently accumulated in the reaction mixture due to the spontaneous dismutation reaction of O ₋ ² , while a part of H₂O₂ may have been produced directly from cell walls by the action of enzymes. Singlet molecular oxygen (¹O₂) generated in the reaction mixture was detected by cholesterol oxidation in small unilamellar liposomes. It seems likely that¹O₂ may be generated by the peroxidase-H₂O₂-halide system during enzymic treatment of the leaves. The work was partially supported by the Research Project “Research and development of the improvement of bacterial and plant cells by cell fusion” of the Food and Agriculture Research and Development Association (Japan).     

Hydrogen peroxide depolarizes mitochondria and inhibits IP3-evoked Ca2+ release in the endothelium of intact arteries

Hydrogen peroxide (H₂O₂) is a mitochondrial-derived reactive oxygen species (ROS) that regulates vascular signalling transduction, vasocontraction and vasodilation. Although the physiological role of ROS in endothelial cells is acknowledged, the mechanisms underlying H₂O₂ regulation of signalling in native, fully-differentiated endothelial cells is unresolved. In the present study, the effects of H₂O₂ on Ca²⁺ signalling were investigated in the endothelium of intact rat mesenteric arteries. Spontaneous local Ca²⁺ signals and acetylcholine evoked Ca²⁺ increases were inhibited by H₂O₂. H₂O₂ inhibition of acetylcholine-evoked Ca²⁺ signals was reversed by catalase. H₂O₂ exerts its inhibition on the IP₃ receptor as Ca²⁺ release evoked by photolysis of caged IP₃ was supressed by H₂O₂. H₂O₂ suppression of IP₃-evoked Ca²⁺ signalling may be mediated by mitochondria. H₂O₂ depolarized mitochondria membrane potential. Acetylcholine-evoked Ca²⁺ release was inhibited by depolarisation of the mitochondrial membrane potential by the uncoupler carbonyl cyanide 3-chlorophenylhydrazone (CCCP) or complex 1 inhibitor, rotenone. We propose that the suppression of IP₃-evoked Ca²⁺ release by H₂O₂ arises from the decrease in mitochondrial membrane potential. These results suggest that mitochondria may protect themselves against Ca²⁺ overload during IP₃-linked Ca²⁺ signals by a H₂O₂ mediated negative feedback depolarization of the organelle and inhibition of IP₃-evoked Ca²⁺ release.     

Abatement of Sorbed Crude Oil by Heterogeneous Fenton Process Using A Contaminated Soil Pre-Impregnated with Dissolved Fe(II) and Humic Acid

Dissolved Fe(II) and humic acid (HA) were pre-impregnated into contaminated soil to catalyze hydrogen peroxide to remove crude oil (CO). The effects of parameters such as initial Fe(II), HA and H₂O₂ concentrations on the oxidation of total petroleum hydrocarbon (TPH) were investigated using response surface methodology based on Box–Behnken design. The rate of hydrogen peroxide decomposition is decreased by pre-impregnating with dissolved Fe(II) + HA compared with only pre-impregnated Fe(II) and modified Fenton (MF). Oxygen evolution is the predominant route of hydrogen peroxide decomposition at natural pH. Unlike O₂ evolution, the kinetics of hydroxyl radical (OH^?) production are clearly uncoupled from H₂O₂ decay in these systems. The steady-state hydroxyl radical production rate is higher in the systems with pre-impregnated dissolved Fe(II) and HA, and more significance is the decrease in detectable TPH (70.84% removal efficiency) when soil is pre-impregnated with dissolved 25 mM Fe(II) + 0.7 mg/mL HA, and with the application of 700 mM H₂O₂, possibly due to hydrogen peroxide catalyzed by the iron of this complex (CO-HA–Fe(II)) producing hydroxyl radical in close proximity to the CO. Meanwhile, the removal efficiency of C₂₁–C₃₀ is up to 65.69%, which is 2.6 times higher than that of the MF (25.52%).     

