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Query: EC:3.4.21.69 (
APC
)
16,337
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Recent advances in the understanding of blood coagulation provide strong evidence that exposure of tissue factor is the "match" which initiates blood coagulation. A novel plasma protease inhibitor, called
EPI
or
LACI
, effectively extinguishes this "match," leaving Factors IXa, VIII, X, V, and II to function as a "fuse." Activated Factors IX, X, and II are controlled by heparin-enhancable protease inhibitors. Activated Factors VIII and V are destroyed by the
protein C
/S system. Fibrinolysis is largely cell-based and controlled by differential secretion of plasminogen activators and plasminogen activator inhibitors.
...
PMID:Blood coagulation and fibrinolysis: an overview. 219 14
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.
...
PMID:Blood protein defects associated with thrombosis. Laboratory assessment. 778 Dec 75
The baboon model of E. coli sepsis illustrates three concepts with respect to the host response and vascular endothelium. First, the endothelium is the primary target. E. coli sepsis is an acute inflammatory disease of the vascular endothelium. Second, the endothelium is not a passive target. Initially it regulates both the inflammatory and coagulopathic aspects of E. coli sepsis through membrane associated regulatory receptor/plasma protein assemblies including
protein C
/thrombomodulin,
activated protein C
/protein S, C4bBP/protein S, tissue factor pathway inhibitor/Xa, antithrombin III/glycosaminoglycans. Third, when overridden by inflammatory events, the endothelium can change its anticoagulant phenotype and mount a massive procoagulant fibrinolytic counter-attack on its luminal side through the expression of tissue factor and release of tissue plasminogen activator. Fourth, again when overridden by inflammatory events, the endothelium can change its antioxidant phenotype and produce a "distal" tissue hypoxia on its abluminal side through induction of free radical generation and peroxidation of mitochondrial lipid membranes of those tissues with high metabolic rates. It has become increasingly clear that the so-called anticoagulant systems which act on the proximal factors of the clotting cascade (
protein C
,
TFPI
, AT-III, PGI2) also attenuate the amplification of the inflammatory response. Aspects of the mechanism by which this occurs are coming to light. This includes the attenuation of Il-6 response by
TFPI
and the attenuation of the complement effects by C4bBP/PS. The specifics of these observations in the E. coli sepsis model will be reviewed.
...
PMID:Studies on the inflammatory-coagulant axis in the baboon response to E. coli: regulatory roles of proteins C, S, C4bBP and of inhibitors of tissue factor. 783 58
The coagulation enzyme thrombin, a serine protease like all other coagulation factors, plays a central role in the hemostatic processes engaged after injurious events. It induces, with particular efficacy, the aggregation of blood platelets (primary hemostasis) and accounts, via splitting of fibrinogen to fibrin, for the event actually responsible for the coagulation of blood (secondary hemostasis). As is well-known, thrombin itself is generated by a cascade of activation events involving various coagulation factors (F). In this respect the "tissue factor" (TF, formerly known as thromboplastin), in combination with F VIIa, attains decisive significance, not only in the extrinsic pathway of coagulation (activation of F X-->Xa), but also in the intrinsic pathway (activation of F IX-->IXa). Under physiological circumstances, platelet aggregation and coagulation are restricted to the area of the vascular lesion, since the surrounding intact endothelium inhibits an intraluminal spreading of both processes. These "antithrombotic" features of the endothelium encompass antiaggregatory mechanisms (formation and release of prostacyclin [PGI2], adenosine, EDRF [NO], degradation of ADP and other nucleotides mediated by ecto-nucleotidases) as well as anti-coagulatory properties (formation and release of "tissue factor pathway inhibitor" [
TFPI
], which blocks the coagulation cascade by joining F Xa, TF and F VIIa into an inactive complex, thrombomodulin--thrombin induced activation of
protein C
, which, together with protein S, inactivates F Va and F VIIIa, thereby attenuating further generation of thrombin, and the heparan sulfate-enhanced activation of antithrombin III and heparin-cofactor II).(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:[Interaction of blood and the vascular wall: hemostatic aspects]. 815 53
The effects of the components of the
protein C
pathway on thrombin generation were studied in a reconstituted model in which thrombin is generated by factor VIIa and relipidated tissue factor (TF) via the activation of the purified coagulation factors X, IX, VIII, V, and prothrombin. The influence of
protein C
and soluble thrombomodulin on thrombin generation was correlated with factor Xa generation, factor V(a) and factor VIII(a) formation/inactivation, and
protein C
activation. Thrombin generation initiated by low concentrations of factor VIIa.TF (1.25 pM) occurs in an explosive fashion during a propagation phase which occurs after an initiation phase of approximately 1 min in which only traces of thrombin are formed. In the absence of other inhibitors,
protein C
(65 nM) in combination with high concentrations of soluble thrombomodulin (10 nM) resulted in a reduced rate of thrombin generation during the propagation phase without affecting the initiation phase; the
activated protein C
generated failed to neutralize prothrombinase activity and did not prevent prothrombin consumption. In the presence of plasma levels of the tissue factor pathway inhibitor (2. 5 nM recombinant
TFPI
), the
protein C
pathway reduced the rate of thrombin generation, initiated by 1.25 pM factor VIIa.TF, and completely eliminated prothrombinase activity at soluble thrombomodulin concentrations of >/=1 nM. The neutralization of prothrombinase activity coincided with cleavages at Arg-506 and subsequent cleavage at Arg-306 of the factor Va heavy chain by
activated protein C
. Thus, the
protein C
pathway combined with
TFPI
creates a minimal inhibitory potential required to shut down TF-initiated thrombin generation. The
protein C
pathway constituents did not influence factor Xa generation or factor VIIIa degradation over the interval in which prothrombinase activity was neutralized. Our data thus suggest that the
protein C
pathway regulates thrombin generation solely by the inactivation of factor Va. At low initiating factor VIIa.TF (1.25 pM) and high thrombomodulin concentrations (10 nM), the factor Va heavy chain is cleaved before significant amounts of light chain are generated. The ability of the
protein C
pathway to inhibit thrombin generation was greatly reduced when the reaction was initiated in the presence of factor Va, supporting the hypothesis that effective down-regulation of thrombin generation by the
protein C
pathway, in reactions initiated with the procofactor, occurs by prevention of the coexistence of the factor Va heavy and light chains.
