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.     

Superoxide anion radical-independent pathway for reduction of tetrazolium salts in aerobic mixtures consisting of NADH and 5-methylphenazinium methyl sulfate in the presence of aqueous micelles of nonionic and cationic detergents

The effect of Triton X-100 and certain other nonionic as well as cationic detergents on 5-methyl-phenazinium methyl sulfate (PMS)-mediated reduction of tetrazolium salts was studied under aerobic conditions using an exogenous source of reducing equivalents, such as NADH or by generating NADPH through an enzymatic reaction. In the absence of detergents, 5,10-dihydro-5-methylphenazine (MPH), formed on reduction of 5-methylphenazinium cation (MP+) of PMS by NAD[P]H, was reoxidized allowing first the univalent reduction of molecular oxygen (O2) to the superoxide anion radical (O2-.) which, in turn, reduced tetrazolium salts. In the presence of detergents, however, a significant fraction of the PMS-mediated reduction of tetrazolium salts appeared to proceed without the intervention of O2-. The reasons for this were examined experimentally and it was suggested that the reduced phenazine (i.e., MPH), which is sparingly soluble in aqueous solutions, migrates into detergent micelles where tetrazolium salts are reduced in preference to O2. By lowering the pH and thereby facilitating the H+-mediated dismutation of O2-., it was possible to obtain the reduction of tetrazolium salts, mediated selectively and directly by MPH in the micellar pseudophase. Employing the technique of saturation analysis, further evidence was obtained that lends support for preferential reduction of tetrazolium salts (e.g., nitroblue tetrazolium chloride) to that of O2 by the micelle-bound MPH.     

Studies on the phenazine methosulphate--tetrazolium salt capture reaction in NAD(P)+-dependent dehydrogenase cytochemistry. III. The role of superoxide in tetrazolium reduction

Summary A study was made of the involvement of superoxide anions in the aerobic reduction of tetrazolium salts by NAD(P)H and phenazine methosulphate (PMS). On the basis of experiments with superoxide dismutase two mechanisms of tetrazolium reduction could be distinguished-one in which fully reduced PMS (PMSH) is the reducer and one in which superoxide anion is the reducer of tetrazolium salts. It is proposed that superoxide anion is formed after a PMSH-PMS⁺ dismutation reaction. The relative contributions of the two distinct pathways to tetrazolium salt reduction are controlled by the PMS redox state and the oxygen tension. The consequences of the presence of superoxide anions and scavengers of superoxide anions for quantitative dehydrogenase cytochemistry are discussed.     

Localized Tetrazolium Reduction in Relation to N2 Fixation, CO2 Fixation, and H2 Uptake in Aquatic Filamentous Cyanobacteria

The aquatic filamentous cyanobacteria Anabaena oscillarioides and Trichodesmium sp. reveal specific cellular regions of tetrazolium salt reduction. The effects of localized reduction of five tetrazolium salts on N₂ fixation (acetylene reduction), ¹⁴CO₂ fixation, and ³H₂ utilization were examined. During short-term (within 30 min) exposures in A. oscillarioides, salt reduction in heterocysts occurred simultaneously with inhibition of acetylene reduction. Conversely, when salts failed to either penetrate or be reduced in heterocysts, no inhibition of acetylene reduction occurred. When salts were rapidly reduced in vegetative cells, ¹⁴CO₂ fixation and ³H₂ utilization rates decreased, whereas salts exclusively reduced in heterocysts were not linked to blockage of these processes. In the nonheterocystous genus Trichodesmium, the deposition of reduced 2,3,5-triphenyl-2-tetrazolium chloride (TTC) in the internal cores of trichomes occurs simultaneously with a lowering of acetylene reduction rates. Since TTC deposition in heterocysts of A. oscillarioides occurs contemporaneously with inhibition of acetylene reduction, we conclude that the cellular reduction of this salt is of use in locating potential N₂-fixing sites in cyanobacteria. The possible applications and problems associated with interpreting localized reduction of tetrazolium salts in cyanobacteria are presented.     

