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

Summary An improved histochemical technique for the demonstration of lactate dehydrogenase activities in tissue sections is described. With this technique a semipermeable membrane is interposed between the incubating solution and the tissue sections preventing diffusion of lactate dehydrogenase into the medium during incubation. In the histochemical system the NAD⁺-dependent enzyme catalyzes the electron transfer from lactate into NAD⁺. Phenazine methosulphate and menadione serve as intermediate electron acceptors between reduced coenzyme and nitro-BT. Amytal is incorporated into the incubating-medium to block electron transfer to the cytochromes. Problems involved in the histochemical demonstration of lactate dehydrogenase activity are discussed.This investigation was in part supported by a grant from the Netherlands Organization for the Advancement of Pure Research (ZWO).     

Histochemical technique for the demonstration of pyruvate kinase activity

We describe an enzyme histochemical multistep technique for the demonstration of pyruvate kinase activity. In this technique, a semipermeable membrane is interposed between the incubation medium and the tissue sections, thus preventing diffusion of the enzyme into the medium during the incubation period. In this histochemical system, phosphoenolpyruvate (PEP) donates its phosphate group to ADP in a reaction catalysed by pyruvate kinase. Next, exogenous and endogenous hexokinase catalyses the reaction between ATP and D-glucose to yield D-glucose-6-phosphate and ADP. The D-glucose-6-phosphate is oxidized by exogenous and endogenous D-glucose-6-phosphate dehydrogenase, and concomitantly, the generated electrons are transported via NADP+, phenazine methosulphate and menadione to nitro-BT, which is finally precipitated as formazan. Sodium azide and amytal are included to block electron transfer to cytochromes. The method proved to be of value for the qualitative demonstration of pyruvate kinase activity in tissue sections of kidneys, heart muscle and skeletal muscle. For quantitative studies and for investigating the activity of this enzyme in liver sections, the method cannot be recommended.     

Histochemical technique for the demonstration of phosphofructokinase activity in heart and skeletal muscles

A histochemical multi-step technique for the demonstration of phosphofructokinase activity in tissue sections is described. With this technique a semipermeable membrane is interposed between the incubating solution and the tissue sections preventing diffusion of the non-structurally bound enzyme into the medium during incubation. In the histochemical system the enzyme converts the substrate D-fructose-6-phosphate to D-fructose-1,6-diphosphate, which in turn is hydrolyzed by exogenous and endogenous fructose diphosphate aldolase to dihydroxyacetone phosphate and D-glyceral-dehyde-3-phosphate. The dihydroxyacetone phosphate is reversibly converted into D-glyceraldehyde-3-phosphate by exogenous and endogenous triosephosphate isomerase. Next the D-glyceraldehyde-3-phosphate is oxidized by exogenous and endogenous glyceraldehyde-3-phosphate dehydrogenase into 1,3-diphospho-D-glycerate. Concomitantly the electrons are transported via NAD+, phenazine methosulphate and menadione to nitro-BT. Sodium azide and amytal are incorporated to block electron transfer to the cytochromes.     

The histochemical demonstration of fructose diphosphate aldolase activity using a semipermeable membrane technique

Summary In this communication an enzyme histochemical multistep technique for the demonstration of class 1 fructose-1,6-diphosphate aldolase in heart and skeletal muscle sections is described. With this technique a semipermeable membrane is interposed between the incubating solution and the tissue sections preventing diffusion of the enzyme into the medium during incubation. In the histochemical system the enzyme cleaves the substrate D-fructose-1,6-diphosphate to dihydroxyacetone phosphate and D-glyceraldehyde-3-phosphate. The dihydroxyacetone phosphate is reversibly converted into D-glyceraldehyde-3-phosphate by exogenous and endogenous triose phosphate isomerase. Next the D-glyceraldehyde-3-phosphate is oxidized by exogenous and endogenous glyceraldehyde-3-phosphate dehydrogenase and the electrons are transported concomitantly via NAD⁺, phenazine methosulphate and menadione to nitro-BT. Sodium azide and amytal are incorporated to block electron transfer to the cytochromes.     

