Tetrazolium methods for the histochemical investigation of hydrolases (author's transl)]

Using freeze-dried or sections from fresh-frozen or aldehyde-fixed material nitro BT (NBT), tetranito BT (TNBT), distyryl nitro BT (DS-NBT), thiocarbamyl nitro BT (TC-NBT) or benzothiazolylstyrylphthalhydrazidyl tetrazolium chloride (BSPT) were tested as auxiliary reagents for the localization of glycosidases, phosphatases and non-specific esterases with indoxyl substrates in rat tissues. By means of NBT or TNBT as a tetrazolium salt acid beta-D-galactosidase, beta-D-N-acetylglucosaminidase, acid phosphatase, neuraminidase and non-specific esterase can only be localized at the cellular level; a more precise localization is possible for lactase-beta-D-glucosidase in the intestinal brush border, and the best results are obtained in the demonstration of alkaline phosphatase; among all methods described previously the tetrazolium procedure with TNBT is the method of choice for the light microscopic localization of this enzyme. Reverse data are observed with BSPT as a tetrazolium salt; then, all acid and neutral hydrolases can be exactly localized in lysosomes, secretion granules, cytoplasm and/or microvilli of many cells and tissues provided BSPT-formazan is stabilized by osmification. Furthermore, this procedure enables the reliable ultracytochemical demonstration of these enzymes. However, in the case of alkaline phosphatase only sites with high enzyme activity reveal a positive reaction. -DS- and TC-NBT are inferior to NBT, TNBT or BSPT.     

ULTRASTRUCTURAL DEMONSTRATION OF CYTOCHROME OXIDASE ACTIVITY BY THE NADI REACTION WITH OSMIOPHILIC REAGENTS

A new method for the subcellular and cytochemical demonstration of cytochrome oxidase has been developed with the introduction of N-benzyl-p-phenylenediamine (BPDA) and the discovery that indoanilines are osmiophilic. These indoanilines produced upon oxidation of BPDA in the presence of naphthols are highly colored compounds that yield electron-opaque coordination polymers of osmium (osmium black) that are amorphous, insoluble in water, and in organic solvents. The best methods for preparing rat tissue were in decreasing order: fixation in formaldehyde solution, fresh tissue slices, and frozen sections of fresh or fixed tissue. Ultrathin sections were counterstained by bridging with the thiocarbohydrazide-osmium tetroxide (T-O) procedure for enhancing underlying membranous structures. Cytochrome oxidase activity was noted primarily in mitochondria and occasionally in sarcotubules of heart, in mitochondria and occasionally in infoldings of the plasma membrane of renal tubular cells, and in mitochondria and, to a great extent, in endoplasmic reticulum of hepatic cells. Cytochrome oxidase activity produced deposits in droplet form, whereas dehydrogenase activity resulted in uniform staining of mitochondrial cristae, as recently demonstrated with an osmiophilic tetrazolium salt. Even more recently we have succeeded in demonstrating cytochrome oxidase activity in nondroplet staining on mitochondrial cristae with an osmiophilic benzidine-type reagent that apparently polymerizes upon oxidation (to be published later).     

A cerium method for the ultracytochemical localization of monoamine oxidase activity

Summary A cytochemical method based on the complex formation between cerous ions and hydrogen peroxide is described for the ultrastructural localization of monoamine oxidase (MAO). First, the residual MAO activity after fixation was measured by a radiochemical assay technique and was found to be sufficiently retained for cytochemical detection. Although the Tris buffer used in the present method was found to be inhibitory to MAO, considerable activity was still retained after fixation and incubation in Tris.MAO activity, detected as precipitates of cerium perhydroxide, was observed in the mitochondrial outer compartment, mitochondrial cristae and perinuclear space of myocardial cells and endothelial cells of rat heart. MAO activity was also found along the plasma membrane of capillary endothelia. Omission of substrate from the incubation medium or pre-incubation with pargyline, a specific MAO inhibitor, drastically reduced the amount of deposits. The present cerium method seems promising because of its reproducibility and the high electron density of the reaction products.     

