Biphasic effect of nitric oxide on the cardiac voltage-dependent anion channel

Nitric oxide (NO) effects on the cardiac mitochondrial voltage-dependent anion channel (VDAC) are unknown. The effects of exogenous NO on VDAC purified from rat hearts were investigated in this study. When incorporated into lipid bilayers, VDAC was inhibited directly by an NO donor, PAPA NONOate, in a concentration-dependent biphasic manner. This was prevented by an NO scavenger, 2-phenyl-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide. The effect paralleled that of NO in delaying the opening of the mitochondrial permeability transition (PT) pore. These biphasic effects on the cardiac VDAC and the mitochondrial PT pore reveal a tandem impact of NO on the two mitochondrial entities.     

Kinetics of reduction of tyrosine phenoxyl radicals by glutathione

Modification of tyrosine (TyrOH) is used as a marker of oxidative and nitrosative stress. 3,3′-Dityrosine formation, in particular, reflects oxidative damage and results from the combination of two tyrosyl phenoxyl radicals (TyrO). This reaction is in competition with reductive processes in the cell which ‘repair’ tyrosyl radicals: possible reductants include thiols and ascorbate. In this study, a rate constant of 2 × 10⁶ M⁻¹ s⁻¹ was estimated for the reaction between tyrosyl radicals and glutathione (GSH) at pH 7.15, generating the radicals by pulse radiolysis and monitoring the tyrosyl radical by kinetic spectrophotometry. Earlier measurements have suggested that this ‘repair’ reaction could be an equilibrium, and to investigate this possibility the reduction (electrode) potential of the (TyrO,H⁺/TyrOH) couple was reinvestigated by observing the fast redox equilibrium with the indicator 2,2′-azinobis(3-ethylbenzothiazoline-6-sulphonate). Extrapolation of the reduction potential of TyrO measured at pH 9–11 indicated the mid-point reduction potential of the tyrosyl radical at pH 7, E_m7(TyrO,H⁺/TyrOH) = 0.93 ± 0.02 V. This is close to the reported reduction potential of the glutathione thiyl radical, E_m7 = 0.94 ± 0.03 V, confirming the ‘repair’ equilibrium constant is of the order of unity and suggesting that efficient reduction of TyrO by GSH might require removal of thiyl radicals to move the equilibrium in the direction of repair. Loss of thiyl radicals, facilitating repair of TyrO, can arise either via conjugation of thiyl with thiol/thiolate or oxygen, or unimolecular transformation, the latter important at low concentrations of thiols and oxygen.     

Zeolites are effective ROS-scavengers in vitro

We report on the use of zeolites to limit the effects of reactive oxygen species (ROS) on human albumin under in vitro conditions. Zeolites of different structure type, channel size, channel polarity, and charge-compensating cation were screened for the elimination of ROS, notably HO, resulting from the Fenton reaction. A test based on ischemia-modified albumin (IMA) was used as a marker to monitor the activity of HO after co-exposure of human serum to these zeolites. Two commercial zeolites, faujasite (FAU 13×, channel opening 0.74 × 0.74 nm with Na⁺ as charge-compensating cation) and ferrierite (FER, channel opening 0.54 × 0.42 nm with H⁺ as charge-compensating cation), were found to reduce IMA formation by more than 65% due to removal of HO relative to reference values. It was established that partial ion exchange of the zeolites’ respective charge-compensating cation vs. Fe³⁺ implicated in the Fenton reaction plays a major role in HO deactivation process. Moreover, our results show that no saturation of the respective zeolite active sites occurred. This is possible only when ROS are actively converted to water molecules within the zeolite void system, which generates H⁺ ion transport.Because zeolites cannot be administered in blood, their use in medicine should be limited to extra corporeal circuits. Zeolites could be of use during cardiopulmonary bypass or hemodialysis procedures.     

