Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P00750 (PLA)
 16,800 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Neutrophils and macrophages produce, store and release large amounts of various acid and neutral proteinases. The two main proteinases of neutrophils are elastase and cathepsin G. They are localized in the azurophil granules, together with proteinase 3 and the acid cathepsins B and D. In addition neutrophils contain collagenase in the specific granules, acid proteinases in the C-particles and plasminogen activator in organelles with the characteristics of secretory vesicles. The granule-bound proteinases are released during phagocytosis while plasminogen activator is apparently secreted. In macrophages, the acid hydrolases are bound to lysosomes while the neutral proteinases are confined to secretory vesicles. The main mechanism of enzyme release in macrophages is secretion. Lysosomal hydrolases are also released by phagocytosis. Enzyme secretion is a characteristic property of activated or inflammatory macrophages. Macrophages become activated after phagocytosis of certain particles and the metabolic burst appears to be an initial event in the activation process. The action of neutrophils and of purified elastase or plasmin on cartilage was tested. These experiments indicate that neutrophil-mediated degradation of cartilage proteoglycans is largely dependent on elastase.
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PMID:Cellular mechanisms of proteinase release from inflammatory cells and the degradation of extracellular proteins. 39 84

Plasma levels of antithrombin III, alpha 2-macroglobulin and inter-alpha-trypsin inhibitor, as well as those of various clotting, complement and other plasma factors, were significantly decreased in 18 patients suffering from hyperdynamic septic shock. A similar statistically significant reduction of the concentrations of several plasma factors (prothrombin and antithrombin III, plasminogen and alpha 2-plasmin inhibitor, complement factor C3 and clotting factor XIII) was observed in experimental endotoxaemia. In this model the reduction in the plasma levels of these factors was considerably diminished by the intravenous injection of a granulocytic elastase--cathepsin G inhibitor of lower molecular weight from soybeans. The results of both studies indicate that consumption of plasma factors in the course of Gram-negative sepsis proceeds not only via the classical routes (by activation of the clotting, fibrinolytic and complement cascades by system-specific proteinases such as thrombokinase or the plasminogen activator) but also to an appreciable degree of unspecific degradation of plasma factors by neutral proteinases such as elastase and cathepsin G. The endotoxin-induced release of both sorts of proteinases, the system-specific ones and the unspecific lysosomal proteinases from leucocytes and other cells, is likely to be mainly responsible for the consumption of antithrombin III and alpha-2-macroglobulin via complex formation (followed by elimination of the complexes) and the increased turnover of the inter-alpha-trypsin inhibitor as observed in the clinical study. The therapeutic use of an exogenous elastase--cathepsin G inhibitor in the experimental model was stimulated by the observation that human mucous secretions contain and acid-stable inhibitor of the neutral granulocytic proteinases, called HUSI-I or antileucoproteinase. This inhibitor protects mucous membranes and soluble proteins against proteolytic attack by leucocytic proteinases released in the course of a local inflammatory response. Preliminary results indicate that HUSI-I, which is produced by the epithelial cells of mucous membranes, does not belong to any known structural type of acid-stable proteinase inhibitor. The search for other candidates suitable for medication in humans led to the discovery of a potent elastase--cathepsin G inhibitor, called eglin, in the leech Hirudo medicinalis. This acid-stable inhibitor with a molecular weight close to 8100 has an unusual structural property in that the structure of the molecule is not stabilized by any disulphide bridge.
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PMID:Proteinase inhibitors in severe inflammatory processes (septic shock and experimental endotoxaemia): biochemical, pathophysiological and therapeutic aspects. 39 95

There are two types of collagenases, products of two distinct genes, called MMP-1 (matrix metalloproteinase 1 or "fibroblast-type collagenase") and MMP-8 ("neutrophil collagenase"). In synovial fluid, MMP-8 is stored as latent proenzyme in polymorphonuclear neutrophils. MMP-8 is activated by hypochlorous acid produced by myeloperoxidase from hydrogen peroxide and chloride ion and by the hydroxyl radical produced in Haber Weiss reaction fed by superoxide produced by, eg, NADPH (reduced nicotinamide adenine dinucleotide) oxidase and xanthine oxidase. In addition to activation upon secretion, oxidatively modified MMP-8 is susceptible to a subsequent proteolytic attack and activation by cathepsin G. The authors suggest that activation of neutrophil-derived MMP-8 involves oxidative, nonproteolytic activation upon secretion and a more slowly progressive proteolytic activation by cathepsin G (or chymases and tryptases), and that these oxidative and proteolytic activation mechanisms act in concert. In contrast to MMP-8, MMP-1 is synthesized de novo and secreted immediately after synthesis by fibroblasts, macrophages, and some epithelial cells. Human rheumatoid synovial tissue contains mainly fibroblast-type MMP-1 collagenase as assessed by collagenase extracted from synovial tissue and by MMP-1 and MMP-8 immunostaining. It is suggested that in vivo, MMP-1 in synovitis tissue is activated by a plasminogen activator/plasminogen/prostromelysin (alternatively tryptases)/proMMP-1 cascade. In conclusion, MMP-8 and MMP-1 show type-specific compartmentalization and modes of activation in rheumatoid synovial fluid and tissue.
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PMID:Collagenase in synovitis of rheumatoid arthritis. 141 81

