Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0033036 (APC)
 10,214 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A series of new compounds, 6-amino-1-naphthalenesulfonamides (ANSN), were used as fluorescent detecting groups for substrates of amidases. These compounds have a high quantum fluorescent yield, and the sulfonyl moiety permits a large range of chemical modification. Fifteen ANSN substrates with the structure (N alpha-Z)Arg-ANSNR1R2 were synthesized and evaluated for their reactivity with 8 proteases involved in blood coagulation and fibrinolysis. Thrombin, activated protein C, and urokinase rapidly hydrolyzed substrates with monosubstituted sulfonamide moieties (R1 = H). The maximum rate of substrate homologue). The hydrolysis rates for substrates with branched substituents were slower than their linear analogues. Monosubstituted (N alpha-Z)Arg-ANSNR1R2 possessing cyclohexyl or benzyl groups in the sulfonamide moiety were hydrolyzed by these three enzymes at rates similar to that of the n-butyl homologue (except the cyclohexyl compound for u-PA). Factor Xa rapidly hydrolyzed substrates with short alkyl chains, especially when R1 = R2 = CH3 or C2H5. Lys-plasmin and rt-PA demonstrated low activity with these compounds, and the best results were accomplished for monosubstituted compounds when R2 = benzyl (for both enzymes). Factor VIIa and factor IXa beta exhibited no activity with these substrates. A series of 14 peptidyl ANSN substrates were synthesized, and their reactivity for the same 8 enzymes was evaluated. Thrombin, factor Xa, APC, and Lys-plasmin hydrolyzed all of the substrates investigated. Urokinase, rt-PA, and factor IXa beta exhibited reactivity with a more limited group of substrates, and factor VIIa hydrolyzed only one compound (MesD-LGR-ANSN(C2H5)2). The substrate ZGGRR-ANSNH (cyclo-C6H11) showed considerable specificity for APC in comparison with other enzymes (kcat/KM = 19,300 M-1 s-1 for APC, 1560 for factor IIa, and 180 for factor Xa). This kinetic advantage in substrate hydrolysis was utilized to evaluate the activation of protein C by thrombin in a continuous assay format. Substrate (D-LPR-ANSNHC3H7) was used to evaluate factor IX activation by the factor VIIa/tissue factor enzymatic complex in a discontinuous assay. A comparison between the commercially available substrate chromozyme TH (p-nitroanilide) and the ANSN substrate with the same peptide sequence (TosGPR) demonstrated that aminonaphthalenesulfonamide increased the specificity (kcat/KM) of substrate hydrolysis by thrombin more than 30 times, with respect to factor Xa substrate hydrolysis.
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PMID:Aminonaphthalenesulfonamides, a new class of modifiable fluorescent detecting groups and their use in substrates for serine protease enzymes. 160 66

This review has stressed the common hereditary and acquired blood protein defects associated with thrombosis. The most common of the hereditary defects appear to be antithrombin, protein C, and protein S deficiency, and the most common acquired defects are anticardiolipin antibodies and the lupus anticoagulant. Therefore, these are the defects which should first be searched for in an individual with unexplained thrombosis. If these more common defects are not found, the rarer defects, including HC-II, plasminogen, or TPA deficiency, dysfibrinogenemia, elevated PAI-1, or heterozygous homocystinemia should be looked for. The incidence of activated protein C co-factor deficiency (APC resistance) is not yet clear but may also represent a common defect. PAI-1 defects may, with time, be shown to be common. Finding these defects has important implications for therapy for the individual patient and for the institution of family studies to identify, inform, and possibly treat others at risk. It is expected that as knowledge of hemostasis expands, more hereditary and acquired defects, such as elevated lipoprotein(a) or defects of extrinsic (tissue factor) pathway inhibitor (EPI, TFPI), may be associated with enhanced risks for thrombosis.
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PMID:Blood protein defects associated with thrombosis. Laboratory assessment. 778 Dec 75

