EC:3.4.23.5 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.23.5 (cathepsin D)
4,130 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In recent years the lysosomal cathepsins have been implicated as important agents in the physiological degradation of various cartilages. In the present study, the nature of cathepsin present in human articular cartilage was investigated by microtechniques and a possible role for cathepsins in the cartilage degradation observed in osteoarthritis was sought. The results of this study indicated that the hemoglobin and proteoglycan-digesting activity in the human cartilage observed is predominantly that of a cathepsin D-type enzyme. This cathepsin D-type enzyme activity was present in two to three times greater amounts in yellowish or ulcerated articular cartilage from patients with primary osteoarthritis than in control "normal" human cartilages. The human cathepsin D-type enzyme, as well as a highly purified cathepsin D from bovine uterus degraded proteoglycan subunit (PGS) maximally at pH 5. Both enzyme preparations were inactive on hemoglobin at pH 6-8, but degraded PGS considerably at neutral pH. The activity of the human cathepsin extract was not affected by reagents which inhibit or activate cathepsins A and B. Neutral proteases which are active on hemoglobin or are inhibited by diisopropylfluorophosphate (DFP) were not detected in these preparations, but contamination by another type of neutral protease cannot be excluded. Chloroquine inhibited the degradation of PGS at neutral pH by the human cartilage enzyme extract.
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PMID:The action of cathepsin D in human articular cartilage on proteoglycans. 426 83

1. An enzyme present in rat liver extracts degraded insoluble collagen maximally at pH3.5. Collagenolytic activity was more abundant in kidney, spleen and bone marrow and was also present in decreasing concentrations in ileum, lung, heart, skin and muscle. 2. The crude collagenolytic cathepsin was activated by cysteine and dithiothreitol, but not by 2-mercaptoethanol. Iodoacetamide, p-chloromercuribenzoate and 7-amino-1-chloro-3-l-tosylamidoheptan-2-one hydrochloride inhibited the enzyme. Zn(2+), Fe(3+) and Hg(2+) ions were strongly inhibitory, but Ca(2+), Co(2+), Mg(2+) and Fe(2+) ions had little or no effect. EDTA was an activator of the enzyme. Inhibitors of cathepsin B were found to enhance collagenolysis, but phenylpyruvic acid, a cathepsin D inhibitor, inhibited the enzyme. Di-isopropyl phosphorofluoridate had no effect. 3. Collagenolysis at pH3.5 and 28 degrees C was restricted to cleavage of the telopeptide region in insoluble collagen, and the material that was solubilized consisted mostly of alpha-chains. 4. The collagenolytic cathepsin was separated from cathepsins B2 and D by fractionation on Sephadex G-100 and a partial separation from cathepsin B1 was obtained by chromatography on DEAE-Sephadex. 5. The function of the collagenolytic cathepsin in the catabolism of collagen is discussed in relation to the action of the other lysosomal proteinases and the neutral collagenase.
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PMID:The nature of the collagenolytic cathepsin of rat liver and its distribution in other rat tissues. 465 Nov 35

BCG lesions were produced in the skin of rabbits, and biopsies were performed at 7, 21, and 42 days, when they were developing, maximal in size, and almost healed, respectively. Tissue sections were prepared and stained histochemically for several enzymes. The percentage of cells stained for a given enzyme and the distribution of such cells within lesions of various ages were determined. Seven-day BCG lesions contained few esterase- and beta-galactosidase-positive macrophages, but 21-day lesions contained many, especially in the viable and nonviable tuberculous granulation tissue at the edge of the now prominent caseous necrotic center. Both 7-day and 21-day lesions contained many acid phosphatase- and cathepsin-D-positive macrophages, which were numerous in the more peripheral parts of the lesion, where little or no necrosis was present. Enzyme patterns in 42-day lesions resembled those in 21-day lesions. The role of each of these enzymes in the development and regression of the BCG lesion is unknown. Nonetheless, these studies clearly demonstrate that this macrophage population is heterogeneous and that macrophages carry out different functions in different parts of the lesion at different times. Histochemical techniques were developed to stain two enzymes in the same tissue section. The first stain usually contained a naphthol substrate and produced a red color; the second stain contained an indoxyl substrate and produced a blue color. A cell staining with both was colored purple. The peroxidase-antiperoxidase immunocytochemical technique for cathepsin D (producing a red color) was also employed. 1) Red esterase (hydrolyzing naphthol AS-D acetate) and beta-galactosidase, and 2) red esterase and blue esterase (hydrolyzing 5-bromo-4-chloro-indoxyl acetate), probably the same enzyme, were usually present in the same macrophage. In contrast, each of the following enzyme pairs was usually present in a different macrophage: 3) cathepsin D and beta-galactosidase, 4) cathepsin D and blue esterase, 5) acid phosphatase and beta-galactosidase, and 6) acid phosphatase and blue esterase. Roughly 10% of the macrophages stained for one enzyme existed side by side with macrophages stained for a different enzyme. These results suggest that local macrophage activation is under two levels of control. The first, macrolocal control, would determine the overall enzyme distribution in the lesion; whereas the second, microlocal control, would determine enzyme distribution on a cell-by-cell basis, ie, how two neighboring macrophages can each be rich in a different enzyme.
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PMID:Macrophage functional heterogeneity in vivo. Macrolocal and microlocal macrophage activation, identified by double-staining tissue sections of BCG granulomas for pairs of enzymes. 615 72

