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)

We investigated the effect of ulinastatin, a candidate anti-osteoarthritic drug, in comparison with indomethacin and triamcinolone, two well-known drugs for osteoarthritis, on IL-1 production by monocytes, proteoglycan synthesis by chondrocytes and superoxide generation by leukocytes. Ulinastatin, a glycoprotein purified from human urine, suppressed both the IL-1 production and the IL-1 induced reduction of proteoglycan synthesis. In addition, ulinastatin inhibited superoxide generation. These actions of ulinastatin seemed to be related to its inhibitory actions against serine proteases such as trypsin, alpha-chymotrypsin, plasmin, leukocyte elastase and leukocyte cathepsin G. Triamcinolone suppressed the IL-1 production more potently than ulinastatin and it also suppressed the IL-1 induced reduction of proteoglycan synthesis. Triamcinolone alone, however, reduced the proteoglycan synthesis, and it did not affect the superoxide generation. In contrast, indomethacin had no effect on proteoglycan synthesis and superoxide generation, although it accelerated the IL-1 production. These results indicate that these three drugs have different mechanisms of action on the factors involved in the pathogenesis of osteoarthritis. Since ulinastatin has broad actions, which are considered to be beneficial for preventing some process of osteoarthritic pathogenesis, ulinastatin is expected to be an useful drug for the treatment of osteoarthritis.
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PMID:[Mechanism of the anti-osteoarthritic action of ulinastatin in comparison with those of indomethacin and triamcinolone]. 131 79

The plasminogen activator (PA)/plasmin system has been implicated in the inflammation and connective tissue remodelling occurring in arthritic joints. PA activity is detected in cultures of human monocytes, synoviocytes and chondrocytes and can be regulated by a variety of cytokines found in diseased joints; PA inhibitors (PAI-1 and/or PAI-2) are also produced by these cells. We have shown that human monocytes can synthesize both urokinase-type PA (u-PA) and tissue-type PA (t-PA). One cytokine present in rheumatoid synovial fluids, granulocyte macrophage colony stimulating factor (GM-CSF), stimulates monocyte u-PA production; since this cytokine can also be produced by activated monocytes and other cell types in joints, than a "CSF network" can be produced leading to u-PA production. Another monocyte cytokine, interleukin 1, causes human synoviocytes to increase their u-PA expression, a response which can be dependent on the presence of endogenous cyclooxygenase products; this cytokine also causes human chondrocytes and cartilage tissue to produce increased u-PA and t-PA activity, i.e., under conditions during which cartilage is resorbed.
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PMID:Regulation of plasminogen activator activity in arthritic joints. 190 74

1. The interaction between interleukin 1 (IL-1) and the fibrinolytic system in the control of collagen degradation by rabbit chondrocytes has been investigated in a tissue-culture system where cells are grown on a 14C-labelled collagen matrix. 2. Culture of rabbit chondrocytes in the presence of human recombinant IL-1 beta at a concentration of 57pM for 48 h led to the presence of procollagenase but not active collagenase in the medium. The latent collagenase could be activated by incubation with an organomercurial, aminophenylmercuric acetate (APMA). 3. Addition of IL-1 beta to chondrocytes grown on a 14C-labelled collagen matrix did not increase the degradation of the matrix compared to control over a 48 h period. However, in the presence of plasmin (200 micrograms ml-1) or plasminogen (100 micrograms ml-1), IL-1 beta (57 pM) caused almost complete degradation of the collagen matrix. Plasmin or plasminogen alone caused only slight degradation of the collagen matrix. 4. Tissue inhibitor of metalloproteinases (TIMP) or the selective metalloproteinase inhibitor, SC44463, inhibited the degradation induced by IL-1 beta and plasminogen in a concentration-related manner and at concentrations that were correlated with inhibition of collagenase. 5. When concentrations of IL-1 beta which caused only minimal degradation of the matrix in the presence of plasminogen were combined with fibrin (1 microgram ml-1), there was almost total degradation of the matrix by 48 h. 6. These results indicate there is a synergistic interaction between IL-1 and the fibrinolytic system in the degradation of collagen by rabbit chondrocytes in culture.
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PMID:Co-operation between interleukin-1 and the fibrinolytic system in the degradation of collagen by articular chondrocytes. 216 39

The human alveolar macrophage product, enzyme-releasing peptide (ERP), has a molecular mass of 8,000 Da, and releases azurophilic and specific granule constituents from neutrophils. A murine monoclonal anti-ERP antibody (12E10H), previously used to show a lack of antigenic identity between ERP and C5a, interleukin 1, tumor necrosis factor, and gamma-interferon, showed no cross-reactivity with interleukin 8. 12E10H and a fluorescein-labeled second antibody were used to visualize ERP on the macrophage surface. ERP was removed from alveolar macrophages by a 3-min incubation with 5 X 10(-7) M bovine pancreatic trypsin at 37 degrees C. The washed trypsinized cells could readhere to plastic and exclude trypan blue. Dilution of the trypsin-derived ERP released myeloperoxidase from cytochalasin-B-treated neutrophils dose dependently. The enzyme-releasing ability of the trypsin-derived material was removed by immunoprecipitation using antibody 12E10H bound to Staphylococcal protein A Sepharose 4B. The estimated molecular mass of the trypsin-derived ERP (by molecular sieve chromatography on HPLC) was approximately 8,500 Da. Other proteases (plasmin, thrombin, and cathepsin G) also released ERP from the cell surface, but the ERP was not an active secretagogue for neutrophils. However, macrophages cultured with protease inhibitors did not show decreased ERP accumulation in the medium. Our data indicate that ERP exists on the surface of human alveolar macrophages and can be released by proteases found within the lung environment in some disease states.
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PMID:Liberation of a neutrophil enzyme-releasing peptide from the surface of human alveolar macrophages. 236 Jun 46

