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.     

The sensitivity to light of solutions of phenazine methosulphate: a quantitative cytochemical study

Summary The ability of phenazine methosulphate to transfer electrons from reduced coenzymes to a tetrazolium salt, neotetrazolium chloride, after exposure to light for various periods of time has been studied. Enzymes assayed for this purpose were: glucose-6-phosphate dehydrogenase (NADP⁺-dependent); lactate dehydrogenase (NAD⁺-dependent) and succinate dehydrogenase (flavoprotein-dependent). Enzyme activity was measured in sections of rodent liver by scanning and integrating microdensitometry. Phenazine methosulphate in solution was found to be sufficiently stable in light for up to two hours for reproducible quantitative measurements of cytochemical dehydrogenase activity to be obtained over this period.     

Quantitative succinic dehydrogenases histochemistry

Summary Activity of succinic dehydrogenase (SD, EC 1.3.99.1) was investigated in the livers of 17 male albino rats by means of the tetrazolium salts NBT, INT, MTT, BT and TT, incubations carried out at a determined pH optimum of 7.9 and activities calculated with regard to activity of nothing dehydrogenase (ND) measured in control sections incubated without substrate. The highest activity could be achieved by means of NBT, the ratios of activities measured by NBT, INT, MTT, BT and TT being 100:86:82:29:18 and the order of activities corresponding to the order of redox potentials of the tetrazoles. A determination of ND was necessary, because of its influence on the real activity of SD measured in the slices by means of NBT, INT and MTT. Exact measurements could be made if activity was related to the dry weight of the slices or to the content of nucleic acid — bound phosphorus of reference slices; if activity was related to the content of protein of reference slices, the standard deviation would be the 1.4 fold. Meldola Blue (MB) was not a suitable soluble redox dye, the use of it leading to an activity only 23% of that determined when phenazine methosulphate (PMS) applied. A special measuring of the half-formazan of NBT, the molar extinction coefficient determined being 21,840 l/Mol/cm, produced higher accuracy of measurement, but had no influence on the amount of activity of SD. A comparison of the measured activity with reference values obtained by biochemical methods and histochemically quantified with PMS applied, showed a good conformity.     

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.     

Purification and properties of the trimethylamine dehydrogenase of Bacterium 4B6

1. The trimethylamine dehydrogenase of bacterium 4B6 was purified to homogeneity as judged by analytical polyacrylamide-gel electrophoresis. The specific activity of the purified enzyme is 30-fold higher than that of crude sonic extracts. 2. The molecular weight of the enzyme is 161000. 3. The kinetic properties of the purified enzyme were studied by using an anaerobic spectrophotometric assay method allowing the determination of trimethylamine dehydrogenase activity at pH8.5, the optimum pH. The apparent K(m) for trimethylamine is 2.0+/-0.3mum and the apparent K(m) for the primary hydrogen acceptor, phenazine methosulphate, is 1.25mm. 4. Of 13 hydrogen acceptors tested, only Brilliant Cresyl Blue and Methylene Blue replace phenazine methosulphate. 5. A number of secondary and tertiary amines with N-methyl and/or N-ethyl groups are oxidized by the purified enzyme; primary amines and quaternary ammonium salts are not oxidized. Of the compounds that are oxidized by the purified enzyme, only trimethylamine and ethyldimethylamine support the growth of bacterium 4B6. 6. Trimethylamine dehydrogenase catalyses the anaerobic oxidative N-demethylation of trimethylamine with the formation of stoicheiometric amounts of dimethylamine and formaldehyde. Ethyldimethylamine is also oxidatively N-demethylated yielding ethylmethylamine and formaldehyde; diethylamine is oxidatively N-de-ethylated. 7. The activity of the purified enzyme is unaffected by chelating agents and carbonyl reagents, but is inhibited by some thiol-binding reagents and by Cu(2+), Co(2+), Ni(2+), Ag(+) and Hg(2+). Trimethylamine dehydrogenase activity is potently inhibited by trimethylsulphonium chloride, by tetramethylammonium chloride and other quaternary ammonium salts, and by monoamine oxidase inhibitors of the substituted hydrazine and the non-hydrazine types. 8. Inhibition by the substituted hydrazines is time-dependent, is prevented by the presence of trimethylamine or trimethylamine analogues and in some cases requires the presence of the hydrogen acceptor phenazine methosulphate. The inhibition was irreversible with the four substituted hydrazines that were tested.     