NONDROPLET ULTRASTRUCTURAL DEMONSTRATION OF CYTOCHROME OXIDASE ACTIVITY WITH A POLYMERIZING OSMIOPHILIC REAGENT, DIAMINOBENZIDINE (DAB)

A new method for demonstrating cytochrome oxidase activity, based upon the oxidative polymerization of 3,3'-diaminobenzidine (DAB) to an osmiophilic reaction product, has improved the localization of this enzyme over methods based upon the Nadi reaction, in both the light and electron microscopes. The reaction product occurs in nondroplet form, which more accurately delineates the localization of cytochrome oxidase in mitochondria of heart, liver, and kidney. In electron microscopic preparations the excess reaction product is found to overflow into the intracristate spaces and into the outer compartment between inner and outer limiting mitochondrial membranes. This finding suggests that the enzymatic activity of cytochrome c is located on the inner surface of the intracristate space which is the outer surface of the inner mitochondrial membrane. Succinic dehydrogenase activity has also been located at this site by using an osmiophilic ditetrazolium salt, TC-NBT. Considered together, the sites of reactivity of both parts of the respiratory chain have implications for the chemiosomotic hypothesis of Mitchell who suggests a mechanism of energy conservation during electron transport in the respiratory chain of the mitochondrion.     

Quantitative aspects of the histochemical tetrazolium salt reaction on monoamine oxidase activity in rat liver

Summary The tetrazolium method for the histochemical detection of monoamine oxidase (MAO) activity in rat liver cryostat sections has been tested for its specificity and its possible use in quantification. The tetrazolium salt tetranitro blue tetrazolium is recommended for the localization of MAO activity, rather than nitro blue tetrazolium or BPST [2-(2-benzothiazolyl)-3(4-phthalhydrazidyl)-5-styryl-tetrazolium]. Hardly any formazan was produced in the absence of the substrate tryptamine and Marsilid, a specific inhibitor of MAO activity, prevented formazan production almost completely. A linear relationship between the integrated absorbance measured with a microdensitometer and either the incubation period or section thickness was obtained. We conclude that the method described in this paper can be used for the quantitative analysis of MAO activity in tissue sections of rat liver. MAO activity was found to be 20–25% higher in the periportal zone of rat liver than in the perivenous zone.     

Electron microscopic localization of monoamine oxidase in the rat liver.

Two methods have been employed to localize monoamine oxidase activity in the cells of rat liver, using either 2-(2'-benzothiazolyl)-5-stryl-3-(4'-phtalhydrazidyl) tetrazolium chloride (BSPT) or ferricyanide as electron acceptor. With both methods monoamine oxidase activity was found both in the inner and the outer mitochondral membrane, although the outer membrane appeared the most probable location. In addition the BSPT method but not the ferricyanide method, revealed monoamine oxidase activity in the endoplasmatic reticulum. The results obtained by the two methods have been compared and are discussed in view of available biochemical data on monoamine oxidase.     

Electron microscopic localization of monoamine oxidase in the rat liver

Summary Two methods have been employed to localize monoamine oxidase activity in the cells of rat liver, using either 2-(2′-benzothiazolyl)-5-stryl-3-(4′-phtalhydrazidyl) tetrazolium chloride (BSPT) or ferricyanide as electron acceptor. With both methods monoamine oxidase activity was found both in the inner and the outer mitochondral membrane, although the outer membrane appeared the most probable location. In addition the BSPT method but not the ferricyanide method, revealed monoamine oxidase activity in the endoplasmatic reticulum. The results obtained by the two methods have been compared and are discussed in view of available biochemical data on monoamine oxidase. Supported by research grants from the National Research Council of Canada (A 3651), The Swedish Medical Research Council (4145) and M. Bergwall's Foundation, Stockholm.     

Trypanosoma cruzi: ultrastructural cytochemistry of mitochondrial enzymes

Mitochondrial enzymes were detected cytochemically in all developmental stages of Trypanosoma cruzi maintained in tissue cultures at the light and electron microscope levels. Cytochrome oxidase (CO) was detected using the diaminobenzidine method. Succinate dehydrogenase (SDH), isocitrate dehydrogenase (ICDH), NADPH diaphorase, α-glycerophosphate dehydrogenase (GPDH), and β-hydroxybutyrate dehydrogenase (HBDH) were detected using the dystyril nitroblue tetrazolium salt. A reaction product indicative of CO, SDH, ICDH, and NADPH diaphorase activities was found either in the inner mitochondrial membrane or in the cristae. β-HBDH and α-GPDH activities, however, were localized only in the inner membrane. No difference in the localization and intensity of the reaction was observed in the various stages of T. cruzi.     

