A new sensitive colorimetric assay for peroxidase using 3,3'-diaminobenzidine as hydrogen donor

A new simple colorimetric assay for measurement of peroxidase activity using 3,3′-diaminobenzidine tetrahydrochloride as hydrogen donor is described. The DAB is stable under the usual assay conditions, and its rate of auto-oxidation is negligible. Under optimal conditions, a linear relationship is found between peroxidase concentration and the rate of oxidation of 3,3′-diaminobenzidine tetrahydrochloride (ΔA_405nm/min). Using horseradish peroxidase, the DAB method appears more sensitive than the o-dianisidine and the guaiacol assays for peroxidase. This method can also be used for measurement of peroxidase activity in tissue fractions.     

Diaminobenzidine Induces Fluorescence in Nervous Tissue and Provides Intrinsic Counterstaining of Sections Prepared for Peroxidase Histochemistry

3,3'-Diaminobenzidine (DAB) is widely used as a chromogen for visualization of horseradish peroxidase activity in neuroanatomical tracing experiments and in immunohistochemistry. The product of the enzymatically catalyzed oxidation of DAB by hydrogen peroxide is brown and nonfluorescent. In frozen sections of formaldehyde fixed rat and mouse brain that had been exposed to DAB either alone or with hydrogen peroxide, we observed strong greenish fluorescence in myelinated nerve fibers and in the somata of some neurons. This fluorescence was not associated with brown coloration and was not due to endogenous peroxidase activity. Extractions, blocking reactions, and other histochemical tests indicate that the fluorescence resulted from the combination of DAB with aldehyde groups that were formed by oxidation of unsaturated linkages in lipids. DAB induced fluorescence provides a simple and useful demonstration of background anatomy in sections that also contain specifically localized deposits of peroxidase activity.     

Evidence of the presence of extraperoxisomal catalase in chloragogen cells of the earthworm,Lumbricus terrestris L.

Summary The DAB reactivity of the midintestine of the earthworm, consisting of epithelial layer, muscle layer, and chloragogen tissue, was examined electron microscopically. Besides the mitochondrial membranes of the examined cell types and the hemoglobin content of the blood vessels and chloragogen cells, a considerable DAB reactivity was found in the whole cytosol of the chloragocytes. The DAB reaction of the cytosol was more intensive when incubation medium for catalase, less intensive when incubation medium for peroxidase, was used and did not occur when H₂O₂ was omitted.Cytosol of the chloragogen cells was isolated and preliminary assay of catalase and peroxidase activities was made. Cytosol samples showed moderate peroxidase activity, but catalase activity measured by the decomposition of hydrogen peroxide showed a very high rate. Catalase and peroxidase activities of the cytosol were heat-sensitive and might have been inhibited by azide and cyanide, respectively. Results prove the assumption that the intensive DAB reactivity of the chloragocyte cytosol is caused by its extraperoxisomal catalase content.     

Activity of secreted cell wall-modifying enzymes and expression of peroxidase-encoding gene following germination of <Emphasis Type="Italic">Orobanche ramosa</Emphasis>

Radicle growth of germinated seed of the root parasite O. ramosa is shown to be rapidly accompanied by secretion of proteins including pectinolytic enzymes, polygalacturonase and rhamnogalacturonase. These secretions peaked between 4 to 8 d after induction of germination and remained constant for some further days in the case of polygalacturonases. After 6 d, germinated seeds secreted proteins which exhibit peroxidase activity. The latter may be correlated with expression of OrPOX1, a putative gene encoding for secreted peroxidase. The involvement of these enzymes in host root attack and haustorium formation by the parasite is discussed.     