In vivo real-time measurement of superoxide anion radical with a novel electrochemical sensor

The dynamics of superoxide anion (O₂⁻) in vivo remain to be clarified because no appropriate method exists to directly and continuously monitor and evaluate O₂⁻ in vivo. Here, we establish an in vivo method using a novel electrochemical O₂⁻ sensor. O₂⁻ generated is measured as a current and evaluated as a quantified partial value of electricity (Q_part), which is calculated by integration of the difference between the baseline and the actual reacted current. The accuracy and efficacy of this method were confirmed by dose-dependent O₂⁻ generation in xanthine–xanthine oxidase in vitro in phosphate-buffered saline and human blood. It was then applied to endotoxemic rats in vivo. O₂⁻ current began to increase 1 h after lipopolysaccharide, and Q_part increased significantly for 6 h in endotoxemic rats, in comparison to sham-treated rats. These values were attenuated by superoxide dismutase. The generation and attenuation of O₂⁻ were indirectly confirmed by plasma lipid peroxidation with malondialdehyde, endothelial injury with soluble intercellular adhesion molecule-1, and microcirculatory dysfunction. This is a novel method for measuring O₂⁻ in vivo and could be used to monitor and treat the pathophysiology caused by excessive O₂⁻ generation in animals and humans.     

Production of superoxides and nitric oxide generation in haemocytes of mussel Mytilus galloprovincialis (Lmk.) after exposure to cadmium: A possible involvement of Na/H exchanger in the induction of cadmium toxic effects

The present study investigates cadmium (Cd) ability to enhance superoxides (O₂⁻) and nitric oxide (NO) production (as nitrites) in haemocytes of mussel Mytilus galloprovincialis as well as the possible involvement of Na⁺/H⁺ exchanger (NHE) in the induction of NADPH oxidase and NO synthase activity. PMA, a well-known PKC-mediated NADPH oxidase as well as NO synthase stimulator was also used, in order to verify Cd effects on both O₂⁻ and NO generation. According to the results of the present study, micromolar concentrations of Cd (0.05, 5, 10 and 50 μM) seemed to enhance O₂⁻ and NO generation in haemocytes of mussels. Moreover, O₂⁻ and NO generation in haemocytes exposed to Cd could be enhanced by its ability to induce reactive oxygen species (ROS) but respiratory burst activation as well. Inhibition of NO synthase with 10 μM l-NAME, significantly attenuated Cd ability to enhance O₂⁻ production and diminished NO generation, thus leading to the suggestion that Cd toxic effects, started at concentration of 50 μM, could enhance NADPH oxidase and NO synthase stimulation in haemocytes of mussels. NHE seems to play a regulatory role in the induction of either O₂⁻ or NO generation in haemocytes exposed to the metal, since its inhibition with the use of 10 μM EIPA significantly decrease both O₂⁻ and NO production. The involvement of NHE in the induction of O₂⁻ and NO generation, probably via PKC-mediated NADPH oxidase and NO synthase activation, is likely to be crucial to haemocytes exposed to heavy metals, such as Cd.     

A comparative study of antioxidative activities of cell-wall polysaccharides

Oxidative burst in plants is elicited by biotic and abiotic stressors. Analogously to some monosaccharides which act as intracellular antioxidants, cell-wall polysaccharides may be in charge of buffering free-radical production in the extracellular compartment under pronounced prooxidative settings. Although a wide range of plant polysaccharides have been examined for their antioxidative properties, this usually has not been done in a coherent and comparative manner and against biologically relevant reactive species. Here we show that different cell-wall polysaccharides, cellulose, pectin, d-galacto-d-mannan, arabinogalactan, and xylan, exhibit distinctive antioxidative activities against the hydroxyl radical (OH)-generating Fenton reaction and superoxide. We found, using an EPR spin-trapping method, that the main carriers of ‘anti-Fenton’ activity in the plant cell wall are pectin and xylan. They most likely act by binding metal ions in such a manner to allow the Fenton reaction, after which they scavenge OH. Such a mode of action is preferred by cells resulting in a safe degradation of H₂O₂. On the other hand, the polysaccharides examined showed similar superoxide scavenging capacities. We propose that plants may employ different antioxidative characteristics of polysaccharides to regulate their redox status by modifying the composition of the cell wall.     