Relationship between NaCl- and H2O2-Induced Cytosolic Ca2+ Increases in Response to Stress in Arabidopsis

Salinity is among the environmental factors that affect plant growth and development and constrain agricultural productivity. Salinity stress triggers increases in cytosolic free Ca²⁺ concentration ([Ca²⁺]_i) via Ca²⁺ influx across the plasma membrane. Salinity stress, as well as other stresses, induces the production of reactive oxygen species (ROS). It is well established that ROS also triggers increases in [Ca²⁺]_i. However, the relationship and interaction between salinity stress-induced [Ca²⁺]_i increases and ROS-induced [Ca²⁺]_i increases remain poorly understood. Using an aequorin-based Ca²⁺ imaging assay we have analyzed [Ca²⁺]_i changes in response to NaCl and H₂O₂ treatments in Arabidopsis thaliana. We found that NaCl and H₂O₂ together induced larger increases in [Ca²⁺]_i in Arabidopsis seedlings than either NaCl or H₂O₂ alone, suggesting an additive effect on [Ca²⁺]_i increases. Following a pre-treatment with either NaCl or H₂O₂, the subsequent elevation of [Ca²⁺]_i in response to a second treatment with either NaCl or H₂O₂ was significantly reduced. Furthermore, the NaCl pre-treatment suppressed the elevation of [Ca²⁺]_i seen with a second NaCl treatment more than that seen with a second treatment of H₂O₂. A similar response was seen when the initial treatment was with H₂O₂; subsequent addition of H₂O₂ led to less of an increase in [Ca²⁺]_i than did addition of NaCl. These results imply that NaCl-gated Ca²⁺ channels and H₂O₂-gated Ca²⁺ channels may differ, and also suggest that NaCl- and H₂O₂-evoked [Ca²⁺]_i may reduce the potency of both NaCl and H₂O₂ in triggering [Ca²⁺]_i increases, highlighting a feedback mechanism. Alternatively, NaCl and H₂O₂ may activate the same Ca²⁺ permeable channel, which is expressed in different types of cells and/or activated via different signaling pathways.     

Electrochemical detection of natural DNA damage induced by ferritin/ascobic acid/H2O2 system and amplification of DNA damage by endonuclease Fpg

Oppositely charged natural DNA and chitosan (CS) were assembled into (CS/DNA)_n layer-by-layer films on electrode surface, and Ru(bpy)₃²⁺ (bpy = bipyridyl) in solution was used as electroactive catalyst to detect damage of DNA in the films after incubation of the films in ferritin/AA/H₂O₂ solutions (AA = ascorbic acid). The mechanism of DNA damage caused by the ferritin/AA/H₂O₂ system was similar to that of Fenton reaction, where the reaction of ferritin with AA would release some Fe(II) ions from ferritin and the following reaction between Fe(II) ions and H₂O₂ would produce hydroxyl radical, which could induce DNA oxidative damage. This system provided an in vitro model to imitate the DNA damage indirectly induced by ferritin in real bio-systems. In addition, formamidopyrimidine DNA glycosylase (Fpg), a key endonuclease enzyme in repair of oxidatively damaged DNA, was used to amplify the DNA damage caused by ferritin/AA/H₂O₂ system through conversion of oxidative purine bases into single-strand breaks. The high sensitivity of electrocatalytic method with Ru(bpy)₃²⁺ as the catalyst in detection of DNA damage and the magnification function of Fpg may provide a novel idea to detect natural DNA lesion sensitively.     

H2O2 in plant peroxisomes: an in vivo analysis uncovers a Ca2+‐dependent scavenging system

Oxidative stress is a major challenge for all cells living in an oxygen‐based world. Among reactive oxygen species, H₂O₂, is a well known toxic molecule and, nowadays, considered a specific component of several signalling pathways. In order to gain insight into the roles played by H₂O₂ in plant cells, it is necessary to have a reliable, specific and non‐invasive methodology for its in vivo detection. Hence, the genetically encoded H₂O₂ sensor HyPer was expressed in plant cells in different subcellular compartments such as cytoplasm and peroxisomes. Moreover, with the use of the new green fluorescent protein (GFP)‐based Cameleon Ca²⁺ indicator, D3cpv–KVK–SKL, targeted to peroxisomes, we demonstrated that the induction of cytoplasmic Ca²⁺ increase is followed by Ca²⁺ rise in the peroxisomal lumen. The analyses of HyPer fluorescence ratios were performed in leaf peroxisomes of tobacco and pre‐ and post‐bolting Arabidopsis plants. These analyses allowed us to demonstrate that an intraperoxisomal Ca²⁺ rise in vivo stimulates catalase activity, increasing peroxisomal H₂O₂ scavenging efficiency.     

