The Azolla-Anabaena azollae relationship

The heterocystous blue-green alga, Anabaena azollae, was isolated from the leaf cavities of the water fern, Azolla caroliniana, where it occurs as an endophyte. The isolated alga was capable of light dependent CO₂ fixation and acetylene reduction. Aerobic dark acetylene reduction occurred and was dependent upon endogenous substrates. Vegetative cells of the alga reduced nitro-blue tetrazolium chloride (NBT) to blue formazan. Heterocysts did not. Heterocysts reduced triphenyl tetrazolium chloride (TTC) to red formazan faster than vegetative cells. Reduction of TTC by both heterocysts and vegetative cells was much more rapid than has been reported for free-living heterocystous blue-green algae. Both NBT and TTC inhibited acetylene reduction and CO₂ fixation. The inhibition by TTC was more closely correlated to the time of exposure of the cells to the reagent and to the amount of deposition per cell than to the number of cells containing red formazan. No differential inhibition of acetylene reduction versus CO₂ fixation was observed. Autoradiography showed that CO₂ fixation occurred only in vegetative cells. Heterocysts caused a darkening of nuclear emulsions (chemography). This observation has been employed by others as an index of reducing activity in these cells. DCMU inhibited the acetylene reducing capacity of alga isolated from dark pretreated fronds more rapidly and to a greater extent than that in alga isolated from light pretreated fronds. Ammonia in excess of 5 mM was required before any inhibition of acetylene reduction was observed under either aerobic or anaerobic conditions in the light.     

Re-evaluation of superoxide scavenging capacity of xanthohumol

Abstract

The chemopreventive chalcone xanthohumol (Xh) has been reported to decrease xanthine oxidase (XOD) catalysed formation of formazan from nitroblue tetrazolium (NBT) and is discussed as a potent scavenger of superoxide. Re-evaluation of the scavenging capacity indicated that Xh disturbed detection of superoxide with NBT, in case of an insufficient NBT/Xh ratio. Xh lacked superoxide scavenging activity in contrast to the Xh-derivative 3′-hydroxy-Xh with catechol substructure, used as positive control. This was shown by the use of sufficient concentration of NBT and other detectors such as hydroxylamine, XTT, cytochrome c and hydroethidine. HPLC analysis of reaction products in a xanthine/XOD/peroxidase system demonstrated beside enhanced inhibition of NBT-formazan by Xh that NBT even prevented oxidation of Xh. p-coumaric acid or ferulic acid could replace Xh in that system, indicating that superoxide detection using NBT is likely jeopardized by interference of phenoxyl-radicals. Furthermore, this study provides evidence that Xh can moderately generate superoxide via auto-oxidation.     

Cytochemical demonstration of 5-formyl tetrahydrofolate cyclodehydrase and 5,10-methenyl tetrahydrofolate cyclohydrolase activity.

The enzyme 5-formyl tetrahydrofolate cyclodehydrase plays an important role in the conversion of 5-formyl tetrahydrofolate to 5,10-methenyl tetrahydrofolate. A second enzyme, cyclohydrolase, converts 5,10-methenyl tetrahydrofolate to 10-formyl tetrahydrofolate. These folate derivatives play a significant part in the biosynthesis of purines. A method has been devised for the cytochemical demonstration of 5-formyl tetrahydrofolate cyclodehydrase and 5,10-methenyl tetrahydrofolate cyclohydrolase activity which uses 5-formyl tetrahydrofolate or 5,10-methenyl tetrahydrofolate as substrate respectively, blocking possible interferences by other enzymes, and allows the nonenzymatic reduction of nitro-blue tetrazolium by 5,10-methenyl tetrahydrofolate formed by the action of the cyclodehydrase on the substrate 5-formyl tetrahydrofolate, and by 10-formyl tetrahydrofolate formed by the action of cyclohydrolase on the substrate 5,10-methenyl tetrahydrofolate, thus revealing intracellular sites of enzyme activity. The methods appear to show only intracellular localization of the blue formazan deposits of reduced tetrazolium. The distribution of positivity in cells of human blood and bone marrow is described.     