Human monocytes cultured in monolayer for 6 days were found to secrete a factor that suppressed the T cell proliferative response to soluble Ag and to alloantigens. The elaboration of this monocyte suppressor factor (MSF) was not inhibited by indomethacin. It has an apparent Mr of 50 to 60 kDa. It does not inhibit soluble IL-1 in the murine thymocyte costimulator assay but does inhibit the activity of membrane bound IL-1, which we observed to be almost exclusively IL-1 alpha. MSF contains elevated amounts of plasminogen activator inhibitor (PAI) when measured either as bioactivity or in an ELISA. Its immunosuppressive properties are inhibited by anti-PAI antibody. Furthermore, the eluate but not the effluent of an anti-PAI immunoabsorbent column contains all of the immunosuppressive activity. Based on these data we suggest that MSF is, in fact, PAI and postulate that the mechanism of action is inhibition of the plasmin cascade, thereby preventing the release of membrane bound IL-1. This suggests that monocytes possess an autoregulatory circuit that may have implications for the kinetics of the inflammatory response.
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PMID:Monocyte suppressor factor is plasminogen activator inhibitor inhibition of membrane bound but not soluble IL-1. 252 89

The interstitial collagens are degraded predominantly extracellularly, by specific collagenases (metalloproteinases) capable of cleaving the helical region across the three chains at a similar locus, solubilizing the cleaved products from the fibril. Other neutral proteinases may also function in this role by cleaving near cross-links in the fibril. Collagen type, molecular aggregation and small changes in temperature all markedly affect rates of collagenolysis in the fibril. Regulation of collagenolysis is also modulated at the levels of (1) cellular production of latent collagenase (procollagenase), (2) activation of latent collagenase, and (3) production of collagenase inhibitors. Fibroblastic cells and certain macrophages are probably the predominant sources of collagenases in inflammation; an enzyme in polymorphonuclear leucocytes (neutrophils) is distinct from the tissue enzyme. Molecules such as mononuclear cell factor (MCF), homologous with interleukin 1, which augment cellular collagenase production in inflammation, are derived from monocytes. The mechanisms of augmented collagenase production involve new protein synthesis and, if this augmentation is analogous to that produced by urate crystals, it is probably associated with increased levels of procollagenase mRNA. MCF production is itself controlled by products of lymphocytes as well as by interactions of monocytes with the Fc portion of immunoglobulins and components of the extracellular matrix. Activation of latent (pro)collagenase probably occurs in vivo through the action of neutral proteinases such as plasmin (through plasminogen activator). These effects may be indirect and exerted through proteolytic activation of a procollagenase activator. Tissue inhibitors act to regulate the active collagenase.
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PMID:The turnover and degradation of collagen. 299 13

Agents such as retinol, interleukin 1 and catabolin stimulate resorption of cultured cartilage. This process seems to be mediated by chondrocytes, but the mechanism by which breakdown occurs remains unknown. We have found that (10(-6)-10(-8) M) retinoic acid and (1 X 10(-6) M) retinol, in the presence or absence of a factor derived from cultured synovium (synovial factor), stimulate the degradation of fibrin by human chondrocytes in culture. Plasminogen was required for the enhancement of fibrinolysis, suggesting that the breakdown depended upon the production of plasminogen activators and subsequent liberation of plasmin. However, the chondrocytes did not release significant amounts of plasminogen activator, and the effects of the synovial factor and retinoids resulted from augmentation of the production or activity of enzymes which remained bound to the cell layer. The role of plasminogen in the resorption of cultured cartilage was also investigated. In the presence of plasminogen, (1 X 10(-8) M) retinoic acid or synovial factor stimulated the breakdown of cultured bovine nasal cartilage, but in the absence of plasminogen, the effect of synovial factor was abolished and that of retinoic acid reduced. However, in cultures containing both retinoic acid and synovial factor the resorption process was not affected by removal of plasminogen. Thus, the resorption of cartilage matrix in vitro may be partially mediated by plasminogen activators and plasmin.
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PMID:Retinoids and synovial factor(s) stimulate the production of plasminogen activator by cultured human chondrocytes. A possible role for plasminogen activator in the resorption of cartilage in vitro. 391 88

