EC:3.4.22.32 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.22.32 (bromelain)
1,025 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A new proteolytic assay is described involving Coomassie blue. Under specified conditions, the amount of Coomassie-stained casein protein hydrolyzed by several proteases was proportional to the amount of protease. Coomassie dye reaction was used directly to determine the change in protein concentration of the substrate casein during proteolysis by three proteases: stem bromelain, papain, and trypsin. This method can be used with 0.1- to 0.5-micrograms quantities of protease. The dye reagent was used directly on the protease protein in order to obtain an assay of autodigestion. Autodigestion of bromelain at 50 and 25 degrees C was followed by measuring the amount of residual protease protein with time.
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PMID:Protease activity and autodigestion (autolysis) assays using Coomassie blue dye binding. 848 11

The hepatitis B viruses replicate by reverse transcription of an RNA pregenome by using a virally encoded polymerase. A key early step in replication is binding of the polymerase to an RNA stem-loop (epsilon) of the pregenome; epsilon is both the RNA encapsidation signal and the origin of reverse transcription. Here we provide evidence that this interaction is also key to the development of enzymatic activity during biosynthesis of the polymerase. Duck hepatitis B virus polymerase expressed in Saccharomyces cerevisiae can synthesize DNA from epsilon-containing RNAs and can also end label other small RNAs. Expression of functional polymerase in S. cerevisiae requires interaction between the polymerase and epsilon during or shortly after translation for it to develop any enzymatic activity; if epsilon is absent during expression, the polymerase is inactive on RNAs both with and without epsilon. Functional duck polymerase can also be produced by in vitro translation, and synthesis of the polymerase in the presence of epsilon induces resistance in the polymerase to proteolysis by papain, trypsin, and bromelain. Induction of the resistance is specific for epsilon sequences that can support RNA encapsidation and initiation of DNA synthesis. Induction of the resistance precedes initiation of DNA synthesis and is reversible by degradation of epsilon. These two sets of data (i) support a model in which binding of epsilon to the polymerase induces a structural alteration of the polymerase prior to the development of enzymatic activity and (ii) suggest that this alteration may be required for the polymerase to mature to an active form.
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PMID:Evidence for activation of the hepatitis B virus polymerase by binding of its RNA template. 870 89

The enzyme allergens Der p I and Der f I produced by the house dust mites Dermatophagoides pteronyssinus and D. farinae display partial sequence homology with other members of the cysteine proteinase superfamily. We report that certain widely used mouse mAbs against these Group I allergens indeed crossreact with the plant enzymes papain, bromelain and ficin. The recognition sites of these anti Group I mAbs comprise conformational and thermolabile epitopes involved in molding the catalytic center of the proteinases. Thus, the mAbs inhibit the enzymatic hydrolysis of specific chromogenic substrates by the Group I allergens, while specific cysteine proteinase inhibitors abolish the recognition of the enzymes by the mAbs. Similarly, activation of the thiol-proteases with L-cysteine abrogates their binding in the two-site mAb system, indicating that the mAbs recognize a proenzyme conformational peptide epitope. It follows that mAb-based assays for mite Group I components can neither detect the allergens after inactivation, nor in their fully activated forms.
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PMID:Monoclonal antibodies against Dermatophagoides group I allergens as pseudo-cystatins blocking the catalytic site of cysteine proteinases. 880 16