The use of menadione as an intermediate hydrogen-carrier for measuring cytoplasmic dehydrogenating enzyme activities

Summary Phenazine methosulphate is often used as an intermediate hydrogen-carrier in the demonstration of dehydrogenase activities. It cannot be used with adrenal tissue sections because it appears to have an inhibitory effect in this tissue.The water-soluble menadione sodium-bisulphite salt has been shown to be quantitatively as efficient as phenazine methosulphate for pentose-shunt dehydrogenase activity in rat liver sections; at optimal concentrations it does not inhibit this activity in the adrenal.     

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.     

Methods of microphotometric assay of succinate dehydrogenase and cytochrome c oxidase activities for use on human skeletal muscle

Microphotometric assay media for the measurement of succinate dehydrogenase (SDH) and cytochrome oxidase activities in sections of human skeletal muscle have been developed. The optimal constitution of these media was determined experimentally. Factors investigated include the effects of substrate concentration, pH, use of different electron acceptors and electron donors, influence of intermediate electron carriers and tissue-stabilizing agents, effects of inhibitors, the extent of endogenous and non-specific reactions and the linearity of the reactions during the time course of the assays. Optimal assay media (SDH) contained 130 mM succinate, 1.5 mM Nitro Blue tetrazolium, 0.2 mM phenazine methosulphate and 1.0 mM sodium azide in 0.1 m phosphate buffer, pH7.0. Cytochrome oxidase was optimally assayed in media containing 4 mM diaminobenzidine and 100 microns cytochrome c. Reactions in individual muscle fibers were found to be linear for incubation times up to 10 min in SDH assays and for more than 15 min in cytochrome oxidase determinations. Some potential uses of these microphotometric assays in the investigation of human metabolic muscle disorders are discussed.     

A permeability test for the study of mitochondrial injury in in vitro cultured heart muscle and endothelioid cells.

A cytochemical permeability test for the detection of injury to in situ mitochondria of cultured heart cells is presented. The test is based on the increased rate at which injured mitochondria stain for succinate dehydrogenase activity. Whereas an intact inner mitochondrial membrane limits the rate at which Nitro Blue tetrazolium and phenazine methosulphate reach succinate dehydrogenase, injured mitochondria allow these reactants to reach the enzyme more rapidly to form microscopically-observable formazan granules. The extent of staining at fixed durations of incubation with the reactants was assessed on a blind basis with pseudo dark-field microscopy, using a standardized rating scale. Differences in the staining of control and treated cells were analysed statistically by a semi-quantitative method. Treatment of the cultures with either vitamin A or chlorpromazine, resulted in more rapid mitochondrial staining. Brief pre-fixation of the cells with cold acetone also labilized the mitochondria as did a delay in the change of culture medium.     

A tetrazolium technique for the histochemical localization of ATP: Creatine phosphotransferase

Summary A tetrazolium technique is presented that permits the study of ATP: Creatine phosphotransferase, or creatine kinase, in fixed skeletal muscle tissue sections, within the limits imposed by the properties of the chosen ditetrazole, nitro blue tatrazolium. There is a variation in creatine kinase activity between the muscle fibres. Those with high creatine kinase activity also have high succinate dehydrogenase activity.List of Abbreviations ADP Adenosine-5-diphosphate - ATP adenosine-5-triphosphate - CK creatine kinase - G-6-P glucose-6-phosphate - G-6-P-DH glucose-6-phosphate dehydrogenase - HK hexokinase - NADP nicotinamide adenine dinucleotide phosphate - NBT nitro blue tetrazolium - PMS phenazine methosulphate - SDH succinate dehydrogenase     

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.     

Characterization of a cellobiose dehydrogenase in the cellulolytic fungus Sporotrichum (Chrysosporium) thermophile.

An extracellular enzyme from culture filtrates of Sporotrichum (Chrysosporium) thermophile (A.T.C.C. 42 464) after growth on cellulose or cellobiose was shown to oxidize cellobiose to cellobionic acid in vitro. Lactose and cellodextrins were also efficiently oxidized, but the enzyme was not active against most mono- and di-saccharides. Several redox substances could act as electron acceptors, but molecular oxygen, tetrazolium salts and NAD(P) were not reduced. Activity was stimulated up to 2-fold in the presence of 0.05 M-Mg2+. The pH optimum of the enzymic reaction was acidic when the activity was tested with dichlorophenol-indophenol or Methylene Blue, but was neutral to alkaline for 3,5-di-t-butyl-1,2-benzoquinone or phenazine methosulphate as electron acceptors. As the enzyme was formed inductively in parallel with the endocellulase, its possible function in relation to cellulolysis is discussed.     

