EC:3.4.21.7 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.7 (plasmin)
9,023 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The ability of various reactive oxygen species and serine proteases to activate latent collagenase (matrix metalloproteinase-1) purified from human neutrophils was examined. Latent 70-75 kD human neutrophil collagenase (HNC) was efficiently activated by known non-proteolytic activators phenylmercuric chloride (an organomercurial compound) and gold thioglucose (Au(I)-salt). Corresponding degree of activation was achieved by reactive oxygen species including hypochlorous acid (HOCl), hydrogen peroxide (H2O2) and hydroxyl radical generated by hypoxanthine/xanthine oxidase (HX/XAO). The presence of trace amounts of iron and EDTA were necessary and even enhanced H2O2 induced activation of latent HNC. This activation could be abolished by an iron chelator desferrioxamine and a hydroxyl radical scavenger mannitol. HOCl induced activation of latent HNC was not affected by desferrioxamine and mannitol. Thus, these compounds do not inhibit the active/activated form of HNC. Latent HNC could also be activated by trypsin and chymotrypsin but not by plasmin and plasma kallikrein. The ability of mannitol and desferrioxamine to inhibit the H2O2-induced activation of HNC suggests the transition metal dependent Fenton reaction to be responsible for localized and/or site-specific generation of hydroxyl radical/hydroxyl radical -like oxidants to act as the activating oxygen species. Our results support the ability of myeloperoxidase derived HOCl to act as a direct oxidative activator of HNC and further suggest the existence of a new/alternative oxidative activation pathway of HNC involving hydroxyl radical.
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PMID:Activation of latent human neutrophil collagenase by reactive oxygen species and serine proteases. 217 13

Polymorphonuclear leucocyte (PMN) accumulation is associated with damage to airways epithelial cells in bronchitis, bronchiectasis and some forms of asthma. PMNs release several molecules which may mediate this damage, particularly proteases and oxidants. Using an in vitro model of intact human amnionic epithelial cells (EC) attached to native basement membrane (BM), we evaluated the capacity of several proteases and oxidants to induce detachment of EC from the BM. Maximum desquamation was observed with collagenase, elastase and trypsin, with minimum effective concentrations required to produce 50% EC-desquamation (MEC50) for highly purified collagenase, pancreatic elastase, human leucocyte elastase, human leucocyte cathepsin-G (Cath-G), trypsin, and kallikrein being 3616 +/- 989 U/mL, 32.3 +/- 14.7 U/mL, 85.8 +/- 26.7 U/mL, 360 +/- 20 U/mL, 340 +/- 49 BAEE U/mL and 300 +/- 23 U/mL, respectively. Urokinase (20 U/mL) and plasmin (500 U/mL) produced no desquamation in this system. Relatively high concentrations of oxidants also produced detachment (MEC50 for H2O2 and HOCl being 0.59 +/- 0.006 mol/L and 0.015 +/- 0.009 mol/L, respectively) and pretreatment of EC membranes with non-detaching concentrations of H2O2 rendered them 10-fold more susceptible to protease-induced desquamation, suggesting synergism. Reduced glutathione (GSH), N-acetyl cysteine (NAC), ethylenediamine tetra-acetic acid (EDTA) and 1,10 phenanthroline ablated collagenase induced EC-detachment. Elastase induced detachment was sensitive to inhibition by phenyl methyl sulfonyl fluoride (PMSF) and alpha 1-anti-proteinase (alpha 1-AP) and, to a lesser extent by aprotinin; trypsin-induced detachment was ablated by PMSF, alpha 1-AP and soybean trypsin inhibitor (SBTI) but not by 1,10 phenanthroline or EDTA. Cath-G induced detachment was profoundly inhibited by SBTI, GSH and NAC. These data demonstrate that human EC can be detached from intact BM by several PMN products, including collagenase, Cath-G and elastase, and that PMN-mediated detachment can be prevented by Cath-G and collagenase inhibitors. The data suggest a role for proteases, particularly Cath-G and collagenase, plus oxidants in synergism with proteases, in mediating PMN-induced EC detachment.
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PMID:Study of human epithelial cell detachment and damage: effects of proteases and oxidants. 220 Jul 49

S-S cross-linking enzyme, skin sulfhydryl oxidase (SSO), catalyzes the formation of disulfide bonds from sulfhydryl groups in skin. The activity of SSO was detected in differing amounts in each of the four layers--stratum corneum, stratum granulosum, stratum spinosum with basal cell layer, and dermis--of cow snout skin, with the highest specific activity being recorded in the stratum granulosum. SSO was stimulated to 130-150% of its initial activity by treatment with 1 mg/ml trypsin, chymotrypsin, or urokinase, but was not affected by plasmin or cathepsin D. These findings suggest that SSO may be activated by some kinds of serine proteases during the keratinocyte autolysis process in the stratum granulosum. SSO showed the highest activity with the addition of 5 microM of Cu2+. The atomic absorptive analysis of purified SSO showed 0.5 atoms of Cu in one molecule of SSO. From these findings, it was determined that Cu2+ was essential for the activity of SSO. The molar ratio of the disappearance of DTT, consumption of O2, and production of H2O2 during the enzyme reaction was 1:1.05:0.89. From these findings, the reactions catalyzed by SSO is suggested to be represented by the following equation: (table; see text).
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PMID:[Localization in skin, activation and reaction mechanisms of skin sulfhydryl oxidase]. 258 80