Native tubulin alpha beta dimers and microtubules have been subjected to limited proteolysis with trypsin, chymotrypsin, elastase, clostripain, proteinase lysine-C, thermolysin, protease V8, papain, subtilisin, proteinase K, proteinase aspartic-N, and bromelain. Eighty nicking points have been mapped onto the alpha- and beta-tubulin sequences with the aid of site-directed antibodies, of which 18 sites have been exactly determined by N-terminal sequencing, and the probable position of 6 others deduced from protease specificities. Proteolytic sites cluster into five characteristic zones, including the C termini of both chains. Residues accessible to proteases in the tubulin dimer include alpha-tubulin Lys40-Thr41-Ile42, Glu168-Phe169-Ser170, Ser178-Thr179-Ala180-Val181, Lys280-Ala281, Glu290-Ile291, Ala294-Cys295, Arg339-Ser340 (plus probably Lys60-His61 and Glu183-Pro184) and beta-tubulin Gly93-Gln94, Lys174-Val175, Gly277-Ser278, Tyr281-Arg282-Ala283, Cys354-Asp355 (plus probably Arg121-Lys122, Phe167-Ser168, Tyr183-Asn184, and Glu426-Asp427 or Ala430-Asp431). While the majority of these sites remain accessible at the outer surface of taxol-induced microtubules, alpha-tubulin Lys280-Ala281, Arg339-Ser340 and beta-tubulin Tyr281-Arg282-Ala283 (and probably Arg121-Lys122) become protected from limited proteolysis, suggesting that they are close to or at intermolecular contacts in the assembled structure. The protease nicking points constitute sets of surface constraints for any three-dimensional model structures of tubulin and microtubules. The dimer tryptic site at alpha-tubulin 339-340 jumps approximately 12-22 residues upstream (probably to Lys326-Asp327 or Lys311-Tyr312) in taxol microtubules, suggesting a tertiary structural change. The cleavage of the approximately 10 C-terminal residues of alpha-tubulin by protease V8, papain, and subtilisin is inhibited in taxol microtubules compared to tubulin dimers, while the approximately 20 C-terminal residues of beta-tubulin are similarly accessible to protease V8, subtilisin, proteinase K, proteinase AspN, and bromelain and show enhanced papain cleavage. This is consistent with models in which the alpha-tubulin C-terminal zone is near the interdimer contact zone along the protofilaments, whereas the C terminus of beta is near the interface between both subunits.
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PMID:Mapping surface sequences of the tubulin dimer and taxol-induced microtubules with limited proteolysis. 891 4

Cysteine proteinases are widely distributed among living organisms. According to the most recent classifications (Rawlings and Barrett, 1993, 1994), they can be subdivided on the basis of sequence homology into 14 or even 20 different families, the most important being the papain and the calpain families. The papain-like cysteine proteinases are the most abundant among the cysteine proteinases. The family consists of papain and related plant proteinases such as chymopapain, caricain, bromelain, actinidin, ficin, and aleurain, and the lysosomal cathepsins B, H, L, S, C and K. Most of these enzymes are relatively small proteins with Mr values in the range 20000-35000 (reviewed in Brocklehurst et al., 1987; Polgar, 1989; Rawlings and Barrett, 1994; Berti and Storer, 1995), with the exception of cathepsin C, which is an oligomeric enzyme with Mr approximately 200000 (Metrione et al., 1970; Dolenc et al., 1995). A number of cysteine proteinases are located within lysosomes. Four of them, cathepsins B, C, H and L, are ubiquitous in lysosomes of animals, whereas cathepsin S has a more restricted localisation (Barrett and Kirschke, 1981; Kirschke and Wiederanders, 1994). The enzymes, except cathepsin C, are endopeptidases (reviewed in Kirschke et al., 1995), although cathepsin B was found also to be a dipeptidyl carboxypeptidase (Aronson and Barrett, 1978) and cathepsin H also an aminopeptidase (Koga et al., 1992). Cathepsin C is a dipeptidyl aminopeptidase, but at higher pH it exhibits also dipeptidyl transferase activity (reviewed in Kirschke et al., 1995). Among the lysosomal cysteine proteinases, cathepsin L was found to be the most active in degradation of protein substrates, such as collagen, elastin and azocasein (Barrett and Kirschke, 1981; Maciewicz et al., 1987; Mason et al., 1989), arid cathepsin B the most abundant (Kirschke and Barrett, 1981). All the enzymes are optimally active at slightly acidic pH, although their pH optima for degradation of synthetic substrates vary from 5.5 for cathepsin L to 6.8 for cathepsin H (reviewed in Kirschke et al., 1995). Several other lysosomal cysteine proteinases, such as cathepsins N, T and K, are known, although their properties are less well characterised (reviewed in Kirschke et al., 1995). In particular cathepsin K has attracted recent interest (Bromme et al., 1996; Shi et al., 1995; Bossard et al., 1996; Drake et al., 1996) and was found to be expressed specifically in osteoclasts (Drake et al., 1996) with properties similar to cathepsin L (Bossard et al., 1996).
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PMID:Structural and functional aspects of papain-like cysteine proteinases and their protein inhibitors. 916 64

Some biochemical and functional characteristics of the swine swC1 antigen, determined by the use of the authors' swC1-specific monoclonal antibody (mAb) 335-2, are reported. The molecular weight of the antigen was determined by immunoprecipitation. The swC1 antigen has 41 and approx. 15 kD components under reducing conditions. It is sensitive to proteolytic enzymes such as bromelain or trypsin, but not to papain. Phosphatidylinositol-specific phospholipase C treatment diminished the expression of swC1 on the surface of leukocytes. Cross-linking of swC1 on the cell surface did not influence the proliferation of mitogen-activated mononuclear cells and had no mitogenic activity by itself. During 48 h of mitogen activation its surface expression did not change significantly. Possible relationships of swC1 to human CD antigens are discussed in the light of the results obtained.
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PMID:Characterisation of the swine swC1 antigen. 927 Jan 26