A quantitative study of peroxidase activity in unfixed tissue sections of the guinea-pig thyroid gland

Summary A technique for the cytochemical demonstration of peroxidase activity in unfixed guinea-pig thyroid tissue is described in this paper. The substrate 3,3-diaminobenzidine tetrahydrochloride (DAB) is oxidized by the peroxidase to form an insoluble reaction product. Optimal results were obtained after 20 min incubation at 37° C in reaction medium containing 1.4mm DAB (in 0.1m Tris-HCl) and 0.15mm hydrogen peroxide at pH 8.0. Peroxidase activity was seen in the thyroid follicle cells as a diffuse brown reaction product (which was more dense and granular in erythrocytes). The enzyme activity was quantified using a scanning-integrating microdensitometer, and the effects of two specific peroxidase inhibitors were evaluated. Both 3-amino-1,2,4-triazole and methimazole inhibited peroxidase activity in the follicle cells (enzyme activity was still seen in the erythrocytes), maximal inhibition occurring at 10mm. Stimulation of peroxidase in the thyroid was observedin vivo (1 I.U. TSH administered every 8 h for two days), with the maximal stimulation occurring after 1 day.     

Evidence for two classes of microbodies in meiocytes of the red algaPalmaria palmata

Summary Microbodies, usually spherical and about 0.2 m in diameter, were found to be associated with prophase nuclei in vegetative cells and meiocytes of the red algaPalmaria palmata. Nucleus-associated microbodies in meiocytes were numerous, but they did not react to the DAB cytochemical test for catalase and peroxidase activity. Microbodies not associated with nuclei in the same cells were intensely DAB-positive. Neither aminotriazole nor potassium cyanide inhibited the DAB reaction.     

Ultrastructural cytochemistry of the diaminobenzidine reaction in the aquatic fungus Entophlyctis variabilis

Ultrastructural localization of peroxidatic activity was investigated in the chytrid Entophlyctis variabilis with the 3,3-diaminobenzidine (DAB) cytochemical prodedure. The subcellular distribution of reaction product varied with changes in pH of the DAB medium and with the developmental stage of the fungus. Incubations in the DAB reaction medium at pH 9.2 produced an electron dense reaction product within single membrane bounded organelles which resembled microbodies but which varied in shapes from elongate to oval. At this pH the cell wall also stained darkly. When the pH of the DAB medium was lowered to pH 8.2 or 7.0, DAB oxidation product was localized within mitochondrial cristae as well as in microbodies and zoosporangial walls. As soon as zoospores were completely cleaved out of the zoosporangial cytoplasm, endoplasmic reticulum (ER) also stained. When the wall appeared around the encysted zoospore, ER staining was no longer found. The influence of the catalase inhibitor, aminotriazole, and the inhibitors of heme enzymes, sodium azide and sodium cyanide, on the staining patterns within cells incubated in the DAB media indicates that microbody staining is due to both catalase and peroxidase, mitochondrial staining is due to cytochrome c, and ER staining is due to peroxidase.Abbreviations DAB 3,3-diaminobenzidine-HCl - ER endoplasmic reticulum     

A novel tetrazolium method for peroxidase histochemistry and immunohistochemistry.

We developed a new method for the histochemical demonstration of peroxidase. This method, which has a novel reaction mechanism, is based on the oxidation of phenol by peroxidase and coupling of this reaction to the reduction of a tetrazolium salt, with the deposition of an insoluble formazan at sites of enzyme activity. This new method was compared with an established diaminobenzidine (DAB) technique for peroxidase histochemistry and immunohistochemistry. Although both methods identified peroxidase activity in myeloid cells of bone marrow biopsy specimens, there was no interference from red cell pseudoperoxidase activity with the phenol-tetrazolium method, in contrast to the diaminobenzidine method. The detection of cytokeratin using an indirect immunoperoxidase technique was compared with both methods for demonstrating peroxidase activity. The phenol-tetrazolium method gave results similar to that obtained with DAB and appeared to be at least as sensitive as DAB in detecting low amounts of antigen. In addition, the production of a formazan as the final reaction product means that the phenol-tetrazolium method is ideally suited for quantitative peroxidase histochemistry. Therefore, the phenol-tetrazolium method represents a useful alternative method to DAB and for certain applications offers significant advantages over DAB.     