Menadiol diphosphate, a new substrate for non-specific alkaline phosphatase in histochemistry and immunohistochemistry.

Menadiol diphosphate was introduced as a new substrate for nonspecific alkaline phosphatase, following a search for new and less expensive substrates, which give a more sensitive response and are easily synthesized in the laboratory. Menadiol released by phosphatase action can be assayed by its reduction of tetrazolium salts, or it can be coupled with diazonium salts; alternatively, the phosphate can be trapped by metal ions. The synthesis and purification of menadiol diphosphate are described, and it was shown to be sufficiently stable for qualitative and semiquantitative histochemistry, as well as for the immunohistochemistry of enzymes and cytoskeletal proteins with nonspecific alkaline phosphatase as the enzyme label. For qualitative as well as semiquantitative histochemistry and immunohistochemistry, the best results were obtained by applying the method with nitro-blue tetrazolium (NBT) to acetone-chloroform pretreated cryostat sections. Tetranitro-blue tetrazolium (TNBT), benzothiazolylphthalhydrazidyl tetrazolium (BSPT) and various diazonium salts were less suitable. Fast Blue BB and VB produced satisfactory results. Ce3+ ions and the DAB-Ni-H2O2 procedure yielded better results than Ca2+ ions in the Co-(NH4)2S visualization method. The NBT method with menadiol diphosphate is superior to existing methods employing azo, azoindoxyl or tetrazolium salts and to metal precipitation methods. The Ce3+ technique and the NBT/menadiol diphosphate method give similar results, and appear to be of equal value. In qualitative histochemistry and immunohistochemistry the NBT/menadiol diphosphate method resulted in higher quantities of precisely localized stain. Semiquantitative histochemistry with minimal incubation revealed more favorable kinetics for the menadiol diphosphate method, especially when using NBT.     

Localized Tetrazolium Reduction in Relation to N(2) Fixation, CO(2) Fixation, and H(2) Uptake in Aquatic Filamentous Cyanobacteria

The aquatic filamentous cyanobacteria Anabaena oscillarioides and Trichodesmium sp. reveal specific cellular regions of tetrazolium salt reduction. The effects of localized reduction of five tetrazolium salts on N(2) fixation (acetylene reduction), CO(2) fixation, and H(2) utilization were examined. During short-term (within 30 min) exposures in A. oscillarioides, salt reduction in heterocysts occurred simultaneously with inhibition of acetylene reduction. Conversely, when salts failed to either penetrate or be reduced in heterocysts, no inhibition of acetylene reduction occurred. When salts were rapidly reduced in vegetative cells, CO(2) fixation and H(2) utilization rates decreased, whereas salts exclusively reduced in heterocysts were not linked to blockage of these processes. In the nonheterocystous genus Trichodesmium, the deposition of reduced 2,3,5-triphenyl-2-tetrazolium chloride (TTC) in the internal cores of trichomes occurs simultaneously with a lowering of acetylene reduction rates. Since TTC deposition in heterocysts of A. oscillarioides occurs contemporaneously with inhibition of acetylene reduction, we conclude that the cellular reduction of this salt is of use in locating potential N(2)-fixing sites in cyanobacteria. The possible applications and problems associated with interpreting localized reduction of tetrazolium salts in cyanobacteria are presented.     

