Z. Lojda

Studies on dipeptidyl(amino)peptidase IV (glycyl-proline naphthylamidase)

SummaryThe activity of dipeptidyl(amino)peptidase IV (DAP IV, glycylproline naphthylamidase) was discovered in the endothelial cells of the venous part of capillary bed and of small venules of many organs of the rat, mini-pig, rabbit, cock as well as man. In aortae, large arteries and veins only a portion of vase vasorum displays a positive reaction. Glycyl-proline-4-methoxy-2-naphthylamide (Gly-Pro-MNA) is the substrate of choice both from the viewpoint of enzyme kinetics as well as localization. Phenylalanyl-proline-4-methoxy-2-naphthylamide (Phe-Pro-MNA) is cleaved less easily, however, it enables a good localization. 1- and 2-naphthylamine derivatives of glycylproline display better kinetic properties than Phe-Pro-MNA, however they enable a satisfactory localization under special conditions only.The recommended diazonium salt for the routine is Fast Blue B. The enzyme is quite firmly associated with the structure and chloroform-acetone preextraction of cryostat sections does not influence its activity significantly while improving the localization. Block fixation in aldehydes inhibits the enzyme activity (glutaraldehyde more than formaldehyde). The osmificated azo-dye originated of 4-methoxy-2-naphthylamine and Fast Blue B or hexazonium-p-rosaniline is still partially soluble in solvents used for the usual embedding in epoxyresins for electron microscopical examination. This is a drawback for a reliable demonstration of DAP IV in endothelial cells on the electronmicroscopical level using the epoxy-resin technique. DAP IV of the endothelium is inhibited totally by DFP (10−3M), partially by E 600 (10−3); and slightly by phenanthroline (10−3M). It is unaffected by EDTA (10−3M) and N-ethyl maleimide (10−3M).The combined demonstration of alkaline phosphatase and DAP IV in the same section renders a reliable demonstration of the capillary bed in many organs.The contribution of DAP IV activity of the capillary endothelium to the total DAP IV activity in a particular organ is decisive in the myocardium, striated muscle, aorta and lung; it represents about one half of the total activity in spleen and pancreas and is less expressed in the liver, intestine and particularly in the kidney.In the jejunum of patients sufferring coeliac sprue the activity of capillary endothelium in the propria is decreased or not demonstrable in the acute stage. After a gluten-free diet it is restituted. The activity of DAP IV does not change significantly in aortae of the rabbit and man with atherosclerosis. In plaques of human aortae the capillary endothelium reacts at the most. Vasa vasorum in the adventitia overlying large plaques, which penetrate into the media, display a high DAP IV activity and their number can be increased. In plaques of arteries of cocks there is a positive DAP IV reaction in foam cells. DAP IV does not belong to the enzymes indicating early changes in atherogenesis.The function of DAP IV in the endothelium is not known. It may be a part of the machinery influeneing the protein part of the endothelial coat or may participate in the degradation of some vasoactive peptides.

Phosphates of the naphthol AS series in the quantitative determination of alkaline and acid phosphatase activities “in situ” studied in polyacrylamide membrane model systems and by cytospectrophotometry