The activity (free and total) of cathepsin D and acid phosphatase was studied in cells of peritoneal exudate of mice of different ages in the process of interferon production in the presence of sera from newborn and adult animals. Cathepsin D release in newborn mice upon interferon induction is actively stimulated by serum factors of newborn animals altering lysosome permeability selectively for this enzyme alone. Another lysosomal enzyme, acid phosphatase, was more strongly bound to the structures and showed no such features. With an increased age of the donor the amount of stimulating factors in the serum decreases and that of inhibiting factors increases. Inhibition of cathepsin release from lysosomes by the serum factor of adult animals protects the synthesized interferon molecules from degradation and facilitates intensive interferon production in adult mice. A higher susceptibility of children to virus infections and inefficiency of the earliest defence system, interferon, may be due to degradation of newly synthesized interferon molecules by lysosomal cathepsin D.
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PMID:[Role of age-related serum factors in the mechanism of interferon production]. 615 32

We have studied the dog as a potential model for the human plasma prorenin-renin system. On a regular sodium intake, healthy conscious dogs apparently have a much lower plasma renin activity (PRA) than healthy human volunteers. Cryoactivation of prorenin is virtually absent in dogs, in contrast to that in humans, but becomes more effective after preacidification of the plasma. The concentration of trypsin required for optimal activation of prorenin is 6 to 10 times higher for dog plasma, revealing a prorenin:renin ratio about 10 times greater than in humans. Dialysis of posttryptic plasma decreases the PRA, but it remains 5 times higher than in pretryptic plasma, indicating that activation is not totally dependent on any renin system component that has been rendered dialyzable by trypsin, e.g., substrate converted to tetradecapeptide (TDP). This argues against the view that tryptic activation is attributable to angiotensin production from TDP by the action of cathepsin D, rather than from new renin converted from prorenin. The posttryptic increase in PRA is evident whether plasma incubation is carried out at pH 6.0 or at 7.4, and can be largely blocked by pepstatin, which also implicates a prorenin-renin mechanism rather than TDP-cathepsin. The low PRA in dogs, the negligible cryoactivation and its improvement by preacidification, and the requirement and tolerance of high trypsin concentrations, all point to greater protease inhibition in dog plasma and/or departures from the enzyme(s) responsible for human prorenin activation. Moreover, the tryptic activation of prorenin is not completed quickly as in human plasma, but carries over into the posttryptic stage of angiotensin generation, even in the presence of excess soybean trypsin inhibitor (SBTI), and other potent inhibitors. Such ongoing prorenin activation cannot be attributed only to trypsin itself, nor to kallikrein (both are inhibited by SBTI), but rather to some other enzyme(s) derived by the action of trypsin. This new prorenin convertase activity (possibly renin itself) can be effectively transferred from trypsinized to control dog plasma, in which it greatly accelerates prorenin activation. Thus, contrary to other reports, dog plasma has a high content of activatable prorenin, and with appropriate methodological changes, the dog can be used as an animal model for physiological and biochemical studies of the prorenin-renin system.
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PMID:Plasma prorenin in humans and dogs. Species differences and further evidence of a systemic activation cascade. 634 Dec 16

Lysosomal cysteine proteinases were fractionated from partially purified rat muscle lysosomes. By gel filtration on Sephadex G75, cathepsin D was separated from two thiol-requiring proteolytic fractions of Mr 25 000 and 55 000, respectively. By chromatofocusing, the first fraction (Mr = 25 000) was resolved into three isoenzymic forms of cathepsin H, eluted at pH 5.8, 6.0 and 7.2, respectively, and two isoenzymic forms of cathepsin B, eluted at pH 5.5 and 5.25. Cathepsin H isoenzymes hydrolyzed Arg-NNap and BANA, were totally inhibited by 1 mM p-CMB and only to 60% by 5.10(-5) M leupeptin. The two forms of cathepsin B which degraded Z-Phe-Arg-NMec, Z-Arg-Arg-NNap and BANA were very sensitive to p-CMB and leupeptin. In addition to cathepsins B and H, a typical cathepsin-L- like activity was found in this fraction but only as a very minor component. The high Mr fraction (Mr = 55 000) contained a cysteine proteinase hydrolyzing, at pH 6.0, Z-Phe-Arg-NMec, and to a lesser extent Z-Arg-Arg-NNap and BANA. Unlike cathepsins B and H, it was very sensitive to p-CMB and HgCl2 and was fully activated only in the presence of 10 mM DTT, and inhibited to 93% by 2.10(-8) M leupeptin. By chromatofocusing, it was resolved into several isoenzymatic forms, eluted between pH 5.8 and 4.0.
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PMID:Cysteine proteinase content of rat muscle lysosomes. Evidence for an unusual proteinase activity. 639

