The reaction of nitro-blue tetrazolium with d,l-L-tetrahydrofolate: The effect of pH,oxygen, formaldehyde and palladium(II)

d,l-L-Tetrahydrofolate (d,l-L-FH₄) transfers two electrons to nitro-blue tetrazolium (NBT) in oxygen-free buffers to form the highly coloured nitro-blue formazan and oxidized folate. Both the rate and extent of this reaction are affected by the pH, the nature of the buffer and the oxygen concentration. Inhibition of both the rate and extent of this reaction in air-saturated solutions by superoxide dismutase (SOD) indicates that the superoxide anion is an intermediate in the reaction so that formazan can be produced by both superoxide independent and superoxide dependent routes in air-saturated solutions.In oxygen-free solutions several lines of evidence can be interpreted to mean that the reduced pteridine ring of tetrahydrofolate is the electron donor in the reaction with NBT. Ionization of the amide hydrogen of the pteridine ring and subsequent increase in electron density of that ring might explain the large increases observed in the rate and extent of the reaction of tetrahydrofolate with NBT as the pH increases. Formaldehyde reacts non-enzymatically with tetrahydrofolate to form a methylene bridge between nitrogens 5 and 10 of methylenetetrahydrofolate. This molecule is much less reactive with nitro-blue tetrazolium than tetrahydrofolate. Complexes formed between tetrahydrofolate and palladium(II) ions are also less reactive with NBT than the tetrahydrofolate alone. This result provides added evidence that palladium(II) ions interact with tetrahydrofolate at the nitrogen 5, nitrogen 10 site of the molecule.     

Protein Method for Investigating Mercuric Reductase Gene Expression in Aquatic Environments

A colorimetric assay for NADPH-dependent, mercuric ion-specific oxidoreductase activity was developed to facilitate the investigation of mercuric reductase gene expression in polluted aquatic ecosystems. Protein molecules extracted directly from unseeded freshwater and samples seeded with Pseudomonas aeruginosa PU21(Rip64) were quantitatively assayed for mercuric reductase activity in microtiter plates by stoichiometric coupling of mercuric ion reduction to a colorimetric redox chain through NADPH oxidation. Residual NADPH was determined by titration with phenazine methosulfate-catalyzed reduction of methyl thiazolyl tetrazolium to produce visible formazan. Spectrophotometric determination of formazan concentration showed a positive correlation with the amount of NADPH remaining in the reaction mixture (r² = 0.99). Mercuric reductase activity in the protein extracts was inversely related to the amount of NADPH remaining and to the amount of formazan produced. A qualitative nitrocellulose membrane-based version of the method was also developed, where regions of mercuric reductase activity remained colorless against a stained-membrane background. The assay detected induced mercuric reductase activity from 10² CFU, and up to threefold signal intensity was detected in seeded freshwater samples amended with mercury compared to that in mercury-free samples. The efficiency of extraction of bacterial proteins from the freshwater samples was (97 ± 2)% over the range of population densities investigated (10² to 10⁸ CFU/ml). The method was validated by detection of enzyme activity in protein extracts of water samples from a polluted site harboring naturally occurring mercury-resistant bacteria. The new method is proposed as a supplement to the repertoire of molecular techniques available for assessing specific gene expression in heterogeneous microbial communities impacted by mercury pollution.     

Reduction of tetrazolium salts catalyzed by soluble diaphorase in rat liver and embryos of Vicia faba

Summary The presence of two diaphorases has been shown in rat liver and embryos of Vicia fdba. One of these, the NAD(P)H tetrazolium reductase, was firmly bound in the section and was not lost into the incubation medium under conditions of histochemical assay The second diaphorase (soluble diaphorase) was lost from the section into the incubation medium during the first five minutes of incubation. This soluble diaphorase from both rat liver and embryos of V. faba is capable of transferring electrons from NAD(P)H to MTT, INT, NBT and TNBT, but not to tellurite, TTC, BT and NT. The behaviour of the soluble diaphorase in histochemical reactions involving tetrazolium salts as electron acceptors is discussed.     

