Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0027651 (tumor)
685,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

When human granulocytes were stimulated with the chemotactic peptide FNLPNTL (N-formyl-norleucyl-leucyl-phenylalanyl-norleucyl-tyrosinyl- lysin; in the presence of cytochalasin B), proteolytic enzymes were released which prevented activation of tumor-cell derived pro-uPA by plasmin. Elastase was identified by use of eglin C (elastase inhibitor) and an inhibitory monoclonal antibody to elastase as the functional proteolytic enzyme in these granulocyte supernatants. Purified human granulocyte elastase cleaves pro-uPA at amino acid position lle159-lle160 thus generating an enzymatically inactive two-chain form of uPA, as judged by N-terminal amino acid sequence analysis. An additional minor elastase-mediated cleavage site was detected at position Thr165-Thr166. This form of uPA was indistinguishable by SDS-PAGE from plasmin-generated enzymatically active HMW-uPA. Action of plasmin on the proenzyme form of uPA (pro-uPA) generates an enzymatically active uPA-molecule (high molecular weight form; HMW-uPA) which is cleaved at amino acid position Lys158-lle159 (Mr = 33,000 (B-chain) and 22,000 (A-chain). Thus elastase cannot substitute for plasmin in the proteolytic activation of pro-uPA to enzymatically active HMW-uPA. Enzymatically active HMW-uPA, however, was not affected by elastase. Elastase-containing granulocytes were identified by immunohistochemical staining of elastase in breast cancer tissue. Granulocytes were located close to the tumor cells and also in the tumor stroma surrounding the tumor nests. These tumor cells contain pro-uPA. Evidently, the conversion of tumor cell pro-uPA into enzymatically active HMW-uPA is controlled by elastase released from granulocytes into the tumor tissue.
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PMID:Human tumor cell urokinase-type plasminogen activator (uPA): degradation of the proenzyme form (pro-uPA) by granulocyte elastase prevents subsequent activation by plasmin. 183 19

The occurrence and distribution of components of fibrinolysis pathways were determined using immunohistochemical techniques applied to 10 cases of primary carcinoma of the breast, normal breast tissue obtained from two patients undergoing reductive mammoplasty, and three cases of benign breast tumors. Tumor cells stained for urokinase- and tissue-type plasminogen activators, plasminogen activation inhibitor-1, plasminogen, and plasmin-antiplasmin complex neoantigen. The tumor connective tissue stained for fibrinogen and its D fragment plasmin digestion product. By contrast, only occasional nonneoplastic duct epithelial cells stained for urokinase- and tissue-type plasminogen activators and there was little or no staining for the other antigens tested. These results are consistent with the existence of local amplification of expression of enzymatically active plasminogen activators, and particularly of urokinase-type plasminogen activator, in situ in primary breast cancer tissue. These features distinguish malignant from benign breast tissue and may modulate neoplastic progression through an effect on tumor cell proliferation, invasion, and metastatic dissemination.
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PMID:Occurrence of components of fibrinolysis pathways in situ in neoplastic and nonneoplastic human breast tissue. 184 11

Action of purified human cathepsin B on recombinant single-chain urokinase-type plasminogen activator (pro-uPA) generated enzymatically active two-chain uPA (HMW-uPA), which was indistinguishable by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blot from plasmin-generated HMW-uPA and from elastase- or thrombin-generated inactive two-chain urokinase-type plasminogen activator. Preincubation of cathepsin B with E-64 (transepoxysuccinyl-L-leucylamino- (4-guanidino)butane, a potent inhibitor for cathepsin B) prior to the addition of pro-uPA prevented the activation of pro-uPA. The cleavage site within the cathepsin B-treated urokinase-type plasminogen activator (uPA) molecule, determined by N-terminal amino acid sequence analysis, is located between Lys158 and Ile159. Pro-uPA is cleaved by cathepsin B at the same peptide bond that is cleaved by plasmin or kallikrein. Binding of cathepsin B-activated pro-uPA to the uPA receptor on U937 cells did not differ from that of enzymatically inactive pro-uPA, indicating an intact receptor-binding region within the growth factor-like domain of the cathepsin B-treated uPA molecule. Not only soluble but also tumor cell receptor-bound pro-uPA could be efficiently cleaved by cathepsin B to generate enzymatically active two-chain uPA. Thus, cathepsin B can substitute for plasmin in the proteolytic activation of pro-uPA to enzymatically active HMW-uPA. In contrast, no significant activation of pro-uPA by cathepsin D was observed. As tumor cells may produce both pro-uPA and cathepsin B, implications for the activation of tumor cell-derived pro-uPA by cellular proteases may be considered.
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PMID:Cathepsin B efficiently activates the soluble and the tumor cell receptor-bound form of the proenzyme urokinase-type plasminogen activator (Pro-uPA). 190 May 15

