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.     

Enzyme histochemical studies on rat lungs 2. Normal enzyme distribution in the alveolar tissue of the mature lung

Synopsis The activity and distribution of the following eighteen oxidative and hydrolytic enzyme systems have been investigated in the lung of the adult rat: reduced NAD dehydrogenase, reduced NADP dehydrogenase, succinate dehydrogenase, malate dehydrogenase, isocitrate dehydrogenase, lactate dehydrogenase, glucose-6-phosphate dehydrogenase, glucose dehydrogenase, glutamate dehydrogenase, -hydroxybutyrate dehydrogenase, acid phosphatase, alkaline phosphatase, glucose-6-phosphatase, adenosine triphosphatase, 5-nucleotidase, non-specific esterase, cytochrome oxidase and -glucuronidase.The low concentration of cells in sections of inflated lung may have made histochemical demonstration of some enzymes impossible because the enzyme concentration was below that detectable by the method employed.The carboxylic acid cycle and the hexose monophosphate shunt were potentially active but fatty acid metabolism was not indicated.The granular reaction sometimes encountered in alveolar cell cytoplasm may be useful for differentiating alveolar cell types, but further cytochemical studies are required to resolve the possible metabolic differences of alveolar cells.     

Comparison of kinetic and end-point microdensitometry for the direct quantitative histochemical assessment of cytochrome oxidase activity

Synopsis Cytochrome oxidase activity has been assessed by a method of kinetic microdensitometry which involves applying tissue sections to gel films containing phenylamine substrates and measuring the rate of azine dye production by continuously recording the rate of change in extinction. Optimum conditions for the technique were defined, and the results compared with those obtained by conventional end-point microdensitometry in which sections are incubated in histochemical substrate solutions and azine dye production estimated by a single measurement of extinction at the end of the incubation period. When compared with biochemically-determined enzyme activity, kinetic microdensitometry gave a better index of the proportionate activity of cytochrome oxidase in various normal tissues than did end-point microdensitometry. In addition, the degree of inhibition of cytochrome oxidase activity in tissues removed from cyanide-poisoned animals was assessed more reliably by kinetic microdensitometry than by end-point measurements. With end-point microdensitometry, the reaction is non-linear over the comparatively long incubation times required and there is also a spontaneous reactivation of cyanide-inhibited cytochrome oxidase during incubation and thus a progressively increased rate of substrate utilization. In contrast, with kinetic microdensitometry the initial linear reaction rate is measured before significant reactivation occurs. Kinetic microdensitometry can be used for direct dynamic quantitation of enzyme activity in tissues or cells; it may be a valuable technique for quantitative histochemical confirmation or extension of biochemical studies; and it appears to be a reliable direct quantitative histochemical method for investigatingin vivo inhibition of enzyme activity, where spontaneous reactivation of the enzyme-inhibitor complex may occur.     

The relationship of structure of glucoamylase and glucose oxidase to antigenicity

Glucoamylase and glucose oxidase fromAspergillus niger have been purified to homogeneity by chromatography on DEAE-cellulose and the purified enzymes have been used to investigate structural and antigenicity relationships. In structure, glucoamylase and glucose oxidase are glycoproteins containing 14% and 16% carbohydrate. Earlier methylation and reductive -elimination results have shown that glucoamylase has an unusual arrangement of carbohydrate residues, with 20 single mannose units and 25 di-, tri-, or tetrasaccharide chains of mannose, glucose, and galactose, all attached O-glycosidically to serine and threonine residues of the protein moiety. The antigenicity of the glucoamylase has now been found to reside predominantly in the types and arrangement of the carbohydrate chains. Glucose oxidase contains mannose, galactose, and glucosamine in the N-acetyl form in the native enzyme, but the complete structure of the carbohydrate chains has not yet been determined. The antigenicity of this enzyme does not reside in the carbohydrate units, but rather in the polypeptide chains of the two subunits of the enzyme. Glucose oxidase can be dissociated into subunits by mercaptoethanol and sodium dodecyl sulfate treatment, while glucoamylase cannot be dissociated, but undergoes only an unfolding of the polypeptide chain under these conditions. The subunits of glucose oxidase do not react with the anti-glucose oxidase antibodies, but the unfolded molecule and peptide fragments produced from glucoamylase by cyanogen bromide cleavage do react with antiglucoamylase antibodies.     