Leukocyte elastase and leukocyte cathepsin G degrade porcine plasminogen primarily by hydrolysis of the A447-I448 bond between kringle4 and kringle5. The rate of formation of des-kringle1-4-plasminogen is faster with elastase (k"obs greater than 10(5) mol-1 s-1) than with cathepsin G (kobs less than 300 mol-1 s-1). In contrast to elastase, leukocyte cathepsin G does not inactivate alpha 2-antiplasmin. Consequently, plasminogen activation by urokinase in the presence of alpha 2-antiplasmin is elastase-dependent, but cathepsin G does not overcome the action of alpha 2-antiplasmin. The rate-enhancing effect of fibrin(ogen) fragments in plasminogen activation by tissue-type plasminogen activator is also disabled efficiently by these proteases. It is concluded that enhancement of plasmin expression by neutrophil proteases is accounted for primarily by the action of elastase.
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PMID:Neutrophil proteases in plasminogen activation. 171 63

To identify the relationship of the severity of inflammation and fibrinolytic activity in arthritis, the fibrinolytic activity of synovial fluid was studied in acute experimental arthritis induced by injecting monosodium urate crystals into dogs' knee joints. The maximum activity in the synovial fluid was observed 6 h after crystal injection. It was inferred that the fibrinolytic activity was mainly due to plasminogen activator based on fibrin plate assays, substrate specificity, inhibitor effects and zymography. On the other hand, the activity of lysosomal enzymes (beta-glucuronidase and cathepsin G) reached a peak in the synovia after 12 h. Histological examination of the synovial membrane after 12 h also showed greater inflammation than at 6 h. The peak in fibrinolytic activity preceded the peak of lysosomal enzymes and histological changes. These results suggest that an increase in fibrinolytic activity by plasminogen activator may contribute to the development of an acute inflammatory response.
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PMID:Activated fibrinolytic enzymes in the synovial fluid during acute arthritis induced by urate crystal injection in dogs. 178 32

The purpose of these studies was to identify some of the extracellular proteolytic enzymes associated with the development and healing of acute inflammatory lesions. Lesions were produced in the skin of rabbits by the topical application of the military vesicant, sulfur mustard (SM). Full-thickness, 1-cm2 central biopsies of the lesions were organ-cultured for one to three days, and the culture fluids were assayed for proteases with a variety of substrates. When compared to culture fluids from normal skin, the culture fluids from both developing and healing SM lesions had three to six times the levels of proteases hydrolyzing two synthetic peptide substrates: (1) t-butyloxycarbonyl-Leu-Gly-Arg-4-trifluoromethylcoumarin-7-amide(Boc-Leu -Gly- Arg-AFC, herein abbreviated LGA-AFC), and (2) N-benzoyl-phenylalanine-beta-naphthyl ester (BPN). LGA-AFC is a substrate for trypsin, plasmin, plasminogen activator, thrombin, kallikrein, and the C3 and C5 convertases; BPN is a chymotrypsin and cathepsin G substrate. The culture fluids did not consistently hydrolyze four other synthetic peptide substrates or the proteins [14C]-casein and [14C]elastin. In order to determine the likely sources of LGA-AFCase and BPNase activity, we counted the number of granulocytes (PMNs), macrophages (MNs) and activated fibroblasts in histologic sections of developing and healing SM lesions, and we measured the levels of these enzymes in serum, in culture fluids of PMN and MN peritoneal exudate cells, and in culture fluids of two fibroblast cell lines. In SM lesions, serum and fibroblasts seemed to be the major source of LGA-AFCase, and serum alone the major source of BPNase. Tissue PMNs and MNs seemed to be only minor sources. The crusts of healing lesions, which were full of dead PMNs, seemed to be a rich source of both enzymes. In the SM lesion culture fluids, whether LGA-AFC and BPN were hydrolyzed by endopeptidases or only by exopeptidases could be determined by evaluating complex formation with alpha-macroglobulin proteinase inhibitors (alpha M). Endopeptidases, but not exopeptidases, are entrapped and inhibited by alpha M, because an internal peptide band in alpha M must first be hydrolyzed before molecular rearrangement (required for proteinase inhibition) occurs. The catalytic site of endopeptidases that are entrapped and inhibited by alpha M is known to remain active on (and reachable by) small synthetic peptide substrates such as LGA-AFC and BPN.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Proteases released in organ culture by acute dermal inflammatory lesions produced in vivo in rabbit skin by sulfur mustard: hydrolysis of synthetic peptide substrates for trypsin-like and chymotrypsin-like enzymes. 304 42