Reaction rate studies of glucose-6-phosphate dehydrogenase activity in sections of rat liver using four tetrazolium salts

Summary The reaction rate of glucose-6-phosphate dehydrogenase activity in liver sections from fed and starved rats has been monitored by the continuous measurement at 37 C of the reaction product as it is formed using scanning and integrating microdensitometry. Control media lacked either substrate or both substrate and coenzyme. All reactions were nonlinear; however, subtraction of either of the controls from the test response produced linearity. Differing responses in sections of livers from fed and fasted rats indicate that the appropriate control medium for use in the assay of this dehydrogenase is one lacking both substrate and coenzyme rather than a medium containing coenzyme. The reaction rate was the same with each of the final acceptors. Problems with the diffusion of the formazan of BPST and with the failure to precipitate the formazan of Neotetrazolium make Tetranitro BT and Nitro BT the tetrazolium salts of choice in quantitative dehydrogenase assays.     

The use of tetrazolium salts in the histochemical demonstration of succinic dehydrogenase activity in plant tissues

Summary Succinic dehydrogenase activity was determined in fresh or cryostat sections of tissues from Allium cepa, Vicia faba, Pisum sativum and Helianthus tuberosus using different tetrazolium salts as electron accepters. In 10 fresh or frozen sections a reaction was obtained with TNBT, NBT, MTT, and INT but not with NT, BT or TTC. In contrast a reaction was obtained with each of the tetrazolium salts in 50–150 fresh or frozen sections. The observed differences in the abilities of the tetrazolium salts to demonstrate succinic dehydrogenase activity are discussed.The sites of acceptance of electrons from the electron transport pathway in plant cells by the tetrazolium salts has been demonstrated cytochemically, and shown to differ from those observed in animal cells in that unlike animal cells, there is no apparent acceptance of electrons by MTT and INT from cytochrome C₁-C region of the pathway.     

The quantification of formazans in tissue sections by microdensitometry. II. The use of BPST, a new tetrazolium salt

Synopsis This article describes the use of a microdensitometer for the measurement of BPST formazan in tissue sections. BPST is a new tetrazolium salt, 2-(2-benzothiazolyl)-3-(4-phthalhydrazidyl)-5-styryl-tetrazolium chloride, which produces a single, well-defined formazan, and is thus easily quantified. The formazan gives an excellent localization, since BPST was originally designed for ultrastructural work. Activities are expressed in absolute units as n moles hydrogen/mm³, and are thus directly comparable with standard biochemical data.     

On the role of oxygen in dehydrogenase reactions using tetrazolium salts

Summary Fundamental aspects of the reduction fo tetrazolium salts were investigated and, in particular, the role of oxygen in the reduction. It was found that oxygen had a competitive inhibitory effect on the reduction of (Tetra)Nitro BT mediated by NADH and phenazine methosulphate. This competitive effect, under aerobic conditions, could be reversed by using tetrazolium concentrations of 5mm. Oxygen did not have a signIficant effect on BPST reduction, whereas the inhibitory effect of oxygen on the reduction of Neotetrazolium was not reversed by increasing the tetrazolium concentration. The oxygen effect on Nitro BT reduction was considerably less when macromolecular substances such as albumin or polyvinyl alcohol were added to the medium. This may be due to increased Nitro BT concentrations being built up at the surface of macromolecules due to the nonpolar components of the Nitro BT molecule. When demonstrating glucose-6-phosphate dehydrogenase activityin vitro or in tissue sections with the use of Nitro BT, oxygen also had a direct inhibitory effect, even when azide was added to the medium for the inhibition of flavoprotein-mediated electron transfer to oxygen. Again, this direct inhibition of Nitro BT reduction by oxygen could be excluded by using a high Nitro BT concentration. Macromolecules present in the incubation medium or in tissue sections counteracted the oxygen effect. It is concluded that the maximum reaction rate and optimum localization of dehydrogenases is obtained when histochemical media are used containing 5mm (Tetra)Nitro BT and 20% polyvinyl alcohol.     