Semipermeable membranes for improving the histochemical demonstration of enzyme activities in tissue sections. V. Isocitrate: NADP+ oxidoreductase (decarboxylating) and malate: NADP+ oxidoreductase (decarboxylating).

Improved histochemical techniques for the demonstration of NADP+-specific isocitrate dehydrogenase and malate dehydrogenase 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 NADP+-dependent enzymes catalyze the electron transfer from threo-Ds-isocitrate or L-malate into NADP+. Phenazine methosulphate and menadione serve as intermediate electron acceptors between reduced coenzyme and nitro-BT. Sodium-azide and amytal are incorporated into the incubating-medium to block electron transfer to the cytochromes. For demonstrating enzyme activities in sections containing non-specific alkaline phosphatase, a phosphatase inhibitor is added into the incubation media. Problems involved in the histochemical demonstration of both enzymes are discussed.     

Histochemical technique for the demonstration of pyruvate kinase activity

Summary We describe an enzyme histochemical multistep technique for the demonstration of pyruvate kinase activity. In this technique, a semipermeable membrane is interposed between the incubation medium and the tissue sections, thus preventing diffusion of the enzyme into the medium during the incubation period. In this histochemical system, phosphoenolpyruvate (PEP) donates its phosphate group to ADP in a reaction catalysed by pyruvate kinase. Next, exogenous and endogenous hexokinase catalyses the reaction between ATP andd-glucose to yieldd-glucose-6-phosphate and ADP. Thed-glucose-6-phosphate is oxidized by exogenous and endogenousd-glucose-6-phosphate dehydrogenase, and concomitantly, the generated electrons are transported via NADP⁺, phenazine methosulphate and menadione to nitro-BT, which is finally precipitated as formazan. Schurin azide and amytal are included to block electron transfei to cytochromes. The method proved to be of value for the qualitative demonstration of pyruvate kinase activity in tissue sections of kidneys, heart muscle and skeletal arusele. For quantitative studies and for investigating the activity of this enzyme in liver sections, the method cannot be recommended.Dedicafed to Professor Dr. T.H. Schicbler on the occasion of his 65th birthday     

Histochemical technique for the demonstration of phosphofructokinase activity in heart and skeletal muscles

Summary A histochemical multi-step technique for the demonstration of phosphofructokinase activity in tissue sections is described. With this technique a semipermeable membrane is interposed between the incubating solution and the tissue sections preventing diffusion of the non-structurally bound enzyme into the medium during incubation. In the histochemical system the enzyme converts the substrate d-fructose-6-phosphate to d-fructose-1,6-diphosphate, which in turn is hydrolyzed by exogenous and endogenous fructose diphosphate aldolase to dihydroxyacetone phosphate and d-glyceraldehyde-3-phosphate. The dihydroxyacetone phosphate is reversibly converted into d-glyceraldehyde-3-phosphate by exogenous and endogenous triosephosphate isomerase. Next the d-glyceraldehyde-3-phosphate is oxidized by exogenous and endogenous glyceraldehyde-3-phosphate dehydrogenase into 1,3-diphospho-d-glycerate. Concomitantly the electrons are transported via NAD⁺, phenazine methosulphate and menadione to nitro-BT. Sodium azide and amytal are incorporated to block electron transfer to the cytochromes.     

Combined histochemical and biochemical investigation to the reliability of the demonstration of arylsulphatase activity in cryostat sections

Summary The reliability of the enzyme histochemical technique, for the demonstration of arylsulphatase activity, using 6-bromo-2-naphthylsulphate as a substrate, is biochemically tested by using partly purified lysosome and microsome preparations from fresh human placenta tissue. Microsomes from frozen placenta with an arylsulphatase deficiency and lysosomes from rat liver, are also investigated. For the biochemical test methods, 6-bromo-2-naphthylsulphate and p-nitrocatecholsulphate are used as substrates. Under similar reaction conditions, varying the pH of the incubation medium and adding inhibitors or activators, the histochemical and biochemical reactions are compared. The results of this study whow that the enzyme histochemical technique — except for some limitations — is suitable for the demonstration of microsomal arylsulphatase in cryostat sections.     