Endothelial cells play a critical role in thromboregulation by controlling the assembly of fibrinolytic constituents on the membrane. The assembly system illustrated in FIGURE 6 is characterized by the binding of circulating glu-plasminogen to a membrane receptor (Pathway 1). A membrane-associated protease (possibly plasmin) converts the inactive zymogen into a catalytically more efficient zymogen lys-plasminogen (Pathway 2). T-PA binds to a specific receptor, retains its catalytic activity, and is protected from its natural inhibitor PAI-1. The membrane provides a favorable environment for plasmin generation (Pathway 3) at the vessel surface and contributes to the maintenance of a physiological nonthrombogenic state. The immobilization and surface activation of plasminogen provides an important mechanism for localizing proteolytic activity at the surface of other cells such as macrophages and tumor cells. Lp(a), a plasminogen-like lipoprotein, by competing at the endothelial surface for plasminogen binding down-regulates endothelial cell plasmin generation and may thus promote localized thrombogenesis that over a period of time contributes to progressive atherosclerosis.
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PMID:Endothelial cell fibrinolytic assembly. 190 39

The authors report on the influence of plasminogen activators (PA) on implantation of TA3Ha mammary tumor cells in the healing hepatic wounds of syngeneic strain A mice. Intravenously injected TA3Ha cells, although they rarely metastasize to the liver, formed tumors in the hepatic wounds of a significant percent (42%, P less than 0.0001) of mice. The frequency of tumor formation declined as the interval between surgery and tumor cell inoculation was increased. Furthermore, preexposure of cells to fibrinogen, fibronectin, laminin, or peptides containing the arginine-glycine-aspartic acid-serine residues dramatically reduced the frequency of tumor formation in the hepatic wounds. These results indicate that TA3Ha cells interact with fibrinogen-related proteins in the wound to aid their attachment and growth. Because these proteins are susceptible to digestion by plasmin, PA were used in this study to examine whether administration of these drugs to the mice would modulate tumor formation in the liver wounds. Among the PA tested, human plasmin B-chain-streptokinase complex (B-SK) and recombinant tissue plasminogen activator (t-PA) inhibited tumor implantation in a dose-related manner. Administration of 900 units (U) of B-SK or 3300 U of t-PA per mouse reduced the frequency of tumor formation from 42% to 0% (P = 0.02) and 11% (P = 0.02), respectively. The B-SK was complexed with p-nitrophenyl-p-guanidinobenzoate; it did not activate the plasminogen or inhibit tumor formation in the hepatic wounds. Although urokinase activated the plasminogen, it did not inhibit tumor implantation in the hepatic wound. Heparin, an anticoagulant that prevents conversion of fibrinogen to fibrin without being fibrinolytic, had no influence on tumor formation in the hepatic wounds. The PA can generate plasmin that digests the cell attachment proteins in wounds and consequently inhibits tumor cell attachment.
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PMID:Inhibition of tumor implantation at sites of trauma by plasminogen activators. 191 15

Neoplastic growth and metastatic spread of adenocarcinomas is characterized by a marked increase of urokinase-type plasminogen activator (u-PA) and a decrease of tissue-type plasminogen activator (t-PA). In this study, the authors determined the activity and antigen levels of u-PA and t-PA, and their inhibitors, plasminogen-activator inhibitors types 1 and 2 (PAI-1 and PAI-2), in normal mucosa, adenomatous polyps, and adenocarcinomas of the human colon. The decrease in t-PA activity in the neoplastic tissues, determined enzymatically and zymographically, was significantly correlated with an increase in PAI-1 and PAI-2, in particular in carcinomas. In spite of significantly higher inhibitor levels in the neoplastic tissues, u-PA was found to be increased as well, both in antigen level and in activity. The authors conclude that PAI-1 and PAI-2 are significantly increased in neoplastic tissue of the human colon and contribute considerably to the decrease of t-PA activity in carcinomas. However, the malignancy-associated increase in u-PA seems not to be affected by the plasminogen activator inhibitors. Thus, it appears that there is an imbalance between plasminogen activators and their inhibitors in colonic neoplasia in favor of u-PA, which may contribute to plasmin-mediated growth, invasiveness, and metastasis. This feature was also noticed in adenomatous polyps, supporting the malignant potency of adenomas.
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PMID:Imbalance of plasminogen activators and their inhibitors in human colorectal neoplasia. Implications of urokinase in colorectal carcinogenesis. 195 18

