Amines for detection of dopamine by generation of hydrogen peroxide and peroxyoxalate chemiluminescence

A range of nitrogen-containing compounds (alkyl amines, piperazines, cyclohexylamines and nitrogen heterocyclics) were investigated for generation of hydrogen peroxide from dopamine and detection by peroxyoxalate chemiluminescence. Imidazole, ethyleneurea and allantoin among the nitrogen heterocyclic compounds tested generated hydrogen peroxide from dopamine following incubation at 60°C, pH 9.5–10.5, for 0–30 min. Imidazole was the most effective for generation of hydrogen peroxide, but imidazole derivatives with a primary amine side chain (histamine) or thiol (ethylenethiourea) were not effective. The presence of a ketone group (ethyleneurea, allantoin) did not hinder the reaction. Under optimal conditions (30 min incubation, 50 mmol/L imidazole) 10.5 nmol of dopamine could be detected. The cyclohexylamines tested produced low amounts of hydrogen peroxide (0.09–2.74% of light intensity with imidazole), and the piperazines and the alkyl amines tested produced no detectable hydrogen peroxide. Imidazole reacts with the phenolic groups of dopamine in a different manner from monoamine oxidase, and a reagent containing imidazole, ethyleneurea or allantoin was useful for non-enzymatic detection of dopamine by peroxyoxalate chemiluminescence.© John Wiley & Sons, Ltd.     

Chemiluminescence intensities and spectra of luminol oxidation by sodium hypochlorite in the presence of hydrogen peroxide

Hydrogen peroxide amplifies the chemiluminescence in the oxidation of luminol by sodium hypochlorite. A linear relationship between concentration of hydrogen peroxide and light intensity was found in the concentration range 5 × 10^?8?7.5 × 10^?6 mol/l. At 7.5 × 10^?6 mol/l H₂O₂ the chemiluminescence is amplified 550—fold. The chemiluminescence spectra of these reactions have a wavelength maximum at 431 nm independent of the concentration of hydrogen peroxide. The results indicate that hydrogen peroxide is a necessary component in the chemiluminescent oxidation of the luminol by sodium hypochlorite.     

Antisteroidogenic effects of hydrogen peroxide on rat granulosa cells

Abstract

Rat granulosa cells (GCs) were treated with human chorionic gonadotropin (hCG), 8-bromo-adenosine 3′,5′-cyclic monophosphate (8-Br-cAMP), forskolin, phorbol 12-myristate 13-acetate (PMA), A23187 or pregnenolone in the absence or presence of hydrogen peroxide (H₂O₂). Different doses of trilostane were applied to GCs treated with steroidogenic precursors, that is, 25-hydroxy-cholesterol (25-OH-C) in the absence or presence of H₂O₂. Results showed that all of the chemicals stimulated the progesterone (PG) release from rat GCs, but the stimulatory effects were inhibited by H₂O₂ dose-dependently. 25-OH-C stimulated the PG release, which was inhibited by H₂O₂ in the presence of trilostane. H₂O₂ attenuated steroidogenic acute regulatory (StAR) protein expression, but did not alter the expression of cytochrome P450 side chain cleavage (P450scc) in Western blotting. This study indicated that H₂O₂ inhibited PG production by GCs via cAMP pathway, protein kinase C (PKC) and the activities of intracellular calcium, P450scc and StAR protein.     

Regulation of morphologicaland functional properties of astroglial cells by hydrogen peroxide

Effects of hydrogen peroxide on morphological characteristics, proliferation index, menadione-dependent lucigenin-enhanced chemiluminescence of C6 glioma cells were studied. It was established that H2O2 at 1 x 10(-8) - 5 x 10(-7) M concentrations acts as a regulator of morphological and functional properties of astrocytes by inducing their reactivation that is manifested as a cell body hypertrophy and an increase of proliferative activity and of menadione-dependent production of superoxide (O2- ). Cytodestructive action of hydrogen peroxide at a concentration higher than 1 microM on C6 glioma cells shows itself as a decrease of their proliferation index and the ability to generate O2- under menadione action. Using lipopolysaccharide B as a functional stimulator it has been shown that H2O2 modifies signaling pathways leading to the increase of mitotic activity of C6 glioma cells and decreases the yield of lucigenin-enhanced chemiluminescence of astrocytes under menadione action to the level of control values.     