SummaryHistochemical media for the demonstration of alkaline and acid phosphatases using phosphates of naphthol AS series as the substrates and various diazonium salts as the couplers were tested in the capability of reflecting various levels of enzyme activities.Polyacrylamide membranes with incorporated enzymes (various concentrations of purified enzymes as well as of sonicated leucocytes, macrophages and of sonicated homogenates of various organs) were used as model systems in which the activity was estimated both with biochemical and with histochemical methods. Parallel experiments were performed in sedimentation chamber preparations of guinea-pig leucocytes and macrophages in which the activity was demonstrated with the same media as in polyacrylamide films. The quantitative measurements were performed in a cytospectrophotometer using the two-wavelength method.Increasing the substrate concentration which in “standard” histochemical media has been 1/8 mg per ml more azo-dye is produced in the reactions for both phosphatases. If the substrate concentration is higher than 1/2 mg per ml the “standard” concentration of the diazonium salt (1 mg per ml) becomes insufficient for an effective capturing of the released naphthol AS in the reaction for alkaline phosphatase. Due to a very high inhibitoty effect in the case of most commercially available diazonium salts the increase of their concentration annules the beneficial action of an increased substrate concentration on the azo-dye production. 4-amino-diphenylamine diazonium sulfate has an exceptional position because it was not inhibitory even in the concentration of 4 mg/ml.In the case of acid phosphatase the higher substrate concentration was incompatible with the use of Past Red Violet LB. Hexazo-p-rosanilin was an efficient and the most chromogenic coupler used in simultaneous as well as in postincubation coupling. With the latter localization is possible on the cellular (not subcellular) level.More chromogenic combinations are generally better for the cytospectrophotometrical measurement. The shape of extinction curves of azo-dyes produced with combinations studied was similar in models and in smears. In many combinations it was dependent on the presence of lipoproteins. A too steep decline of some curves prevented the use of some combinations in alkaline phosphatase determination with the two-wavelength method, even if they are very good in the qualitative studies and might be suitable for scanning cytospectrophotometry. p]The shape of extinction curves of azo-dyes produced in the reaction for acid phosphatase using hexazo-p-rosanilin as the coupling agent was independent of the presence of lipoproteins.The curves of azo-dyes produced in simultaneous coupling are not exactly the same as the curves obtained by postincubation coupling.

Study on dipeptidylpeptidase II (DPP II)

SummaryThe activity of dipeptidylpeptidase II (DPP II; E.C. 3.4.14.2) was investigated by biochemical and histochemical methods in rat, mouse and guinea-pig organs as well as in human enterobiopsies. Lys-Pro-MNA and Ala-Pro-MNA showed the most favorable kinetic properties (Km, Vmax) and proved to be the most sensitive substrates for biochemical and histochemical studies of DPP II. Lys-Ala-MNA is more specific and is to be preferred due to its relatively low hydrolysis by DPP IV. Lys-Ala-2NA is suitable for the biochemical determination of DPP II activity. Lys-Ala-1NA, Leu-Ala-2NA, Phe-Pro-2NA and Phe-Pro-MNA are inferior. The pH optimum of DPP II amounts to 5.5. Cacodylate, phosphate, citric acid phosphate and succinate buffers deliver similar hydrolysis rates; with citrate and acetate buffers the recorded activities are lower. The reaction can be inhibited by 1 mM DFP, 50 mM Tris and 10 mM puromycin. In the ileum of suckling rats and in human enterobiopsies similar data (Km, pH optimum, optimal substrate concentration) were obtained by biochemical determination and by quantitative histochemistry (microdensitometry) with Lys-Ala-MNA. For the histochemical demonstration of DPP II freeze-dried celloidin-coated cryostat sections are very suitable. Frozen sections of formaldehyde and glutaraldehyde fixed tissue blocks are inferior due to a higher inhibition of DPP II and less precise localization of the azo-dye. Km values and optimal pH are identical in fresh and fixed material. Fast Blue B is the best coupling agent for light microscopical localization. DPP II is present in all organs and tissues investigated. Conspicious organ and species differences exist. In adult rats the highest DPP II activity resides in the kidney, epididymis and spleen; in guinea-pigs the epididymis and testis are the most active organs. In the majority of guinea-pig organs the DPP II activity is lower than in rats. The histochemical demonstration of DPP II shows, in addition, cell-dependent differences of DPP II activity. In most cells the enzyme activity is depicted in lysosomes. Highly active are lysosomes of cells of proximal renal tubules, macrophages, thyroid cells, clear and principal cells of the epididymis of adult animals and of enterocytes of suckling rats. Lysosomes of endocrine cells of adenohypophysis, pancreaas, stomach, small intestine and nerve cells display moderate activity. In lysosomes of smooth muscle cells (intestine, myometrium), myocardial cells, and fibers of striated muscle the enzyme is also present. Spermatids and sperms of guinea-pigs are highly active. In some cases secretion granules of endocrine and exocrine gland cells display a positive reaction. Possibly the Golgi apparatus and the endoplasmic reticulum also show a positive staining in the principle cells of the rat and mouse epididymis. Furthermore, DPP II seems to be secreted into the lumen of several organs.