Association of redox-active iron bound to high molecular weight structures in nuclei with inhibition of cell growth by H2O2

Perturbations to Fe species contributing to generation of DNA single-strand breaks (SSBs) and inhibition of growth by H₂O₂ were studied in HL-60 cells made Fe-deficient by 24 h pretreatment with 144 μM bathophenanthroline disulfonic acid and 400 μM ascorbic acid (Free Radic. Biol. Med. 20: 399; 1996). The diffusion distance for SSB generation (d) in Fe-deficient cells, measured via inhibition with the ^0OH scavenger Me₂SO using alkaline elution, was 6.5 nm. This is similar to the d for Fe-normal cells reported previously. After 1 and 3 h in fresh RPMI 1640 medium containing 10% serum, SSB generation increased from 29 to 56 and 93% of control Fe-normal cells, respectively. The d of the major contributor to SSB generation at these two treatment times was 1.9 nm. This d resembled the d for Fe-ATP as determined in isolated Ehrlich cell nuclei. The association of ATP with Fe²⁺ was further supported by decreased SSB generation in cells in which ATP synthesis was inhibited. In contrast to SSB generation, H₂O₂-induced inhibition of growth of Fe-deficient cells treated immediately after placing in fresh medium was not appreciably different from Fe-normal cells. However, after 3 h, an approximately 70% greater concentration of H₂O₂ than for control, Fe-normal cells was required to inhibit growth. This increase in H₂O₂ concentration was associated with decreased generation of SSBs by H₂O₂ in isolated HL-60 cell nuclei. Thus, Fe bound to nuclear structures is more closely associated with inhibition of cell growth than apparent Fe-ATP species. In parallel experiments, changes in total cellular Fe assayed by ashing and complexing with ferrozine were consistent with a non-transferrin mode of acquisition. These short-term changes appear due to processes accompanying reestablishment of the Fe content and distribution normally observed during long-term growth.     

Visualization of the microbody division inCyanidioschyzon merolae with the fluorochrome brilliant sulfoflavin

Summary A novel procedure is described for fluorescence staining of microbodies, which can be applied quickly and easily. We developed this technique of microbody staining with the unicellular red algaCyanidioschyzon merolae. Cyanidioschyzon merolae only contains a single chloroplast, mitochondrion, and microbody per cell, and the mitotic cycle and the organelle division cycle are easily synchronized. Knowing that the concentration of H₂O₂ in the microbody is higher than it is in the cytosol and other cell components, we attempted to visualize the microbody by using fluorescence microscopy to detect H₂O₂. Brilliant sulfoflavin (BSF), used for detecting Fe²⁺ in analytical chemistry, fluoresces when it reacts with Fe²⁺ and H₂C₂. We were able to specifically stain microbodies with BSF, under acidic conditions (pH 3.0 or pH 2.5) with blue-light excitation. Using this procedure, we observed division of the microbody and the effect of aphidicolin on the microbody. We also discovered that microbody division is regulated by the cell nucleus and follows division of the cell nucleus.     

Sensitization of H2O2-induced TRPM2 activation and subsequent interleukin-8 (CXCL8) production by intracellular Fe2+ in human monocytic U937 cells