On the oxygen-sensitivity of various tetrazolium salts

Summary 1. Eight different tetrazolium salts have been chemically reduced with NADPH and PMS¹ under oxygenated and oxygen-free conditions. 2. PMS has been shown to be able to remove all of the hydrogen from NADPH very rapidly, and to transfer all of this hydrogen onto tetrazolium salts, under suitable atmospheric conditions. 3. MTT, INT, TNBT, and NBT¹ produced the same amount of formazan under both conditions; NT BT, TV, TT¹ produced formazan under oxygen-free conditions, but produced no formazan under oxygenated conditions. 4. These results are explained on the basis of competition for the NADP Hhydrogen between oxygen and the four tetrazolium salts NT, BT, TV and TT.I should like to thank The Arthritis and Rheumatism Council for financial support.     

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.     

Re-evaluation of superoxide scavenging capacity of xanthohumol

The chemopreventive chalcone xanthohumol (Xh) has been reported to decrease xanthine oxidase (XOD) catalysed formation of formazan from nitroblue tetrazolium (NBT) and is discussed as a potent scavenger of superoxide. Re-evaluation of the scavenging capacity indicated that Xh disturbed detection of superoxide with NBT, in case of an insufficient NBT/Xh ratio. Xh lacked superoxide scavenging activity in contrast to the Xh-derivative 3'-hydroxy-Xh with catechol substructure, used as positive control. This was shown by the use of sufficient concentration of NBT and other detectors such as hydroxylamine, XTT, cytochrome c and hydroethidine. HPLC analysis of reaction products in a xanthine/XOD/peroxidase system demonstrated beside enhanced inhibition of NBT-formazan by Xh that NBT even prevented oxidation of Xh. p-coumaric acid or ferulic acid could replace Xh in that system, indicating that superoxide detection using NBT is likely jeopardized by interference of phenoxyl-radicals. Furthermore, this study provides evidence that Xh can moderately generate superoxide via auto-oxidation.     

Generation of Superoxide Anion and Localization of CuZn-Superoxide Dismutase in the Vascular Tissue of Spinach Hypocotyls: Their Association with Lignification

The sites of generations of superoxide anions and hydrogen peroxidein cross sections of hypocotyls from spinach seedlings werelocated by staining with nitroblue tetrazolium (NBT) and withstarch-iodide, respectively. Formazan, produced upon the reductionof NBT by superoxide, was observed mainly in the vascular tissueonly in the presence of inhibitors of CuZn-superoxide dismutase(CuZn-SOD), and its formation was suppressed under anaerobicconditions. Thus, NBT was reduced to formazan specifically bythe superoxide anions generated in vascular tissue. The reductionof NBT was suppressed by inhibitors of NAD(P)H oxidase, butneither by cyanide nor azide, indicating the involvement ofNAD(P)H oxidase in the generation of superoxide anions in thevascular tissue. Starch-I₂ complex also was formed in the vasculartissue, but not in the presence of either the CuZn-SOD inhibitoror the NAD(P)H oxidase inhibitor, indicating that the hydrogenperoxide is produced via the catalytic disproportionation withCuZn-SOD of the superoxide generated by NAD(P)H oxidase. Generationsof superoxide anions and hydrogen peroxide in the vascular tissuewere particularly apparent in the xylem and associated withthe sites of distribution of CuZn-SOD as determined by an immunohistochemicalmethod, and also with the location of lignin as determined bythe phloroglucin-HCI reaction. ⁴Present address: Chemical Research Laboratories, Toray IndustriesInc., 9–1 Oe-cho, Minato-ku, Ngagoya, 455 Japan     

Superoxide-dependent and superoxide-independent pathways for reduction of nitroblue tetrazolium in isolated rat cardiac myocytes.