A chimeric cDNA, encoding residues 1-46 (the gamma-carboxyglutamic acid module and its trailing helical stack) of human coagulant factor (f) VII, bound to residues 47-419 of human anticoagulant protein C (PC), was constructed and expressed. The resulting protein, r-[delta GD-HSPC/[symbol: see text] GD-HSfVII]PC, was properly processed with regard to signal/propeptide release, cleavage of the K156R dipeptide, Gla and Hya contents, and the presence of glycosylation. The mutant protein displayed normal dependencies on Ca2+ for adoption of its metal ion-dependent conformation and for binding to acidic phospholipid vesicles. The chimera failed to recognize a monoclonal antibody (MAb) specific for the Ca(2+)-induced conformation of the Gla domain (GD) of PC, but did react with another MAb directed in part to the Ca(2+)-dependent conformation of the GD of fVII. Further, this chimeric protein possessed similar steady state constants as wild-type r-PC toward activation by thrombin and thrombin/thrombomodulin. The activated form of the chimera was very similar to that of its wild-type counterpart in its whole plasma anticoagulant activity, as well as its activity toward inactivation of coagulation factor VIII. The chimeric protein did not bind to the fVII cofactor, tissue factor, showing that the GD/HS domain region of fVII is insufficient for that particular interaction. The results demonstrate that the GD/HS of fVII, when present in the PC and APC background, serves to maintain the Ca2+/PL-related functions of these latter proteins, and suggest that the Ca2+ and PL-dependent interactions of the GD-HS of PC are sufficiently general in nature such that the GD-HS regions of other proteins of this type can satisfy most of the requirements of PC and APC. The data presented also offer support for the independent nature of the domain unit consisting of the GD/HS module.
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PMID:Properties of a recombinant chimeric protein in which the gamma-carboxyglutamic acid and helical stack domains of human anticoagulant protein C are replaced by those of human coagulation factor VII. 918 4

Venous valves are more frequent in distal veins and venulae, providing a protecting action against blood skin reflux. Structurally simple, collagen and endothelium, they allow a cavity to be formed by distension, when occlusion occurs. Venous angioscopy can distinguish bicuspid floating valves, reinforced, reinforcing valves with free edges and seat valves as well as the presence of apertures of small collateral vessels in the sinus, of which they play a role in the filling up. Valves are inefficient in supine and in standing among 20% of the adult population. Sinuses allow vortices to be created, low recirculating zones, where blood flow move slowly in niches, at a low shear rate, independently from the main stream. A deep vortex is located in sinus, usually empty, but likely to receive red cell aggregates and leukocytes in the condition of stasis and hyperviscosity. Such a vortex is hypoxic, cause of endothelial activation. In such areas fibrin-leucocytic nidus are created, histologically recognized, of which sub-endothelium has become thick and thrombogenic. Two stages characterized its progression: stage I: a few alteration in the valves, little thrombin generation, taken over by the coagulation inhibitors: AT III, APC and TFPI. Stage II: damaged valves, local consumption of the inhibitors and extended generation of thrombin over the platelets, through factor IXa. Hereditary inhibitor deficits increase the risk (frequent factor Leyden V). When the coagulation cascade is considered, VIIa-tissue factor complex appears to be the thrombotic pathway, leading first to wall linked thrombin, uneasily reached by AT III and facteur IXa non inhibited by TFPI, therefore explaining the platelet extension. Monocytes, which can bear tissue factor, may be "lodged" inside the niches. Besides this important role in deep venous thrombosis, incompetent venous valves are responsible for the skin venous hypertension, a subsequent ground for ulcers. Their role in chronic venous insufficiency is uncertain. In the near future, venous angioscopy will bring about new findings about the pathophysiology of venous valves.
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PMID:[Venous valves in the legs: hemodynamic and biological problems and relationship to physiopathology]. 948 Mar 31

