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)

Cathepsin D was purified from the lactating rabbit mammary gland by a rapid procedure, which included fractionation with (NH4)2SO4, acid precipitation, double affinity chromatography on pepstatin-Sepharose 4B and gel filtration on Sephadex G-100, resulting in approximately 360-fold purification of the enzyme over the homogenate and approximately 16% recovery. After isoelectric focusing, the enzyme dissociated into four (pI 5.8, 6.3, 6.5 and 7.2) multiple forms, but appeared homogeneous on polyacrylamide gel electrophoresis. Cathepsin D has a Mr of 45 kDa as determined by Sephadex G-100 column chromatography. On sodium dodecylsulfate/polyacrylamide gel electrophoresis the enzyme gave a single protein band, corresponding to Mr of 45 kDa. The amino acid composition of the enzyme is similar to that of cathepsins D from other tissues. A single N-terminal amino acid was glycine. Cathepsin D contains 6.4% carbohydrates consisting of mannose, galactose, fucose and glucosamine at a ratio of 3:9:2:2. Cathepsin D is inhibited by pepstatin with Ki of 2.5 X 10(-9) M and irreversibly by N-diazoacetyl-N'-2.4-dinitrophenyl-ethylene diamine. The enzyme hydrolyzes bovine hemoglobin with the maximal activity at pH 3.0 with Km = 10(-5) M and HLeu-Ser-Phe(NO2)-Nle-Ala-Leu-OMe with Km = 4 X 10(-5) M and Rcat = 0.95 s-1. The major cleavage sites were Leu15-Tyr16, Phe24-Phe25 and Phe25-Tyr26 during hydrolysis of the oxidized insulin B-chain by cathepsin D.
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PMID:[Purification and properties of cathepsin D from the mammary glands of lactating rabbits]. 400 22

1. Cathepsin B1 was purified from human liver by a method involving autolysis, fractional precipitation with acetone, adsorption on, and stepwise elution from, CM-cellulose and an organomercurial adsorbent, gel chromatography and finally equilibrium chromatography on CM-cellulose. 2. The early stages of the procedure, including the use of the organomercurial adsorbent, were suitable for the simultaneous isolation of cathepsin D. The two cathepsins were sharply separated on the organomercurial column, and particular attention was given to the method for the preparation and use of this adsorbent. 3. A method is described for the staining of analytical isoelectric-focusing gels for cathepsin B1 activity, as well as protein. By this method it was shown that cathepsin B1 was represented by at least six isoenzymes during the greater part of the purification procedure. After the gel-chromatography step this group of isoenzymes was obtained essentially free of other proteins, in good yield. The isoenzymes were resolved from this mixture by chromatography on CM-cellulose. The purified enzyme was stable for several weeks at slightly acid pH values in the absence of thiol compounds; it was unstable above pH7. 4. The pI values of the isoenzymes of cathepsin B1 extended from pH4.5 to 5.5, that of the major isoenzyme tending to increase from 5.0 to 5.2 during the purification procedure. Gel chromatography indicated a molecular weight of 27500 for all of the isoenzymes, whereas polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate gave a value of 24000. 5. An antiserum raised in sheep against the purified enzyme reacted specifically with the alkali-denatured molecule. Purified cathepsin B1 contained no material precipitable by an anti-(human cathepsin D) serum. 6. The enzyme hydrolysed several N-substituted derivatives of l-arginine 2-naphthylamide, as well as haemoglobin, azo-haemoglobin, azo-globin and azo-casein. Greatest activity was obtained near pH6.0. 7. The sensitivity of human cathepsin B1 to chemical inhibitors was generally similar to that of other thiol proteinases. The enzyme was inactivated by the chloromethyl ketones derived from tosylphenylalanine, tosyl-lysine, acetyltetra-alanine and acetyldialanylprolylalanine. 8. The hydrolysis of alpha-N-benzoyl-dl-arginine 2-naphthylamide by extracts of human liver at pH6 was attributable entirely to cathepsin B1.
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PMID:Human cathepsin B1. Purification and some properties of the enzyme. 412 67