Spectroscopic studies indicated that nitroblue tetrazolium (NBT) could be reduced to blue formazan by several distinct reactions in suspensions of isolated rat cardiac myocytes. Both NADPH- and NADH-linked pathways for reduction of NBT were observed. NADPH-linked NBT reduction showed little activity in the absence of digitonin, but could be stimulated an average of 9.5-fold by digitonin permeabilization of the plasma membrane. NADH-linked NBT reduction occurred in the absence of digitonin, and could be increased an average of 3.5-fold by digitonin treatment. Analysis of the effects of cell viability on the extent of digitonin stimulation with these substrates suggested that the NADPH-linked reaction involved a cytosolic component, while the NADH-linked reaction involved an intracellular membrane enzyme system. With either NADPH or NADH, NBT reduction was completely inhibited by dicoumarol (100 microM). Dicoumarol-insensitive NBT reduction could subsequently be observed following the addition of 2 mM cyanide, a level of cyanide known to inhibit cytosolic superoxide dismutase. Cyanide-stimulated, dicoumarol-insensitive NBT reduction was augmented by the presence of either antimycin or doxorubicin, two agents which enhance superoxide formation by different mechanisms. The results indicate the existence of multiple pathways for both superoxide-independent and superoxide-dependent reduction of NBT. Dicoumarol-insensitive, cyanide-stimulated NBT reduction may be useful as a spectroscopic probe for intracellular superoxide formation.     

THE USE OF TETRANITRO-BLUE TETRAZOLIUM FOR THE CYTOCHEMICAL LOCALIZATION OF SUCCINIC DEHYDROGENASE : Cytochemical and Cytological Studies of Sarcoma 37 Ascites Tumor Cells

Succinic dehydrogenase (SDH) was localized in the mitochondria of Sarcoma 37 ascites tumor cells by the use of tetranitro-BT (TNBT) and nitro-BT (NBT) in smear preparations. Results with each tetrazolium salt as electron acceptor were evaluated with respect to: (a) size and shape of the formazan precipitate relative to standard mitochondrial morphology; (b) crystallization phenomena of reduced dye; (c) lipid adsorption of formazan. The association of formazan- or iron hematoxylin-stained mitochondria with lipid droplets within the cells was investigated, as was also the influence of formalin fixation, with and without cold acetone pretreatment, on mitochondrial morphology and enzymatic staining. Data from these studies appear to indicate that TNBT is more suitable than NBT for use as a cytochemical reagent in oxidative and/or dehydrogenase enzyme histochemistry and cytochemistry.     

Iron Autoxidation in Mops and Hepes Buffers

Iron autoxidation in Mops and Hepes buffers is characterized by a lag phase that becomes shorter with increasing FeCl₂ concentration and pH. During iron oxidation in these buffers a yellow colour develops in the solution. When the reaction is conducted in the presence of nitro blue tetrazolium (NBT), blue formazan is formed. Of the many OH' scavengers tested, mannitol and sorbitol are most effective in inhibiting Fe²⁺ oxidation, yellow colour development and NBT reduction. Some inhibition was also noted with catalase. The iron product of the oxidative reaction differs from Fe³⁺ in its absorption spectrum and its low reactivity with thiocyanate. Similar results are obtained when iron autoxidation is studied in unbuffered solutions brought to alkaline pH with NaOH. In phosphate buffer, no lag phase is evident and the absorption spectrum of the final solution is identical to that of Fe³⁺ in this buffer. The iron product reacts immediately with thiocyanate. When iron oxidation is conducted in the presence of NBT the formation of formazan is almost undetectable. Of the many compounds tested only catalase inhibits iron autoxidation in this buffer. The sequence of reactions leading to iron autoxidation in Good-type buffers¹ thus resembles that occurring in unbuffered solutions brought to alkaline pH with NaOH and greatly differs from that occurring in phosphate buffer. These results are in agreement with the observation that these buffers have very low affinity for iron.¹ The data presented define experimental conditions where Fe²⁺ is substantially stable for a considerable length of time in Mops buffer.     