Tetrazoliummethoden zum histochemischen Hydrolasennachweis

Zusammenfassung An gefriergetrockneten und Schnitten von nativem oder aldehyd-fixiertem Material wird die Eignung von Nitro BT (NBT), Tetranitro BT (TNBT), Distyryl Nitro BT (DS-NBT), Thiocarbamyl Nitro BT (TC-NBT) und Benzothiazolylstyrylphthalhydrazidyltetrazoliumcholorid (BSPT) als Hilfsreagentien zur Lokalisation von Glykosidasen, Phosphatasen und unspezifischen Esterasen mit Indoxylsubstraten an Rattenorganen geprüft.Mit NBT und TNBT lassen sich die saure -d-Galactosidase, -d-N-Acetylglucosaminidase, saure Phosphatase, Neuraminidase und unspezifische Esterase höchstens auf Zellebene nachweisen; präziser kann die Lactase--d-glucosidase im intestinalen Bürstensaum dargestellt werden. Die besten Resultate liefert die Untersuchung der alkalischen Phosphatase; mit TNBT ist das Tetrazoliumverfahren unter allen bisher beschriebenen Reaktionen die Methode der Wahl für die lichtmikroskopische Darstellung dieses Enzyms.Mit BSPT als Tetrazoliumsalz und anschließender Osmierung seines Formazans lassen sich alle sauren und neutralen Hydrolasen exakt in Lysosomen, Sekretgranula, Cytoplasma und/oder Mikrovilli fassen; gleichzeitig sind damit ultracytochemische Studien möglich. Die alkalische Phosphatase reagiert mit BSPT nur an hochaktiven Stellen positiv.-DS- und TC-NBT sind NBT, TNBT und BSPT unterlegen.

---

Tetrazolium methods for the histochemical investigation of hydrolases

Summary Using freeze-dried or sections from fresh-frozen or aldehyde-fixed material nitro BT (NBT), tetranitro BT (TNBT), distyryl nitro BT (DS-NBT), thiocarbamyl nitro BT (TC-NBT) or benzothiazolylstyrylphthalhydrazidyl tetrazolium chloride (BSPT) were tested as auxiliary reagents for the localization of glycosidases, phosphatases and non-specific esterases with indoxyl substrates in rat tissues.By means of NBT or TNBT as a tetrazolium salt acid -d-galactosidase, -d-N-acetylglucosaminidase, acid phosphatase, neuraminidase and non-specific esterase can only be localized at the cellular level; a more precise localization is possible for lactase--d-glucosidase in the intestinal brush border, and the best results are obtained in the demonstration of alkaline phosphatase; among all methods described previously the tetrazolium procedure with TNBT is the method of choice for the light microscopic localization of this enzyme.Reverse data are observed with BSPT as a tetrazolium salt; then, all acid and neutral hydrolases can be exactly localized in lysosomes, secretion granules, cytoplasm and/or microvilli of many cells and tissues provided BSPT-formazan is stabilized by osmification. Furthermore, this procedure enables the reliable ultracytochemical demonstration of these enzymes. However, in the case of alkaline phosphatase only sites with high enzyme activity reveal a positive reaction.-DS- and TC-NBT are inferior to NBT, TNBT or BSPT.

     

The oxidation of N,N′-bis(4-aminophenyl)-N,N′-dimethylethylenediamine (BED) by rat liver

We have examined the oxidation of N,N′-bis(4-aminophenyl)-N,N′-dimethylethylenediamine (BED) by tissue homogenates and fractions of liver homogenates. We find that this agent both gives osmiophilic deposits in tissue blocks and readily increases the uptake of oxygen by hepatic homogenates. The highest activity was in the mitochondrial and, next, in the microsomal fractions. Kinetic evidence indicates that the former represents two enzymatic activities while the latter is only a single site. The activity was greatest in the outer membrane of the mitochondria, in agreement with electron micrographic studies and in the rough microsomal fraction. Further, it was very sensitive to both formaldehyde and detergents. The activity was not well associated with either monamine oxidase (benzylamine substrate) or xanthine oxidase activities. Activity was observed in a large number of tissues.     

