Chemiluminescence enzyme immunoassay of 8-oxoguanine in DNA.

A test system has been developed to determine 8-oxoguanine in DNA, the most important biomarker of damage to DNA bases by reactive oxygen species. The system is based on a chemiluminescence enzyme immunoassay with the use of monoclonal antibodies (mcAB) against 8-oxoguanine. The test involves several stages: 1) immobilization of DNA on nitrocellulose membrane filters using an efficient technique with preliminary formation of a complex with protamine sulfate; 2) formation of antigen--antibody complexes (mcAB with 8-oxoguanine in DNA) with secondary antibodies and with a peroxidase--antiperoxidase complex (PAP method); 3) detection of increased chemiluminescence in a solution of hydrogen peroxide, luminol, and p-iodophenol. The increased chemiluminescence is determined with a conventional liquid scintillation counter for measuring beta-radioactivity. The system was tested by determining 8-oxoguanine formation in DNA upon gamma-irradiation and upon photosensitized oxidation of guanine under visible light in the presence of methylene blue. A linear dose dependence of 8-oxoguanine formation in DNA was shown for gamma-irradiation. The radiation-chemical yield of 8-oxoguanine (G = 0.57 molecule per 100 eV) is convenient to use for calibration of the amount of 8-oxoguanine formed under other conditions. The sensitivity of the method permits the detection of several femtomoles of 8-oxoguanine in a 40 microg sample of DNA.     

Dependence of the properties of dioxane-based scintillation systems on the concentration of the components

Characteristics of dioxan-based scintillation system have been studied. A composition for scintillation cocktails ensuring an effective homogeneous count of radioactive water samples (0-8% V) at minimum expense of ethyl alcohol has been suggested.     

Liquid scintillation counting of polyacrylamide gels crosslinked with N,N′-methylene-bis-acrylamide and N,N′-diallyltartardiamide

Tritium (³H)-labeled material within polyacrylamide gel slices is commonly quantified by four general liquid scintillation counting methods: combustion, gel solubilization, selective solubilization of modified crosslinked gels, and elution. Of these four methods examined in this study, only combustion ensured complete recovery of ³H label; however, a less expensive and more convenient elution method yielding both a high recovery and cocktail counting efficiency was the use of Soluene-350 with 0.55% Permablend III in toluene. This particular solubilizer-cocktail system eliminates almost all chemiluminescence as does combustion.     

Plant chemiluminescence

Light production by plants was confirmed by measuring chemiluminescence from root and stem tissue of peas (Pisum sativum), beans (Phaseolus vulgaris), and corn (Zea mays) in a modified scintillation spectrophotometer. Chemiluminescence was inhibited by treating pea roots with boiling ethanol or by placing them in a N₂ gas phase. Chemiluminescence was increased by an O₂ gas phase or by the addition of luminol. NaN₃ and NaCN blocked both in vitro and in vivo chemiluminescence.

It is postulated that the source of light is the hydrogen peroxide-peroxidase enzyme system. It is known that this system is responsible for chemiluminescence in leukocytes and it seems likely that a similar system occurs in plants.

     

Measurement of 14CO2 evolution during tissue oxidation in vitro; an alternative to the Kontes well

1. An alternative method to the use of the disposable Kontes well for trapping 14CO2 produced in the course of biological oxidations is described. 2. A polyethylene miniature scintillation vial was used to contain the hyamine hydroxide-impregnated filter paper wick. 3. The two methods are compared in their abilities to trap 14CO2 produced directly by acidification of sodium [14C]bicarbonate and during beta-oxidation of 1[14C] palmitic acid. 4. The miniature vial and Kontes well methods showed similar efficiencies in the trapping of 14CO2 (97% and 95%, respectively, on average) the radioactivity of which was determined in the miniature vial using 5 ml only of scintillation fluid compared with a minimum of 10 ml required by the standard scintillation vial used to accommodate the Kontes well. 5. The technical advantages of the suggested miniature vial system, during both incubation and counting stages, are discussed.     