Transient receptor potential melastatin 2 (TRPM2) is an oxidative stress-sensitive Ca²⁺-permeable channel. In monocytes/macrophages, H₂O₂-induced TRPM2 activation causes cell death and/or production of chemokines that aggravate inflammatory diseases. However, relatively high concentrations of H₂O₂ are required for activation of TRPM2 channels in vitro. Thus, in the present study, factors that sensitize TRPM2 channels to H₂O₂ were identified and subsequent physiological responses were examined in U937 human monocytes. Temperature increase from 30 °C to 37 °C enhanced H₂O₂-induced TRPM2-mediated increase in intracellular free Ca²⁺ ([Ca²⁺]_i) in TRPM2-expressing HEK 293 cells (TRPM2/HEK cells). The H₂O₂-induced TRPM2 activation enhanced by the higher temperature was dramatically sensitized by intracellular Fe²⁺-accumulation following pretreatment with FeSO₄. Thus intracellular Fe²⁺-accumulation sensitizes H₂O₂-induced TRPM2 activation at around body temperature. Moreover, intracellular Fe²⁺-accumulation increased poly(ADP-ribose) levels in nuclei by H₂O₂ treatment, and the sensitization of H₂O₂-induced TRPM2 activation were almost completely blocked by poly(ADP-ribose) polymerase inhibitors, suggesting that intracellular Fe²⁺-accumulation enhances H₂O₂-induced TRPM2 activation by increase of ADP-ribose production through poly(ADP-ribose) polymerase pathway. Similarly, pretreatment with FeSO₄ stimulated H₂O₂-induced TRPM2 activation at 37 °C in U937 cells and enhanced H₂O₂-induced ERK phosphorylation and interleukin-8 (CXCL8) production. Although the addition of H₂O₂ to cells under conditions of intracellular Fe²⁺-accumulation caused cell death, concentration of H₂O₂ required for CXCL8 production was lower than that resulting in cell death. These results indicate that intracellular Fe²⁺-accumulation sensitizes TRPM2 channels to H₂O₂ and subsequently produces CXCL8 at around body temperature. It is possible that sensitization of H₂O₂-induced TRPM2 channels by Fe²⁺ may implicated in hemorrhagic brain injury via aggravation of inflammation, since Fe²⁺ is released by heme degradation under intracerebral hemorrhage.     

The lactate-dependent enhancement of hydroxyl radical generation by the Fenton reaction

The effect of lactic acid (lactate) on Fenton based hydroxyl radical (^·OH) production was studied by spin trapping, ESR, and fluorescence methods using DMPO and coumarin-3-carboxylic acid (3-CCA) as the ^·OH traps respectively. The ^·OH adduct formation was inhibited by lactate up to 0.4mM (lactate/iron stoichiometry = 2) in both experiments, but markedly enhanced with increasing concentrations of lactate above this critical concentration. When the H₂O₂ dependence was examined, the DMPO-OH signal was increased linearly with H₂O₂ concentration up to 1 mM and then saturated in the absence of lactate. In the presence of lactate, however, the DMPO-OH signal was increased further with higher H₂O₂ concentration than 1 mM, and the saturation level was also increased dependent on lactate concentration. Spectroscopic studies revealed that lactate forms a stable colored complex with Fe³⁺ at lactate/Fe³⁺ stoichiometry of 2, and the complex formation was strictly related to the DMPO-OH formation. The complex formation did not promote the H₂O₂ mediated Fe³⁺ reduction. When the Fe³⁺-lactate (1:2) complex was reacted with H₂O₂, the initial rate of hydroxylated 3-CCA formation was linearly increased with H₂O₂ concentrations. All the data obtained in the present experiments suggested that the Fe³⁺-lactate (1:2) complex formed in the Fenton reaction system reacts directly with H₂O₂ to produce additional ^·OH in the Fenton reaction by other mechanisms than lactate or lactate/Fe³⁺ mediated promotion of Fe³⁺/Fe²⁺ redox cycling.     

Ca<Superscript>2+</Superscript> and CaM are Involved in NO- and H<Subscript>2</Subscript>O<Subscript>2</Subscript>-Induced Adventitious Root Development in Marigold