The cytochemical localization of succinic dehydrogenase in the sperm mitochondria of the gastropod Biomphalaria glabrata. A comparison of two methods.

The mitochondrial derivative of the sperm of the gastropod pulmonate Biomphalaria glabrata was studies to ascertain succinic dehydrogenase localization cytochemically. Two techniques were compared. One technique depends on a tetrazolium salt that yields an osmiophilic formazan upon reduction. The other technique is dependent on the reduction of copper ferricyanide. The effects of several electron transport inhibitors were studied. The reaction product observed in the matrix of the mitochondrial derivative using the former technique is sensitive to rotenone and is believed to be nicotinamide adenine dinucleotide-dependent. The reaction product observed in the intracristal spaces using the copper ferricyanide method is insensitive to rotenone and is believed to cytochemically demonstrate succinic dehydrogenase in this material.     

Possible mechanism of selective inhibition of rat liver mitochondrial monoamine oxidase by chlorgiline and deprenyl]

The inhibition of the deamination of serotonin (the main substrate of monoamine oxidase (MAO) type A) by chlorgiline and deprenyl and of beta-phenylethylamine (the main substrate of the B type MAO) by fragments of rat liver mitochondrial membrane as well as the influence of 4-ethylpyridine on this process were studied. It was shown that the MAO activity of the mitochondrial membrane fragments was highly sensitive to chlorgiline, when serotonin was used as substrate, whereas a high sensitivity toward deprenyl was observed with beta-phenylethylamine as substrate. 4-Ethylpyridine (5.10(-3) M), a competitive and reversible inhibitor of the MAO activity, inhibited deamination of serotonin and beta-phenylethylamine by 34 and 30%, respectively. In experiments with chlorgiline (the specific inhibitor of MAO type A) 4-ethylpyridine (5.10(-3) M) introduced into the samples after preincubation of mitochondria with increasing concentrations of chlorgiline (30 min, 23 degrees C) decreased the inhibition by chlorgiline of the deamination of beta-phenylethylamine, but sharply increased the inhibitory effect of chlorgiline on the oxidation of serotonin. In analogous experiments with deprenyl (the specific inhibitor of MAO type B) 4-ethylpyridine (5.10(-3) M) decreased the inhibitory effect of deprenyl not only on the deamination of serotonin (substrate of MAO A), but also on the oxidation of beta-phenylethylamine (the main substrate of MAO type B). The decrease in the inhibitory effect of deprenyl on the deamination of beta-phenylethylamine after the addition of 4-ethylpyridine may be intensified upon preincubation of deprenyl with mitochondria in the presence of 4-ethylpyridine. The data obtained demonstrate the difference in the type and mechanism of inhibition of the deamination of serotonin by chlorgiline as well as in the type and mechanism of oxidation of beta-phenylethylamine by deprenyl. The possible mechanism of selective blocking of MAO activity by chlorgiline and deprenyl was discussed in terms of our previous data on the existence in the active center of mitochondrial MAO of specific sites for substrate binding, differing in their structure-functional characteristics.     

The use of diaminobenzidine (DAB) for the histochemical demonstration of cytochrome oxidase activity in unfixed plant tissues

Summary Cytochrome oxidase activity was demonstrated in unfixed root segments from Lupinus albus at the ultrastructural level using the osmiophilic reagent 3,3-diaminobenzidine (DAB). Precipitate, the formation of which was completely inhibited by 0.01 M KCN, and observed almost entirely on mitochondrial cristae, is considered to be produced by cytochrome oxidase activity. Heterogeneity of mitochondria as to the intensity of the reaction in the same cell could not be established with certainity. However, mitochondria of the root tip cells and cells belonging to the plerome consistently did not show histochemically demonstrable cytochrome oxidase activity.     