Some remarks concerning the histochemical detection of disaccharidases and glucosidases

Summary In the histochemical detection of the disaccharidases and glucosidases the reliability of methods with coupled oxidation of glucose (with various buffers, tetrazolium salts and concentrations of substrates, tetrazolium salts and PMS) and azo-dye methods with the postincubation as well as simultaneous azo-coupling in cryostat sections (unfixed, fixed with Baker's formol and acetone) and frozen sections after fixation in cold Bakers's formol and glutaraldehyde was tested. Various rat organs and human enterobiopsies were used. The methods were modified.Despite the fact that glutaraldehyde and formol fixation does not completely destroy enzyme activities splitting maltose, sucrose, trehalose and lactose (as it could be shown by a simple Glukophan test) the use of the fixed sections is not recommended. Activity of these enzymes is not completely structurally bound and a part of them escapes from the unfixed cryostat sections into the solutions used for rinsing or for incubation. Activities of these enzymes were demonstrated in the content of the rat jejunum as well. The results of the detection of disaccharidases with a coupled oxidation of glucose are dependent on buffer (type and pH), on the tetrazolium salt (type and concentration), on the concentration of phenazine methosulfate and of disaccharides, on the conditions during the incubation (temperature, anaerobic or aerobic conditions, aqueous or gel media) and on the type of sections. With all the substrates used (maltose, sucrose, trehalose and lactose) a positive reaction in the enterocytes (both of rat and human) and in the cells of convoluted tubules in rat kidney was obtained. With lactose the reaction was weak and irregular and could be obtained under anaerobic conditions only. A proximodistal gradient in the rat intestine was revealed. In the detection of lactose the use of galactose oxidase in combination with glucose oxidase decreased the intensity of the staining. In evaluating the validity of the localization the artifacts caused by the diffusion of disaccharidases and by the method with coupled oxidation of glucose were considered, the latter being their main source. By no means such artifacts could be avoided. The positive staining is revealed in the sites of the bound tetrazolium salt where it is contacted by the reduced PMS. No reaction can be obtained in sites lacking affinity for the tetrazolium salts even if they contained an active enzyme. The technique allows at the most the localization on the cellular but not intracellular level. The disaccharidase granules of Dahlquist and Brun are artifacts.When the sections are incubated individually with the described gel media or in the incubation chambers the amount of produced formazan may serve as a measure of the activity of the respective disaccharidase. Such technique proved to be of value in investigating the changes of activities of disaccharidases in the jejunum of patients with primary malabsorption syndrome. These activities were reduced in comparison with the normal jejunum.The limitations in localization of the postincubation azo-coupling methods for the deection of glucosidases and galactosidases are much the same as those of the methods with coupled oxidation of glucose. In addition to it the relative substrate specificity of the intestinal disaccharidases has to be considered, because identical enzymes may not be detected with synthetic and natural substrates. Using our new method with hexazo-p-rosaniline in the simultaneous azocoupling an improved localization of 6-Br-2-naphthyl--D-glucosidase was achieved. In the enterocytes the enzyme was localized in the microvillous zone and apical part of the cytoplasma.     

The effect of sodium ethylenediaminetetra-acetate (na2 edta) on the histochemical demonstration of some enzyme activities in neonatal mouse molar tissues

Summary Décalcification of neonatal mouse tissues, including the first molar germs, by 10 per cent ethylenediaminetetra-acetate (Na₂EDTA) containing 7.5 per cent polyvinylpyrrolidone (PVP) was found to increase the histochemical reactions of lactate and malate dehydrogenase activities, as compared with non-decalcified preparations. The activity of glucose-6-phosphate dehydrogenase was not significantly affected by the demineralization procedure. Adenosinetriphosphatases (ATPases) in the endothelial cells and in the nuclei of most of the cells in the cryostat sections (8 ) showed enhanced activities after the EDTA-treatment (48 hours at 4° C). ATPase in matrix-forming odontoblasts and ameloblasts, however, was consistently inhibited.The biochemical test indicated that the EDTA- and PVP-solutions, according to Fullmer (1966), allowed only a trace amount of protein leakage into the decalcification fluid.Preservation and retention of protein molecules and a simultaneous removal of contaminating ions and de-masking of active sites of the enzymes might be responsible for some of the effects observed in enzyme histochemical registrations.     