Menadiol diphosphate,a new substrate for non-specific alkaline phosphatase in histochemistry and immunohistochemistry

Summary Menadiol diphosphate was introduced as a new substrate for nonspecific alkaline phosphatase, following a search for new and less expensive substrates, which give a more sensitive response and are easily synthesized in the laboratory. Menadiol released by phosphatase action can be assayed by its reduction of tetrazolium salts, or it can be coupled with diazonium salts; alternatively, the phosphate can be trapped by metal ions. The synthesis and purification of menadiol diphosphate are described, and it was shown to be sufficiently stable for qualitative and semiquantitative histochemistry, as well as for the immunohistochemistry of enzymes and cytoskeletal proteins with nonspecific alkaline phosphatase as the enzyme label. For qualitative as well as semiquantitative histochemistry and immunohistochemistry, the best results were obtained by applying the method with nitro-blue tetrazolium (NBT) to acetone-chloroform pretreated cryostat sections. Tetranitro-blue tetrazolium (TNBT), benzothiazolylphthalhydrazidyl tetrazolium (BSPT) and various diazonium salts were less suitable. Fast Blue BB and VB produced satisfactory results. Ce³⁺ ions and the DAB−Ni−H₂O₂ procedure yielded better results than Ca²⁺ ions in the Co−(NH₄)₂S visualization method. The NBT method with menadiol diphosphate is superior to existing methods employing azo, azoindoxyl or tetrazolium salts and to metal precipitation methods. The Ce³⁺ technique and the NBT/menadiol diphosphate method give similar results, and appear to be of equal value. In qualitative histochemistry and immunohistochemistry the NBT/menadiol diphosphate method resulted in higher quantities of precisely localized stain. Semiquantitative histochemistry with minimal incubation revealed more favorable kinetics for the menadiol diphosphate method, especially when using NBT. Supported by the Alexander von Humboldt-Stiftung and the Deutsche Forschungsgemeinschaft (Sfb 174)     

The role of plasma membrane in bioreduction of two tetrazolium salts, MTT, and CTC

Despite widespread use of various tetrazolium assays, the mechanisms of bioreduction of these compounds have not been fully elucidated. We investigated the capacity of tetrazolium salts to penetrate through intact cell plasma membranes. 5-cyano-2,3-ditolyl tetrazolium chloride (CTC) and 3-(4,5-dimethylthiazol-2-yl)-2,5 diphenyltetrazolium bromide (MTT) tetrazolium salts appear to represent examples of species that are reduced by different mechanisms. We provide evidence suggesting that MTT readily crosses intact plasma membranes and is reduced intracellularly. MTT appears to be reduced by both plasma membrane and intracellular reductases; reducing cells are not damaged and remain metabolically active for at least 45 min. In contrast, CTC remains extracellular with respect to viable cells and thus requires plasma membrane permeable electron carrier to be reduced efficiently. However, reduction of CTC in the presence of an electron carrier inflicts damage on plasma membranes. The intracellular vs extracellular sites of reduction of tetrazolium salts were established on the basis of deposition of formazans. Crystals of formazan were detected using fluorescence or backscattered light confocal laser microscopy. We postulate that the capacity of a tetrazolium salt to cross intact plasma membranes constitutes an important experimental variable which needs to be controlled in order to correctly interpret the outcome of tetrazolium assays designed to measure cellular production of oxygen radicals, activity of mitochondrial, cytosolic, or outer membrane reductases, etc.     

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.     

Some effects of tetrazolium salt on the metabolism of mitochondria isolated from Jerusalem artichoke tubers

Summary A series of tetrazolium salts were found to accept electrons more readily from succinate than malate even though the rate of oxygen uptake was similar with both substrates. This difference was explained by showing that all the tetrazolium salts tested caused a reduction in electron flow between NAD⁺ and Cyt.b. The tetrazolium salts were also found to be able to uncouple phosphorylation from electron transport. The monotetrazolium salts causing complete uncoupling around 100 moles/litre and the ditetrazolium salts causing complete uncoupling around 20 moles/litre.     