A fluorescent redox dye. Influence of several substrates and electron carriers on the tetrazolium salt-formazan reaction of Ehrlich ascites tumour cells

Summary This study was performed to elaborate the best conditions for measuring the redox activity of Ehrlich ascites tumour cells by using a new tetrazolium salt, cyantolyl tetrazolium chloride (CTC). This tetrazolium salt forms a fluorescent water-insoluble formazan on reduction on the surface of intact vital cells. The influences of fixation and of various substrates and electron carriers on the cellular reduction of CTC were investigated quantitatively using an elution technique. The amount of formazan obtained after incubating vital cells with Meldola Blue as electron carrier was greater than that obtained with Methylene Blue, menadione, 2,6-dichloroindophenol, 1-methoxyphenazine methosulphate or phenazine methosulphate. Using flow cytometry, the formazan production per cell and, after staining the nuclear DNA, the distribution of the redox activity in the cell population can be visualized with satisfactory resolution. We conclude from our findings that dehydrogenases are only partially involved in the reduction of tetrazolium salts by intact cells and that a redox activity, probably related to a cell membrane-bound NAD(P)H—oxidase system, is mainly measured.     

A model for NADH-tetrazolium reductase

Summary In the presence of light, reduced nicotinamide adenine dinucleotide (NADH) and riboflavin formed a complex which was able to reduce certain tetrazolium salts. Neither NADH (10^–3 M) nor riboflavin (10^–4 M) alone was able to induce tetrazolium reduction in the presence of oxygen, but in a nitrogen atmosphere photoreduction of riboflavin induced reduction of tetrazolium salts. Only electrophilic nitro and thiazolyl substituted tetrazolium salts with more positive redox potentials were reduced by the NADH-riboflavin complex, and only monoformazans were produced from the ditetrazolium salts. The reduction kinetics of these tetrazolium salts are given, and the spectral area capable for induction of electron transfer in the NADH-riboflavin complex is screened. It is concluded that the electron transfer in flavin nucleotide dependent dehydrogenase systems will probably proceed without direct interference with the apoenzyme. This may have practical implications for the histochemistry of tetrazolium reductases especially as regards fixation. The catalytic action of light on tetrazolium reduction should also be taken into consideration when tetrazolium salts are used as electron acceptors in a histochemical reaction.     

Studies on the phenazine methosulphate-tetrazolium salt capture reaction in NAD(P)+-dependent dehydrogenase cytochemistry. I. Localization artefacts caused by the escape of reduced co-enzyme during cytochemical reactions for NAD(P)+-dependent dehydrogenases

The correct localization of oxidative enzymes using cytochemical tetrazolium methods, in which low molecular weight electron carriers such as NAD(P)H and reduced phenazine methosulphate (PMSH) are used, can be endangered by the escape of the reduced intermediates before they react to form the insoluble formazan at the true enzyme-containing sites. To investigate this phenomenon, the glucose-6-phosphate dehydrogenase reaction was studied in fixed erythrocytes which, because of their microscopic dimensions, are well-suited for studying the loss of intermediates. A mixture of active and heat-inactivated fixed erythrocytes was incubated in a PMS-supplemented medium for glucose-6-phosphate dehydrogenase. The cytophotometric histograms showed that the final formazan precipitate was equally distributed over both active and inactivated cells. When bovine serum albumin was added to the medium, all the formazan was found to be bound to this protein and the erythrocytes remained essentially unstained. The false localization in this system could be explained by an unfavourable balance between the capture of electrons carried by NADPH within the erythrocyte and the diffusion of NADPH out of the erythrocyte. The rate constant of NADPH oxidation was determined, as was also the diffusion constant of NADPH in a protein matrix. Substituting the data obtained into formulae derived from the enzyme cytochemical localization theory of Holt & O'Sullivan (1958), it was calculated that the capture reaction was highly deficient and, theoretically, less than 1% of the total amount of formazan produced was localized within the erythrocyte which explains the false localization observed. The importance of these findings for the cytochemical demonstration of NAD(P)+-dependent dehydrogenases in cells and electropherograms is briefly discussed.     