Hydrogen peroxide- and nitric oxide-induced systemic antioxidant prime-like activity under NaCl-stress and stress-free conditions in citrus plants

We tested whether pre-treatments of roots with H₂O₂ (10 mM for 8 h) or sodium nitroprusside (SNP; 100 μM for 48 h), a donor of NO, could induce prime antioxidant defense responses in the leaves of citrus plants grown in the absence or presence of 150 mM NaCl for 16 d. Both root pre-treatments increased leaf superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidase (APX) and glutathione reductase (GR) activities, and induced related-isoform(s) expression under non-NaCl-stress conditions. When followed by salinity, certain enzymatic activities also exhibited an up-regulation in response to H₂O₂ or SNP pre-exposure. An NaCl-stress-provoked decrease in the ascorbate redox state was partially prevented by both pre-treatments, whereas the glutathione redox state under normal and NaCl-stress conditions was increased by SNP. Real-time imaging of NO production was found in vascular tissues and epidermal cells. Furthermore, NaCl-induced inhibition in OH scavenging activity and promotion of OH-mediated DNA strand cleavage was partially prevented by SNP. Moreover, NaCl-dependent protein oxidation (carbonylation) was totally reversed by both pre-treatments as revealed by quantitative assay and protein blotting analysis. These results provide strong evidence that H₂O₂ and NO elicit long-lasting systemic primer-like antioxidant activity in citrus plants under physiological and NaCl-stress conditions.     

Decreased S-nitrosation of peptide thiols in the membrane interior

It has been proposed that autoxidation of nitric oxide (NO) stimulates S-nitrosation of thiols located in the hydrophobic milieu. We tested whether thiols located in hydrophobic membranes undergo enhanced S-nitrosation in the presence of NO/O₂. The transmembrane cysteinyl peptides C₄ (AcNH-KKACALA(LA)₆KK-CONH₂) and C₈ (AcNH-KKALALACALA(LA)₃KK-CONH₂) were incorporated into dilauroylphosphatidylcholine bilayers; their location in the membrane was determined by EPR spin labeling. The peptides, C₈ and C₄, and glutathione (GSH; 300 μM) were treated with a NO donor, DEA-NONOate, and nitrosothiol formation was determined under various O₂ levels. Surprisingly, the more hydrophobic cysteinyl peptide, C₈, did not yield any S-nitrosated product compared to GSH in the aqueous phase or C₄ peptide in the liposomes in the presence of NO/O₂. These data suggest that thiols located deeply in the hydrophobic core of the membrane may be less likely to undergo S-nitrosation in the presence of NO/O₂.     

Chlorinated and brominated phosphatidylcholines are generated under the influence of the Fenton reagent at low pH-a MALDI-TOF MS study

Lipid (phospholipid) oxidation is an increasingly important research topic due to the significant physiological relevance. The Fenton reaction, i.e. the transition metal catalyzed decomposition of H₂O₂ is frequently used to generate hydroxyl radicals (HO). Lipids with unsaturated fatty acyl residues are primarily converted by HO radicals into peroxides.In contrast, chloro- and bromohydrins as well as dihalogenides are formed by the addition of HOCl or HOBr to the olefinic groups of the fatty acyl residues of lipids or under the influence of the enzyme myeloperoxidase (MPO) from Cl⁻ and H₂O₂. We will show here by using MALDI-TOF MS for product analysis that halogenated products may also be generated in the presence of the Fenton reagent, if either FeCl₂ or FeBr₂ is used. In the presence of FeSO₄, however, peroxides are exclusively generated. It will also be shown that the generation of halogen-containing products is a competing reaction with the cleavage of the double bond under generation of the corresponding aldehyde or carboxylic acid that is favored at prolonged incubation times and at elevated pH.     