Chemiluminescence studies on the generation of oxygen radicals from the interaction of NADPH-cytochrome P-450 reductase with iron

The ability of NADPH-cytochrome P-450 reductase to interact with iron and generate oxygen radicals was evaluated by assaying for low level chemiluminescence. The basic reaction system which contained the reductase, an NADPH-generating system, ferric-EDTA as an electron acceptor, and t-butyl hydroperoxide as the oxidant acceptor, resulted in the production of chemiluminescence. Omission of any of these components resulted in a complete loss of chemiluminescence. The light emission was completely sensitive to inhibition by glutathione and butylated hydroxytoluene, partially sensitive (about 60% decrease) to catalase and hydroxyl radical scavengers, and relatively insensitive (about 20% decrease) to superoxide dismutase. The ability of other ferric chelates to replace ferric-EDTA in catalyzing the reductase-dependent chemiluminescence was evaluated. Ferric-citrate, -ADP, -ATP, and ferric-ammonium sulfate were ineffective in promoting chemiluminescence, whereas ferric-diethylenetriaminepentaacetic acid was even more effective than ferric-EDTA. Thus, the ferric chelates, which catalyze reductase-dependent chemiluminescence, are those which are efficient electron acceptors from the reductase and were previously shown to be those capable of catalyzing hydroxyl radical production by microsomes and the reductase. It is suggested that chemiluminescence results from (a) the direct interaction of the reduced iron chelate with the hydroperoxide (Fenton-type of reaction) to generate alkoxyl and peroxyl radicals, and (b) the generation of hydroxyl radicals, which subsequently react with the hydroperoxide to generate secondary radicals. The latter, but not the former, would be sensitive to inhibition by catalase and competitive hydroxyl radical scavengers, whereas both would be sensitive to antioxidants such as butylated hydroxytoluene. Chemiluminescence appears to be a versatile tool for studying the reductase-dependent generation of oxygen radicals and for the interaction of reductase with iron.     

Chemiluminescence by Listeria monocytogenes.

Listeria monocytogenes cells suspended in brain heart infusion broth or in carbonated saline solution emitted light (chemiluminescence) that could be detected by a liquid scintillation spectrometer. This chemiluminescence was inhibited by superoxide dismutase and catalase but not by the hydroxyl radical scavengers mannitol and benzoate; it was also dependent upon and proportional to the carbonate ion concentration in the medium. Organisms suspended in carbonated saline solution which had ceased to chemiluminesce immediately began to chemiluminesce again when acetaldehyde was added but not when glucose, sucrose, or xanthine was added. Acetaldehyde-induced chemiluminescence was inhibited by suproxide dismutase and catalase but not by allopurinol. Our data indicate that the superoxide anion, hydrogen peroxide, and the carbonate ion are involved in chemiluminescence by L. monocytogenes. Chemiluminescence is apparently initiated by the extracellular generation of superoxide anon by this organism. The mechanism for the production of the superoxide anion is not known, but xanthine oxidase does not appear to be involved.     

Chemiluminescence behaviour of CdTe–potassium permanganate enhanced by sodium hexametaphosphate and sensitized sensing of l‐ascorbic acid

A highly sensitive flow‐injection chemiluminescence (FIA‐CL) method based on the CdTe nanocrystals and potassium permanganate chemiluminescence system was developed for the determination of l ‐ascorbic acid. It was found that sodium hexametaphosphate (SP), as an enhancer, could increase the chemiluminescence (CL) emission from the redox reaction of CdTe quantum dots with potassium permanganate in near‐neutral pH conditions. l ‐Ascorbic acid is suggested as a sensitive enhancer for use in the above energy‐transfer excitation process. Under optimal conditions, the calibration graph of emission intensity against logarithmic l ‐ascorbic acid concentration was linear in the range 1.0 × 10^?9–5.0 × 10^?6 mol/L, with a correlation coefficient of 0.9969 and relative standard deviation (RSD) of 2.3% (n = 7) at 5.0 × 10^?7 mol/L. The method was successfully used to determine l ‐ascorbic acid in vitamin C tablets. The possible mechanism of the chemiluminescence in the system is also discussed. Copyright © 2012 John Wiley & Sons, Ltd.     