Changes in activities of a new proteinase cathepsin T as well as some other lysosomal acid proteinases and hydrolases were examined in liver homogenate from rats treated with a single hepatotoxic dose of carbon tetrachloride. The most striking changes were several-fold increases of liver cathepsin T and D activities over their levels in untreated rats 3 days after administration of the agent to rats. Increase of cathepsin T was greater than that of cathepsin D at all doses of the hepatotoxin examined. The activities of N alpha-benzoyl-DL-arginine 2-naphthylamide hydrolase, acid phosphatase, beta-galactosidase and beta-glucuronidase in poisoned rat liver were unchanged or only slightly increased. Cathepsin T and D activities were less enhanced in mitochondrial lysosomal fractions than in the homogenate, and were greatly elevated in the supernatant fractions of liver from the treated rats. As judged from the molecular weights, the elevated activities of cathepsins T and D in the treated rat liver could be attributable to the two cathepsins themselves and not to other proteinases. Administration to rats of other hepatotoxic agents, thioacetamide and dimethylnitrosamine, also induced the elevation of the two cathepsin activities in liver, but on partial hepatectomy the activities of liver cathepsins T and D did not show such marked increases. Nonparenchymal liver cell fractions were responsible for almost all the increased activities of liver cathepsins T and D. It is possible that cathepsins T and D play a role in the heterolytic breakdown of hepatocyte molecules following CCl4 poisoning.
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PMID:Increased activities of liver cathepsins T and D in carbon tetrachloride-treated rats. 649 24

The uptake and degradation of 125I-labeled (a) native aldolase, (b) cathepsin D-inactivated aldolase, and (c) aldolase inactivated by oxidized glutathione were studied in perfused rat liver. All three forms of aldolase were removed from the perfusion medium and degraded by the liver, but the uptake of the glutathione-inactivated enzyme (half-life in perfusate = 10 min) was much faster than that of the native enzyme (half-life = 30 min) or the cathepsin-inactivated enzyme (half-life = 42 min). The degradation of the enzyme was almost totally inhibited by leupeptin, indicating that thiol proteinases in lysosomes play an important role in the digestion process. Degradation of native and cathepsin D-inactivated aldolase appeared to be slower than that of the glutathione-inactivated enzyme but studies in which liver was preloaded with aldolase by perfusion at 19 degrees C and then warming to 37 degrees C indicated that the rate of degradation of all three forms was similar. It is concluded that the liver is capable of distinguishing between the glutathione-altered aldolase and native or partially degraded aldolase with regard to endocytosis, but that all three forms are degraded at similar rates once within lysosomes.
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PMID:Endocytosis and degradation of native, cathepsin D-degraded, and glutathione-inactivated aldolase by perfused rat liver. 666 22

Cathepsin D inactivated aldolase at pH values between 4.2 and 5.2; the chloride, sulphate or iodide, but not citrate or acetate, salts of sodium or potassium accelerated the rate of inactivation. Cathepsin D cleaved numerous peptide bonds in the C-terminus of aldolase, but the major site of cleavage in this region was Leu354-Phe355. The most prominent peptide products of hydrolysis were Phe-Ile-Ser-Asn-His-Ala-Tyr and Phe-Ile-Ser-Asn-His. Up to 20 amino acids were removed from the C-terminus of aldolase, but no further degradation of native aldolase was observed. By contrast, extensive degradation of the 40 000-Mr subunit was observed after aldolase was denatured. The cathepsin D-inactivated aldolase cross-reacted with antibodies prepared against native aldolase and had the same thermodynamic stability as native aldolase, demonstrated by differential scanning calorimetry and fluorescence quenching of tryptophan residues. Furthermore, the cathepsin-modified and native forms of aldolase were both resistant to extensive proteolysis by other purified cellular proteinases and lysosomal extracts at pH values of 4.8-8.0.
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PMID:Action of cathepsin D on fructose-1,6-bisphosphate aldolase. 688 56

Sublethal hypoxic injury in rat and rabbit hearts was accompanied by a biochemical redistribution of cathepsin D activity from the particulate to the supernatant fraction of the tissue homogenate, which was partially reversible on reoxygenation. Immunofluorescent staining for cathepsin D failed to reveal major anatomic release of the acid hydrolase until necrosis was present, suggesting that the earlier biochemical redistribution was primarily a result of increased lysosomal fragility during homogenization, with significant intracellular diffusion of the enzyme occurring only as irreversible damage took place. Hypoxia produced enlargement of both cathepsin-D-staining lysosomes and nonstaining vacuoles, as well as their aggregation. These changes were intensified during reoxygenation and recovery of reversibly damaged hearts, suggesting a possible role for the lysosomal-vacuolar apparatus in myocytic repair following hypoxic injury.
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PMID:Lysosomal alterations in hypoxic and reoxygenated hearts. II. Immunohistochemical and biochemical changes in cathepsin D. 698 84

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