A histochemical method for the demonstration of acetylcholinesterase activity using semipermeable membranes

SummaryThe “direct coloring” thiocholine method of Karnovsky and Roots (1964) for the demonstration of acetylcholinesterase (AChE) activity was modified and adapted to the technique of semipermeable membranes. In this way it is possible to demonstrate histochemically both the bound as well as the soluble part of AChE activity. The localization of the reaction product is very distinct. Microdensitometric investigations of results of this method showed a linear increase of the amount of reaction product up to an incubation time of 180 min and section thickness up to 24 μm. The medium supplemented with buffer (instead of agar) can be used for the demonstration of AChE activity in cryostat sections adherent to slides and is also very suitable for the defection of multiple forms of AChE in polyacrylamide or agarose gels.

The use of hexazonium-p-rosanilin in the histochemical demonstration of peptidases.

SummaryThe suitability of hexazonium-p-rosanilin (HP) in the histochemical demonstration of peptidases was investigated. The detection was carried out in cold microtome sections adherent to slides or semipermeable membranes. Alanyl-1-naphthylamide, alanyl-2-naphthylamide, leucyl-2-naphthylamide, leucyl-4-methoxy-2-naphthylamide (all substrates in concentration of 0.4 mg/1 ml of citrate phosphate buffer pH 6.5), γ-L-glutamyl-1-naphthylamide, γ-L-glutamyl-2-naphthylamide (both substances in concentration of 0.24 mg/1 ml of acetate buffer pH 6.5) were used as the substrates. Results were compared with those obtained with Fast Blue B and Fast Garnet GBC.In comparison with Fast Blue B and Fast Garnet GBC HP is a faster coupler, furnishes azodyes which are stable, amorphous (even without lipid extractions from sections), more substantive and in the case of 1-naphthylamine almost insoluble in ordinary lipid solvents used for the dehydration and clearing of sections before mounting. The molecular extinction coefficient of azodyes furnished by HP is 1.5x higher for 1-naphthylamine than for 2-naphthylamine. It is higher than that of Fast Garnet GBC, however, lower than that of Fast Blue B. The inhibitory influence of individual diazonium salts on enzyme activity (activities) splitting leucyl-2-naphthylamide amounts to 36% (Fast Garnet GBC), 37% (Fast Blue B), 52% (HP, 0.03 ml/1 ml) and 63% (HP, 0.09 ml/1 ml) at pH 6.5. For γ-glutamyl-transpeptidase the corresponding values are 50%, 59%, 62% and 67%. The higher inhibitory influence of HP is compensated by the possibility of its using in the technic of semipermeable membranes.HP improves greatly the localization of peptidases in cold microtome sections from which lipids were not extracted. The best results are furnished by 1-naphthylamine dervatives. In the case of 4-methoxy-2-naphthylamine derivatives the localization is very sharp, however, the azodye is less distinct than that of 2-naphthylamine.The localization as obtained with HP in combination with substrates derived of simple naphthylamines is similar or even better than with 4-methoxy-2-naphthylamine derivatives applied with Fast Blue B. Typical examples are shown.

Histochemical study of alkali-burned rabbit anterior eye segment in which severe lesions were prevented by aprotinin treatment.