Comparison of antioxidant abilities of magnolol and honokiol to scavenge radicals and to protect DNA

The antioxidant properties of magnolol and honokiol were evaluated in the experimental systems of reducing ONOO⁻ and ¹O₂, bleaching β-carotene in linoleic acid (LH) emulsion, and trapping 2,2′-azinobis(3-ethylbenzothiazoline-6-sulfonate) cationic radical (ABTS⁺) and 2,2′-diphenyl-1-picrylhydrazyl radical (DPPH), and then were applied to inhibit the oxidation of DNA induced by Cu²⁺/glutathione (GSH) and 2,2′-azobis(2-amidinopropane hydrochloride) (AAPH). Magnolol and honokiol were active to reduce ONOO⁻ and ¹O₂. Honokiol showed a little higher activity to protect LH and to inhibit Cu²⁺/GSH-induced oxidation of DNA than magnolol. In addition, honokiol exhibited higher activities to trap ABTS⁺ and DPPH than magnolol. In particular, honokiol trapped 2.5 radicals while magnolol only trapped 1.8 radicals in protecting DNA against AAPH-induced oxidation. The obtained results suggested that low antioxidant ability of magnolol may be related to the intramolecular hydrogen bond formed between di-ortho-hydroxyl groups, which hindered the hydrogen atom in hydroxyl group to be abstracted by radicals. Therefore, the antioxidant capacity of magnolol was lower than that of honokiol.     

Quantum mechanical study of antioxidative ability and antioxidative mechanism of rutin (vitamin P) in solution

A quantum mechanical approach has been used to shed light on the antioxidative mechanism for scavenging hydroxyl radicals (OH) and superoxide radicals () by rutin in the solution phase. Density-functional theory (DFT) using B₃LYP and UB₃LYP functional and split-valance 6-311+G^∗∗ basis sets were used to optimize rutin and its different radical forms. Analysis of the theoretical bond dissociation enthalpy (BDE) values for all OH sites of rutin in solution clearly shows the importance of the B-ring and the 3′-OH and 4′-OH groups in the antioxidant activity. We have also investigated the spin density of the radicals to determine the delocalization possibilities. The results of the calculations showed that the oxidation of rutin by both the hydroxyl radical and superoxide radical is an exothermic reaction. In all calculations solvent effects were considered using a polarized continuum model (PCM).     

Striatal dopamine level contributes to hydroxyl radical generation and subsequent neurodegeneration in the striatum in 3-nitropropionic acid-induced Huntington's disease in rats

We tested the hypothesis that dopamine contributes significantly to the hydroxyl radical (OH)-induced striatal neurotoxicity caused by 3-nitropropionic acid (3-NP) in a rat model of Huntington's disease. Dopamine (10–100 μM) or 3-NP (10–1000 μM) individually caused a significant increase in the generation of hydroxyl radical (OH) in the mitochondria, which was synergistically enhanced when the lowest dose of the neurotoxin (10 μM) and dopamine (100 μM) were present together. Similarly, systemic administration of l-DOPA (100–250 mg/kg) and a low dose of 3-NP (10 mg/kg) potentiated OH generation in the striatum, and the rats exhibited significant decrease in stride length, a direct indication of neuropathology. The pathology was also evident in striatal sections subjected to NeuN immunohistochemistry. The significant changes in stride length, the production of striatal OH and neuropathological features due to administration of a toxic dose of 3-NP (20 mg/kg) were significantly attenuated by treating the rats with tyrosine hydroxylase inhibitor α-methyl-p-tyrosine prior to 3-NP administration. These results strongly implicate a major contributory role of striatal dopamine in increased generation of OH, which leads to striatal neurodegeneration and accompanied behavioral changes, in 3-NP model of Huntington's disease.     