Luminol-hydrogen peroxide chemiluminescence produced by sweet potato peroxidase.

Anionic sweet potato peroxidase (SPP; Ipomoea batatas) was shown to efficiently catalyse luminol oxidation by hydrogen peroxide, forming a long-term chemiluminescence (CL) signal. Like other anionic plant peroxidases, SPP is able to catalyse this enzymatic reaction efficiently in the absence of any enhancer. Maximum intensity produced in SPP-catalysed oxidation of luminol was detected at pH 7.8-7.9 to be lower than that characteristic of other peroxidases (8.4-8.6). Varying the concentrations of luminol, hydrogen peroxide and Tris buffer in the reaction medium, we determined favourable conditions for SPP catalysis (100 mmol/L Tris-HCl buffer, pH 7.8, containing 5 mmol/L hydrogen peroxide and 8 mmol/L luminol). The SPP detection limit in luminol oxidation was 1.0 x 10(-14) mol/L. High sensitivity in combination with the long-term CL signal and high stability is indicative of good promise for the application of SPP in CL enzyme immunoassay.     

过氧化氢预处理对褐煤物化性质及生物产气的影响

【目的】研究过氧化氢预处理对褐煤物化性质及生物产气的影响。【方法】以胜利5号褐煤为研究对象,利用正交试验对过氧化氢预处理褐煤条件进行优化,在最优条件下处理褐煤得到处理后的残煤和处理液,通过X射线衍射分析(X-ray diffraction, XRD)、扫描电镜分析(scanning electron microscopy, SEM)、比表面积分析及孔隙分析(brunauer-emmett-teller, BET)、气相色谱-质谱分析(GC-MS)、高效液相色谱分析(HPLC)等方法对原煤、残煤和处理液的物化性质进行比较分析。【结果】经过氧化氢预处理,褐煤的最优条件为过氧化氢浓度5.0%、预处理时间20 d、液固比30:1,处理液中总有机碳含量为105 mg/L。在最优条件下,过氧化氢处理后残煤表面裂痕、凹陷增多,表面结构变得松散;煤的芳香面网间距增加,芳环结构更加疏松,晶核结构变小;孔隙度和比表面积均增大。处理后残煤中的固定碳、C元素和镜质组的相对含量降低,而灰分、挥发分、O和H元素及惰质组含量增加,残煤中O=C-O、C=C、C=O官能团含量增加,而N-H、C-H官能团含量则减少。生物产气结果表明反应液和残煤产气量均低于原煤,分别减少了39.13%和94.46%。过氧化氢预处理主要作用于煤中镜质组,使其有机碳溶解,煤中大分子结构的官能团发生变化,改变煤的芳环结构,在氧化作用下煤结构中的小分子溶解进入处理液。处理液中有机物以短链脂肪酸为主。经生物产气后,反应液中小分子酸以及有机物种类减少,被微生物利用产气。而各产气试验组中优势菌门及优势菌属的菌群丰度呈现出显著差异,古菌中原煤产气组盐杆菌门(Halobacteriota)为优势菌门,甲烷八叠球菌属(Methanosarcina)为优势菌属;反应液产气组热变形菌(Thermoprotei)为优势菌门,深古菌属(Bathyarchaeia)为优势菌属;细菌中原煤产气组放线菌门(Actinomycetota)为优势菌门,Gaiellales为优势菌属;反应液产气试验组假单胞菌门(Pseudomonadota)为优势菌门,代尔夫特菌属(Delftia)为优势菌属。【结论】煤溶解有机碳可以被微生物利用产气,但是煤中有机组分的过氧化脱除导致生物产气量减少。     