Meldola Blue: A new electron carrier for the histochemical demonstration of dehydrogenases (SDH,LDH, G-6-PDH)

Summary A new electron carrier, Meldola Blue (8-dimethylamino-2,3-benzophenoxazine; Boehringer Mannheim GmbH, Deutsche Patentschrift P 1959410) was tested for its usefulness in the histochemical demonstration of dehydrogenase activity in adrenal cortex, liver, heart muscle of guinea pig and human oviduct and compared with PMS.For demonstrating SDH activity Meldola Blue (MB) is as efficient as PMS. A decisive advantage of MB as compared with PMS is its low sensitivity to light exposure, facilitating direct visualisation of histochemical reaction processes.Generally, a high diffusion rate of reduced electron carriers (PMS and MB) from the section into the incubation medium (PVA) leads to a loss of reduction equivalents, particularly in the demonstration of NAD- or NADP-dependent dehydrogenases (LDH, G-6-PDH) with lower TNBT concentrations. However, no inhibition of SDH-, LDH- and G-6-PDH activities was observed with incubation media containing the tested concentrations of PMS and MB.     

FURTHER INVESTIGATION OF HISTOCHEMISTRY OF FRUCTOSE-1,6-DIPHOSPHATE d-GLYCERALDEHYDE-3-PHOSPHATE-LYASE IN THE RAT BRAIN

The distribution of fructose-1,6-diphosphate d -glyceraldehyde-3-phosphate-lyase (I.U.B. 4.1.2.13) (fructose diphosphate aldolase) in brain sections fixed by alcohol was studied using a gelled substrate mixture containing d -glyceraldehyde-3-phosphate: NAD oxidoreductase (I.U.B. 1.2.1.12) and phenazine methosulphate. The formazan precipitation pattern in brain sections depends on the experimental conditions determining the affinity of the complex of Nitro-blue tetrazolium and phenazine methosulphate to tissue components. The complex is unable to precipitate on the white matter in fresh sections but alcohol fixation increases its affinity to the white matter and decreases it to the neuropil. Using the modified histochemical method, aldolase activity in the brain was seen both in the gray and white matter. Although the distribution of this enzyme activity in the gray matter was generally identical with that obtained previously, in the present study enzyme activity was found in the paraventricular structures and in the white matter where negative activity was previously obtained.     

Elimination of artifacts due to glutaraldehyde fixation in the histochemical detection of glucose oxidase with tetrazolium salts

Summary High background staining due to glutaraldehyde fixation prevents phenazine methosulphate and a tetrazolium salt being used to visualize glucose oxidase activity in tissue slices prepared from mice injected with the enzyme. Experiments in solution showed that products formed during the reaction between amino groups and glutaraldehyde are, at least in part, responsible for the non-enzymatic reduction of tetrazolium salts. Experiments performed with artificial membranes chemically akin to glutaraldehyde-fixed sections and prepared by cross-linking albumin by glutaraldehyde, showed that double bonds in amino-glutaraldehyde products are mainly responsible for the background staining development, whereas thiol groups play only a minor role. A sequential treatment with sodium borohydride andN-ethylmaleimide greatly reduced the background staining, thus permitting the detection of glucose oxidase activity. Optimal conditions for glucose oxidase activity demonstration (maximum enzyme velocity for minimum nothing dehydrogenase phenomenon) were studied: choice of the tetrazolium salt, nature, pH and molarity of the buffer used for the staining mixture. A procedure similar to that developed with artificial membranes was applied to tissue sections of mice in which glucose oxidase had been injected intravenously. It allowed detection of glucose oxidase activity without artifactual staining in control slices.     