1. Experiments were made to determine whether the purified lysosomal proteinases, cathepsins B1 and D, degrade acid-soluble collagen in solution, reconstituted collagen fibrils, insoluble collagen or gelatin. 2. At acid pH values cathepsin B1 released (14)C-labelled peptides from collagen fibrils reconstituted at neutral pH from soluble collagen. The purified enzyme required activation by cysteine and EDTA and was inhibited by 4-chloromercuribenzoate, by the chloromethyl ketones derived from tosyl-lysine and acetyltetra-alanine and by human alpha(2)-macroglobulin. 3. Cathepsin B1 degraded collagen in solution, the pH optimum being pH4.5-5.0. The initial action was cleavage of the non-helical region containing the cross-link; this was seen as a decrease in viscosity with no change in optical rotation. The enzyme also attacked the helical region of collagen by a mechanism different from that of mammalian neutral collagenase. No discrete intermediate products of a specific size were observed in segment-long-spacing crystalloids (measured as native collagen molecules aligned with N-termini together along the long axis) or as separate peaks on gel filtration chromatography. This suggests that once an alpha-chain was attacked it was rapidly degraded to low-molecular-weight peptides. 4. Cathepsin B1 degraded insoluble collagen with a pH optimum below 4; this value is lower than that found for the soluble substrate, and a possible explanation is given. 5. The lysosomal carboxyl proteinase, cathepsin D, had no action on collagen or gelatin at pH3.0. Neither cathepsin B1 nor D cleaved Pz-Pro-Leu-Gly-Pro-d-Arg. 6. Cathepsin B1 activity was shown to be essential for the degradation of collagen by lysosomal extracts. 7. Cathepsin B1 may provide an alternative route for collagen breakdown in physiological and pathological situations.
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PMID:Cathepsin B1. A lysosomal enzyme that degrades native collagen. 420 88

Several new synthetic substrates fulfilling the specificity requirements of cathepsin D were synthesized. One of these D-Phe-Ser(O-CH2-C6H5)-Phe-Phe-Ala-Ala-pAB(pAB = p-aminobenzoate) proved to be highly sensitive and convenient for measuring activity. Enzyme determination was carried out in a two-step reaction. In the first step the enzyme hydrolyzes the Phe-Phe bond of the substrate at pH 3.4. In the second step aminopeptidase M (EC 3.4.11.2) degrades one of the products Phe-Ala-Ala-pAB at pH 7 to 8 with the release of free pAB, which is then determined by a diazotization procedure. Activity can be measured in as little as 1 to 5 micrograms of macrophage protein. The activity of cathepsin D in rat alveolar macrophages was almost ten times higher than in resident peritoneal macrophages, and more than 25 times higher than in blood monocytes. The data indicate that transformation of blood monocytes into macrophages is associated with a much greater increase of cathepsin D activity in alveolar than peritoneal macrophages.
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PMID:A sensitive procedure for determination of cathepsin D: activity in alveolar and peritoneal macrophages. 615 Apr 34

To elucidate the metabolic abnormality of musclar dystrophy, 27 kinds of enzyme activity in various organs of control and dystrophic mice were examined. The organs examined included muscle, bone, heart, testis, uterus, spleen, thymus, submaxillary gland, stomach, pancreas, liver, kidney, brain, and lung. The activities of 14 different aminopeptidases, 5 endopeptidases, 4 glycosidases, phosphatase, esterase, and ribonuclease were measured. Most of the enzyme activities were significantly elevated in muscles and bones of dystrophic mice. These organs were similar in their patterns of enzyme abnormality. Among the 14 kinds of aminopeptidase activity studied, the degree of increased activity was greater for the aminopeptidases (AP):Ala-AP, Leu-AP, Met-AP, Phe-AP, Trp-AP, Gly-Pro-Leu-AP. In addition to aminopeptidases, there were significant increases in activities of chymotrypsinlike enzyme, cathepsin C, cathepsin D, several glycosidases and neutral ribonuclease in the muscles of dystrophic mice. Similarly increased enzyme activity was also observed in organs other than muscle and bone. Furthermore, protein content in most organs was higher in dystrophic mice than in those of control mice. These abnormalities were seen in both males and females. The present results suggest that there are extensive abnormalities in the protein metabolism in dystrophic mice. It seems therefore that the therapeutic approach to muscular dystrophy should be studies not only from the well-known abnormality of intramuscular endopeptidases, but from other aspects as well.
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PMID:Various enzyme activities in muscle and other organs of dystrophic mice. 625 14

Protein synthesis and degradation and net uptake and release of amino acids and minerals were examined in the perfused hemicorpus of bilaterally nephrectomized and sham-operated control rats. Animals were studied 30 h after surgery. In comparison with controls, uremic rats had greater urea N appearance (net urea generation) and lower plasma and muscle concentrations of most amino acids. Muscle protein synthesis was not altered, but protein degradation was greater in uremic versus sham rats. There was greater net release of phenylalanine, tyrosine, alanine, total nonessential amino acids, total amino acids, potassium, and phosphorus from the perfused hemicorpus of uremic rats and greater release of citrulline from sham rats. ATP, creatine phosphate, cAMP, and activities of cathepsin B1, cathepsin D, and alkaline protease were not different in muscles of the uremic versus sham rats. Thus, in acutely uremic rats there is increased protein wasting in the hemicorpus due to enhanced protein degradation. The enhanced protein degradation does not appear to be due to increased muscle cathepsin B1, cathepsin D, or alkaline protease activities.
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PMID:Protein and amino acid metabolism in posterior hemicorpus of acutely uremic rats. 630 4