Evidence of the presence of extraperoxisomal catalase in chloragogen cells of the earthworm, Lumbricus terrestris L

The DAB reactivity of the midintestine of the earthworm, consisting of epithelial layer, muscle layer, and chloragogen tissue, was examined electron microscopically. Besides the mitochondrial membranes of the examined cell types and the hemoglobin content of the blood vessels and chloragogen cells, a considerable DAB reactivity was found in the whole cytosol of the chloragocytes. The DAB reaction of the cytosol was more intensive when incubation medium for catalase, less intensive when incubation medium for peroxidase, was used and did not occur when H2O2 was omitted. Cytosol of the chloragogen cells was isolated and preliminary assay of catalase and peroxidase activities was made. Cytosol samples showed moderate peroxidase activity, but catalase activity measured by the decomposition of hydrogen peroxide showed a very high rate. Catalase and peroxidase activities of the cytosol were heat-sensitive and might have been inhibited by azide and cyanide, respectively. Results prove the assumption that the intensive DAB reactivity of the chloragocyte cytosol is caused by its extraperoxisomal catalase content.     

Early Detection of Bacterium-induced Basal Resistance in Tobacco Leaves with Diaminobenzidine and Dichlorofluorescein Diacetate

The present study demonstrate that in tobacco leaves the diaminobenzidine (DAB) and 2′,7′‐dichlorofluorescein diacetate (DCFH‐DA) staining is a useful indicator of the basal (also known as general or innate) defence‐associated reactions, especially of the early developing form of basal resistance (EBR). DAB and DCFH‐DA, in the presence of H₂O₂ and peroxidase converts to a brown polymer and fluorescent DCF respectively. In the present study, the hypersensitive response (HR)‐inducing avirulent Pseudomonas syringae pv. syringae 61, its HR‐negative hrp/hrc mutants and even non‐pathogenic bacteria such as P. fluorescens and Escherichia coli caused DAB and DCFH‐DA staining, if the dyes were injected 3–4 h after bacterial inoculation into tobacco leaves. The conditions that enable the staining of plant leaves infiltrated with HR‐negative bacteria were persisted for 1 to several days depending on the physiological state of the plant, and plant activity was required to the development of the staining. The live virulent P. syringae pv. tabaci was able to suppress the development of the staining reaction. Bacteria that induced more intensive staining reaction triggered stronger local resistance response, which was verified by its ability to inhibit the HR by challenging avirulent bacteria and by expression analysis of genes that are activated during the basal defence response. The peroxidase enzyme activity increased in bacterially treated tobacco tissue, and inhibition of peroxidase activity blocked the development of the staining. The results showed that in tobacco leaves the staining reactions were associated with the general recognition and basal defence reaction of tobacco plant and can be used as markers in tobacco leaves for testing the occurrence of this type of defence.     

Biochemical evidence for an endocytically inactive population of lysosomes

The peroxidase dependent, diaminobenzidine (DAB) density shift procedure was applied to the characterization of lysosomes from Chinese hamster ovary (CHO) cells. Peroxidase activity was localized in lysosomes by a 15-18 h internalization period. After treatment with DAB, the distribution of peroxidase activity in Percoll gradients was shifted, as a population, to a higher density. A bimodal distribution which included a low density population was observed for the native lysosomal enzyme beta-hexosaminidase after DAB treatment. A second lysosomal enzyme, alpha-fucosidase, was strongly inhibited by DAB treatment with the residual activity corresponding in distribution to the light beta-hexosaminidase population. The occurrence of a low density lysosomal population after the DAB procedure suggests the existence of an endocytically inactive lysosomal population in fibroblasts. Probable physiological candidates for such a population are discussed.     