SummaryActivities of different enzymes (acid glycosidases, phosphatases, Na+−K+-dependent ATPase, proteases, dehydrogenases) and acid glycosaminoglycans were studied by histochemical methods in sections of rabbit anterior eye segments after experimental alkali burn and treatment with aprotinin, an inhibitor of plasmin and other serine proteinases. Solutions of sodium hydroxide (0.25–1.0M) were applied on corneas using 12-mm-diameter plastic tube for 15–60 s. After wiping with cotton and rinsing with tap water, aprotinin solutions were applied in saline (in experimental animals) and saline (in control animals) dropwise in 12-h intervals for a month. Within the first two weeks aprotinin was used at a concentration of 5000 IU/ml. During the subsequent two weeks the aprotinin concentration was reduced to 2500 IU/ml.Striking differences in enzyme activities and in the healing between treated and untreated eyes were found. Without aprotinin, ulcers developed in most corneas within 3 weeks and plasmin was regularly demonstrated in tears and in the aqueous. When aprotinin treatment was started within 24 h after the burn, the number of enzymatically active inflammatory cells was significantly lower, not only in the cornea itself but also in the whole anterior eye segment. With aprotinin treatment no ulcerations and no plasmin in tears and the aqueous were observed and the corneas healed within a month. The healing process started from the zone of enzymatically activated corneal cells in the unburned zone at the corneal periphery. In the regenerating epithelium and endothelium high activities of Na+−K+-dependent ATPase, γ-glutamyltransferase, lactate and succinate dehydrogenases appeared very soon. Keratocytes displayed high activities of all enzymes studied. The restoration of corneal transparency depended on concentration of alkali used and parallelled the regeneration of the stroma and normalization of corneal hydration. Our results demonstrate that aprotinin is a potent therapeutic agent in the treatment of experimentally induced corneal ulcers, presumably due to its inhibitory action on plasmin and other serine proteases present in the alkali-burned anterior eye segment.

The histochemical demonstration of aminopeptidase with bromoindolyl leucinamide

SummaryThe indigogenic method for aminopeptidase of Pearson et al. (1963) was critically evaluated. The localization obtained with it is not correct due to diffusion artifacts. Ferricyanide cannot be used as an oxidation agent. Based on experiments with other oxidation agents (phenazonium methosulfate, nitro BT, tetranitro BT) a new method was devised.The recommended incubation medium contains 0.9 mM L-N-(5-bromoindol-3-yl) leucinamide hydrobromide (chloride), 0.73 mM tetranitro BT, 0.27 mM phenazonium methosulfate and 0.67 M phosphate buffer pH 7.4. The enzyme activity is indicated by the deposition of tetranitro BT formazan.Results with this method in rat kidney, jejunum, liver, lung, and submaxillary gland, in monkey kidney and jejunum, and in human jejunal biosies are almost identical with those obtained with L-leucyl-4-methoxy-β-naphthylamide applied in a simultaneous azocoupling procedure. The given principle of the demonstration of aminopeptidase activity with an indolylamine substrate deserves a further exploration in the demonstration of peptidases “in situ” both on optical as well as electronmicroscopical levels.

Aminopeptidases in the circumventricular organs of the mouse brain: A histochemical study

The localization of four membrane-bound aminopeptidases--aminopeptidase A, aminopeptidase M, dipeptidylpeptidase IV, and gamma-glutamyl transpeptidase--known as characteristic enzymes of the blood-brain barrier was studied in the microvasculature of some circumventricular organs of the mouse brain (subfornical organ, area postrema, choroid plexus, and neurohypophysis). Enzyme activities were demonstrated histochemically in chloroform-acetone-pretreated cryostat sections applying an azo-coupling method. Reactions were evaluated using light microscopy and end-point microdensitometry. The results revealed differences in microvascular enzyme pattern between circumventricular organs and regions having a blood-brain barrier. Moreover, the cytochemical picture of the circumventricular organs themselves was not uniform. Dipeptidylpeptidase IV reaction showed a strongly reduced activity in the microvessels of all studied circumventricular organs. On the other hand, aminopeptidase M seemed to be present in both the leaky and the tight capillaries. Only a low activity of aminopeptidase A was found in parts of the choroid endothelium and the subfornical organ microvasculature. gamma-Glutamyl transpeptidase could neither be detected in the capillary part of the choroid plexus nor in the neurohypophysis. We are led to conclude that at least dipeptidylpeptidase IV might be involved in special mechanisms of the blood-brain barrier.

