Wilma M. Frederiks

Metabolic mapping of proteinase activity with emphasis on in situ zymography of gelatinases: review and protocols

Proteases are essential for protein catabolism, regulation of a wide range of biological processes, and in the pathogenesis of many diseases. Several techniques are available to localize activity of proteases in tissue sections or cell preparations. For localization of the activity of matrix metalloproteinases, in situ zymography was introduced some decades ago. The procedure is based on zymography using SDS polyacrylamide gels containing gelatin, casein, or fibrin as substrate. For in situ zymography, either a photographic emulsion containing gelatin or a fluorescence-labeled proteinaceous macromolecular substrate is brought into contact with a tissue section or cell preparation. After incubation, enzymatic activity is revealed as white spots in a dark background or as black spots in a fluorescent background. However, this approach does not allow precise localization of proteinase activity because of limited sensitivity. A major improvement in sensitivity was achieved with the introduction of dye-quenched (DQ-)gelatin, which is gelatin that is heavily labeled with FITC molecules so that its fluorescence is quenched. After cleavage of DQ-gelatin by gelatinolytic activity, fluorescent peptides are produced that are visible against a weakly fluorescent background. The incubation with DQ-gelatin can be combined with simultaneous immunohistochemical detection of a protein on the same section. To draw valid conclusions from the findings with in situ zymography, specific inhibitors need to be used and the technique has to be combined with immunohistochemistry and zymography. In that case, in situ zymography provides data that extend our understanding of the role of specific proteinases in various physiological and pathological conditions. (J Histochem Cytochem 52:711–722, 2004)

The value of enzyme leakage for the prediction of necrosis in liver ischemia.

SummaryFollowing the clamping of the afferent vessels of the left lateral and median lobes in rat liver, a considerable part of these lobes show signs of necrosis 24 h after 90 min of ischemia, wheras no necrotic areas can be detected after 30 min interruption of the blood flow. The purpose of this study was to examine the value of an analysis of the leakage of enzymes from the liver parenchyma in the early phase after restoration of the blood flow after ichemia for a prediction of the occurrence of necrosis. Leakage of the enzymes GPT, GOT and LDH can be detected in the blood plasma with a maximum activity between 1 and 5 h both following 30 and 90 min of ischemia; a considerable difference in clearance is observed, however, in the period afterwards, the normal situation being reached after 24 h with the 30-min ischemic period, but not following the 90-min period. With use of an enzyme histochemical reaction, in situ a depletion of LDH-activity in the hepatocytes could be detected within a short period of time after 30 min temporary ischemia and a restoration during the following period of 24 h; the decrease in LDH-activity persisted during 24 h with a 90-min period of ischemia. Electronmicroscopically cytoplasmic blebs arosen from hepatocytes are observed in the lumen of sinusoids immediately after 30 min of ischemia, whereas after 90 min of ischemia actual leakage of cytoplasmic material takes place through the damaged surface of the hepatocytes. Enzyme leakage probably takes place via these both types of shedding of cytoplasm. It is concluded that the enzyme leakage as such cannot be used as a discriminating test between reversible and irreversible damage of the liver parenchyma.

Metastasis is promoted by a bioenergetic switch: new targets for progressive renal cell cancer.

Targeted therapies have demonstrated clinical benefit with limited impact on long‐term disease specific survival in the treatment of renal cell cancer (RCC). New opportunities for the treatment of tumors that are resistant or have relapsed, are needed. Increased anaerobic glucose fermentation to lactate (aerobic glycolysis), leading to oxygen‐ and mitochondria‐independent ATP generation is a hallmark of aggressive cancer growth. This metabolic shift results in increased lactate production via cycling through the pentose phosphate pathway (PPP), and plays an important role in tumor immune escape, progression and resistance to immune‐, radiation‐ and chemo‐therapy. This study explored the activity and impact of the oxidative and nonoxidative branches of the PPP on RCC to evaluate new therapeutic options. Activity was determined in the oxidative branch by glucose‐6‐phosphate‐dehydrogenase (G6PD) activity, and in the nonoxidative branch by the total transketolase activity and the specific expression of the transketolase‐like‐1 (TKTL1) protein. Transketolase and G6PD activity were intensely elevated in tumor tissues. Transketolase, but not G6PD activity, was more elevated in metastasizing tumors and TKTL1 protein was significantly overexpressed in progressing tumors (p = 0.03). Lethal tumors, where surrogate parameters such as grading and staging had failed to predict progression, showed intensive TKTL1 protein expression. RCC was found to have activated oxidative and nonoxidative glucose metabolism through the PPP, displaying a bioenergetic shift toward nonoxidative glucose fermentation in progressing tumors. The coexistence of cancer cells with differentially regulated energy supplies provides new insights in carcinogenesis and novel anticancer targets.