Pretreatment of hemoglobin with 50-5000 nmol hydrogen peroxide (H2O2) increased its susceptibility to proteolysis by a number of purified enzymes, including trypsin, chymotrypsin, elastase, and plasmin, and by the neutral protease of rat peritoneal leukocytes. Pretreatment of the protein substrate with catalase-inactivated H2O2 had no effect. Separation of the proteolytic fragments by G-75 Sephadex gel filtration indicated no apparent differences in the size distribution of the fragments produced by treatment with the H2O2/proteolytic enzyme combination as compared with enzyme treatment alone. A partially purified preparation of rat glomerular basement membrane was also treated with proteolytic enzyme alone or in combination with H2O2. As with the hemoglobin, pretreatment of the glomerular basement membrane with H2O2 increased its susceptibility to subsequent proteolytic attack. In addition, treatment of a basement membrane glycoprotein, fibronectin, with H2O2 also increased its sensitivity to subsequent proteolysis. These results suggest that in addition to their other proinflammatory activities, oxygen-derived metabolites may contribute to tissue destruction by altering the susceptibility of proteins to hydrolytic enzymes.
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PMID:Protein degradation following treatment with hydrogen peroxide. 637 92

The modification of fibrin monomer with H2O2 caused reduction of the association activity of fibrin monomer. The association activity was not reduced even by modification of approx. 16 out of the total 64 tryptophan residues in the fibrin molecule; it was then abolished by further modification of the following several residues. Fragment D obtained by proteolysis of fibrinogen with plasmin, inhibited the association activity of fibrin monomer and the modification of approx. six out of the total 21 tryptophan residues in the fragment led to the complete loss of the inhibitory effect. It was concluded from these studies that about six tryptophan residues in the D-domain of fibrin are important for the association of fibrin monomer.
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PMID:Significance of tryptophan residues in the D-domain of the fibrin molecule in fibrin polymer formation. 644 20

Fibrin thrombi form at sites of injury, where leukocytes release a variety of oxidants. To determine whether oxidants might affect proteins of the fibrinolytic system, we examined the effects of various oxidants on plasmin. Plasmin was not inhibited by micromolar concentrations of hypochlorous acid, chloramine T, or H2O2. Neither Fe nor Cu affected plasmin alone or in the presence of H2O2. However, incubation of plasmin with 5 mumol/L Cu(I or II) in the presence of the reducing agent ascorbic acid resulted in a loss of its hydrolytic activity towards proteins as well as towards small synthetic substrates. The addition of EDTA, but not mannitol, prevented its inactivation. Inactivation was prevented by the addition of catalase and accelerated by hydrogen peroxide. Preincubation of plasmin with the competitive inhibitor alpha-N-acetyl-L-lysine methyl ester prevented inactivation by Cu(II) and ascorbate. These results together suggest site-specific oxidation of plasmin's active site. Treatment of the plasminogen activators tissue plasminogen activator and two-chain urokinase-type plasminogen activator, as well as trypsin, neutrophil elastase, and thrombin with Cu(II) and ascorbate resulted in a loss of their amidolytic and proteolytic activity, indicating the general susceptibility of serine proteases to this type of oxidation. Oxidation of the zymogens Glu-plasminogen and single-chain urokinase-type plasminogen activator by Cu(II) and ascorbate resulted in the failure of these molecules to generate active enzymes when treated with plasminogen activators or plasmin, respectively. The active site His residue may be the target of oxidative inactivation, as evidenced by the partial protection afforded plasmin by the addition of Zn(II), histidine, or the platinum derivative, platinum(II) (2,2':6',2"-terpyridine) chloride. Because platelets contain micromolar concentrations of Cu and leukocytes are rich in ascorbate, Cu-dependent site-specific oxidation might play a role in modulating proteolytic events and the life span of thrombi formed at sites of tissue injury.
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PMID:Oxidative inactivation of plasmin and other serine proteases by copper and ascorbate. 836 3

Activated phagocytes participate in physiological thrombolysis producing non-radical excited oxidants and the important proteases elastase and urokinase. The interaction of oxidized fibrin with the proteases of the fibrinolytic system is therefore physiologically relevant. Here it is shown that human pro-urokinase is activated three- to four-fold faster in the presence of an oxidized solid fibrin matrix. In contrast, oxidized fibrin did not favour the fibrinolytic activity of urokinase or t-PA. Measurement of urokinase antigen showed that urokinase bound slightly to strongly oxidized denatured fibrin, whereas pro-urokinase did not. Plasmin degraded oxidized fibrin more rapidly than non-oxidized fibrin. Thus, singlet molecular oxygen (1O2) converts fibrin to a form that stimulates the activation of plasminogen (bound to oxidized fibrin) by pro-urokinase and that of pro-urokinase by plasmin. The oxidative modification of fibrin by 1O2 is specific. In contrast to oxygen radicals (H2O2 in high concentration) 1O2 does not directly destroy protein chains but favours subsequent fibrinolysis. Thus 1O2 prepares fibrin for its specific degradation.
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PMID:Oxidized fibrin stimulates the activation of pro-urokinase and is the preferential substrate of human plasmin. 845 38