The usefulness of the analytical electrofocusing in a thin-layer polyacrylamide gel (PAG) in the histochemistry of enzymes cleaving peptide bonds.

SummaryThe usefulness of the analytical electrofocusing in a thin-layer polyacrylamide (PAG) plate is shown on the basis of experiments with 10%–20% homogenates of various rat, rabbit and human organs as well as in lysates of isolated human lymphocytes and leucocytes in 2% Triton X100. 0.1–0.3 μl of 12000 g supernatants were applied on LKB Ampholine PAG plates pH range 3.5–9.5 and subjected to electrofocusing. Afterwards portions of PAG plates were processed in optimized histochemical media for the demonstration of enzymes cleaving peptide bonds using various substrates. The same media were used in the histochemical detection of enzymes in sections on slides or semipermeable membranes. Electrofocused zymograms display species and organ differences. Ala-MNA, Leu-MNA and Met-MNA furnish similar zymograms. Bands obtained with Ala-MNA are most intense. Zymograms with Gly-Pro-MNA and Lys-Pro-MNA at pH 7.2 are not entirely identical. The majority of bands is more intense when Gly-Pro-MNA is used as the substrate and is due to the activity of DAP IV. The anodal band(s) focusing around pH 4.9 (rat) or 5.5 (man) is (are) much stronger with Lys-Pro-MNA and DAP II is responsible for it (them). Zymograms with His-Ser-MNA and Lys-Ser-MNA are similar. However, they differ form those revealed with Gly-Pro-MNA and Lys-Pro-MNA. Zymograms of lysates of leucocytes obtained with naphthol AS-D-chloroacetate and Ac-Ala-l-naphthyl ester are not identical showing that more than one enzyme is responsible for the bands. Results obtained with closely related substrates such as Ac-Ala-l-naphthyl ester and Ac-Met-l-naphtyl ester are not identical either. Zymograms of lysates of human lymphocytes revealed with Gly-Pro-MNA at pH 7.2 and Lys-Ala-MNA or Lys-Pro-MNA at pH 5.5 or 5.3 respectively show clearly the presence of DAP IV and DAP II in these cells. The analytical electrofocusing in PAG plates is a very useful tool in the histochemistry (and biochemistry) of enzymes cleaving peptide bonds. It helps very much in the evaluation of the substrate specificity, choosing of the discriminating substrate and enables a quick and reliable testing of the quality of various batches of commercially supplied substrates, diazonium salts and other reagents. The correlation of zymograms with the “in situ” pattern helps in the elucidation of the origin of individual bands in zymograms and suggests different molecular forms of peptidases in different localizations.

Histochemistry of some acid hydrolases in striated muscles of the rat.

SummaryThe distribution of acid phosphatase, β-n-acetylglucosaminidase, β-glucuronidase, and acid β-galactosidase was studied in mm. extensor digitorum longus, soleus, and diaphragm of rats. Using the technic of semipermeable membranes activities of these enzymes were demonstrated beside cells of the interstitial tissue in muscle fibers themselves as well. Acid phosphatase displayed the highest activity which appeared in many small dots dispersed in the fiber. The activity of acid phosphatase was about 1.2 x higher in the m. soleus than in the m. extensor digitorum longus. In the latter muscle a somewhat higher activity was often found in muscle fibers displaying a higher staining for NADH tetrazolium reductase. The activity of β-n-acetylglucosaminidase was slightly lower, that of β-glucuronidase very weak but still discernible. The activity of acid β-galactosidase was not ascertained in the majority of fibers. The ratio of activities measured in an area of the same size in cells of the interstitial tissue and in muscle fibers amounted in average to 2.6: 1 in the case of acid phosphatase, 2.5:1 in the case of β-n-acetylglucosaminidase, 5.7: 1 in the case of β-glucuronidase, and 44.3:1 in the case of acid β-galactosidase. The importance of the histochemical technic in studies concerned with acid hydrolases in striated muscle fibers in normal and pathological conditions is pointed out.