Sensitivity of various visualization methods for peroxidase and alkaline phosphatase activity in immunoenzyme histochemistry

Summary Various chromogen protocols for visualizing peroxidase and alkaline phosphatase activity in immunoenzyme histochemistry were compared with respect to their sensitivity. They were tested on tissue sections of human skeletal muscle and in an antigen spot test using antibodies against slow skeletal muscle myosin. The chromogens included 3-amino-9-ethylcarbazole (AEC), 3, 3-diaminobenzidine (DAB),p-phenylenediamine-pyrocatechol (PPD-PC) and 4-chloro-1-naphthol (CN) in peroxidase histochemistry, and 5-bromo-4-chloro-3-indolyl phosphate-nitro blue tetrazolium salt (BCIP-NBT), BCIP-tetra nitro blue tetrazolium salt (TNBT) and various combinations of substituted naphthol phosphate-diazonium salt in alkaline phosphatase histochemistry. DAB, CN, and PPD-PC were also employed with imidazole and DAB in addition to Co²⁺ and Ni²⁺ ions. The results indicate that DAB-imidazole and DAB-Co²⁺ and Ni²⁺ ions are the most sensitive chromogen protocols for visualizing peroxidase activity. Although no large differences were found between the various chromogen protocols for visualizing alkaline phosphatase activity, the protocol BCIP-TNBT is especially recommended. Furthermore, the various chromogen protocols were evaluated as to stability of chromogen solutions and final precipitates, background staining, localization properties, and enhancement of enzyme activity.     

Fine structural and cytochemical analysis of phragmosomes (microbodies) during cytokinesis inAllium root tip cells

Summary The ontogeny and distribution of phragmosomes (microbodies) during cytokinesis inAllium sativum root tip cells have been studied and complemented with a cytochemical analysis of reactivity with diaminobenzidine (DAB). Incubation in different DAB media revealed the presence of catalase but not peroxidase in these organelles, identifying them as a type of microbody associated with the forming cell plate. Only vacuoles, segments of endoplasmic reticulum and portions of the mature walls stained positively with DAB for peroxidase activity. Microbodies begin to appear in the region of the future cell plate as cells enter late anaphase. They exhibit a moderately electron-opaque anucleoid matrix and are continuous with segments of endoplasmic reticulum (ER). Certain observations have led us to consider that certain aspects of plate formation inAllium require the participation of microbodies: (a) their pronounced numerical increase at the onset of plate formation, (b) their intimate association with regions of the plate where vesicle fusion is in progress, and (c) their rapid numerical decline following vesicular fusion and concomitant cell plate formation. The characteristic spatial association observed between microbodies and the plate-forming vesicles may well reflect their mutual involvement in the metabolism of carbohydrates comprising the middle lamella, being coordinated by metabolic activities in the cytosol, mitochondria and dictyosomes.This study was supported in part by NIH training grant HD 174 to Dr.Hewson Swift and the Marquette University Committee on Research Grants 5641 and 5532.     

A Biolchemical and Cytochemical Study of Peroxidase Activity in Roots of Pisum sativum: I. A COMPARISON OF DAB-PEROXIDASE AND GUAIACOL-PEROXIDASE WITH PARTICULAR EMPHASIS ON THE PROPERTIES OF CELL WALL ACTIVITY

Peroxidase activity in roots of Pisum sativum has been examinedusing both guaiacol and 3,3'-diaminobenzidine (DAB) as hydrogendonors. Biochemically, differences were observed between thetwo donors with respect to the pH optimum (6–9 and 4–0,respectively), and in response to added NaCl (guaiacol-peroxidasewas unaffected while the DAB-peroxidase was markedly inhibited).Both reactions showed highest specific activity in a high speedsupernatant fraction, and, of nine anionic bands demonstratedby gel electrophoresis with DAB, only six were visible withguaiacol. Histochemically, similar staining patterns were observedwith both donors. Cell wall fractions prepared by bead filtration contained 2%and 3.5% of the total peroxidase and acid phosphatase activitiesrespectively. 50% and 27% of these activities were ionicallybound, as indicated by salt treatment In addition, washing withsalt solutions produced a marked stimulation of peroxidase activityat high salt concentrations: this affect was not observed withthe supernatant peroxidase or with cell wall acid phosphatase.Possible functions of cell wall peroxidase are discussed     

Peroxisomes: 40 years of histochemical staining,personal reminiscences

The historical circumstances that led to the discovery of the 3,3′-diamino-benzidine (DAB) method for staining of peroxisomes 40 years ago are reviewed. In the course of studies on the uptake and absorption of horse radish peroxidase in mammalian liver, in sections incubated for detection of peroxidase activity in DAB, it was noted that peroxisomes also stained positively for peroxidase activity. Subsequently, it was revealed that the peroxidatic activity of catalase, which is abundantly present in peroxisomes, is responsible for that staining. This notion was confirmed in quantitative biochemical studies with crystalline beef liver catalase and in tracer studies using catalase as an ultrastructural tracer. The application of the DAB method led to the discovery of peroxisomes as a ubiquitous eukaryotic cell organelle, attracting great interest in their investigation in biomedical research.     