Formation of the Neurotransmitter Glycine from the Anticonvulsant Milacemide Is Mediated by Brain Monoamine Oxidase B

Milacemide (2-n-pentylaminoacetamide) is a secondary monoamine that in the brain is converted to glycinamide and glycine. This oxidative reaction was suspected to involve the reaction of monoamine oxidase (MAO). Using mitochondrial preparations from tissues that contain MAO-A and -B (rat brain and liver), MAO-A (human placenta), and MAO-B (human platelet and bovine adrenal chromaffin cell), it has been established that mitochondria containing MAO-B rather than MAO-A oxidize (H2O2 production and glycinamide formation) milacemide. The apparent Km (30-90 microM) for milacemide oxidation by mitochondrial MAO-B preparations is significantly lower than that for milacemide oxidation by mitochondrial MAO-A (approximately 1,300 microM). In vitro MAO-B (l-deprenyl and AGN 1135) rather than MAO-A (clorgyline) selectively inhibited the oxidation of milacemide. These in vitro data are matched by ex vivo experiments where milacemide oxidation was compared to oxidation of serotonin (MAO-A) and beta-phenylethylamine (MAO-B) by brain mitochondria prepared from rats pretreated with clorgyline (0.5-10 mg/kg) and l-deprenyl (0.5-10 mg/kg). Furthermore, in vivo experiment demonstrated that l-deprenyl selectively increased the urinary excretion of [14C]milacemide and the total radioactivity with a concomitant decrease of [14C]glycinamide. Such changes were not observed after clorgyline treatment, but were evident only at doses beyond clorgyline selectivity. The present data therefore demonstrate that milacemide is a substrate for brain MAO-B, and its conversion to glycinamide, further transformed to the inhibitory neurotransmitter, glycine, mediated by this enzyme may contribute to its pharmacological activities.     

Extinction coefficient of polymerized diaminobenzidine complexed with cobalt as final reaction product of histochemical oxidase reactions

The extinction coefficient is essential for the conversion of cytophotometric (mean integrated) absorbance values into absolute units of enzyme activity, for instance expressed in terms of moles of substrate converted per unit time and per unit wet weight of tissue. The extinction coefficient of polymerized diaminobenzidine (polyDAB) complexed with cobalt as the final reaction product of oxidase reactions was estimated at 575 nm by comparison of the amounts of final reaction products formed after incubation of serial unfixed cryostat sections of rat kidney to demonstrate D-amino acid oxidase activity with either the tetrazolium salt method or the cerium-DAB-cobalt-hydrogen peroxide method. Both procedures resulted in similar localization patterns of final reaction product in a granular form in epithelial cells of proximal tubules in rat kidney. The granules were peroxisomes. Linear relationships were found for both methods between the specific amounts of final reaction product generated by D-amino acid oxidase activity and incubation time. The cerium salt method gave rise to 7.4 times higher absorbance values of final reaction product generated per unit time and per unit wet weight of tissue than the tetrazolium salt procedure. The extinction coefficient of tetranitro BT-formazan is 19 000 at 557 nm. Therefore, the cytophotometric extinction coefficient of the poly DAB-cobalt complex as final reaction product of oxidase reactions was established to be 140 000.     

The cytochemical localization of oxidative enzymes. II. Pyridine nucleotide-linked dehydrogenases

Methods are presented for the intramitochondrial localization of various diphosphopyridine nucleotide and triphosphopyridine nucleotide-linked dehydrogenases in tissue sections. The cytochemical reactions studied involve the oxidation of the substrates by a specific pyridino-protein. The electron transfer of tetrazolium salt is mediated by the diaphorase system associated with the dehydrogenase. The final electron acceptor was either p-nitrophenyl substituted ditetrazole (nitro-BT) or N-thiazol-2-yl monotetrazole (MTT), the latter giving rise to metal formazan in the presence of cobaltous ions. Mitochondrial localization of the formazan precipitate could be achieved by using hypertonic incubating media containing high concentrations of substrate and co-enzyme. A fast reduction of tetrazolium salt was obtained by chemically blocking the respiratory chain enzymes beyond the flavoproteins. Although diaphorase systems are implicated in the reduction of tetrazolium salts, specific dehydrogenases are solely responsible for the distinct distribution pattern obtained in tissues with various substrates. The present findings in tissue sections are discussed in conjunction with existing biochemical evidence from differential centrifugation experiments.     