Hydroperoxide-initiated chemiluminescence: an assay for oxidative stress in biopsies of heart, liver, and muscle.

Hydroperoxide-initiated chemiluminescence was standardized as a microassay to evaluate the occurrence of oxidative stress in human biopsies. Samples of 10 to 50 mg of rat liver or heart were homogenized, diluted in reaction medium, added with tert-butyl hydroperoxide, and assayed for chemiluminescence in a liquid scintillation counter in the out-of-coincidence mode. Optimal conditions for the assay were: 0.3 to 1.2 mg/mL of homogenate protein in 120 mM KCl, 30 mM phosphate buffer (pH 7.4), and 3 mM tert-butyl hydroperoxide at 30 degrees C. In these conditions, maximal chemiluminescence values were 550 +/- 30 and 1100 +/- 40 cps/mg protein, for liver and heart homogenates, respectively. Liver and heart homogenates were subjected to in vitro oxidative stresses such as supplementation with organic hydroperoxide or with enzymatic systems generating superoxide anion or hydrogen peroxide. Chemiluminescence was higher in the poststress samples than in the control ones. The ratio: poststress chemiluminescence/control chemiluminescence (B/A) was about 1.4 or higher for both tissues. Human heart biopsies were utilized to investigate the occurrence of oxidative stress after clinical situations associated to ischemia-reperfusion. B/A ratios were 2.1 +/- 0.4, 1.4 +/- 0.1, and 2.8 +/- 0.4 for human heart, liver, and skeletal muscle, respectively.     

A simple method for the elimination of chemiluminescence in the liquid scintillation counting of alkaline protein digests.

A liquid scintillation mixture is described with which chemiluminescence is virtually absent ten minutes or less after mixing with alkaline digests of blood serum. The mixture provides a clear colourless solution for counting, and was found to be equally effective with three commercial solubilizers. If the digest contains hydrogen peroxide it must be heated for a period of time before the addition of the mixture.     

Variables in xanthine oxidase-initiated luminol chemiluminescence: Implications for chemiluminescence measurements in biological systems

We tested the effects of generally used chemiluminescence inhibitors on an example of luminol chemiluminescence elicited by xanthine oxidase/hypoxanthine system, and attempted to assess their capabilities in discovering the reaction pathways leading to chemiluminescence. Luminol itself is a xanthine oxidase inhibitor and its concentration affects the reaction mechanism. Maximal chemiluminescence response was observed at luminol concentration inhibiting urate production. Chemiluminescence was totally inhibited by superoxide dismutase, the inhibition by catalase depended on luminol concentration. Ferricytochrome c, a detector of superoxide, either stimulated or inhibited chemiluminescence in a concentration-dependent manner. Chemiluminescence was highly stimulated by peroxidases. A pronounced inhibition of chemiluminescence was caused by chelators; 1 mm desferal and 0.01 mm diethyldithiocarbamate. It is suggested that measurement of luminol chemiluminescence is not a suitable method for discrimination among individual reactive oxygen species and their quantitative determination in biological systems.     

Detection of chemiluminescence in lipid peroxidation of biological systems and its application to HPLC

A combined system of chemiluminescence detection and high performance liquid chromatography (CL–HPLC) was developed to determine primary peroxidation products in biological tissues, such as phosphatidylcholine hydroperoxide (PCOOH). The CL–HPLC assay consists of separation of lipid classes with HPLC and detection of hydroperoxide-specific chemiluminescence. Hydroperoxides react with heme compounds to produce oxidants as suggested by our early studies on tissue low-level chemiluminescence in which singlet molecular oxygen is generated as one of the excited species in several biological systems involving free radical events. In the CL–HPLC method, a cytochrome c–luminol mixture was used as a hydroperoxide-specific luminescent reagent, and the quantification of hydroperoxide was performed by detecting chemiluminescence due to the luminol oxidation caused by the oxidant produced during the lipid hydroperoxides with heme. The detection limit of PCOOH was 10 pmole hydroperoxide–O₂. PCOOH in normal human blood was found to be 10–500 pmol/ml plasma and significantly higher levels of PCOOH were observed in some hospitalized patients.     