Elektronenmikroskopische Darstellung peroxydatischer Aktivitäten bei Phaseolus vulgaris nach Infektion mit Uromyces phaseoli typica

Zusammenfassung Bei der Wirt-Parasit-Kombination Phaseolus vulgaris (cv. Favorit) und Uromyces phaseoli typica wird die Aktivität peroxydatischer Enzyme am dritten Tag nach Infektion elektronenmikroskopisch dargestellt. Die Aktivität in den Mitochondrien (möglicherweise eine Cytochromoxydase oder Cytochromperoxydase) ist in der infizierten Zelle erhöht. Die Peroxisomen (sie enthalten eine Katalase) bleiben in der infizierten Zelle unverändert. Im Pilz wird keine Katalaseaktivität gefunden.Die Schicht mit peroxydatischer Aktivität auf der Außenseite der Zellwand (Zellwandperoxydase) ist an der Berührungsstelle Hyphe—Wirtswand oft verdickt. An der Eintrittsstelle des Haustoriums in die Zelle wird Aktivität auf der Wand des Haustoriumhalses und auf den Cisternen des benachbarten ribosomenbesetzten endoplasmatischen Reticulums beobachtet. Manchmal findet man auch eine Schicht mit peroxydatischer Aktivität zwischen Scheide und Wand des Haustoriums.

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Electronmicroscopic demonstration of peroxidase activities in Phaseolus vulgaris after infection with Uromyces phaseoli typica

Summary Peroxidase activity in Phaseolus vulgaris (cultivar Favorit), infected with Uromyces phaseoli typica, was studied with the help of an electronmicroscope. The plant material was prefixed three days after inoculation and 3,3-diaminobenzidine was used as a substrate to detect the enzyme activity.The mitochondrial membranes showed an enhanced enzyme activity (due to a cytochrome oxidase or possibly due to a cytochrome peroxidase) in the infected cell. There was no change in the structure and catalase activity of peroxisomes of the host. No catalase activity was detected in the fungus.A layer with evident peroxidase activity is seen outside the cell wall. This layer is sometimes thickened especially when it is in touch with intercellular hyphae.The penetration site of the haustorium has been intensively studied. Activity was observed in the neck region (from the penetration site of the haustorium to the neckband) in the zone between the host plasmalemma and the plasmalemma of the fungus. Some activity was also seen on the cisternae of the endoplasmic reticulum surrounding the neck. In a few preparations, activity was also found between sheath and wall of the haustorium.

     

Substrate specificity of IgGs with peroxidase and oxidoreductase activities from sera of patients with systemic lupus erythematosus and multiple sclerosis