Discrepancy between the histochemically and biochemically determined 3β-hydroxysteroiddehydrogenase activity in the calf adrenal cortex

Summary In sections of the calf adrenal cortex the histochemically determined3-hydroxysteroiddehydrogenaae activity is lower in the zona glomerulosa than in the zona fasciculata. Biochemically the activity of this enzyme was found in mitochondrial as well as in microsomal fractions. The mitochondrial, respectively the microsomal fractions of the two zones showed identical enzyme activities. So there is a discrepancy between the histochemical results on tissue sections and biochemical results obtained with isolated subcellular fractions.However, if the histochemical determination of 3-hydroxysteroiddehydrogenase activity is carried out on sections of mitochondrial and microsomal pellets of the two zones the results are in agreement with the biochemical findings. Therefore the observed discrepancy rather seems to be related with the state of tissue—intact or cell fractions—than with the used histochemical method.     

Glucose oxidase as label in histological immunoassays with enzyme-amplification in a two-step technique: coimmobilized horseradish peroxidase as secondary system enzyme for chromogen oxidation

Summary A sensitive staining procedure for glucose oxidase (GOD) as marker in immunohistology is described. The cytochemical procedure involves a two-step enzyme method in which GOD and horseradish peroxidase (HRP) are coimmobilized onto the same cellular sites by immunological bridging or by the principle of avidin-biotin interaction. In this coupled enzyme technique, H₂O₂ generated during GOD reaction is the substrate for HRP and is utilized for the oxidation of chromogens such as 3,3-diaminobenzidine or 3-amino-9-ethylcarbazole. Due to the immobilization of the capture enzyme HRP in close proximity to the marker enzyme (GOD), more intense and specific staining is produced than can be obtained with soluble HRP as coupling enzyme in the substrate medium. Indirect antibody labelled and antibody bridge techniques including the avidin (streptavidin)-biotin principle have proven the usefulness of this GOD labelling procedure for antigen localization in paraffin sections. Antigens such as IgA in tonsil, alpha-feroprotein in liver and tissue polypeptide antigen in mainmary gland served as models. The immobilized twostep enzyme procedures have the same order of sensitivity and specificity as comparable immunoperoxidase methods. The coupled GOD-HRP principle can be superior to conventional immunoperoxidase labelling for the localization of biomolecules in tissue preparations rich in endogenous peroxidase activities.     

In situ heterogeneity of peroxisomal oxidase activities: An update

Summary Oxidases are a widespread group of enzymes. They are present in numerous organisms and organs and in various tissues, cells, and subcellular compartments, such as mitochondria. An important source of oxidases, which is investigated and discussed in this study, are the (micro)peroxisomes. Oxidases share the ability to reduce molecular oxygen during oxidation of their substrate, yielding an oxidized product and hydrogen peroxide. Besides the hydrogen peroxide-catabolizing enzyme catalase, peroxisomes contain one or more hydrogen peroxide-generating oxidases, which participate in different metabolic pathways. During the last four decades, various methods have been developed and elaborated for the histochemical localization of the activities of these oxidases. These methods are based either on the reduction of soluble electron acceptors by oxidase activity or on the capture of hydrogen peroxide. Both methods yield a coloured and/or electron dense precipitate. The most reliable technique in peroxisomal oxidase histochemistry is the cerium salt capture method. This method is based on the direct capture of hydrogen peroxide by cerium ions to form a fine crystalline, insoluble, electron dense reaction product, cerium perhydroxide, which can be visualized for light microscopy with diaminobenzidine. With the use of this technique, it became clear that oxidase activities not only vary between different organisms, organs, and tissues, but that heterogeneity also exists between different cells and within cells, i.e. between individual peroxisomes. A literature review, and recent studies performed in our laboratory, show that peroxisomes are highly differentiated organelles with respect to the presence of active enzymes. This study gives an overview of thein situ distribution and heterogeneity of peroxisomal enzyme activities as detected by histochemical assays of the activities of catalase, and the peroxisomal oxidasesd-amino acid oxidase,l--hydroxy acid oxidase, polyamine oxidase and uric acid oxidase.     