Highly hydroxylated or γ-cyclodextrin-bicapped water-soluble derivative of fullerene: The antioxidant ability assessed by electron spin resonance method and β-carotene bleaching assay

Antioxidant ability of the water-soluble derivative of fullerene (C60), prepared by high-degree hydroxylation [C60-(OH)₃₂·8H₂O] or C60/γ-cyclodextrin (1:2 mol/mol) clathrate formation [C60/(γ-CD)₂], was assessed by electron spin resonance method and β-carotene bleaching assay. These C60 derivatives have an ability to diminish a 1:2:2:1 quartet ESR spectrum attributed to hydroxyl radicals (OH) as shown by DMPO-spin trap/ESR method. Meanwhile, a singlet radical-signal different from OH-attributed signals increased in a manner dependent on concentrations of C60-(OH)₃₂·8H₂O. This might suggest that C60-(OH)₃₂·8H₂O scavenges OH owing to dehydrogenation of C60-(OH)₃₂·8H₂O, and is simultaneously oxidized to a stable radical species, which may be a dehydrogenated fullerenol radical (C60-O). Furthermore, these water-soluble derivatives of C60 suppressed fading of yellowish color characteristic of intact β-carotene in β-carotene bleaching assay. Antioxidant abilities of these derivatives were assessed as retention of yellowish color (viz absorbance at 470 nm) for 180 min. Namely, β-carotene-attributed chromaticity (% relative absorbance at 470 nm compared with the control) after 180 min was 69% for C60-(OH)₃₂·8H₂O (400 μM: C60-eq.), and 32% for C60/(γ-CD)₂ (400 μM: C60-eq.), whereas it was 6% for l(+)-ascorbic acid (400 μM) which is hydrophilic, and 85% for (±)-α-tocopherol (400 μM) which is lipophilic, respectively. Thus C60-(OH)₃₂·8H₂O and C60/(γ-CD)₂ can scavenge OH, and have a distinct antioxidative activity in the aqueous system containing linoleic acid which is abundantly contained in the cell membrane together with other unsaturated lipids. These C60 derivatives have a potential to protect the cell membrane from oxidative stress due to OH.     

Reactive oxygen-induced reactive oxygen formation during human sperm capacitation

Physiological processes are often activated by reactive oxygen species (ROS), such as the superoxide anion (O₂^–) and nitric oxide (NO) produced by cells. We studied the interactions between NO and O₂^–, and their generators (NO synthase, NOS, and a still elusive oxidase), in human spermatozoa during capacitation (transformations needed for acquisition of fertility). Albumin, fetal cord serum ultrafiltrate, and L-arginine triggered capacitation and ROS generation (NO and O₂^–) and superoxide dismutase (SOD) and NOS inhibitors prevented all these effects. Surprisingly, capacitation due to exogenous NO (or O₂^–) was also blocked by SOD (or NOS inhibitors). Probes used were proven specific and innocuous on spermatozoa. Whereas O₂^– was needed only for 30 min, the continuous NO generation was essential for hours. Capacitation caused a time-dependent increase in protein tyrosine nitration that was prevented by SOD and NOS inhibitors, suggesting that O₂^– and NO· also act via the formation of ONOO^–. Spermatozoa treated with NO (or O₂^–) initiated a dose-dependent O₂^– (or NO) production, providing, for the first time in cells, a strong evidence for a two-sided ROS-induced ROS generation. Data presented show a close interaction between NO and O₂^– and their generators during sperm capacitation.     

Mechanisms and kinetic profiles of superoxide-stimulated nitrosative processes in cells using a diaminofluorescein probe