The analysis of IgGs to protect humans from oxidative stress through oxidation of harmful compounds was carried out. We have compared here for the first time peroxidase (in the presence of H₂O₂) and oxidoreductase (in the absence of H₂O₂) activities of IgGs from sera of healthy humans and patients with systemic lupus erythematosus (SLE) and multiple sclerosis (MS). In addition, substrate specificity of SLE and MS IgG preparations in the oxidation of different compounds was analyzed: 2,2′‐azino‐bis(3‐ethylbenzothiazoline‐6‐sulfonic acid) (ABTS), 3,3′‐diaminobenzidine (DAB), homovanillic acid (HVA), o‐phenylenediamine (OPD), α‐naphthol, 3‐amino‐9‐ethylcarbazole (AEC), p‐hydroquinone (pHQ), and adrenaline. IgGs of healthy humans and SLE and MS patients oxidized DAB, ABTS, and OPD due to their peroxidase and oxidoreductase activities, while other compounds were substrates of IgGs only in the presence of H₂O₂: adrenaline was not oxidized by both activities of IgGs. The average SLE IgGs peroxidase activity increased statistically significant in comparison with abzymes from healthy humans in the order (‐fold): OPD (1.2) <  DAB (1.7) < α‐naphtol (2.2) ≤ AEC (2.4) < ABTS (4.5) < 5‐ASA (10.6), while with oxidoreductase activity: OPD (1.8) ≤ DAB (2.1‐fold) < ABTS (5.0). Only HVA was oxidized by IgGs with peroxidase activity of healthy donors faster than by SLE (1.3‐fold) and MS abzymes (2.4‐fold). In the oxidation of several substrates, only three IgGs of MS patients were used. The data speak of a tendency to increase the peroxidase and oxidoreductase activities of MS IgGs in comparison with healthy donors, but to a lesser extent: OPD (1.1 to 1.2‐fold) ≤ ABTS (1.2 to 1.8‐fold). It was shown that development of SLE and MS leads to increase in peroxidase and oxidoreductase activities of IgGs toward most of classical substrates. Thus, abzymes can serve as an additional factor of reactive oxygen species detoxification protecting of patients with SLE and MS from some harmful compounds somewhat better than healthy peoples.     

The parasitic mechanism of the holostemparasitic plant Cuscuta

Cuscuta is a stem holoparasitic plant without leaves or roots, which develops a haustorium and sucks nutrients from host plants. The genus Cuscuta comprises about 200 species, many of which can cause severe problems for certain crops. The parasitic process in Cuscuta begins in finding and attaching to a host plant and then developing a haustorium. The process does not always require any chemical signal, but does require a light signal. Finding a host involves detecting the lower red light:far-red light ratio near a potential host plant by phytochrome. A contact signal is also necessary for haustorium induction. Apparently, cytokinin increase is downstream of the light and contact signal and is critical for haustorium induction. This pathway, however, appears to be slightly different from a standard pathway. The direct connection between Cuscuta and its host involves both the xylem and phloem, and mRNA and proteins can translocate. Several features indicate that Cuscuta is a useful model plant for parasite plant research as well as plant–plant interaction research. These include the simple anatomical structure and seedling development, no chemical requirement for haustorium induction, and the wide range of host plants.     

Some cytochemical correlations between oxidase activity (cytochrome and peroxidase) and chemical structure of bis(phenylenediamines)

Summary A series of 17 bis(phenylenediamine) derivatives have been prepared and compared with 3,3-diaminobenzidine (DAB) with regard to their ability to demonstrate cytochrome oxidase activity, peroxisome activity, horseradish peroxidase activity, erthrocytic peroxidase activity in cytochemical preparations, and bovine catalase activity in in vitro experiments. The results are tabulated, some illustrative photomicrographs are included and interesting correlations are discussed.This investigation was supported by a research grant (CA-02478) from the National Cancer Institute, U. S. Public Health Service.Acknowledgement for technical assistance is due Charles Hatton and William Brown.     

Inhibition of the yeast-mycelial transition and the phorogenesis of Mucorales by diamino butanone

Diamino butanone (DAB), a competitive inhibitor of ornithine decarboxylase (ODC) a key enzyme in polyamine biosynthesis, inhibited the yeast to hyphae transition in Mucor rouxii, induced by transfer from anaerobiosis to aerobiosis, but not the opposite phenomenon. Addition of DAB to anaerobic yeast cells brought about a decrease in ODC and polyamine levels. In these conditions, the aerobic shift produced only a weak increase in ODC activity and no change in polyamine levels. DAB also blocked phorogenesis in M. rouxii and in Phycomyces blakesleeanus. At the effective concentrations DAB did not affect cell growth of either fungus. It is suggested that low, constant levels of ODC and polyamines are necessary for cell growth, and that high transient levels are required during the differentiative steps. DAB, at the concentrations used, affects this last process, but does not interfere with the maintenance level of polyamines.Abbreviations ODC ornithine decarboxylase - DAB 1,4-diamino butanone