We compared the sensitivity and specificity of a tissue factor-based assay (FVR) with the addition of a phospholipid/silica preparation, to the commercially available aPTT-based method, APCR (CoatestTM), and a modified aPTT-based method (APCM) which utilized factor V-depleted plasma, for the detection of the factor V Leiden mutation. A total of 110 patients were included in this study. This included 32 patients on coumadin therapy, 7 patients on heparin therapy, 5 patients on both anticoagulants therapy, and 24 patients who were positive for anticardiolipin antibody (ACL) and/or lupus inhibitor (LI). Our data demonstrate that the FVR is not affected by anticoagulation treatment or ACL/LI antibodies, whereas in the APCR method, 33 patients cannot be determined either due to the anticoagulant therapy or presence of the ACL and/or LI. With the APCM method, the clotting endpoint could not be determined in 1 patient due to the presence of a strong LI. The additional phospholipid/silica material utilized in the FVR enhanced the APC degradation of factor Va and therefore sharpened the demarcation between the factor V Leiden-positive and -negative patients. The sensitivity for the APCR, APCM and FVR was 42, 97 and 100% respectively. The specificity for the APCR, APCM and FVR was 94, 96 and 100% respectively.
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PMID:A highly specific functional test for factor V leiden: A modified tissue factor assay for activated protein C resistance. 973 Nov 10

The molecular links between inflammation and coagulation are unquestioned. Inflammation promotes coagulation by leading to intravascular tissue factor expression, eliciting the expression of leukocyte adhesion molecules on the intravascular cell surfaces, and down regulating the fibrinolytic and protein C anticoagulant pathways. Thrombin, in turn, can promote inflammatory responses. This creates a cycle that logically progresses to vascular injury as occurs in septic shock. Most complex systems are regulated by product inhibition. This inflammation-coagulation cycle seems to follow this same principle with the protein C pathway serving as the regulatory mechanism. The molecular basis by which the protein C pathway functions as an anticoagulant is relatively well established compared to the mechanisms involved in regulating inflammation. As one approach to identifying the mechanisms involved in regulating inflammation, we set out to identify novel receptors that could modulate the specificity of APC in a manner analogous to the mechanisms by which thrombomodulin modulates thrombin specificity. This approach led to the identification of an endothelial cell protein C receptor (EPCR). To understand the mechanism, we obtained a crystal structure of APC (lacking the Gla domain). The crystal structure reveals a deep groove in a location analogous to anion binding exosite 1 of thrombin, the location of interaction for thrombomodulin, platelet thrombin receptor and fibrinogen. Thrombomodulin blocks the activation of platelets and fibrinogen without blocking reactivity with chromogenic substrates or inhibitors. Similarly, in solution, EPCR blocks factor Va inactivation without modulating reactivity with protease inhibitors. Thus, these endothelial cell receptors for the protein C system share many properties in common including the ability to be modulated by inflammatory cytokines. Current studies seek to identify the substrate for the APC-EPCR complex as the next step in elucidating the mechanisms by which the protein C pathway modulates the response to injury and inflammation.
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PMID:Inflammation, sepsis, and coagulation. 1018 92

Changes of hemostatic parameters during percutaneous transluminal coronary angioplasty (PTCA) in 75 patients with chronic coronary artery disease were evaluated. Plasma levels of D-dimer, soluble fibrin monomer, plasmin-alpha2 antiplasmin inhibitor complex, and tissue factor (TF) were significantly increased in all patients with chronic coronary artery disease. The activity of antithrombin and protein C and the levels of protein C antigen were significantly decreased 1 hr after PTCA, but they returned to normal range 1 day after PTCA. There was no significant difference in the level of plasma APC-PCI complex before and 1 hr after PTCA. The plasma levels of D-dimer, soluble fibrin monomer, thrombomodulin, TF and PPIC were significantly decreased 1 hr, and the plasma levels of plasmin-alpha2 antiplasmin inhibitor complex 1 day after PTCA. These findings suggest that the decrease of protein C and antithrombin resulted in activation of the coagulation system. One hour after PTCA, the plasma levels of (total-free) TF pathway inhibitor (TFPI) were significantly decreased, but the plasma levels of total and free-TFPI were significantly increased, suggesting that consumption of (total-free) TFPI occurs during PTCA. Overall, these findings suggest that the hypercoagulable state improves during PTCA and that transient decrease of antithrombin, protein C, (total-free) TFPI or plasmin-alpha2 antiplasmin inhibitor complex may cause restenosis of coronary artery.
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PMID:Changes of plasma hemostatic markers during percutaneous transluminal coronary angioplasty in patients with chronic coronary artery disease. 1044 Sep 9