Chemiluminescence during oxidation of gossipol by peroxidase]

Gossipol oxidation with peroxidase accompanied by chemiluminescence is revealed. Effect of some factors on chemiluminescence is investigated. Peroxidase gossipol oxidation is suggested to be one of the causes of spontaneous cotton root luminescence. Chemiluminescence in the system studied is inhibited by superoxide dismutase, which indicates the generation of superoxide anion radical. It is suggested that these radicals and other activated oxygen species are involved in the gossipol toxicity for parasitic microorganisms.     

Cumene hydroperoxide-induced chemiluminescence in human erythrocytes: Effect of antioxidants and sulfhydryl compounds

• 1.1. The time-course of cumene hydroperoxide-induced changes in lipid peroxidation, protein sulfhydryl groups and chemiluminescence intensity was determined in human erythrocytes.
• 2.2. Increase in lipid peroxidation was maximal within 60 min of incubation and was paralleled by a decrease in protein sulfhydryl groups and an increase in chemiluminescence formation.
• 3.3. A standard assay system was established to investigate the protective effects of antioxidants and scavenger compounds on cumene hydroperoxide-induced chemiluminescence formation.
• 4.4. Chain-breaking antioxidants (i.e. butylated hydroxytoluene) and sulfhydryl compounds (i.e. dithiothreitol) were able to suppress chemiluminescence formation.
• 5.5. Our results suggested that secondary free radicals, as well as sulfhydryl groups of proteins are involved in cumene hydroperoxide-induced chemiluminescence formation.

     

A chemiluminescence method to detect hydroquinone with water‐soluble sulphonato‐(salen)manganese(III) complex as catalyst

A water‐soluble sulphonato‐(salen)manganese(III) complex with excellent catalytic properties was synthesized and demonstrated to greatly enhance the chemiluminescence signal of the hydrogen peroxide ? luminol reaction. Coupled with flow‐injection technique, a simple and sensitive chemiluminescence method was first developed to detect hydroquinone based on the chemiluminescence system of the hydrogen peroxide–luminol–sulphonato‐(salen)manganese(III) complex. Under optimal conditions, the assay exhibited a wide linear range from 0.1 to 10 ng mL^–1 with a detection limit of 0.05 ng mL^–1 for hydroquinone. The method was applied successfully to detect hydroquinone in tap‐water and mineral‐water, with a sampling frequency of 120 times per hour. The relative standard deviation for determination of hydroquinone was less than 5.6%, and the recoveries ranged from 96.8 to 103.0%. The ultraviolet spectra, chemiluminescence spectra, and the reaction kinetics for the peroxide–luminol–sulphonato‐(salen)manganese(III) complex system were employed to study the possible chemiluminescence mechanism. The proposed chemiluminescence analysis technique is rapid and sensitive, with low cost, and could be easily extended and applied to other compounds. Copyright © 2015 John Wiley & Sons, Ltd.     

Determination of phenobarbital in human urine and serum using flow injection chemiluminescence

A sensitive chemiluminescence method has been proposed for Phenobarbital (PB) determination. It is based on the enhancive effect of PB on the chemiluminescence reaction between luminol and dissolved oxygen in a flow injection system. The chemiluminescence intensity linearly responded to the PB concentrations ranged from 0.05 to 10 ng/ml with the detection limit of 0.02 ng/ml (3σ). At a flow rate of 2.0 ml/ min, the whole procedure of PB determination (including sampling and washing) takes just 0.5 minute, offering the sampling efficiency of 120 per 1 h. The method was applied successfully for the PB assay in pharmaceutical preparations, human urine and serum without any pretreatment with recovery from 95.7 to 106.7% and RSDs of less than 3.0%.     