Applicability of tetrazolium salts for the measurement of respiratory activity and viability of groundwater bacteria

A study was undertaken to measure aerobic respiration by indigenous bacteria in a sand and gravel aquifer on western Cape Cod, MA using tetrazolium salts and by direct oxygen consumption using gas chromatography (GC). In groundwater and aquifer slurries, the rate of aerobic respiration calculated from the direct GC assay was more than 600 times greater than that using the tetrazolium salt 2-(4-iodophenyl)-3-(4-nitrophenyl)-5-phenyl tetrazolium chloride (INT). To explain this discrepancy, the toxicity of INT and two additional tetrazolium salts, sodium 3'-[1-(phenylamino)-carbonyl]-3,4-tetrazolium]-bis(4-methoxy-6-nitro) benzenesulfonic acid hydrate (XTT) and 5-cyano-2,3-ditolyl tetrazolium chloride (CTC), to bacterial isolates from the aquifer was investigated. Each of the three tetrazolium salts was observed to be toxic to some of the groundwater isolates at concentrations normally used in electron transport system (ETS) and viability assays. For example, incubation of cells with XTT (3 mM) caused the density of four of the five groundwater strains tested to decline by more than four orders of magnitude. A reasonable percentage (>57%) of cells killed by CTC and INT contained visible formazan crystals (the insoluble, reduced form of the salts) after 4 h of incubation. Thus, many of the cells reduced enough CTC or INT prior to dying to be considered viable by microscopic evaluation. However, one bacterium (Pseudomonas fluorescens) that remained viable and culturable in the presence of INT and CTC, did not incorporate formazan crystals into more than a few percent of cells, even after 24 h of incubation. This strain would be considered nonviable based on traditional tetrazolium salt reduction assays. The data show that tetrazolium salt assays are likely to dramatically underestimate total ETS activity in groundwater and, although they may provide a reasonable overall estimate of viable cell numbers in a community of groundwater bacteria, some specific strains may be falsely considered nonviable by this assay due to poor uptake or reduction of the salts.     

The two dimensional structure of tetrazolium-mucopolysaccharide complexes deduced from reactivity studies.

The formation of complexes between mucopolysaccharides and tetrazolium salts has been studied both by turbidimetry and nephelometry. The technique of laser nephelometry allows the detection of colloidal aggregates in systems which may, by turbidimetric methods, be ambiguous. The results indicate that binding of tetrazolium salts to polyanions can result in soluble as well as insoluble complexes; the monotetrazolium salts form soluble complexes and the ditetrazolium compounds form insoluble complexes. The insoluble complexes are stable at relatively low pH, and are disrupted during reduction to the formazan. Complex formation is decreased at high ratios of heparin to tetrazolium, and divalent cations, even at high concentration, do not precipitate mucopolysaccharides. It is concluded that stable ionic interactions with spatial charge separation are responsible for the cross linking of the mucopolysaccharides and the formaiton of large insoluble aggregates.     

Use of tetrazolium salts for electron transport studies in meningopneumonitis. I. Reduced nicotinamide adenine dinucleotide system

Allen, Emma G. (Downstate Medical Center, Brooklyn, N.Y.). Use of tetrazolium salts for electron transport studies in meningopneumonitis. I. Reduced nicotinamide adenine dinucleotide system. J. Bacteriol. 90:1505-1512. 1965.-Purified preparations of meningopneumonitis virus (MP) prepared from allantoic fluids of infected chick embryo reduce several tetrazolium salts in the presence of reduced nicotinamide adenine dinucleotide under both aerobic and anaerobic conditions. The pattern of reduction by MP differs from that seen in normal allantoic membrane homogenates, and is inhibited by several cations but not by KCN, atabrine, amytal, antimycin A, or 2,3-dimercaptopropanol (BAL). The reduction of cytochrome c by purified preparations of MP differs from its reduction of tetrazolium salts in that the cytochrome reaction is completely inhibited by BAL and partially inhibited by amytal, atabrine, and antimycin A. The cytochrome reductase of normal allantoic membrane preparations is completely inhibited by each of these compounds.     

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.     