Histochemical model studies of enzyme activity after thermal damage

Summary The reliability of histochemical determinations of the enzyme activity after thermal damage has been studied with the aid of two model systems. Polyacrylamide films and erythrocyte ghosts containing either -glucuronidase or alkaline phosphatase, were submitted to heating and the activities retained were assessed both biochemically and histochemically. For the enzymes studied, the results show that tissue alterations induced by heat can influence histochemical reaction procedures, and that with these model systems, factors which are important for the histochemical quantitation of enzyme activities in thermally damaged tissues can be evaluated quantitatively. Potentialities of these model systems in the study of evaluating thermal damage through histochemical enzyme activity determinations, are discussed.To whom offprint requests should be sent     

Detection of cytokinins and auxin in plant tissues using histochemistry and immunocytochemistry

We report a new method for histochemical localization of cytokinins (CKs) in plant tissues based on bromophenol blue/silver nitrate staining. The method was validated by immunohistochemistry using anti-trans-zeatin riboside antibody. Indole-3-acetic acid (auxin, IAA) was localized by anti-IAA antibody in plant tissues as a proof for IAA histolocalization. We used root sections, because they are major sites of CKs synthesis, and insect galls of Piptadenia gonoacantha that accumulate IAA. Immunostaining confirmed the presence of zeatin and sites of accumulation of IAA indicated by histochemistry. The colors developed by histochemical reactions in free-hand sections of plant tissues were similar to those obtained by thin layer chromatography (TLC), which reinforced the reactive sites of zeatin. The histochemical method for detecting CKs is useful for galls and roots, whereas IAA detection is more efficient for gall tissues. Therefore, galls constitute a useful model for validating histochemical techniques due to their rapid cell cycles and relatively high accumulation of plant hormones.     

The histochemistry of estrogen receptors

Summary Estrogen receptors in frozen section of the rat uterus were demonstrated by a radiolabeled ligand binding technique. The bound hormone was extracted with ethanol and measured by liquid scintillation. The binding of ³H-estradiol-17 at various molar concentrations was inhibited by a 100-fold excess of DES, and the bound ³H-estradiol resisted exhaustive washings at 4°C for 16 h. These binding sites were not present in the sections of the spleen, and perhaps at a very low concentration in the myocardium. Thus their binding behavior and distribution pattern are consistent with those of specific estrogen receptors. The hydrophilic fluorescent estradiol conjugate, 17-estradiol-6-CMO-BSA-FITC was found to be a highly effective competitor against binding of ³H-estradiol to its receptors in tissue sections, and is considered a useful histochemical reagent for localizing target cells with high concentrations of estrogen receptors. Estrogen receptor sites in frozen sections of human breast cancer were also measured by this radiolabeled ligand binding technique, and expressed in femtomoles of hormone bound per 1,000 cancer cells. The values were parallel to the histochemical findings in terms of percentage of the estrogen receptor-positive in the cancer cell population.     

Improved histochemical method for the demonstration of the activity of α-glucan phosphorylase

Summary The activity and localization of -glucan phosphorylase in experimental canine glycogen-depleted heart tissue has been investigated with biochemical and histochemical methods using dextran as enzyme acceptor. Only linear, essentially unbranched, dextrans exhibit acceptor properties; highly branched dextrans are not suitable acceptors for the enzyme. Results of Michaelis-Menten constant measurements for the linear essentially unbranched dextran fractions used, indicate that the affinity of the enzyme for the non-reducing end group of the dextran molecule increases with increasing molecular weight of the acceptor.In the glycogen-depleted tissue of anoxic and ischaemic cardiac musculature there is a gradual inactivation of the enzyme during the ischaemic period. Shortly before total inactivation the affinity of the enzyme, especially for the lower molecular dextran fractions, is greatly reduced. Therefore, for the histochemical demonstration of phosphorylase activity in infarcted areas of the heart it is essential to use as acceptor an unbranched dextran fraction with a high average molecular weight.This investigation was partially supported by a grant from the Netherlands Organization for the Advancement of Pure Research (Z.W.O.).     

Semipermeable membranes for improving the histochemical demonstration of enzyme activities in tissue sections

Summary Improved histochemical multi-step techniques for the demonstration of glucose 6-phosphate isomerase and phosphoglucomutase in tissue sections are described. With these techniques a semipermeable membrane is interposed between the incubating solutions and the tissue sections preventing diffusion of enzymes into the medium during incubation. In the histochemical system the glucosephosphate isomerase converts the substrate d-fructo-furanose 6-phosphoric acid to d-gluco-pyranose 6-phosphoric acid, and the phosphoglucomutase converts the substrate -d-glucose 1-phosphate to the same reagent, which in turn is oxidized, by exogenous and endogenous glucose 6-phosphate dehydrogenase to d-glucono--lactone 6-phosphoric acid. Concomittantly the electrons are transferred via NADP⁺, phenazine methosulphate and menadione to nitro-BT. Sodiumazide and amytal are incorporated to block electron transfer to the cytochromes.     