In this study, we examined the mechanisms and kinetic profiles of intracellular nitrosative processes using diaminofluorescein (DAF-2) as a target in RAW 264.7 cells. The intracellular formation of the fluorescent, nitrosated product diaminofluorescein triazol (DAFT) from both endogenous and exogenous nitric oxide (NO) was prevented by deoxygenation and by cell membrane-permeable superoxide (O₂⁻) scavengers but not by extracellular bovine Cu,Zn-SOD. In addition, the DAFT formation rate decreased in the presence of cell membrane-permeable Mn porphyrins that are known to scavenge peroxynitrite (ONOO⁻) but was enhanced by HCO₃⁻/CO₂. Together, these results indicate that nitrosative processes in RAW 264.7 cells depend on endogenous intracellular O₂⁻ and are stimulated by ONOO⁻/CO₂-derived radical oxidants. The N₂O₃ scavenger sodium azide (NaN₃) only partially attenuated the DAFT formation rate and only with high NO (>120 nM), suggesting that DAFT formation occurs by nitrosation (azide-susceptible DAFT formation) and predominantly by oxidative nitrosylation (azide-resistant DAFT formation). Interestingly, the DAFT formation rate increased linearly with NO concentrations of up to 120–140 nM but thereafter underwent a sharp transition and became insensitive to NO. This behavior indicates the sudden exhaustion of an endogenous cell substrate that reacts rapidly with NO and induces nitrosative processes, consistent with the involvement of intracellular O₂⁻. On the other hand, intracellular DAFT formation stimulated by a fixed flux of xanthine oxidase-derived extracellular O₂⁻ that also occurs by nitrosation and oxidative nitrosylation increased, peaked, and then decreased with increasing NO, as previously observed. Thus, our findings complementarily show that intra- and extracellular O₂⁻-dependent nitrosative processes occurring by the same chemical mechanisms do not necessarily depend on NO concentration and exhibit different unusual kinetic profiles with NO dynamics, depending on the biological compartment in which NO and O₂⁻ interact.     

A tetrameric structure is not essential for activity in dihydrodipicolinate synthase (DHDPS) from Mycobacterium tuberculosis

Nitric oxide (NO) is thought to react with fatty acid alkoxyl radical, which is generated from fatty acid hydroperoxide via one-electron reduction. However, detail in the reaction remains obscure. In the present study, we examined the reaction of nitric oxide with fatty acid alkoxyl radical generated in the lipoxygenase/linoleate/13-hydroperoxyoctadecadienoate (13-HpODE) system under anaerobic conditions via HPLC equipped with mass spectrometry and photodiode array detections. In this reaction system, nitric oxide can scavenge linoleate alkoxyl radical, producing 13-ONO-9Z,11E-ODE. However, instead of 13-ONO-9Z,11E-ODE, 13-NO-9E,11E-ODE and 9-NO-10E,12E-ODE were alternatively detected in the reaction solution. To explain this contradiction, we proposed a mechanism as follows: (1) 13-ONO-9E/11Z-ODE undergoes homolytic cleavage at >CHONO bond into the linoleate allyl radical and nitrogen dioxide, (2) the allyl radical undergoes resonance stabilization into the E/E-form, and (3) nitric oxide scavenges the E/E-pentadiene radical at C9 or C13 position. Consequently, we concluded that nitric oxide immediately converts fatty acid alkoxyl radical into allyl radical.     

On the mechanism of formation and spectral properties of radical anions generated by the reduction of -[Re(CO)3(5-nitro-1,10-phenanthroline)] and -[Re(CO)3(3,4,7,8-tetramethyl-1,10-phenanthroline)] pendants in poly-4-vinylpyridine polymers

The electrochemical reduction in aprotic media of -[Re^I(CO)₃L]⁺ pendants in poly-4-vinylpyridine polymers is compared to that of [Re^I(CO)₃L]⁺ complexes (L = 5-nitro-1,10-phenanthroline and 3,4,7,8-tetramethyl-1,10-phenanthroline). The UV-Vis absorption spectra of the reduced radical anions of 5-nitro-1,10-phenanthroline (NO₂-phen) and 3,4,7,8-tetramethyl-1,10-phenanthroline (tmphen) were obtained by spectro-electrochemistry of [Re^I(CO)₃(NO₂-phen)(CH₃CN)]⁺ and [Re^I(CO)₃(tmphen)(CH₃CN)]⁺, respectively. Similar spectra were obtained for the radical anions -phen and tmphen⁻ after pulse radiolysis experiments with -[Re^I(CO)₃L]⁺-containing polymers. The analysis of the time-resolved difference spectra was performed using “multivariate curve resolution” (MCR) techniques. Unlike , CH₂OH radicals were unable to reduce tmphen ligands. The reaction of and/or CH₂OH with -[Re^I(CO)₃(NO₂-phen)]⁺-containing polymers generates -[Re^I(CO)₃(-phen)] pendants which after disproportionation give rise to products with λ_max = 380 nm. The kinetic behavior of -[Re^I(CO)₃(-phen)] pendants under different experimental conditions is discussed.     