Direct spectrophotometric observation of intracellular nitro-blue tetrazolium and its formazan by multiple internal reflectance infrared spectroscopy.

A technique is described which permits the direct, infrared (IR) spectrophotometric observation of peripheral leukocytes by utilizing multiple internal reflectance (MIR) spectroscopy on zinc selenide prisms. The IR spectra of nitro-blue tetrazolium (NBT) and its derivative, nitro-blue diformazan (NBF), are described and examined and these spectra are compared with those of the intracellular NBT and NBF yielding several peaks which may prove to be analytically useful. Additionally, the presence of unreduced NBT in leukocytes is demonstrated, which microscopic and chemical "NBT tests" have not previously done.     

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)     

Direct spectrophotometric observation of intracellular nitro-blue tetrazolium and its formazan by multiple internal reflectance infrared spectroscopy

Summary A technique is described which permits the direct, infrared (IR) spectrophotometric observation of peripheral leukocytes by utilizing multiple internal reflectance (MIR) spectroscopy on zinc selenide prisms. The IR spectra of nitro-blue tetrazolium (NBT) and its derivative, nitro-blue diformazan (NBF), are described and examined and these spectra are compared with those of the intracellular NBT and NBF yielding several peaks which may prove to be analytically useful. Additionally, the presence of unreduced NBT in leukocytes is demonstrated, which microscopic and chemical NBT tests have not previously done.     

Electron microscopy of the localization of formic dehydrogenase in regenerating forms ofProteus vulgaris

The localization of the formic dehydrogenase system was studied by means of nitro-blue tetrazolium, using the ultrathin section technique, in large long bodies ofProteus vulgaris, which form the intermediate stage in regeneration of penicillin-induced spheroplasts. In the electron microscope, empty areas, numbering on an average four per cell section, were found at the site of formazan deposits, while in the controls (without tetrazolium salts) the average number was 0.05. From these findings, and from the findings of other authors showing that formic dehydrogenase is bound to cell structures, it can be concluded that inProteus cells this enzyme is bound to the cytoplasmic membrane.     

Inhibition of O2−- and HO - Mediated Processes by a New Class of Free Radical Scavengers: The N-ACYL Dehydroalanines

N-phenylacetyl dehydroalanines are captodative olefins. They inhibit two processes mediated by superoxide anion (O₂-) in a concentration dependent manner: reduction of NBT to blue formazan and oxidation of epinephrine to adrenochrome. They also inhibit in a dose related way the degradation of deoxyribose produced during either the Fenton reaction or the radiolysis of water, which are the two experimental sources of hydroxyl radical (HO^?) production. Based on the results obtained with superoxide dismutase, mannitol, thiourea, and uric acid, we postulate that these competitive inhibitory effects suggest a reaction between the dehydroalanine derivatives and the two oxygen derived radicals. Hydroxyl free radical is scavenged more efficiently than superoxide anion. Substitution of the phenyl ring by methoxy groups does not modify significantly the activity. These molecules possess three target active sites which can react with free radicals.     

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.     

Improvement in Soluble Dehydrogenase Histochemistry by Nitroblue Tetrazolium Preuptake in Sections: A Qualitative and Quantitative Study