Diffusion during dehydrogenase reactions: the effects of intermediate electron acceptors

Summary A hamster cheek pouch model has been used to study the diffusion of reactants from the epithelium into adjacent muscle and connective tissue during the histochemical demonstration of glucose-6-phosphate dehydrogenase activity. The effects of the addition of intermediate electron acceptors to the incubation medium varied considerably from one acceptor to another, but were independent of the grade of polyvinyl alcohol incorporated into the medium. Menadione was the least effective intermediate both in transferring reducing equivalents from the primary dehydrogenase to Neotetrazolium chloride and in preventing diffusion. Phenazine methosulphate, Methylene Blue and Thionin were more efficient intermediates. Nevertheless, considerable diffusion occurred in the presence of Phenazine methosulphate, although very little diffusion was detectable with either of the thiazine dyes. It is suggested that these differences are related to different modes and sites of action of the carriers.     

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 gel-sandwich technique for the qualitative and quantitative determination of dehydrogenases in the enzyme histochemistry. I. Development of the new methods on the example of LDH (E.C. 1.1.1.27).

A gel-sandwich technique for the histochemical demonstration of dehydrogenase is introduced with LDH set up as an example. Especially suitable, of the gels examined, for this technique is 1.5% W/V agar-agar low gel strength. In it several reaction ingredients for the histochemical reaction are dissolved. Considering LDH the following gel composition showed good results: 1.5% W/V agar-agar low gel strength, 5 mM TNBT in 150 microliter DMF, 120 mM L-lactate, 3--5 mM NAD+, 10 mM amytal, 22,4--32 X 10(-5) M Meldola Blue, 160 mM soldium phosphate buffer pH 7.6 (total solution of 1 ml). After the solidification of the gel, gel-bars were frozen with CO2-snow. The 40--80 micrometer thick gel slices were gained in the cryostat. Of the three different arrangement possibilities of the gel slices and the tissue-sections a sandwich arrangement (cover-gel slice--tissue section--ground-gel slice) produced the best results. The enzyme reaction is started by thawing of the gel slices (together with the tissue sections) and by putting them between the hotplate and the evaporator-head-piece, especially developed for this technique. The gel slices also remain in combination with the tissue sections after the reaction. The influence of the gel in combination with the electron carrier Meldola Blue on the spontaneous reduction rates of ditetrazolium salts in day light, were examined as well as the diffusion rates of TNBT and NADH out of gel slices and the influence of DMF and DMSO on the LDH activity. This technique prevents both, the loss of enzymes and the loss of reduction equivalents. There are given presuppositions for qualitative and quantitative histochemical investigations as well. The advantages of the new gel technique are discussed.     

Quantitative dehydrogenase histochemistry with exogenous electron carriers (PMS,MPMS, MB)

Summary The relative efficiencies of phenazine methosulfate (PMS), 1-methoxy-phenazine methosulfate (MPMS) and Meldola Blue (MB) as electron carriers were determined biochemically (non-enzymic NADH-tetrazolium salt-test) and by quantitative histochemistry (heart and kidney slices; succinate dehydrogenase, SDH; lactate dehydrogenase, LDH). MPMS developed the highest electron transfer velocity in biochemical assays. The reaction was independent of the pH value between 7.0–8.5. PMS and MB always showed a lower transfer ability in biochemical tests which was higher with iodonitrotetrazolium chloride (INT) than with nitro blue tetrazolium chloride (NBT). A distinct pH dependence was demonstrable with MB in this respect, preferentially using INT as tetrazolium salt.Quantitative histochemical results with electron carriers are often at variance with biochemical ones. MPMS leads to somewhat higher demonstrable activities only in the determination of the NAD-dependent LDH, whereas MB results in somewhat higher LDH activity than PMS (reaction medium with agarose). MB and PMS yielded almost equally high activities in the demonstration of the flavoprotein-dependent SDH using a reaction medium with agarose. With an aqueous reaction medium, PMS resulted in higer SDH activities than MB. MPMS always had the lowest efficiency in electron transfer ability using an aqueous or agarose containing reaction medium (SDH). With PVA in the reaction medium (SDH determination) PMS was clearly superior to MPMS. MB showed only a small transfer activity under these conditions because PVA seems to bind MB almost completely. It is concluded that in histochemistry an appropriate electron carrier and electron carrier concentration must be determined for different incubation conditions, tissues, tissue preparations and dehydrogenases studied. General statements about the efficiency or inefficiency of an electron carrier as a result of only one incubation condition does not seem to be justified.Supported by the Deutsche Forschungsgemeinschaft (SFB 105)     

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.