Our previous results have demonstrated that both nitric oxide (NO) and hydrogen peroxide (H₂O₂) are involved in the promotion of adventitious root development in marigold (Tagetes erecta L.). However, not much is known about the intricate molecular network of adventitious root development triggered by NO and H₂O₂. In this study, the involvement of calcium (Ca²⁺) and calmodulin (CaM) in NO- and H₂O₂-induced adventitious rooting in marigold was investigated. Exogenous Ca²⁺ was capable of promoting adventitious rooting, with a maximal biological response at 50 μM CaCl₂. Ca²⁺ chelators and CaM antagonists prevented NO- and H₂O₂-induced adventitious rooting, indicating that both endogenous Ca²⁺ and CaM may play crucial roles in the adventitious rooting induced by NO and H₂O₂. NO and H₂O₂ treatments increased the endogenous content of Ca²⁺ and CaM, suggesting that NO and H₂O₂ enhanced adventitious rooting by stimulating the endogenous Ca²⁺ and CaM levels. Moreover, treatment with Ca²⁺ enhanced the endogenous levels of NO and H₂O₂. Additionally, Ca²⁺ might be involved as an upstream signaling molecule for CaM during NO- and H₂O₂-induced rooting. Altogether, the results suggest that both Ca²⁺ and CaM are two downstream signaling molecules in adventitious rooting induced by NO and H₂O₂.     

Electrochemical detection of extracellular hydrogen peroxide in Arabidopsis thaliana: a real‐time marker of oxidative stress

An electrochemical approach to directly measure the dynamic process of H₂O₂ release from cultures of Arabidopsis thaliana cells is reported. This approach is based on H₂O₂ oxidation on a Pt electrode in conjunction with continuous measurement of sample pH. For [H₂O₂] <1 mm , calibration plots were linear and the amperometric response of the electrode was maximum at pH 6. At higher concentrations ([H₂O₂] >1 mm ), the amperometric response can be described by Michaelian‐type kinetics and a mathematical expression relating current intensity and pH was obtained to quantitatively determine H₂O₂ concentration. At pH 5.5, the detection limit of the sensor was 3.1 µm (S/N = 3), with a response sensitivity of 0.16 Am ^?1 cm^?2 and reproducibility was within 6.1% in the range 1–5 × 10^?3 m (n = 5). Cell suspensions under normal physiological conditions had a pH between 5.5–5.7 and H₂O₂ concentrations in the range 7.0–20.5 µm (n = 5). The addition of exogenous H₂O₂, as well as other potential stress stimuli, was made to the cells and the change in H₂O₂ concentration was monitored. This real‐time quantitative H₂O₂ analysis is a potential marker for the evaluation of oxidative stress in plant cell cultures.     

Differential effects of superoxide,hydrogen peroxide,and hydroxyl radical on intracellular calcium in human endothelial cells

Changes in intracellular Ca²⁺ homeostasis are thought to contribute to cell dysfunction in oxidative stress. The hypoxanthine-xanthine oxidase system (X-XO) mobilizes Ca²⁺ from intracellular stores and induces a marked rise in cytosolic calcium in different cell types. To identify the reactive O₂ species involved in the disruption of calcium homeostasis by X-XO, we studied the effect of X-XO on [Ca²⁺]_i by spectrofluorimetry with fura-2 in human umbilical vein endothelial cells (HUVEC). The [Ca²⁺]_i response to X-XO was essentially diminished by superoxide dismutase (SOD) (200 U/ml) and catalase (CAT) (200 U/ml), which scavenge the superoxide anion, O₂^?, or H₂O₂, respectively. The [Ca²⁺]_i increase stimulated by 10 nmol H₂O₂/ml/min, generated from the glucose-glucose oxidase system, or 10 μM H₂O₂, given as bolus, was about a third of that induced by X-XO (10 nmol O₂^?/ml/min) but was comparable to that induced by X-XO in the presence of SOD. The X-XO—stimulated [Ca²⁺]_i increase was significantly reduced by 100 μM o-phenanthroline, which inhibits the iron-catalysed formation of the hydroxyl radical. On the other hand, the [Ca²⁺]_i response to low dose X-XO (1 nmol O₂^?/ml/min) was markedly enhanced in the presence of 1 μM H₂O₂, which itself had no effect on [Ca²⁺]_i. More than 50% of this synergistic effect was prevented by o-phenanthroline. These results indicate that the effect of X-XO on calcium homeostasis appears to result from an interaction of O₂^? and H₂O₂, which could be explained by the formation of the hydroxyl radical. © 1995 Wiley-Liss, Inc.