Specificity in steroid histochemistry,with special reference to the use of steroid solvents. distribution of 11 β-hydroxysteroiddehydrogenase in kidney and thymus from the mouse

Summary Several factors influencing the steroiddehydrogenase histochemistry were investigated: diffusion of enzyme; inactivation of enzyme; effects of the steroid solvents commonly used; the validity in localization of the enzyme activity; nothing dehydrogenase reaction. 1. The importance in controlling the diffusion of each enzyme system to be studied is emphasized. Provided that the presence of SH-groups in the active centre of the dehydrogenase can be proved, a control experiment using a double-section incubation method should be carried out. 2. A comparison between the use of unfixed and briefly prefixed sections is recommended in order to avoid a possible distortion of the tissue during the incubation. The influence of prefixation on diffusion of enzymes or reaction products as well as on inactivation of enzymes must be studied. 3. The steroid solvents—especially dimethyl formamide caused a morphological distortion, and an inactivation and/or extraction of reaction products (the red monoformazan) in fresh frozen sections, these solvents should therefore be handled with caution. A special mixture of dimethyl formamide and propylene glycol is recommended. 4. The steroid should be completely soluble in the incubation medium in order to secure zero order kinetics. 5. Avoidance of sulphydryl nothing dehydrogenase reaction, since the reaction predominantly manifests itself as a red formazan obscuring sites with low dehydrogenase activity. 6. The localization of the NAD(P)H oxidase systems must be controlled, in order to ensure that they should not be a limiting factor in the detection of the dehydrogenase activity. Secondly, this investigation may act as a control on diffusion of dehydrogenase and/or reduced coenzyme. 7. That the investigation of the incubation time needed for initial visual reaction allows a certain quantitative estimation of the concentration of enzyme localized at different sites in the same section. The investigation should also include the red formazan, since it has recently been proved to be an intermediary step in the enzymic reduction of Nitro BT, and as such may reflect sites with low enzyme concentration.Further, some of the functional aspects of the activity of 11-hydroxysteroiddehydrogenaseNAD(P)H oxidase systems in the thymus were discussed, and lastly the localization of these systems in the kidney was revised.This work was supported by a grant from Statens almindelige Videnskabsfond, Copenhagen.     

Catalytic enzyme histochemistry and biochemical analysis of dihydroorotate dehydrogenase/oxidase and succinate dehydrogenase in mammalian tissues,cells and mitochondria

Dihydroorotate dehydrogenase (EC 1.3.3.1 or EC 1.3.99.11) catalyzes the fourth sequential step in the de novo synthesis of uridine monophosphate. In eukaryotes it is located in the inner mitochondrial membrane, with ubiquinone as the proximal and cytochrome oxidase as the ultimate electron transfer system, whereas the rest of pyrimidine biosynthesis takes place in the cytosol. Here, the distribution of dihydroorotate dehydrogenase activity in cryostat sections of various rat tissues, and tissue samples of human skin and kidney, was visualized by light microscopy using the nitroblue tetrazolium technique. In addition, a hydrogen peroxide-producing oxidase side-reactivity of dihydroorotate dehydrogenase could be visualized by trapping the peroxide with cerium-diaminobenzidine. The pattern of activity was similar to that of succinate dehydrogenase, but revealed a less intensive staining. High activities of dihydroorotate dehydrogenase were found in tissues with known proliferative, regenerative, absorptive or excretory activities, e.g., mucosal cells of the ileum and colon crypts in the gastro-intestinal tract, cultured Ehrlich ascites tumor cells, and proximal tubules of the kidney cortex, whilst lower activities were present in the periportal area of the liver, testis and spermatozoa, prostate and other glands, and skeletal muscle. Dihydroorotate dehydrogenase and succinate dehydrogenase activity in Ehrlich ascites tumor cells grown in suspension culture were quantified by application of nitroblue tetrazolium or cyanotolyl tetrazolium and subsequent extraction of the insoluble formazans with organic solvents. The ratio of dihydroorotate dehydrogenase to succinate dehydrogenase activity was 14. This was in accordance with that of 15 obtained from oxygen consumption measurement of isolated mitochondria on addition of dihydroorotate or succinate. The ratio determined with mitochondria from animal tissues was up to 115 (rat liver, bovine heart). The application of the enzyme inhibitors brequinar sodium and toltrazuril verified the specificity of the histochemical and biochemical methods applied.     