Enzyme histochemistry on freeze-substituted glycol methacrylate-embedded tissue

We developed a method for histochemical demonstration of a wide range of enzymes in freeze-substituted glycol methacrylate-embedded tissue. Tissue specimens were freeze-substituted in acetone and then embedded at low temperature in glycol methacrylate resin. All enzymes studied (oxidoreductases, hydrolases) were readily demonstrated. The enzymes displayed high activity and were accurately localized without diffusion when tissue sections were incubated in aqueous media, addition of colloid stabilizers to the incubating media not being required. Freeze-substitution combined with low-temperature glycol methacrylate embedding permits the demonstration of a wide range of enzymes with accurate enzyme localization, maintenance of enzyme activity, and excellent tissue morphology.     

Evaluation of histochemical observations of activity of acid hydrolases obtained with semipermeable membrane techniques. 3. The substrate specificity of isoenzymes of acid phosphatase in m.gastrocnemius of rabbits.

Three distinct isoenzymes of acid phosphatase have been separated from extracts of m.gastrocnemius of normal and of vitamin E deficient rabbits by gel filtration and polyacrylamide gel electrophoresis. These isoenzymes, termed I, II and III, have molecular weights of: 110,000--130,000, 60,000--78,000 and 12,500--14,500. Isoenzymes I and II split the substrates 4-methylumbelliferyl phosphate and naphthol AS-BI phosphate and the activity is strongly increased in the muscles of vitamin E deficient rabbits. Isoenzyme III splits only 4-methylumbelliferyl phosphate and the activity is not increased in the muscles of vitamin E deficient rabbits. The pH-optimum for isoenzymes I and II is 4.8 and for isoenzyme III 5.5. It has been shown that the histochemical semipermeable membrane technique, using substrate naphthol AS-BI phosphate, is a very reliable technique for demonstrating activity of the isoenzymes I and II in tissue sections. On the other hand, activity of isoenzyme III cannot be demonstrated with this histochemical technique. In pathologically altered muscles, the activity of the isoenzymes I and II is greatly increased whilst the activity of isoenzyme III is not significantly altered.     

Semipermeable membranes for improving the histochemical demonstration of enzyme activities in tissue sections. VI. D-glucose 6-phosphate isomerase and phosphoglucomutase.

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 alpha-D-glucose 1-phosphate to the same reagent, which in turn is oxidized, by exogenous and endogenous glucose 6-phosphate dehydrogenase to D-glucono-delta-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.     

Combined histochemical and biochemical investigation to the reliability of the demonstration of arylsulphatase activity in cryostat sections.

The reliability of the enzyme histochemical technique, for the demonstration of arylsulphatase activity, using 6-bromo-2-naphthylsulphate as a substrate, is biochemically tested by using partly purified lysosome and microsome preparations from fresh human placenta tissue. Microsomes from frozen placenta with an arylsulphatase deficiency and lysosomes from rat liver, are also investigated. For the biochemical test methods, 6-bromo-2-naphthylsulphate and p-nitrocatecholsulphate are used as substrates. Under similar reaction conditions, varying the pH of the incubation medium and adding inhibitors or activators, the histochemical and biochemical reactions are compared. The results of this study show that the enzyme histochemical technique--except for some limitations--is suitable for the demonstration of microsomal arylsulphatase in cryostat sections.     