Micromolar colorimetric detection of 2-hydroxy ketones with the water-soluble tetrazolium WST-1

The archetypal triphenyl tetrazolium chloride (tetrazolium red) has been used in spectrophotometric microplate assays for 2-hydroxy ketones and, by extension, for the activity of enzymes including aminotransferase, transketolase, and pyruvate decarboxylase. Better sensitivity, dynamic range, and reproducibility of this method may be achieved by (i) in situ solubilization of the colored formazan with Cremophor EL and (ii) use of the newer-generation tetrazolium salts tetrazolium violet, iodonitrotetrazolium, or WST-1 (water-soluble tetrazolium). Two to 125 μM hydroxy pyruvate, dihydroxy acetone, and indole pyruvate produced by serine:pyruvate, β-alanine (ω-amino acid):pyruvate, and aromatic amino acid aminotransferase, respectively, could be detected with WST-1.     

An enzymatic colorimetric assay for glucose-6-phosphate

A specific colorimetric assay for the determination of glucose-6-phosphate (G6P) was developed. This assay is based on the oxidation of G6P in the presence of glucose-6-phosphate dehydrogenase (G6PD) and nicotinamide adenine dinucleotide phosphate (NADP⁺); the NADPH thereby generated reduces the tetrazolium salt WST-1 [2-(4-indophenyl)-3-(4-nitrophenyl)-5-(2,4-disulfophenyl)-2H tetrazolium, monosodium salt] to water-soluble yellow-colored formazan with 1-methoxy-5-methylphenazium methylsulfate (1-mPMS) as an electron carrier. The assay is optimized for reaction buffer pH, enzyme/dye concentration, and reaction time course. The limit of detection of the assay is 0.15 μM (15 pmol/well). The usefulness of the assay is demonstrated by the accurate measurement of the G6P concentration in fetal bovine serum (FBS).     

Anti-Plasmodium activity of imidazolium and triazolium salts

We have previously reported that tetrazolium salts were both potent and specific inhibitors of Plasmodium replication, and that they appear to interact with a parasite component that is both essential and conserved. The use of tetrazolium salts in vivo is limited by the potential reduction of the tetrazolium ring to form an inactive, neutral acyclic formazan. To address this issue imidazolium and triazolium salts were synthesized and evaluated as Plasmodium inhibitors. Many of the imidazolium and triazolium salts were highly potent with active concentrations in the nanomolar range in Plasmodium falciparum cultures, and specific to Plasmodium with highly favorable therapeutic ratios. The results corroborate our hypothesis that an electron-deficient core is required so that the compound may thereby interact with a negatively charged moiety on the parasite merozoite; the side groups in the compound then form favorable interactions with adjacent parasite components and thereby determine both the potency and selectivity of the compound.     

Characteristics of Eliciting Effects of Furostanol Glycosides on Cultured Yam Cells

To unravel mechanisms of elicitor action of furostanol glycosides (FGs), the formation of superoxide anion after the addition of FGs to a suspension culture of yam (Dioscorea deltoidea Wall. ex Griseb) cells was studied. The substantial increase in superoxide level, evaluated by nitroblue tetrazolium (NBT) reduction to formazan, was found at the exponential phase of cell growth. The involvement of NADPH oxidase in the superoxide generation was revealed by means of inhibitory analysis. Diphenyliodonium chloride (DPI), the inhibitor of NADPH oxidase, compromised the action of FGs. Meanwhile, the elimination of apoplastic peroxidase did not affect the accumulation of formazan, which suggests the involvement of NADPH oxidase but not peroxidase in the superoxide generation. In addition to NBT-test, the superoxide formation was judged by changes in activity of superoxide dismutase (SOD). Exogenous FGs activated the enzyme due to the increased production of superoxide anion. In this case, DPI decreased SOD activity that conforms to the NADPH oxidase involvement in the superoxide generation. The analysis of antioxidant activity of FGs by inhibition of radicals of 2,2-diphenyl-1-picrylhydrazyl showed that FGs are weak reductants in comparison with ascorbic acid. The results of the work allow for the suggestion that, supposing a weak reducing capacity of FGs, the special feature of their exogenous action on cultured yam cells is the increase in the level of superoxide anion radical mainly produced by NADPH oxidase.     