Kinetics of ammonium, nitrate and phosphorus uptake by Canna indica and Schoenoplectus validus

Canna indica L. is an upright perennial rhizomatous herb, and Schoenoplectus validus (Vahl) A. Löve and D. Löve is a tall, perennial, herbaceous sedge. The nutrient uptake kinetics of C. indica and S. validus were investigated using the modified depletion method after plants were grown for 4 weeks in simulated secondary-treated wastewater. The maximum uptake rate (I_max) and Michaelis–Menten constant (K_m) were estimated by iterative curve fitting. The I_max for NH₄N (623 μmol g⁻¹ dry root weight h⁻¹) was significantly higher than that for NO₃N (338 μmol g⁻¹ dry root weight h⁻¹) in S. validus. In contrast, no difference was observed in C. indica. The I_max values for NO₃N and NH₄N were higher in S. validus than in C. indica. A significantly lower K_m was detected for NO₃N uptake in C. indica (385 μmol L⁻¹) compared to that in S. validus (1908 μmol L⁻¹). The I_max for PO₄P did not differ between the plant species. The K_m for PO₄P was significantly higher in C. indica (157 μmol L⁻¹) than in S. validus (60 μmol L⁻¹). In conclusion, we found that S. validus preferred NH₄N over NO₃N, had greater capacity for N uptake and higher affinity for PO₄P, but C. indica had greater affinity for NO₃N. Nutrient uptake capacity is likely related to habitat preference, and is influenced by the structure of roots and rhizomes.     

Induction of hydroxyl radical production in Trametes versicolor to degrade recalcitrant chlorinated hydrocarbons

Extracellular hydroxyl radical (OH) production via quinone redox cycling in Trametes versicolor, grown in a chemically defined medium, was investigated to degrade trichloroethylene (TCE), perchloroethylene (PCE), 1,2,4- and 1,3,5-trichlorobenzene (TCB). The activity of the enzymes catalyzing the quinone redox cycle, quinone reductase and laccase, as well as the rate of OH production, estimated as the formation of thiobarbituric acid reactive substances (TBARS) from 2-deoxyribose, increased rapidly during the first 2–3 days and then remained at relatively constant levels. Under quinone redox cycling conditions, TCE degradation was concomitant to TBARS production and chloride release, reaching a plateau after 6 h of incubation. Similar results were obtained in PCE, 1,2,4- and 1,3,5-TCB time course degradation experiments. The mole balance of chloride release and 1,2,4-TCB and TCE degraded suggests that these chemicals were almost completely dechlorinated. Experiments using [¹³C]-TCE confirmed unequivocal transformation of TCE to ¹³CO₂. These results are of particular interest because PCE and 1,3,5-TCB degradation in aerobic conditions has been rarely reported to date in bacterial or fungal systems.     

The influence of the cation of quaternized chitosans on antioxidant activity

Various quaternized chitosans (QCSs) were synthesized according to previous method. Their reducing power and antioxidant potency against hydroxyl radicals (OH) and hydrogen peroxide (H₂O₂) were explored by the established systems in vitro. The QCSs exhibited markedly antioxidant activity, especially TCEDMCS, whose IC₅₀ on hydroxyl radicals was 0.235 mg/mL. They showed 65–80% scavenging effect on hydrogen peroxide at a dose of 0.5 mg/mL. Generally, the antioxidant activity decreased in the order TCEDMCS > TBEDMCS > EDMCS > PDMCS > IBDMCS > Chitosan. Furthermore, the order of their OH and H₂O₂ scavenging activity was consistent with the electronegativity of different substituted groups in the QCSs. The QCSs showed much stronger antioxidant activity than that of chitosan may be due to the positive charge density of the nitrogen atoms in QCSs strengthened by the substituted groups.