On the nature of the ‘nothing dehydrogenase’ reaction

SummaryThe biochemical mechanism underlying the ‘nothing dehydrogenase’ reaction during the histochemical demonstration of dehydrogenases using tetranitro BT as the final electron acceptor has been investigated in unfixed, frozen rat liver sections. The reaction is stronger with NAD+ than either with NADP+ or in the absence of coenzyme. As much as 50% of the reaction is due to lactate dehydrogenase converting endogenous lactate and is largely inhibited by pyruvate. No NAD+-dependent alcohol dehydrogenase activity was detected at pH 7.45, the pH used for the incubations. The coenzyme-independent activity may be caused by SH-groups present in proteins and compounds like glutathione and cysteine and can be inhibited byN-ethylmaleimide andp-chloromercuribenzoic acid. It was also found that the ‘nothing dehydrogenase’ reaction mainly occurs during the first few minutes of incubation, levelling off quickly to a slow rate. When studying the kinetics of dehydrogenase reactions with tetrazolium salts, it should be realized that the ‘nothing dehydrogenase’ reaction, which as a whole is nonlinear with time, can interfere seriously with the dehydrogenase reaction to be analysed and may yield initial reaction rates that are too high. The findings of the present study reveal the nature of the reactions used for detection of necrosis in tissues with tetrazolium salts.

In situ detection of spontaneous superoxide anion and singlet oxygen production by mitochondria in rat liver and small intestine

In the present study, the endogenous formation of reactive oxygen species was localized in rat liver and small intestine. The 3,3′-diaminobenzidine (DAB)-Mn2+ technique in which cobalt ions were included in the incubation medium was applied to unfixed cryostat sections of intact tissues. Addition of manganese ions to the DAB-Co2+- containing medium greatly increased the amounts of final reaction product formed compared with incubations with only DAB and cobalt ions. In liver, a blue final reaction product was deposited, particularly in hepatocytes surrounding portal tracts. In the small intestine, the DAB--cobalt complex was mainly found at the basal side of enterocytes. Goblet cells remained unstained. Electron microscopical images revealed that an electron-dense reaction product was exclusively present at both inner and outer membranes and at the intermembrane space in mitochondria of liver parenchymal cells and duodenal enterocytes. It was shown that the spontaneous formation of final reaction product was enzymatic and dependent on the presence of oxygen in the medium. Sulphide decreased the reaction, which may indicate that cytochrome c oxidase was partially involved. Benzoquinone and histidine, which are scavengers of superoxide anions and singlet oxygen respectively, reduced the amount of final reaction product considerably. Furthermore, the formation of final reaction product was sensitive to specific inhibitors of NADH:coenzyme Q reductase and aldehydeoxidase, indicating that these enzymes were at least partly responsible for the generation of superoxide anions and singlet oxygen and for the formation of the DAB--cobalt complex.

Cerium methods for light and electron microscopical histochemistry

Methods based on the use of cerium to detect the activity of oxidases and phosphatases are rapidly expanding. Both classes of enzymes can be demonstrated with cerium at the electron and light microscopical level. The in situ detection of H2O2 production with cerium is another application that has great potential, particularly in experimental pathological research. The fine precipitate of the cerium‐containing final reaction product, cerium perhydroxide or cerium phosphate, enables a very precise localization. With such techniques, important advances have been made in cell biology, such as the discovery of new organelles, functional subcompartmentization of peroxisomes, tubular lysosomes and the elucidation of the function of extracellular ATPases.