A sedimentation procedure for the detection of binding to concanavalin A and heparin to lipoproteins.

Specific enzymatic bands in disc gel electrophoresis are generally determined by either of two methods: (i) Gel is sliced and the enzymatic activity is assayed on each slice or (ii) gel is stained histochemically, if the product of the enzymatic reaction and the dye can form an insoluble precipitate, and the activity band is located on the gel by a color band. The former is laborious and often inaccurate in the calculation of electrophoretic mobility. The latter, often nonspecific, is not applicable when the enzymatic product cannot form an insoluble precipitate with the dye. Staining with tetrazolium salt has been widely employed for amine oxidase (1–6). However, this method has limitations: (i) Tetrazolium salt is nonspecific for amine oxidase and may show artifacts (6,7), and (ii) the use of tetrazolium salt is limited only to substrates containing indolamine such as tryptamine or serotonin (8). Other substrates, like benzylamine, the most active substrate for plasma amine oxidase, do not form a color band with tetrazolium salt.This communication reports a simple spectrophotometric method for the identification of the enzymatic activity band for amine oxidase on disc gel electrophoresis. Neither slice and assay nor staining is needed. This method may possibly also be used generally for other enzyme systems which have a specific absorption at ultraviolet or visible range.     

The ultracytochemical demonstration of a formaldehyde-resistant dehydrogenase of leuco nitroxyl analogues.

A dehydrogenase which is relatively stable in formaldehyde fixative is demonstrated ultracytochemically by the reduction of various leuco nitroxyl analogues in rat hepatic, renal, myocardial, skeletal muscle and prostatic tubuloalveolar glandular tissues. The nonosmiophilic tetrazolium salt, t-(2'-benzothiazolyl)-5-styryl-3-(4'-phtalhydrazidyl) tetrazolium chloride, is subsequently reduced to an insoluble osmiophilic formazan by the hydrogen ions resulting from the dehydrogenase activity. Exposure of the formazan to osmium tetroxide results in electron density enabling visualization of the reaction product in the electron microscope. Known inhibitors of various dehydrogenases were utilized in an attempt to determine the existence and/or extent of any specific characteristics of the dehydrogenase(s) involved.     

Crystal structure of human monoamine oxidase B, a drug target enzyme monotopically inserted into the mitochondrial outer membrane

Monoamine oxidase B (MAO B) is an outer mitochondrial membrane protein that oxidizes arylalkylamine neurotransmitters and has been a valuable drug target for many neurological disorders. The 1.7 angstrom resolution structure of human MAO B shows the enzyme is dimeric with a C-terminal transmembrane helix protruding from each monomer and anchoring the protein to the membrane. This helix departs perpendicularly from the base of the structure in a different way with respect to other monotopic membrane proteins. Several apolar loops exposed on the protein surface are located in proximity of the C-terminal helix, providing additional membrane-binding interactions. One of these loops (residues 99-112) also functions in opening and closing the MAO B active site cavity, which suggests that the membrane may have a role in controlling substrate binding.     

The Cytochemical Localization of Oxidative Enzymes : II. Pyridine Nucleotide-Linked Dehydrogenases

Methods are presented for the intramitochondrial localization of various diphosphopyridine nucleotide and triphosphopyridine nucleotide-linked dehydrogenases in tissue sections. The cytochemical reactions studied involve the oxidation of the substrates by a specific pyridino-protein. The electron transfer of tetrazolium salt is mediated by the diaphorase system associated with the dehydrogenase. The final electron acceptor was either p-nitrophenyl substituted ditetrazole (nitro-BT) or N-thiazol-2-yl monotetrazole (MTT), the latter giving rise to metal formazan in the presence of cobaltous ions. Mitochondrial localization of the formazan precipitate could be achieved by using hypertonic incubating media containing high concentrations of substrate and co-enzyme. A fast reduction of tetrazolium salt was obtained by chemically blocking the respiratory chain enzymes beyond the flavoproteins. Although diaphorase systems are implicated in the reduction of tetrazolium salts, specific dehydrogenases are solely responsible for the distinct distribution pattern obtained in tissues with various substrates. The present findings in tissue sections are discussed in conjunction with existing biochemical evidence from differential centrifugation experiments.