Detection of hydrogen peroxide with chemiluminescent micelles

The overproduction of hydrogen peroxide is implicated in the progress of numerous life-threatening diseases and there is a great need for the development of contrast agents that can detect hydrogen peroxide in vivo. In this communication, we present a new contrast agent for hydrogen peroxide, termed peroxalate micelles, which detect hydrogen peroxide through chemiluminescence, and have the physical/chemical properties needed for in vivo imaging applications. The peroxalate micelles are composed of amphiphilic peroxalate based copolymers and the fluorescent dye rubrene, they have a ‘stealth’ polyethylene glycol (PEG) corona to evade macrophage phagocytosis, and a diameter of 33 nm to enhance extravasation into permeable tissues. The peroxalate micelles can detect nanomolar concentrations of hydrogen peroxide (>50 nM) and thus have the sensitivity needed to detect physiological concentrations of hydrogen peroxide. We anticipate numerous applications of the peroxalate micelles for in vivo imaging of hydrogen peroxide, given their high sensitivity, small size, and biocompatible PEG corona.     

Inactivation of mushroom tyrosinase by hydrogen peroxide

Hydrogen peroxide (H₂O₂) inactivates mushroom tyrosinase in a biphasic manner, with the rate being faster in the first phase than in the second one. The inactivation of the enzyme is dependent on H₂O₂ concentration (in the range of 0.05–5.0 mM), but independent of the pH (in the range of 4.5–8.0). The rate of inactivation of mushroom tyrosinase by H₂O₂ is faster under anaerobic conditions (nitrogen) than under aerobic ones (air). Substrate analogues such as L-mimosine, L-phenylalanine, p-fluorophenylalanine and sodium benzoate protect the enzyme against inactivation by H₂O₂. Copper chelators such as tropolone and sodium azide also protect the enzyme. Under identical conditions, apotyrosinase is not inactivated by H₂O₂, unlike holotyrosinase. The inactivation of mushroom tyrosinase is not accelerated by an OH^?dot generating system (Fe²⁺-EDTA-H₂O₂) nor is it protected by OH^dot scavengers such as mannitol, urate, sodium formate and histidine. Exhaustive dialysis or incubation with catalase does not restore the activity of H₂O₂-inactivated enzyme. The data suggest that Cu²⁺ at the active site of mushroom tyrosinase is essential for the inactivation by H₂O₂. The inactivation does not occur via the OH^dot radical in the bulk phase but probably via an enzyme-bound OH^dot.     

Effect of broad-band ultraviolet and visible radiation on hydrogen peroxide formation by cultured rose cells

Broad-band radiation from a high-pressure Hg-vapor lamp, including ultraviolet wavelengths from 290 to 400 nm, blue, green and red wavelengths, did not induce the synthesis of H₂O₂ in cultured rose cells. This was in contrast to the effects of shortwave (254 nm) ultraviolet radiation, even though, like shortwave ultraviolet radiation, the UV-B component of the broadband radiation induced a striking K⁺ efflux from the cells, and this efflux has been associated with H₂O₂ synthesis in a previous report. The UV-A and visible wavelengths were shown to inhibit the synthesis of H₂O₂. This effect was associated with inhibition of peroxidase, an enzyme reported to be involved in the synthesis of H₂O₂ in cell walls. UV-B radiation inhibited the alternate pathway for mitochondrial electron transport, but there was no evidence that this effect contributed to the inhibition of H₂O₂ synthesis in cells treated with broad-band radiation.     