Sepsis-induced abnormalities of coagulation may contribute to mortality during severe bacterial infection. The aim of this study was to examine changes in coagulation parameters and to assess the role of protein C supplementation during murine S. aureus sepsis. Gram-positive sepsis was characterized by a hypercoagulable state with predominant activation of the external coagulation pathway, registered as an early increase of tissue factor activity and concomitant reduction in protein C. The internal coagulation pathway was unaffected. No correlation between the changes of coagulation parameters and the intensity of inflammation, determined as serum IL-6 levels, was found. Supplementation with neither protein C or APC favoured survival in S. aureus sepsis. Reduction in thrombin generation in response to protein C supplementation was associated with significantly increased survival.
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PMID:Thrombin generation and mortality during Staphylococcus aureus sepsis. 1131 18

It is becoming increasingly clear that coagulation augments inflammation and that anticoagulants, particularly natural anticoagulants, can limit the coagulation induced increases in the inflammatory response. The latter control mechanisms appear to involve not only the inhibition of the coagulation proteases, but interactions with the cells that either generate anti-inflammatory substances, such as prostacyclin, or limit cell activation. Recent studies have demonstrated a variety of mechanisms by which coagulation, particularly the generation of thrombin, factor Xa and the tissue factor-factor VIIa complex, can augment acute inflammatory responses. Many of these responses are due to the activation of one or more of the protease activated receptors. Activation of these receptors on endothelium can lead to the expression of adhesion molecules and platelet activating factor, thereby facilitating leukocyte activation. Therefore, anticoagulants that inhibit any of these factors would be expected to dampen the inflammatory response. The three major natural anticoagulant mechanisms seem to exert a further inhibition of these processes by impacting cellular responses. Antithrombin has been shown in vitro to increase prostacyclin responses and activated protein C has been shown to inhibit a variety of cellular responses including endotoxin induced calcium fluxes in monocytes and the nuclear translocation of NFKB, a key step in the generation of the inflammatory response. In some, but not all, in vivo models, these natural anticoagulants have been able to inhibit endotoxin/E. coli-mediated leukocyte activation and to diminish cytokine elaboration (TNF, IL-6 and IL-8). Phase III clinical studies for treatment of patients with severe sepsis have been completed for APC, which was successful (1), and for antithrombin, which was not (2). A phase III trial with tissue factor pathway inhibitor is in progress. In this review, the mechanisms by which the different natural anticoagulants are thought to function will be reviewed.
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PMID:Role of coagulation inhibitors in inflammation. 1148 41

The normalized activated protein C sensitivity ratio (nAPC-sr) determined with an assay that quantifies the effect of APC on thrombin formation initiated via the extrinsic coagulation pathway identifies hereditary and acquired defects of the protein C system. We investigated the influence of assay conditions (analytical variables) and plasma handling (pre-analytical variables) on nAPC-sr obtained with this APC resistance test. The effect of the analytical variables (CaCl2, phospholipid and APC concentrations and the concentration and source of tissue factor) was determined in pooled normal plasma. Inhibition of thrombin formation by APC was dependent on the APC concentration and was also affected by the tissue factor, Ca2+ and phospholipid concentrations. Thus, strict standardization of reactant concentrations is required to obtain reproducible nAPC-sr. Three different tissue factor preparations were compared by determining nAPCsr in plasma samples obtained from 90 healthy individuals. nAPC-sr were similar for all three tissue factor preparations although, compared with the noncommercially available tissue factor used in earlier studies, values determined with commercial tissue factor preparations showed larger variation. Pre-analytical variables, investigated in plasma of nine volunteers (3 normal individuals and 6 individuals with an APC-resistant phenotype) were: concentration of anticoagulant (3.2% vs. 3.8% trisodiumcitrate), time before processing of blood (0, 4 and 24 h), centrifugation speed, storage temperature of plasma (-20 degrees C vs. -80 degrees C) and sample thawing. Multiple linear regression analysis showed that only the citrate concentration affected the nAPC-sr, which was higher in samples collected in 3.2% trisodiumcitrate than in samples collected in 3.8% trisodiumcitrate.
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PMID:Effects of (pre-)analytical variables on activated protein C resistance determined via a thrombin generation-based assay. 1192 38


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