1. P. yoelli nigeriensis has an acid endoprotease (cathepsin D) and an endoarylamidase. 2. The acid endoprotease is specific towards haemogloblin. It is found in 2 molecular forms, of molecular weight 100,000 and 50,000. It is inhibited by hematin and pepsatin. 3. In mouse normal red blood cells we find an acid protease having physico-chemical properties similar to those of the enzyme present in P. yoelii nigeriensis extracts, except as regards the pHi. 4. In parasite extracts there exists an enzyme active on the synthesis substrate N-acetyl alanine 4 nitro anilide. The main properties of this enzyme have been determined. 5. This enzyme must be also involved in the mechanism of haemoglobin degradation.
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PMID:Endoprotease in Plasmodium yoelii nigeriensis. 634 Sep 50

Protein synthesis and degradation and net uptake and release of amino acids and minerals were investigated in the perfused hemicorpus of acutely uremic and control Sprague-Dawley rats. Rats underwent bilateral nephrectomy or sham surgery and were studied 30 hr after surgery. The uremic rats displayed greater urea N appearance (net urea generation), lower plasma and muscle concentrations of most amino acids, and increased muscle protein degradation as compared to control rats. Muscle protein synthesis was slightly but not significantly decreased in the uremic animals. There was greater net release of phenylalanine, tyrosine, alanine, total nonessential amino acids, total amino acids, potassium and phosphorus from the perfused hemicorpus of uremic rats and greater release of citrulline from sham rats. Muscle ATP, creatine phosphate, cyclic-AMP, and activities of cathepsin B1, cathepsin D, and alkaline protease were not different in the uremic and sham rats. These data provide evidence that acutely uremic rats sustain increased muscle protein wasting which is due to enhanced protein degradation. The increased protein degradation does not appear to be due to enhanced activities of muscle cathepsin B1, cathepsin D or alkaline protease.
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PMID:Enhanced muscle protein degradation and amino acid release from the hemicorpus of acutely uremic rats. 636 19

Procathepsin D-II (Mr = 37 500) was purified from Japanese monkey lung at pH 7.0, and was shown to be converted to the active form, cathepsin D-II (Mr = 33 000) via an intermediate (Mr = 35 500) upon treatment at pH 3.0 and 14 degrees C. Procathepsin D-II was shown to be the inactive precursor of cathepsin D-II based on the following results: the former was inactive toward heat-denaturated casein at pH 5.4 whereas the latter was active; the former was not inactivated by diazoacetyl-DL-norleucine methyl ester in the presence of Cu2+ ion at pH 6.0 whereas the latter was inactivated rapidly under the same conditions; and the former had no affinity to pepstatin-Sepharose between pH 5 and 7 whereas the latter was adsorbed to it. With a rabbit antiserum against procathepsin D-II, cathepsin D-II, pepsinogen C and pepsin C of Japanese monkey were each found to give a single precipitin line which fused completely with each other on agarose plate. On the other hand, cathepsin D-I purified from the monkey lung, and pepsinogens A (I, II, III-1, III-2 and III-3) obtained from the monkey gastric mucosa failed to precipitate with the antiserum. With the antiserum against the monkey pepsinogen C, the same results were obtained. Further, procathepsin D-II and pepsinogen C were shown to have the same amino-terminal amino acid sequence, Ala-Val-Val-Lys-Val-Pro-Leu-Lys-Lys-Phe-Lys-. All these results indicate a strong similarity of procathepsin D-II and cathepsin D-II to pepsinogen C and pepsin C, respectively.
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PMID:Identification of monkey lung procathepsin D-II as a pepsinogen-C-like acid protease zymogen. 640 25

1. Several peptides containing either of the sequences -Phe(NO2)-Trp- and -Phe(NO2)-Phe- and an uncharged hydrophilic group were synthesized, and the steady-state kinetics of their hydrolysis by pig pepsin (EC 3.4.23.1) and chicken liver cathepsin D (EC 3.4.23.5) were determined. Despite the presence of a hydrophilic group to increase substrate solubility, it was not possible to achieve the condition [S]0 much greater than Km, and, in some cases, only values of kcat./Km could be determined by measuring the first-order rate constant when [S]0 much less than Km. 2. Occupancy of the P2 and P3 sites considerably enhanced the specificity constant, and alanine was more effective than glycine at site P2. 3. The specificity constants for the hydrolysis by pepsin of those substrates in the present series that contain an amino acid residue at site P3 are considerably lower than for comparable substrates containing a cationic group. This difference does not apply to cathepsin D. 4. Hydrolyses with cathepsin D commonly exhibited a lag phase, and a possible explanation for this is given.
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PMID:The kinetics of hydrolysis of some synthetic substrates containing neutral hydrophilic groups by pig pepsin and chicken liver cathepsin D. 640 91

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