Comparative localization of aldehyde oxidase and xanthine oxidoreductase activity in rat tissues

The distribution of aldehyde oxidase activity was evaluated in unfixed cryostat sections from tissues of male Wistar rats using a tissue protectant, polyvinyl alcohol, with Tetranitro BT as a final electron acceptor. The distribution of aldehyde oxidase activity was compared with that of xanthine oxidoreductase. The enzyme histochemical method demonstrated aldehyde oxidase activity in the epithelium of the tongue, renal tubules and bronchioles, as well as in the cytoplasm of liver cells. Such activity was not detected in oesophagus, stomach, spleen, adrenal glands, small or large intestine or skeletal and heart muscle fibres. In contrast, xanthine oxidoreductase activity was demonstrated in the tongue, renal tubules, bronchioles, oesophageal, gastric, small and large intestinal epithelial cells, adrenal glands, spleen and liver cytoplasm but not in skeletal and heart muscle fibres. The significance of the ubiquitous distribution of aldehyde oxidase activity, especially in surface epithelial cells from various tissues, except for the gastrointestinal tract, is unclear. However, aldehyde oxidase may possess some physiological activity other than in the metabolism of N-heterocyclics or of certain drugs. © 1998 Chapman & Hall     

Distribution of xanthine oxidoreductase activity in human tissues--a histochemical and biochemical study.

Localization of the activity of both the dehydrogenase and oxidase forms of xanthine oxidoreductase were studied in biopsy and postmortem specimens of various human tissues with a recently developed histochemical method using unfixed cryostat sections, poly-(vinyl alcohol) as tissue stabilizator, 1-methoxyphenazine methosulphate as intermediate electron acceptor and Tetranitro BT as final electron acceptor. High enzyme activity was found only in the liver and jejunum, whereas all the other organs studied showed no activity. In the liver, enzyme activity was found in sinusoidal cells and both in periportal and pericentral hepatocytes. In the jejunum, enterocytes and goblet cells, as well as the lamina propria beneath the basement membrane showed activity. The oxidase activity and total dehydrogenase and oxidase activity of xanthine oxidoreductase, as determined biochemically, were found in the liver and jejunum, but not in the kidney and spleen. This confirmed the histochemical results for these organs. Autolytic rat livers several hours after death were studied to exclude artefacts due to postmortem changes in the human material. These showed loss of activity both histochemically and biochemically. However, the percentage activity of xanthine oxidase did not change significantly in these livers compared with controls. The findings are discussed with respect to the possible function of the enzyme. Furthermore, the low conversion rate of xanthine dehydrogenase into xanthine oxidase during autolysis is discussed in relation to ischemia-reperfusion injury.     

Histochemical localization of monoamine oxidase in whole-body, freeze-dried sections of mice

Summary Monoamine oxidase was investigated histochemically in tissues of the mouse by incubating freeze-dried, whole-body sections with tryptamine, serotonin, tyramine, -phenylethylamine, or benzylamine as substrate and Nitroblue tetrazolium as the final electron acceptor. The most intense staining with tryptamine was exhibited by intestinal epithelium and adrenal cortex; moderate staining was noted in the epithelium of the nose, bronchi, oesophagus, and upper stomach and in preputial gland, pancreas, nerve, spinal cord and brain. Weak staining was seen in the lung, spleen, liver and kidney. The distribution of the formazan deposition was similar, but much less intense, when serotonin and tyramine were used as the substrates. Only very weak staining was observed when -phenylethylamine was the substrate; no staining was seen with benzylamine. Monoamine oxidase activities with tryptamine were greatly inhibited by pretreatment with clorgyline (10 m), while deprenyl (10 m) slightly inhibited activities in all tissues except liver. This staining technique should be useful in further studies on the identification of the multiple forms of monoamine oxidase in tissues of the mouse. Nicotine and nitrosonornicotine were not substrates in any of the tissues; consequently, this enzyme system does not appear to produce the proximal carcinogen from this nitrosamine.