An in vitro model was employed to study the potential role of streptococcal extra-cellular products, rich in streptolysin O, in cellular injury as related to streptococcal infections and post-streptococcal sequelae. Extra-cellular products (EXPA) rich in streptolysin O were isolated from type 4, group A hemolytic streptococci grown in a chemostat, in a synthetic medium. EXPA induced moderate cytopathogenic changes in monkey kidney epithelial cells and in rat heart cells pre-labeled with 3H-arachidonate. However very strong toxic effects were induced when EXP was combined with oxidants (glucose oxides generated H2O2, AAPH-induced peroxyl radical (ROO.), NO generated by sodium nitroprusside) and proteinases (plasmin, trypsin). Cell killing was distinctly synergistic in nature. Cell damage induced by the multi-component cocktails was strongly inhibited either by micromolar amounts of gamma globulin, and Evan's blue which neutralized SLO activity, by tetracycline, trasylol (aprotinin), epsilon amino caproic acid and by soybean trypsin inhibitor, all proteinase inhibitors as well as by a non-penetrating PLA2 inhibitor A. The results suggest that fasciitis, myositis and sepsis resulting from infections with hemolytic streptococci might be caused by a coordinated 'cross-talk' among microbial, leukocyte and additional host-derived pro-inflammatory agents. Since attempts to prolong lives of septic patients by the exclusive administration of single antagonists invariably failed, it is proposed that the administration of 'cocktails' of putative inhibitors against major pro-inflammatory agonizes generated in inflammation and infection might protect against the deleterious effects caused by the biochemical and pharmacological cascades which are known to be activated in sepsis.
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PMID:Gamma globulin, Evan's blue, aprotinin A PLA2 inhibitor, tetracycline and antioxidants protect epithelial cells against damage induced by synergism among streptococcal hemolysins, oxidants and proteinases: relation to the prevention of post-streptococcal sequelae and septic shock. 984 86

The link between oxidation and increased proteolysis in raw milk was studied. To accelerate oxidation, H2O2 (1 mM) was added to raw milk, resulting in enhanced proteolysis by up to 11.2% after 24 h incubation at 5 degrees C. Addition of Cu2+ (10 microM) to milk or exposure of milk to light (60 min) likewise increased proteolysis. To explain the mechanism responsible for increased proteolysis as a result of oxidation, the effect of lipid oxidation products on plasmin-induced proteolysis was tested. Addition of malondialdehyde to skim milk increased the formation of gamma-caseins, a proteolysis product from plasmin hydrolysis of beta-casein. The same observation was made in a model system containing 4.5 g beta-casein/l sodium tetraborate buffer at pH 8 and plasmin. Addition of a plasmin inhibitor blocked the formation of gamma-casein. The results indicate that aldehydes accumulated from lipid oxidation can modify beta-casein and thereby increase susceptibility of the proteins to proteolysis. Furthermore, the data suggest that proteolysis in raw milk may be connected to oxidative processes.
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PMID:The influence of oxidation on proteolysis in raw milk. 1519 Sep 48

Streptococcus pyogenes is an important pathogen that causes pharyngitis, sepsis, and rheumatic fever. Cell-associated streptococcal C5a peptidase (ScpA) protects S. pyogenes from phagocytosis and has been suggested to interrupt host defenses by enzymatically cleaving complement C5a, a major factor in the accumulation of neutrophils at sites of infection. How S. pyogenes recognizes and binds to C5a, however, is unclear. We detected a C5a-binding protein in 8 M urea extracts of S. pyogenes by ligand blotting using biotinylated C5a. Searching of genome databases showed that the C5a-binding protein is identical to the streptococcal plasmin receptor (Plr), also known as streptococcal surface dehydrogenase (SDH) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH). In the present study we identified a novel function of this multifunctional protein. Western blotting and immunofluorescence microscopy with anti-Plr/SDH/GAPDH showed that Plr/SDH/GAPDH is located on the bacterial surface and released into the culture supernatant. Next, we examined whether the streptococcal Plr/SDH/GAPDH inhibits the biological effects of C5a on human neutrophils. We found that soluble Plr/SDH/GAPDH inhibits C5a-activated chemotaxis and H2O2 production. Furthermore, our results suggested that soluble Plr/SDH/GAPDH captures C5a, inhibiting its chemotactic function. Also, cell-associated Plr/SDH/GAPDH and ScpA were both necessary for the cleavage of C5a on the bacterial surface. Together, these results indicate that the multifunctional protein Plr/SDH/GAPDH has additional functions that help S. pyogenes escape detection by the host immune system.
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PMID:Multifunctional glyceraldehyde-3-phosphate dehydrogenase of Streptococcus pyogenes is essential for evasion from neutrophils. 1656 20

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