Implantation and subsequent placental development in many species including the human are dependent on trophoblast invasion of the uterine epithelium, the underlying basement membrane, connective tissue and blood vessels. However, trophoblast invasion in situ is strictly controlled by the microenvironment provided by the pregnant uterus. Key mechanisms underlying various steps in trophoblast invasion of basement membrane and stroma are similar to those identified in the case of invasive tumor cells: (a) attachment to basement membrane by binding to laminin and possibly other basement membrane components; (b) detachment from the basement membrane matrix prior to its penetration, a process that requires the presence of complex-type oligosaccharides on the cell surface; (c) breakdown of basement membrane components by trophoblast-derived metalloproteases (type IV and interstitial collagenase) and serine proteases (plasminogen activator). Type IV collagenase activity is stimulated by binding to laminin, a molecule also secreted by the trophoblast. Activation of trophoblast-derived metalloproteases appears to be plasmin-dependent. Plasmin results from the cleavage of plasminogen by trophoblast-derived plasminogen activator. Control of trophoblast invasion in situ is mediated by decidua-derived transforming growth factor beta (TGF beta) which in turn induces tissue inhibitor of metalloproteases (TIMP) both in the decidua and the trophoblast. We suggest that this control of trophoblast invasiveness is regulated both spatially as well as temporally during gestation. A preprogrammed decline in trophoblast invasiveness with increasing gestational age remains an additional possibility. The nature of the loss of control of trophoblast invasiveness in choriocarcinoma remains to be identified. Refractoriness to TGF beta action remains to strong possibility.
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PMID:Mechanisms of trophoblast invasiveness and their control: the role of proteases and protease inhibitors. 209 85

Supernatant obtained from granulocytes stimulated in the presence of cytochalasin B by the chemotactic peptide N-formyl-norleucyl-leucyl-phenylalanyl-norleucyl-tyrosyl- lysine displayed an inhibitory effect on the plasmin-dependent conversion of tumor urokinase-type plasminogen activator proenzyme (pro-uPA) to the active form of uPA. Moreover, the supernatant was also found to inhibit the fibrinolytic activity of human vulva (A431) and breast (MCF7) carcinoma cell lines, which contain large amounts of pro-uPA, by 87% and 96%, respectively. By using eglin C (elastase inhibitor) and a monoclonal antibody to elastase (proteolytic activity blocker of the enzyme), elastase was identified as the key enzyme of the supernatant in these phenomena. Purified elastase converted pro-uPA to an enzymatically inactive molecule composed of two polypeptide chains of Mr = 33,000 and 22,000 linked to each other by a disulfide bond. Elastase-containing granulocytes were identified by immunohistochemistry techniques in the tissues of squamous cell carcinoma and adenocarcinoma of uterus. The cells were found close to the tumor cells and in the stroma surrounding the tumor nests. By immunohistochemical staining, uPA was also found in the tumor cells. Evidently, elastase released by chemotactically activated granulocytes, which are attracted into tumor tissues, may inhibit the conversion of pro-uPA to enzymatically active uPA in the tumor cells.
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PMID:Inactivation of human tumor cell pro-urokinase by granulocyte elastase. 212 85

The correlation between urokinase-type plasminogen activator (uPA) expression and tumor cell invasion and metastasis has been well documented. Urokinase converts the zymogen plasminogen to plasmin, a trypsin-like enzyme with broad substrate specificities. Net uPA activity is determined not only by the amount of the enzyme itself, but also by its state of activation and the amount of specific plasminogen activator inhibitors (PAIs) present. Both uPA and its substrate, plasminogen, can bind to cells via specific membrane-associated receptors. Expression of uPA, uPA receptor (uPAR), and PAIs is regulated by growth factors, oncogenes, and other effector molecules. In the present review we discuss the interactions of uPA with its receptor, inhibitors, and substrate and how these interactions influence malignant behavior. We also review recent reports in which investigators have used anti-catalytic antibodies and/or gene transfection to demonstrate that uPA is directly involved in tumor cell invasion and metastasis.
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PMID:The role of urokinase-type plasminogen activator in aggressive tumor cell behavior. 212 23

Recombinant class 2 plasminogen activator inhibitor (PAI-2) was used in an approach to probe the formation and location of enzymatically active urokinase-type plasminogen activator (u-PA) sites on the surface of cultured human rhabdomyosarcoma cells (RD cells). Activation of pro-u-PA on the cell surface and consequent binding of PAI-2 was dependent on the addition of native plasminogen to serum cultures of the cells. Inhibition of the enzyme activity of surface-bound u-PA by the added PAI-2 resulted in a 79% reduction in the capacity of the RD cells to generate cell surface-associated plasmin activity from bound plasminogen. Under these conditions, the PAI-2 probe was localized at focal adhesions of RD cells, where it colocalized with both extracellular u-PA and intracellular vinculin antigens in double immunofluorescence labeling. Specificity of the probe's interaction with cell surface-bound u-PA was confirmed by blocking with a monoclonal antibody to human u-PA, which could also inhibit the formation of bound plasmin activity. These results showed the assembly of the plasmin-generating system at focal adhesions and the accessibility of bound u-PA on which it depends to added PAI-2. Therefore, PAI-2 has the potential both to localize at sites of tumor expression of functionally active u-PA and simultaneously to inhibit cell surface plasminogen activation.
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PMID:Prourokinase activation on the surface of human rhabdomyosarcoma cells: localization and inactivation of newly formed urokinase-type plasminogen activator by recombinant class 2 plasminogen activator inhibitor. 213 29


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