Activation of plasmalemmal NADPH oxidase in etiolated maize seedlings exposed to chilling temperatures

Five-day-old etiolated seedlings of maize (Zea mays L.) were used to study the kinetics of hydrogen peroxide formation upon lowering growth temperature from 25 to 6°C. The total content of hydrogen peroxide in root and shoot tissues increased by 30–40% after 2-h cooling compared to the control level but returned to the initial level or decreased even lower after 24-h cooling. In order to prove the involvement of plasma membrane NADPH oxidase in changes of hydrogen peroxide content upon cooling, isolated plasma membranes were obtained from untreated plants and from seedlings chilled at 6°C for 2 and 24 h. The NADPH-dependent generation of superoxide anion radical in isolated plasma membranes was quantified by measuring the rate of formazan production from the tetrazolium salt XTT. The activity of plasma membrane NADPH oxidase in shoots was 50 ± 9 nmol O₂/(mg protein min), which was 1.5 times higher than the activity in roots. The enzyme activity in plasma membranes was inhibited by low concentrations of diphenyleneiodonium. The effective concentration EC₅₀ was 5.10 μM for shoots and 9.05 μM for roots. The activity of plasma membrane NADPH oxidase increased after 2-h cooling of seedlings but reversed to the control level after 24-h cooling. This transient activation of NADPH oxidase upon cooling was similar to the pattern of hydrogen peroxide formation in shoots and roots. Analysis of NADPH oxidase activity of plasma membrane proteins after their separation in denaturing conditions followed by subsequent renaturation revealed four diphenyleneiodonium-sensitive bands with mol wt of 130, 88, 51, and 48 kD. Western blot analysis of the reaction with antibodies against the catalytic domain of phagocyte NADPH oxidase revealed the proteins with mol wt of only 88 and 48 kD. The properties of molecular organization of plasma membrane NADPH oxidase are discussed in terms of its role in cell signaling.     

Tetrazolium salts: a consumer's guide

Synopsis The purities of seven tetrazolium salts, obtained from various commercial sources, have been assessed by thin layer chromatography, relative extinction coefficients, and melting points. MTT and INT were largely homogeneous on thin layer chromatography, although significant variations occurred in the melting point behaviour. All the samples of TT examined were contaminated to a small extent with non-tetrazolium u.v.-absorbing material. TNBT and NBT were contaminated with small amounts of mono-tetrazolium salts, although one sample of each was heavily contaminated with another di-tetrazolium compound. Four samples of TNBT contained high melting point contaminants. BT was also contaminated with mono-tetrazolium salts, and some samples also contained di-tetrazolium salt contaminants. NT was the most heavily contaminated of all, most samples containing no less than five separate tetrazolium compounds. Prices varied widely, and in general were not related to purity. Some catalogue entries were very easy to find; others were more difficult. Few specifications were given; of these, most were arbitrary (for example, pure, grade I, and ... probably the finest INT offered anywhere).     