Modulation of pentose phosphate pathway during cell cycle progression in human colon adenocarcinoma cell line HT29

Cell cycle regulation is dependent on multiple cellular and molecular events. Cell proliferation requires metabolic sources for the duplication of DNA and cell size. However, nucleotide reservoirs are not sufficient to support cell duplication and, therefore, biosynthetic pathways should be upregulated during cell cycle. Here, we reveal that glucose‐6‐phosphate dehydrogenase (G6PDH) and transketolase (TKT), the 2 key enzymes of oxidative and nonoxidative branches of the pentose phosphate pathway (PPP), respectively, which is necessary for nucleotide synthesis, are enhanced during cell cycle progression of the human colon cancer cell line HT29. These enhanced enzyme activities coincide with an increased ratio of pentose monophosphate to hexose monophosphate pool during late G1 and S phase, suggesting a potential role for pentose phosphates in proliferating signaling. Isotopomeric analysis distribution of nucleotide ribose synthesized from 1,2‐13C2‐glucose confirms the activation of the PPP during late G1 and S phase and reveals specific upregulation of the oxidative branch. Our data sustain the idea of a critical oxidative and nonoxidative balance in cancer cells, which is consistent with a late G1 metabolic check point. The distinctive modulation of these enzymes during cell cycle progression may represent a new strategy to inhibit proliferation in anticancer treatments.

Localization of xanthine oxidoreductase activity using the tissue protectant polyvinyl alcohol and final electron acceptor Tetranitro BT.

We have detected xanthine oxidoreductase activity in unfixed cryostat sections of rat and chicken liver, rat duodenum, and bovine mammary gland using the tissue protectant polyvinyl alcohol, the electron carrier 1-methoxyphenazine methosulfate, the final electron acceptor Tetranitro BT, and hypoxanthine as a substrate. Enzyme activity was localized in rat duodenum at lateral membranes and brush borders of enterocytes and in goblet cells and mucus. Hepatocytes in pericentral areas and especially sinusoidal cells showed high activity in rat liver. Xanthine oxidoreductase was also detected in epithelial cells and milk lipid globules of lactating bovine mammary gland, which is known to contain large quantities of the oxidase form of the enzyme. Chicken liver, which contains an inconvertible dehydrogenase form, also showed high activity in sinusoidal cells. Therefore, we conclude that the tetrazolium reaction demonstrates both the dehydrogenase and the oxidase form of xanthine oxidoreductase. Control activity, in the absence of hypoxanthine or in the presence of the competitive inhibitor allopurinol, was low in all tissues studied. Addition of O2 or NAD to the incubation medium did not change the specific reaction in bovine mammary gland or chicken liver, implying that the dehydrogenase and the oxidase form are not dependent on their natural electron acceptors in this tetrazolium salt reaction. We conclude that the present light microscopic method gives specific and precise localization of xanthine oxidoreductase activity in situ.

High levels of xanthine oxidoreductase in rat endothelial, epithelial and connective tissue cells. A relation between localization and function?

SummaryThe localization of xanthine oxidoreductase activity was investigated in unfixed cryostat sections of various rat tissues by an enzyme histochemical method which specifically demonstrates both the dehydrogenase and oxidase forms of xanthine oxidoreductase. High activity was found in epithelial cells from skin, vagina, uterus, penis, liver, oral and nasal cavities, tongue, esophagus, fore-stomach and small intestine. In addition activity was demonstrated in sinusoidal cells of liver and adrenal cortex, endothelial cells in various organs and connective tissue fibroblasts. Xanthine oxidoreductase produces urate which is a scavenger of oxygenderived radicals. Because the enzyme is found in epithelial and endothelial cells which are subject to relatively high oxidant stress, it is postulated that in these cells xanthine oxidoreductase is involved in the antioxidant enzyme defense system. In addition, a possible role for the enzyme in proliferation and differentiation processes is discussed.

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

SummaryLocalization 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.