Involvement of hydroxyl free radical, but not superoxide, in the cytolytic pathway of natural killer cells. Revision of an earlier hypothesis

Our earlier hypothesis suggested that NK effectors, in response to tumor cells, generate superoxide anion (O2.-) which was necessary for NK cytolysis to proceed. This event could be detected by chemiluminescence. More recent data suggests that O2.- is not necessary for NK cytolysis and that chemiluminescence is the result of an NK-tumor cell-monocyte interaction. Hydroxyl radicals however do contribute to the NK-mediated cytolytic process. The source of OH. is unknown but does not appear to be generated by the NADPH oxidase system. We suggest that hydroxyl radical generation is a necessary event in NK cytolysis but we do not yet know if it acts at the level of NK activation, delivery of the lethal hit or in autolysis by the tumor cells.     

Chemiluminescence of lipid vesicles supplemented with cytochrome c and hydroperoxide.

The increase in light emission of hydroperoxide-supplemented cytochrome c observed on addition of lipid vesicles was related to the degree of unsaturation of the fatty acids of the phospholipids: dipalmitoyl phosphatidylcholine was without effect, whereas dioleoyl phosphatidylcholine and soya-bean phosphatidylcholine enhanced chemiluminescence 2- and 3-fold respectively. Effects on light-emission were similar to those on O2 uptake. The chemiluminescence of the present system was sensitive to cyanide and to the radical trap 2,5-di-t-butylquinol, indicating a catlytic activity of cytochrome c and the presence of free-radical species respectively. Lipid-vesicle enhanced chemiluminescence showed different kinetic behaviours, apparently depending on unsaturation: three phases are described for soya-bean phosphatidylcholine, whereas only one phase was present in mixtures containing dipalmitoyl and dioleoyl phospholipids. Chemiluminescence of lipid vesicles supplemented with cytochrome c and hydroperoxide showed similar kinetic patterns with H2O2 and primary (ethyl) and tertiary (t-butyl and cumene) hydroperoxides. Participation of singlet molecular oxygen, mainly on the phase III of chemiluminescence, is suggested by the increase of light-emission by 1,4-diazabicyclo[2.2.2]-octane as well as by data from spectral analysis.     

The increasing effect of some synthetic peptides on luminol-dependent chemiluminescence of mouse blood

Some synthetic peptides increased the luminol-dependent chemiluminescence of mouse blood during phagocytosis. It is suggested that the levels of antimicrobial activity of the neutrophil peroxidase system can be raised very quickly (within some dozen of seconds) by these peptides. This raises the possibility of finding a new approach to the therapy for infectious diseases.     

Improvements in and Environmental Applications of Double-Vial Radiorespirometry for the Study of Microbial Mineralization

Several variations in the scintillation mixture and the filter paper arrangements for double-vial radiorespirometry were compared. Improved efficiencies (44%) and shorter response times were found by adding wetting agents and methanolic NaOH to the scintillation mixture in the filter paper. The scintillation chemicals used did not contain dioxane and were found to be nontoxic to the test microbiota in this system. Covering the inner reaction vial with aluminum foil minimized the reduction in counting efficiency when testing colored or dense environmental samples. Mineralization rates were determined with ¹⁴C-labeled glucose, acetate, and glutamate and [¹⁴C]cellulose- and [¹⁴C]lignin-labeled lignocellulose for composting cow manure, forest soil, and arctic lake sediment microbiota. This improved method can be used in a variety of procedures involving the measurement of microbial mineralizations of organic compounds. Since no liquid scintillation cocktail is used for counting, the radioactive wastes are aqueous or can be incinerated, making disposal easy.