Enzyme histochemistry on freeze-dried, resin-embedded tissue

We have developed a method for histochemical demonstration of a wide range of enzymes in freeze-dried, resin-embedded tissue. Freeze-dried tissue specimens were embedded without fixation at low temperature (4 degrees C or -20 degrees C) in glycol methacrylate resin or LR Gold resin. Enzyme activity was optimally preserved by embedding the freeze-dried tissue in glycol methacrylate resin. All enzymes studied (oxidoreductases, esterases, peptidases, and phosphatases), except for glucose-6-phosphatase, were readily demonstrated. The enzymes displayed high activity and were accurately localized without diffusion when tissue sections were incubated in aqueous media, addition of colloid stabilizers to the incubating media not being required. Freeze-drying combined with low-temperature resin embedding permits the demonstration of a wide range of enzymes with accurate enzyme localization, high enzyme activity, and excellent tissue morphology.     

Dehydrogenase enzyme histochemistry on freezedried or fixed resin-embedded tissue

Summary A method has been developed for the histochemical demonstration of a variety of dehydrogenases in freeze-dried or fixed resin-embedded tissue. Seven dehydrogenases were studied. Lactate dehydrogenase, NADH dehydrogenase and NADPH tetrazolium reductase were all demonstrable in sections of paraformaldehyde-fixed resin-embedded tissue. Freeze-dried specimens were embedded, without fixation, in glycol methacrylate resin or LR Gold resin at either 4°C or –20°C. All the dehydrogenases except succinate dehydrogenase retained their activity in freeze-dried, resin-embedded tissue. Enzyme activity was maximally preserved by embedding the freeze-dried tissue specimens in glycol methacrylate resin at –20°C. The dehydrogenases were accurately localized without any diffusion when the tissue sections were incubated in aqueous media. Addition of a colloid stabilizer to the incubating medium was not required. Freeze-drying combined with low-temperature resin embedding permits accurate enzyme localization without diffusion, maintenance of enzyme activity and excellent tissue morphology.     

Nature of human spleen red pulp cells with special reference to sinus lining cells

Summary A histological and cytological as well as enzyme histo- and cytochemical analysis (alpha-naphthyl acetate esterases, naphthol AS acetate esterases, naphthol AS-D chloroacetate esterases, acid and alkaline phosphatases) of human spleen cells in sections and imprints was carried out with special reference to sinus lining cells. These cells show strong naphthol AS esterase activity and no or only little alpha-naphthyl acetate esterase and acid phosphatase activity. Thus they can be distinguished from reticular cells in pulp cords and from other macrophages in cords and sinuses. From the morphological and enzyme histochemical aspect it can be deduced that the sinus lining cells are a distinct cell type of the human spleen. The comparison of these enzyme cytochemical findings with the results of biochemical and electron microscopical investigations suggests that reticular cells of pulp cords and littoral cells of sinuses also have different functions: reticular cells seem to have a high phagocytotic activity while littoral cells seem to be only facultatively phagocytic.This work was supported by the Deutsche Forschungsgemeinschaft.     

Histochemical demonstration of glycogen phosphorylase (E.C. 2.4.11) through the use of semipermeable membranes (author's transl)]

A method is described for the histochemical demonstration of phosphorylase in unfixed cryostat sections of rat liver using semipermeable membranes and a gel medium. In comparison to the conventional methods this procedure has the following advantages: 1. Staining of sections through a semipermeable membrane prevents diffusion of cellular glycogen and guarantees optimal localisation of phosphorylase activity. 2. Since diffusion is effectively prevented by the membrane the total activity of this highly soluble enzyme can be demonstrated. 3. Tissue and cell structures are well preserved.     