The Cytochemical Localization of Oxidative Enzymes : II. Pyridine Nucleotide-Linked Dehydrogenases

Methods are presented for the intramitochondrial localization of various diphosphopyridine nucleotide and triphosphopyridine nucleotide-linked dehydrogenases in tissue sections. The cytochemical reactions studied involve the oxidation of the substrates by a specific pyridino-protein. The electron transfer of tetrazolium salt is mediated by the diaphorase system associated with the dehydrogenase. The final electron acceptor was either p-nitrophenyl substituted ditetrazole (nitro-BT) or N-thiazol-2-yl monotetrazole (MTT), the latter giving rise to metal formazan in the presence of cobaltous ions. Mitochondrial localization of the formazan precipitate could be achieved by using hypertonic incubating media containing high concentrations of substrate and co-enzyme. A fast reduction of tetrazolium salt was obtained by chemically blocking the respiratory chain enzymes beyond the flavoproteins. Although diaphorase systems are implicated in the reduction of tetrazolium salts, specific dehydrogenases are solely responsible for the distinct distribution pattern obtained in tissues with various substrates. The present findings in tissue sections are discussed in conjunction with existing biochemical evidence from differential centrifugation experiments.     

Quantitative bioreduction assays for calibrating spore content and viability of commercial Bacillus thuringiensis insecticides

The redox dyes MTT (3-{4,5-dimethylthiazol-2-yl}-2,5-diphenyl tetrazolium bromide, thiazolyl blue) and XTT (sodium 3′- {1-[(phenylamino)-carbonyl]-3,4-tetrazolium}-bis{4-methoxy-6-nitro} benzene sulphonic acid hydrate) were used as dosimetry reporters in liquid (multi-well) and solid support (membrane) assays to estimate spore viability and content of commercial BT products derived from fermentation of Bacillus thuringiensis subsp kurstaki (Btk) and subsp israelensis (Bti). QC tests on five BT products were done using spore, protein and gene contents, and morphology (scanning electron microscopy) as indicators. Spore levels (6–40 × 10⁹ colony forming units (CFU) ml⁻¹) were approximately equivalent when based on International Units (IU) of potency. Spore viability was highly stable over a broad range of temperatures and pHs but germination and growth were restricted (optima: pH ≈ 7.5 and 37°C). Quantitative bioreduction activity (QBA) of MTT and XTT correlated with vegetative cell production. Depending on manipulation of pre-assay conditions, both dyes could discriminate doses from ∼2 to 10⁹ spores (or 10⁻³ to 10⁶ IU). Non-toxic effects of XTT and its formazan product enabled automated collection of data on growth and dose. Solid support assays also reliably estimated product dosage by in situ detection of CFU. With appropriate reference dilutions of microbe-containing products the QBA assays can provide high throughput QC monitoring of product comparisons and field release in aerial spray or water injection applications. Received 18 December 1996/ Accepted in revised form 11 March 1997     

Quantitative determination of superoxide in plant leaves using a modified NBT staining method

Introduction – In plants, the ROS (reactive oxygen species) level is tightly regulated because their accumulation produces irreversible damage leading to cell death. However, ROS accumulation plays a key role in plant signaling under biotic or abiotic stress. Although various methods were reported to evaluate ROS accumulation, they are restricted to model plants or provide only qualitative information. Objective – Develop a simple method to quantify superoxide radicals produced in plant tissues, based on the selective extraction of the formazan produced after nitroblue tetrazolium (NBT) reduction in histochemical staining. Methodology – Plant leaves were stained with a standard NBT method and the formazan precipitated in tissues was selectively extracted using chloroform. The organic phase was dried and formazan residue dissolved in dimethylsulfoxide–potassium hydroxide and quantified by spectrophotometry. The method was tested in strawberry plant leaves under different stressing conditions. Results – Formazan extracted from leaves subjected to stress conditions showed similar absorption spectra to those obtained from standard solutions using pure formazan. Calibration curves showed a linear relationship between absorbance and formazan amounts, within the range 0.5–8 µg. Outcomes suggested that formazan was retained in the solid residue of leaf tissues. This protocol allowed us to quantify superoxide radicals produced under different stress conditions. Conclusions – Chloroform allowed a selective formazan extraction and removal of potential endogenous, exogenous or procedural artefacts that may interfere with the quantitative determination. This protocol can be used to quantify the superoxide produced in plant tissues using any traditional qualitative NBT histochemical staining method.