In Vitro Reduction of Tetrazolium Indicators by Sulfhydryl Compounds

There was considerable variation between the sulfhydryl induced in vitro reduction of the oxidation-reduction indicators (2,3,5-triphenyltetrazolium chloride, 2,3-diphenyl 5-methyl tetrazolium chloride, neotetrazolium chloride, neotetrazolium phosphate-2B, blue tetrazolium, tetrazolium violet, potassium tellurite, methylene blue, and resazurin). The neotetrazolium salts and potassium tellurite showed the greatest reducing activity. The reduction of the indicators by oxidized sulfhydryl compounds in the presence of potassium cyanide closely paralleled the reduction of the sarrte indicators by reduced sulfhydryl compounds. Iodoacetamide was the most effective sulfhydryl inhibitor as demonstrated by indicator reduction.     

Tetrazolium [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide] reduction by mycoplasmas.

We investigated 22 mycoplasma and acholeplasma species for their ability to reduce tetrazolium salts by using the MTT [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide] assay. The test results were evaluated visually, as well as spectrophotometrically, by using an enzyme-linked immunosorbent assay reader. Our results were very similar to the results obtained when the tetrazolium salt reduction assay described by Aluotto et al. was used. However, the MTT reduction assay appeared to be better because it is faster, more objective and sensitive, easier to evaluate, and less expensive; in addition, it allows quantitative determinations. By using regression analysis a linear correlation between formazan production and the number of colony-forming units was demonstrated for all of the species investigated, indicating that the MTT assay can also be used for growth, toxicity, or chemosensitivity tests for the mycoplasma species that are capable of reducing tetrazolium salts.     

The effect of intermediate respiratory chain inhibitors upon the tetrazolium-reductase activity of human polymorphonuclear leukocytes.

Intact human phagocytes are capable of reducing tetrazolium salts in their cytoplasm. The exact mechanism that reduces the dye is not well understood. It has been suggested that increased NADH and stimulation of NADH-oxidase may be responsible for tetrazolium reduction. This reaction is insensitive to terminal respiratory inhibitors such as cyanide, but the effect of intermediate respiratory inhibitors has not been explored. Amytal and Antimycin A were used in blood from 60 healthy subjects to study its effect upon the biochemical and histochemical tetrazolium-reductase reactions. It was found that Amytal and Antimycin block the reaction, while azide and cyanide have no effect. It was concluded that electrons are trapped between cytochromes b and C₁ and that this portion of the respiratory chain is essential for tetrazolium reduction. Since CoQ is the main constituent of that portion of the chain, we assume that this compound could be of prime importance in the biochemical events that lead to intracytoplasmic tetrazolium reduction. The possibility of CoQ participation in some phagocytic functions and in phagocytic disorders is discussed.     

Effects of tetrazolium salts on oxidative phosphorylation in rat-liver mitochondria

1. The effects of five different tetrazolium salts on oxidative phosphorylation in rat-liver mitochondria have been investigated. 2. In all cases the mitochondria were uncoupled by very low concentrations of the tetrazolium salts. Further, the transition from a system just exhibiting respiratory control to one in which the mitochondria were totally uncoupled has been shown to occur over very small concentration ranges of the tetrazolium salts. 3. The effectiveness of the five tetrazolium salts as uncoupling agents is discussed in the light of their standard electrode potentials and effectiveness as electron acceptors in dehydrogenase-linked reactions.     

The enzymic estimation of glutamate and glutamine

A method of estimating glutamic acid is described, based on its dehydrogenation by glutamate dehydrogenase coupled, by means of N-methylphenazine methosulphate, to the reduction of tetrazolium salts. The method is suitable for the estimation of 0-0.3mumole of glutamic acid. The response is linear, but not stoicheiometric: possible reasons for this are discussed. If suitable precautions are taken, the use of a partially purified preparation of glutaminase makes it possible to estimate glutamine also.     

The Menadione-Mediated WST1 Reduction by Cultured Astrocytes Depends on NQO1 Activity and Cytosolic Glucose Metabolism

Neurochemical Research - The reduction of water-soluble tetrazolium salts (WSTs) is frequently used to determine the metabolic integrity and the viability of cultured cells. Recently, we have...