The proteolytic activities of human tumor cell lines deriving from bronchial squamous cell carcinoma, a lung metastasis of an embryonal rhabdomyosarcoma and a pleural mesothelioma were measured by use of chromogenic substrates. N-acetyl-alanine aminopeptidase activity, plasminogen activator activity, H-D-Ile-Pro-Arg-p-NA splitting activity as well as plasmin-like activity, cathepsin G-like activity and plasma-kallikrein-like activity were found in cell lysates. The enzymatic activity of N-acetyl-alanine aminopeptidase, plasminogen activator and H-D-Ile-Pro-Arg-p-NA splitting activity changed during culturing. Plasminogen activator and H-D-Ile-Pro-Arg-p-NA splitting activity decreased to very low values, whereas N-acetyl-alanine aminopeptidase activity leveled at 1 x 10(-5) mU/cell. Unlike other proteolytic activities, plasminogen activator was released into the medium. Plasminogen activator activity could be measured in culture medium which contained no fetal calf serum.
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PMID:Proteolytic activity of human tumor cell lines deriving from bronchial squamous cell carcinoma, pulmonary metastasis of rhabdomyosarcoma and pleural metastasis of mesothelioma. 332 2

A highly active angiotensin-producing enzyme (enzyme II) was obtained from dog serum by acid treatment and fractionation to remove angiotensinase and converting enzyme, separate an inhibitor, and convert an inactive precursor (proenzyme II) to enzyme II. Proenzyme II was found to be converted to enzyme II by an endogenous activating enzyme identified as plasmin. Conversion was also caused by the interaction of bacterial streptokinase with human proactivator, by trypsin, and by an activator formed from liver tissue extract and dog serum. Neither plasma kallikrein nor the labile, human extrinsic tissue-type plasminogen activator induced activation. The inhibitor, which normally blocks the activation of proenzyme II, was unusually stable against high temperatures and extremes of pH, and it was not identical to any of the six known protease inhibitors of serum. Enzyme II was not identical to other angiotensin-producing enzymes such as enzyme I, renin, cathepsin D, pepsin, plasmin, tonin, or cathepsin G. Enzyme II reacted maximally at pH 4.7 and produced up to 2250 ng of angiotensin I/ml serum/hr from the substrate of dog serum (i.e., amounts 3200-fold higher than that produced by endogenous renin of normal dog serum). Since at pH 7.2, angiotensin I formation is still about 30 times higher than that of renin, enzyme II may be physiologically active under some conditions.
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PMID:Angiotensin-producing serum enzyme II. Formation by inhibitor removal and proenzyme activation. 390 15

The proteolytic activity in homogenates and extracts of subcellular fractions prepared from subcutaneous Lewis lung carcinoma was determined using proteins and synthetic peptides as substrates. The presence of cathepsin D, plasminogen activator, cathepsin B-, cathepsin G- and elastase-like enzymes was observed. No difference was revealed between the proteolytic activity in homogenates of Lewis lung carcinoma, at the growth stage examined, and in homogenates of normal lung. High specific activities were found in the lysosomal extract, whereas decreasing activities were found in the nuclear extract, the homogenate and the postlysosomal mitochondrial supernatant; no active or trypsin-activatable collagenase activity was detected. The presence in the tumor tissue of these enzymatic activities is in agreement with their proposed role in the process of metastasis. The lack of differences between homogenates of tumor and normal lung tissue suggests that the use of whole cells is required to selectively study tumor proteinases specifically involved in tumor malignancy.
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PMID:Methodologic problems encountered in the assay of proteinases in Lewis lung carcinoma, a mouse metastasizing tumor. 629 35

Preparative isoelectrofocusing used for fractionating the whole human granulocyte lysate serine proteinases revealed multiple forms of elastase, cathepsin G, kininogenase, human granulocytes plasminogen activator (pI 6.2-10.75). Kinetic characteristics of their substrate specificity were also obtained. It is shown that serine kininogenase of human granulocytes is not identical with elastase as it had been supposed before, it is of trypsin-like nature and is identical with plasminogen activator of these cells. The results obtained reveal new aspects in comprehension of the role of the granulocyte plasminogen activator in development of the inflammatory reaction. It is found that acid-stable proteinase inhibitors formed from blood plasma inter-alpha-inhibitor of trypsin, have an inhibitory effect on the granulocyte plasminogen activator, that supports an assumption on the anti-inflammatory function of these inhibitors.
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PMID:[Identity of human granulocyte kininogenase and plasminogen activator]. 634 22


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