Although studies with interleukin-1 receptor antagonist (IL-1ra) in animal models have shown that IL-1 contributes to mortality in sepsis, the mechanisms whereby IL-1 mediates lethal effects are not well established. A possible mechanism is that IL-1 enhances the activation and release of other inflammatory mediator systems such as coagulation, fibrinolysis, neutrophils, and secretory-type phospholipase A2 (sPLA2). We investigated this possibility by assessing the effect of intravenously injected recombinant human IL-1 alpha (rhIL-1 alpha) on these plasma parameters in baboons. In addition, we examined the course of these inflammatory parameters in baboons after a challenge with a lethal dose of Escherichia coli and while receiving a 24-hour constant infusion of IL-1ra or placebo. Intravenous administration of IL-1 alpha (10 micrograms/kg) induced the formation of thrombin, as evidenced by the appearance of thrombin-antithrombin III (TAT) complexes into the circulation (peak levels, 188 +/- 92 ng/mL at 2 hours), as well as the activation of fibrinolysis, assessed by circulating plasmin-alpha 2-antiplasmin complexes (PAP complexes; peak levels, 0.4% +/- 0.03% of fully activated plasma at 1 hour), the release of tissue-type plasminogen activator (t-PA; peak levels, 6 +/- 2 ng/mL at 2 hours), and its inhibitor, plasminogen activator inhibitor (PAI; peak levels, 724 +/- 246 ng/mL at 4 hours). Il-1 alpha administration also induced the release of sPLA2 (maximal levels, 336 +/- 185 ng/mL at 8 hours), but not degranulation of neutrophils. In the septic baboons, a significant reduction of the formation of thrombin (peak TAT levels decreased from 582 +/- 78 ng/mL to 219 +/- 106 ng/mL; P < .005), the release of t-PA (peak levels decreased from 37 +/- 11 ng/mL to 17 +/- 2 ng/mL; P < .001), and its inhibitor, PAI (peak levels decreased from 2,639 +/- 974 ng/mL to 1,110 +/- 153 ng/mL; P <.001), was observed in the group receiving IL-1ra compared to that receiving placebo. The release of neutrophilic elastase was also significantly attenuated in IL-1a-treated animals (peak levels, 1,024 +/- 393 and 655 +/- 104 ng/mL in control and treatment groups, respectively; P < .05). The difference between sPLA2 levels in both groups, although higher in the controls (maximal levels, 3,140 +/- 1,435 ng/mL in control v 2,217 +/- 1,375 ng/mL in IL-1ra-treated group), was not significant. Thus, IL-1 contributes to activation of various other mediator systems in severe sepsis in nonhuman primates. We propose that these effects may explain the lethal actions of IL-1 in this sepsis model and suggest a similar role for IL-1 in severe human sepsis.
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PMID:Contribution of interleukin-1 to activation of coagulation and fibrinolysis, neutrophil degranulation, and the release of secretory-type phospholipase A2 in sepsis: studies in nonhuman primates after interleukin-1 alpha administration and during lethal bacteremia. 762 Jan 56

Pentoxifylline (oxpentifylline) is a methylxanthine derivative with potent hemorrheologic properties. In the United States it is marketed for the treatment of intermittent claudication. Human and animal studies have shown that pentoxifylline therapy results in a variety of physiological changes at the cellular level, which may be important in treating a diverse group of human afflictions. Immune modulation includes increased leukocyte deformability and chemotaxis, decreased endothelial leukocyte adhesion, decreased neutrophil degranulation and release of superoxides, decreased production of monocyte-derived tumor necrosis factor, decreased leukocyte responsiveness to interleukin 1 and tumor necrosis factor, inhibition of T and B lymphocyte activation, and decreased natural killer cell activity. Hypercoagulable states improve through decreased platelet aggregation and adhesion, increased plasminogen activator, increased plasmin, increased antithrombin III, decreased fibrinogen, decreased alpha 2-antiplasmin, decreased alpha 1-antitrypsin, and decreased alpha 2-macroglobulin. Wound healing and connective tissue disorders may respond to an increase in fibroblast collagenases and decreased collagen, fibronectin, and glycosaminoglycan production. Fibroblast responsiveness to tumor necrosis factor is also diminished. Potential medical uses of pentoxifylline are reviewed.
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PMID:Pentoxifylline. 860 73

Cartilage degradation is mediated by activated matrix metalloproteinases (MMP). Since the plasmin/plasminogen cascade may activate latent MMP during cartilage catabolism, we determined if protease nexin-1 (PN-1), an inhibitor of plasminogen, plasmin, and urokinase could prevent cartilage degradation. Using a rabbit model, we induced cartilage glycosaminoglycan (GAG) loss by intraarticular (IA) injection of IL-1 beta and bFGF. PN-1 was given IA for 4 days, once before IL-1 beta/bFGF and daily for 3 days. Three days after IL-1 beta/bFGF, we determined GAG loss. PN-1 significantly inhibited GAG loss at 2.8, 2.5 mg, and 2.0 mg/knee (p < 0.03). These data suggest the role of the plasmin/plasminogen enzymatic cascade in the cartilage catabolism that occurs during IL-1-induced inflammation and demonstrates the potential of PN-1 to prevent cartilage degradation.
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PMID:Recombinant human protease nexin-1 prevents articular cartilage-degradation in the rabbit. 838 2

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