Non-oxygen-forming pathways of hydrogen peroxide degradation by bovine liver catalase at low hydrogen peroxide fluxes

Heme catalases are considered to degrade two molecules of H₂O₂ to two molecules of H₂O and one molecule of O₂ employing the catalatic cycle. We here studied the catalytic behaviour of bovine liver catalase at low fluxes of H₂O₂ (relative to catalase concentration), adjusted by H₂O₂-generating systems. At a ratio of a H₂O₂ flux (given in μM/min^- 1) to catalase concentration (given in μM) of 10 min^- 1 and above, H₂O₂ degradation occurred via the catalatic cycle. At lower ratios, however, H₂O₂ degradation proceeded with increasingly diminished production of O₂. At a ratio of 1 min^- 1, O₂ formation could no longer be observed, although the enzyme still degraded H₂O₂. These results strongly suggest that at low physiological H₂O₂ fluxes H₂O₂ is preferentially metabolised reductively to H₂O, without release of O₂. The pathways involved in the reductive metabolism of H₂O₂ are presumably those previously reported as inactivation and reactivation pathways. They start from compound I and are operative at low and high H₂O₂ fluxes but kinetically outcompete the reaction of compound I with H₂O₂ at low H₂O₂ production rates. In the absence of NADPH, the reducing equivalents for the reductive metabolism of H₂O₂ are most likely provided by the protein moiety of the enzyme. In the presence of NADPH, they are at least in part provided by the coenzyme.     

Peroxidase-catalysed oxidation of chlorophyll by hydrogen peroxide

Chlorophyll is effectively bleached by H₂O₂ in the presence of certain phenols and peroxidase (EC 1.11.1.7) extracted from acetone powders of orange flavedo (Citrus sinensis). Optimal conditions for chlorophyll: hydrogen peroxide oxidoreductase include: pH, 5.9; [H₂O₂] 222 μM; ionic strength 0.11. A phenol is required and resorcinol is the most effective. Catechol and hydroquinone are inhibitory. Chlorophyll a, chlorophyllide a, and chlorophyll b all have similar V_max but K_m for chlorophyll a is about one-third that of chlorophyll b, while the K_m for chlorophyllide a is about one-half that of chlorophyll a. Pheophytin a was much less reactive than chlorophyll a, and Mg²⁺ included in the reaction system did not affect rates of pheophytin destruction.     

Detection of hydrogen peroxide by lactoperoxidase-mediated dityrosine formation

The aim of this work was to study the dityrosine-forming activity of lactoperoxidase (LPO) and its potential application for measuring hydrogen peroxide (H₂O₂). It was observed that LPO was able to form dityrosine at low H₂O₂ concentrations. Since dityrosine concentration could be measured in a simple fluorimetric reaction, this activity of the enzyme was utilized for the measurement of H₂O₂ production in different systems. These experiments successfully measured the activity of NADPH oxidase 4 (Nox4) by this method. It was concluded that LPO-mediated dityrosine formation offers a simple way for H₂O₂ measurement.     

Enhancement of the growth of Helicobacter pylori in Brucella broth by hydrogen peroxide

We found that a sub-lethal concentration of hydrogen peroxide (HPOx) enhanced the growth of Helicobacter pylori in Brucella broth supplemented with 10% fetal bovine serum (BB/FBS). The enhancement was evident at 0.1 mM HPOx and reached a maximun at 3.5 mM. The growth stimulation was dependent on the basal media used; when brain heart infusion broth (BHIB) was used instead of BB, the growth was not altered regardless of the presence or absence of HPOx. Furthermore, the growth in BHIB/FBS was comparable to that in BB/FBS plus 3.5 mM HPOx. This suggested that the enhancement of growth by HPOx resulted from the derepression of the inhibitory factor existing in BB by HPOx. The inhibitory substance seemed to be bisulfite salt since the bacteria grew to a similar extent in bisulfite-less Brucella broth (BLBB0)/FBS compared to the bacterial growth in BHIB/FBS and BB/FBS plus HPOx. These results indicate that the detoxification of bisulfite in BB can be easily achieved by simply adding HPOx to the medium, which causes the oxidation of bisulfite to bisulfate, a less-toxic compound to the bacterial growth. Since we also found that the morphology and cellular protein profile of BB/FBS-cultured bacteria were apparently different from those cultured in BLBB/FBS, we propose that the use of BB for primary isolation and cultivation of H. pylori should be limited on certain occasions, or if necessary, BB can be used after detoxification of the bisulfite by the addition of a low concentration of HPOx.     