The ratio of kininogen that is substrate of plasma kallikrein to kininogen, which is not substrate of plasma kallikrein in canine plasma, was about 1:3.6 by differential assay of kininogens. When the plasma was gel-filtered through a column of Sephacryl S-300 superfine, two fractions, which released kinin by trypsin, were obtained. These results indicate that two kininogens with different molecular weights are present in the plasma and they show different susceptibility to plasma kallikrein. One kininogen was purified by ion-exchange and zinc-chelating affinity chromatographies. Purified kininogen showed a single band in sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing condition and its molecular weight was 125 kDa. Released kinin from the kininogen by trypsin was bradykinin. The kininogen inhibited papain and ficin but did not inhibit bromelain at the concentration used. The kininogen bound to carboxymethylated-papain and this binding was dissociated by 3M NaSCN. Canine plasma shortened the abnormal clotting time of human high molecular weight kininogen-deficint plasma. The kininogen also shortened the abnormal clotting time of the plasma. From these results, the purified kininogen was high molecular weight kininogen and it was multi-functional protein.
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PMID:Canine plasma kininogen: evidence for the presence of two kininogens and purification of high molecular weight kininogen and characterization as multi-functional molecule. 929 98

We investigated 10 sensitized and 10 nonsensitized workers from a pharmaceutic factory who had been exposed to powdered trypsin, chymotrypsin, bromelain, papain, amylase, and lipase. Ten nonallergic subjects served as a control group. Titrated skin prick tests (SPT), RAST, and immunoblot studies were performed with all six enzymes. SPT reactivity revealed multiple sensitizations to proteolytic enzymes, i.e., papain (specifically sensitized/total number of sensitizations: 9/10), trypsin (8/10), chymotrypsin (8/10), and bromelain (7/10) and appeared to be more frequent and more pronounced than sensitizations to amylase (3/10) or lipase (3/10). The low molecular weight of proteolytic enzymes (20-30 kDa) and their biologic activity might facilitate mucosal penetration more easily and thus-compared to amylase and lipase-permit an immune response and induction of allergic hypersensitivity. Immunoblot studies demonstrated IgG-binding bands in both SPT-positive and -negative workers, indicating exposure to the enzymes, but not in 10 unexposed control subjects. IgE-binding bands of the enzymes were detected only in workers with a positive SPT reaction and/or a positive RAST result. IgG bands were more frequent and the IgG/IgE ratio was increased in workers without allergic complaints compared to symptomatic workers. This might indicate that high levels of specific IgG antibodies to enzymes are associated with an immune response lacking allergic manifestations in spite of IgE-mediated sensitizations to the enzymes. Atopic subjects were at greater risk of developing IgE-mediated sensitization (7/10) and allergic symptoms to enzymes (5/7). However, even without risk of atopy, IgE-mediated hypersensitivity occurred in a few subjects (3/13) exposed to enzymes by inhalation for prolonged periods of time.
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PMID:Multiple IgE-mediated sensitizations to enzymes after occupational exposure: evaluation by skin prick test, RAST, and immunoblot. 929 78

The amino acid sequences of ananain (EC3.4.22.31) and stem bromelain (3.4.22.32), two cysteine proteases from pineapple stem, are similar yet ananain and stem bromelain possess distinct specificities towards synthetic peptide substrates and different reactivities towards the cysteine protease inhibitors E-64 and chicken egg white cystatin. We present here the complete amino acid sequence of ananain and compare it with the reported sequences of pineapple stem bromelain, papain and chymopapain from papaya and actinidin from kiwifruit. Ananain is comprised of 216 residues with a theoretical mass of 23464 Da. This primary structure includes a sequence insert between residues 170 and 174 not present in stem bromelain or papain and a hydrophobic series of amino acids adjacent to His-157. It is possible that these sequence differences contribute to the different substrate and inhibitor specificities exhibited by ananain and stem bromelain.
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PMID:Complete amino acid sequence of ananain and a comparison with stem bromelain and other plant cysteine proteases. 935 53

It is revealed that patients allergic to a water-soluble fraction from wheat flour were sensitive to pineapple enzyme, bromelain. Since bromelain has a high similarity to other SH-proteases such as papain, it may imply that the patients may recognize varieties of other SH-proteases as the epitope.
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PMID:[Cross-reactivity between bromelain and soluble fraction from wheat flour]. 943 35

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