An improvement in the histochemical demonstration of soluble dehydrogenase enzymes has been obtained by preincubating frozen sections in a nitroblue tetrazolium (NBT)/ acetone solution, followed by routine incubation in polyvinyl alcohol (PVA) enriched media. Tissue binding properties of NBT were shown clearly to be decreased in histochemical media containing the colloid PVA for soluble enzymes, thus causing loss of the final reaction product (formazan) from the sections. The preincubation step in NBT/acetone allows tetrazolium salt to bind firmly to tissue lipoprotein (substantivity) and diminishes the loss of reduced formazan from heavily reacting tissue sections. The time course of NBT substantivity was examined and it was found that NBT binds rapidly to tissues (liver, kidney, heart) during preincubation, so that a preincubation of 30-60 seconds at room temperature is sufficient to improve the final morphological results greatly. Microspectrophotometric measurements of matched controls and NBT/acetone preincubated sections show that the preincubation step may slightly decrease lactate dehydrogenase (LDH) and glucose-6-phosphate dehydrogenase (G6PDH) activities. This decrease was probably due to increased binding efficiency of formazan to cell lipoproteins but was judged, however, to be irrelevant compared to the morphological advantages produced by the NBT/acetone preincubation procedure.     

Improvement in soluble dehydrogenase histochemistry by nitroblue tetrazolium preuptake in sections: a qualitative and quantitative study

An improvement in the histochemical demonstration of soluble dehydrogenase enzymes has been obtained by preincubating frozen sections in a nitroblue tetrazolium (NBT)/acetone solution, followed by routine incubation in polyvinyl alcohol (PVA) enriched media. Tissue binding properties of NBT were shown clearly to be decreased in histochemical media containing the colloid PVA for soluble enzymes, thus causing loss of the final reaction product (formazan) from the sections. The preincubation step in NBT/acetone allows tetrazolium salt to bind firmly to tissue lipoprotein (substantivity) and diminishes the loss of reduced formazan from heavily reacting tissue sections. The time course of NBT substantivity was examined and it was found that NBT binds rapidly to tissues (liver, kidney, heart) during preincubation, so that a preincubation of 30-60 seconds at room temperature is sufficient to improve the final morphological results greatly. Microspectrophotometric measurements of matched controls and NBT/acetone preincubated sections show that the preincubation step may slightly decrease lactate dehydrogenase (LDH) and glucose-6-phosphate dehydrogenase (G6PDH) activities. This decrease was probably due to increased binding efficiency of formazan to cell lipoproteins but was judged, however, to be irrelevant compared to the morphological advantages produced by the NBT/acetone preincubation procedure.     

The Tetrazolium Dyes MTS and XTT Provide New Quantitative Assays for Superoxide and Superoxide Dismutase

The tetrazolium dyes MTS and XTT were reduced to their soluble formazans by superoxide radical anions (O₂^_) produced by the oxidation of xanthine by xanthine oxidase under standard conditions. These reactions were compared to the well-known reductions of NBT and cytochrome c by the xanthine/xanthine oxidase system. Reduction of the dyes was completely inhibited by superoxide dismutase (SOD). Rate constants for the reaction of MTS and XTT with O₂^_: were estimated at 1.3 × .1 × 10⁵ M-¹s^-1 and 8.6 × .8 × 10⁴ M^-1s^-1 respectively. The stable MTS and XTT formazans have high extinction coefficients in the visible range which enable sensitive detection and quantification of superoxide radicals, avoiding some of the problems inherent in assays based on production of the insoluble NBT formazan. MTS and XTT have considerable potential both for the quantitative assay of radical production in living tissues and for the assay of superoxide dismutase activity in tissue extracts. Implications for the interpretation of cell culture growth assays which employ these dyes are discussed.     

Superoxide dismutase activity of macrocyclic polyamine complexes

Copper(II) and nickel(II) complexes of macrocyclic polyamine derivatives possessing partial oligopeptide-like structures are found to suppress the xanthine-xanthine oxidase-mediated reduction of nitroblue tetrazolium and also to suppress formazan formation by potassium superoxide. The activity in the superoxide dismutase assay is dependent on ring size, type and number of donor atoms, metal ion, and substituents on the macrocycles. Some of those are more active than the known O₂^? scavengers such as copper(II)-salicylate and copper(II)-amino acid (or peptide) complexes. Nickel (II)-naphthylmethyl-dioxo-[16]ane N₅, 13, 1 : 1 complex (NiH_?2L) is the most active among the 30 chelates examined.