Functional roles of superoxide and hydrogen peroxide generated by mitochondrial DNA mutation in regulating tumorigenicity of HepG2 cells

Mitochondria are a major source of reactive oxygen species (ROS). Recent studies have estimated that mitochondrial DNA mutations inducing the overproduction of ROS are associated with human cancer. However, a substantial challenge in elucidating their diverse roles in regulating tumorigenesis is the lack of methods for probing ROS in living systems with molecular specificity. In this study, we reported the application of two fluorescent probes, 2‐chloro‐1,3‐dibenzothiazolinecyclohexene and naphthofluorescein disulfonate, which showed high selectivity for superoxide (O₂^•−) and hydrogen peroxide (H₂O₂). They were capable of detecting and visualizing O₂^•− and H₂O₂ overproduction caused by a mutation in the gene encoding nicotinamide adenine dinucleotide dehydrogenase subunit 6 (ND6) in HepG2 cells. The levels of O₂^•− and H₂O₂ in mitochondria isolated from HepG2 cells were found to be 0·63 ± 0·07 and 1·13 ± 0·05 μM, respectively. Using assays of tumorigenesis in mouse models, we found that treatment of the mice with different ROS scavengers suppressed tumour growth. These findings suggested that ROS generated by ND6 gene mutation do play an important role in regulating tumorigenesis and H₂O₂ may be a key modulator. Copyright © 2011 John Wiley & Sons, Ltd.     

Activation of murine macrophages by hydrogen peroxide

Hydrogen peroxide at concentrations from 0.1 to 20 μM enhances phagocytosis and oxidative burst of murine peritoneal macrophages. The activation of these macrophage functions is paralled by prolonged hyperpolarization and a transient increase in cytoplasmic free calcium concentration. All the effects are dose- and time-dependent. The results obtained for H₂O₂ are compared with those for a natural activator, peptide N-formyl-methionyl-leucly-phenylalanine. The data demonstrate the ability of small doses of hydrogen peroxide to stimulate macrophages through the intracellular mechanisms of ion transduction.     

Quantification of hydrogen peroxide in plant extracts by the chemiluminescence reaction with luminol

The chemiluminescence of luminol (3-aminophthalhydrazide) with H₂O₂ has been used to quantify endogenous amounts of H₂O₂ in plant tissues. The reaction is linear over at least three orders of magnitude between 10^?5 and 10^?2M H₂O₂. Interference by coloured compounds in the crude extract is calibrated by a purification step with Dowex AG 1-X8. The extract is calibrated with an internal H₂O₂ standard, and the specificity verified by H₂O₂ purging with catalase. The minimum delectability for H₂O₂ of this assay is at least 1 ng, corresponding to 0.1–1 g fresh material. Data are presented for the levels of H₂O₂ in potatoes after treatment with oxygen and ethylene, in tomatoes before and after ripening and in untreated germinating castor beans as well as in beans treated with aminotriazol to inhibit catalase activity. Though data using the titanium test are generally confirmed, the method presented here has the advantage of higher sensitivity and specificity.     

Guard-cell signalling for hydrogen peroxide and abscisic acid

Guard cells can integrate and process multiple complex signals from the environment and respond by opening and closing stomata in order to adapt to the environmental signal. Over the past several years, considerable research progress has been made in our understanding of the role of reactive oxygen species (ROS) as essential signal molecules that mediate abscisic acid (ABA)-induced stomatal closure. In this review, we discuss hydrogen peroxide (H2O2) generation and signalling, H2O2-induced gene expression, crosstalk and the specificity between ABA and H2O2 signalling, and the cellular mechanism for ROS sensing in guard cells. This review focuses especially on the points of connection between ABA and H2O2 signalling in guard cells. The fundamental progress in understanding the role of ABA and ROS in guard cells will continue to provide a rational basis for biotechnological improvements in the development of drought-tolerant crop plants with improved water-use efficiency.     