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

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

Cytofluorometric quantification of the activity and reaction kinetics of acid phosphatase

Synopsis This paper describes how fluorogenic substrates derived from naphthol AS can be used for the microscopic demonstration and cytofluorometric quantification of the activity and reaction kinetics of acid phosphatase in single living cells.A special study has been made of acid naphthol AS-BI phosphatase. However, the method can be extended to other hydrolytic enzymes. The method is sensitive and accurate because: quantification of very low enzyme activity is possible; the reaction kinetics can be evaluated with a good degree of precision inasmuch as the initial reaction velocity is derived over short times; there is an absence of distributional error; and the errors due to extra-cellular diffusion of the hydrolysed substrate, to photo-decomposition, and to autofluorescence can be contained within very narrow limits.The procedures for determining enzyme activity and reaction kinetics, and the instrumental characteristics and devices required for carrying out these measurements, are described. Some possible applications are indicated.     

Simultaneous demonstration of bone alkaline and acid phosphatase activities in plastic-embedded sections and differential inhibition of the activities

Bone alkaline (AlP) and acid phosphatase (AcP) activities were simultaneously demonstrated in tissue sections obtained from mice, rats, and humans. The method involved tissue fixation in ethanol, embedding in glycol methacrylate (GMA), and demonstration of AlP and AcP activities employing a simultaneous coupling azo dye technique using substituted naphthol phosphate as a substrate. AlP activity was demonstrated first followed by AcP activity. Both enzyme activities were demonstrated in tissue sections from bones fixed and/or stored in acetone or 70% ethanol for up to 14 days or stored in GMA for 2 months. AlP activity in tissue sections from bones fixed in 10% formalin, 2% glutaraldehyde, or formal-calcium, however, was markedly inhibited after 3-7 days and was no longer detectable after 14 days of fixation. Moreover, AlP activity was diminished in tissue sections from bones fixed in 70% ethanol or 10% formalin and subsequently demineralized in 10% EDTA (pH 7) for 2 days, and the activity was completely abolished in tissue sections from bones subsequently demineralized in 5% formic acid: 20% sodium citrate (1:1, pH 4.2) for 2 days. Methyl methacrylate (MMA) embedding at concentrations above 66% completely inhibited AlP activity. AcP activity, however, was only partially inhibited by formalin, glutaraldehyde, or formal-calcium after 7 or 14 days of fixation or by MMA embedding and was unaffected by the demineralizing agent formic acid-citrate for 2 days. While AcP activity was preserved in bones fixed in formalin and subsequently demineralized in EDTA, the activity was completely abolished when EDTA demineralization was carried out on bones previously fixed in 70% ethanol.(ABSTRACT TRUNCATED AT 250 WORDS)     

Demonstration of tartrate-resistant acid phosphatase in un-decalcified, glycolmethacrylate-embedded mouse bone: a possible marker for (pre)osteoclast identification

Fixed, undecalcified mouse long bones were embedded in glycol methacrylate (GMA), sectioned, and incubated for acid phosphatase in the presence or absence of tartrate, to investigate the feasibility of tartrate-resistant acid phosphatase as a histochemical marker for osteoclast identification. Naphthol AS-BI phosphate was used as the substrate and hexazonium pararosanaline as coupler. Cytocentrifuge preparations of mouse, rat, and quail bone marrow or frozen and GMA sections of mouse splenic tissue were used as controls to specify acid phosphatase activity. After adequate fixation, acid phosphatase activity sensitive to tartrate inhibition (TS-AP) was demonstrated in macrophages from spleen, bone marrow, and loose connective tissue surrounding bone rudiments. Acid phosphatase activity resistant to tartrate inhibition (TR-AP), was detected in multi-nuclear osteoclasts and in some mononuclear cells from bone marrow and periosteum. In cytocentrifuge preparations and frozen sections of mouse spleen, TR-AP was demonstrated after simultaneous incubation with substrate and tartrate. In GMA sections, however, TR-AP could only be demonstrated after pre-incubation with tartrate before application of substrate. We suggest that histochemical demonstration of TR-AP versus TS-AP on GMA-embedded bone sections by means of a pre-incubation method can be used as an identification marker of (pre)osteoclasts. Plastic embedding is recommended for its excellent preservation of morphology and enzyme activity.