Superoxide and hydrogen peroxide formation during enzymatic oxidation of DOPA by phenoloxidase

Generation of superoxide anion and hydrogen peroxide during enzymatic oxidation of 3-(3,4-dihydroxyphenyl)-dl-alanine (DOPA) has been studied. The ability of DOPA to react with has been revealed. EPR spectrum of DOPA-semiquinone formed upon oxidation of DOPA by was observed using spin stabilization technique of ortho-semiquinones by Zn²⁺ ions. Simultaneously, the oxidation of DOPA by was found to produce hydrogen peroxide (H₂O₂). The analysis of H₂O₂ formation upon oxidation of DOPA by using 1-hydroxy-3-carboxy-pyrrolidine (CP-H), and SOD as competitive reagents for superoxide provides consistent values of the rate constant for the reaction between DOPA and being equal to (3.4±0.6)×10⁵?M^?1?s^?1.

The formation of H₂O₂ during enzymatic oxidation of DOPA by phenoloxidase (PO) has been shown. The H₂O₂ production was found to be SOD-sensitive. The inhibition of H₂O₂ production by SOD was about 25% indicating that H₂O₂ is produced both from superoxide anion and via two-electron reduction of oxygen at the enzyme. The attempts to detect superoxide production during enzymatic oxidation of DOPA using a number of spin traps failed apparently due to high value of the rate constant for DOPA interaction with      

Glycerophosphate-dependent hydrogen peroxide production by brown adipose tissue mitochondria and its activation by ferricyanide

Oxidation of glycerophosphate (GP) by brown adipose tissue mitochondria in the presence of antimycin A was found to be accompanied by significant production of hydrogen peroxide. GP-dependent hydrogen peroxide production could be detected by p-hydroxyphenylacetate fluorescence changes or as an antimycin A-insensitive oxygen consumption. One-electron acceptor, potassium ferricyanide, highly stimulated the rate of GP-dependent antimycin A-insensitive oxygen uptake, which was prevented by inhibitors of mitochondrial GP dehydrogenase (mGPDH) or by coenzyme Q(CoQ). GP-dependent ferricyanide-induced peroxide production was also determined luminometrically, using mitochondria or partially purified mGPDH. Ferricyanide-induced peroxide production was negligible, when succinate or NADH was used as a substrate. These results indicate that hydrogen peroxide is produced directly by mGPDH and reflect the differences in the transport of reducing equivalents from mGPDH and succinate dehydrogenase to the CoQ pool. The data suggest that more intensive production of reactive oxygen species may be present in mammalian cells with active mGPDH.     

The release of iron from different asbestos structures by hydrogen peroxide with concomitant O generation

Treatment of aqueous suspensions of different asbestos fibers (amosite, anthophyllite, chrysotile, and crocidolite) at 0-4°C and pH 7.2 with H O results in the consumption of H O with concomitant release of iron and production of O. During incubations, [H O] decreased in proportion to the mass of the suspended fiber, the duration of incubation, and the initial [H O]. The consumption of H O, production of O and release of iron all vary synergistically with the structure of the asbestos fiber. Release of silicon during the incubation was small relative to the decrement in [H O], reflecting a lack of dissolution of the fiber. The data are consistent with a redox process for the release of surface bound iron and it is significant that iron release occurs in the absence of a Fe(II) or Fe(III) chelator. The implications of iron release from the asbestos surface may be important in inflammatory disorders in which both silicate bound iron and H O accumulate. © Rapid Science 1998.