...
PMID:Inhibitory mechanism of the protein C pathway on tissue factor-induced thrombin generation. Synergistic effect in combination with tissue factor pathway inhibitor. 906 69
The effect of the Arg506 --> Gln mutation in factor VLEIDEN on thrombin generation was evaluated in a reconstituted system using the purified components of the tissue factor (TF) pathway to thrombin and the components of the
protein C
pathway. Recombinant full-length tissue factor pathway inhibitor (RTFPI) was included in the system because of a previously observed synergistic inhibitory effect of
TFPI
and the
protein C
pathway on TF-initiated thrombin generation. Thrombin generation initiated by 1.25 pM factor VIIa.TF in the absence of the
protein C
pathway components occurs following an initiation phase, after which prothrombin is quantitatively converted to 1.4 microM thrombin. The factor VLEIDEN mutation did not influence thrombin generation in the reconstituted model in the absence of the
protein C
pathway. In the presence of 2.5 nM
TFPI
, 65 nM
protein C
, and 10 nM recombinant soluble thrombomodulin (Tm), thrombin generation catalyzed by normal factor V was abolished after the initial formation of 25 nM thrombin. In contrast, persistent thrombin generation was observed in the presence of factor VLEIDEN in the same system, although the rate of thrombin generation was slower compared with the reaction without
protein C
and Tm. The rate of thrombin generation with factor VLEIDEN increased with time and ultimately resulted in quantitative prothrombin activation. When the
TFPI
concentration was reduced to 1.25 nM, thrombin generation is still curtailed in the presence of normal factor V. In contrast, under similar conditions using factor VLEIDEN, the
protein C
pathway totally failed to down-regulate thrombin generation. The dramatic effect of a 50% reduction in
TFPI
concentration on the inhibitory potential of the
protein C
pathway on thrombin generation catalyzed by factor VLEIDEN suggests that the observed synergy between
TFPI
and the
protein C
pathway is directly governed by the
TFPI
concentration and by cleavage of the factor Va heavy chain at Arg506. This cleavage appears to have a dramatic regulatory effect in the presence of low concentrations of
TFPI
. Markedly increased thrombin generation in the presence of both 1.25 nM
TFPI
and factor VLEIDEN was also observed when antithrombin-III was added to the system to complete the natural set of coagulation inhibitors. Protein S (300 nM) had a minimal effect in the model on the inhibition of thrombin generation by
protein C
, Tm, and
TFPI
, with either normal factor V or factor VLEIDEN. Protein S also failed to significantly potentiate the action of the
protein C
pathway in the presence of antithrombin-III in reactions employing normal factor V or factor VLEIDEN. The absence of an effect of protein S in the model, which employs saturating concentrations of phospholipid, suggests that the reported interactions of protein S with coagulation factors are not decisive in the reaction. Altogether the data predict that
TFPI
levels in the lower range of normal values are a risk factor for thrombosis when combined with the Arg506 --> Gln mutation in factor VLEIDEN.
...
PMID:Increased tissue factor-initiated prothrombin activation as a result of the Arg506 --> Gln mutation in factor VLEIDEN. 925 93
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.
...
PMID:[Venous valves in the legs: hemodynamic and biological problems and relationship to physiopathology]. 948 Mar 31
We have previously reported high levels of the coagulation inhibitor
TFPI
in the blood of patients with gastrointestinal cancer.
TFPI
is not an acute-phase reactant, but high levels have also been reported in patients with septicaemia and disseminated intravascular coagulation (DIC). To study its relationship with other types of malignancy,
TFPI
activity was first determined in plasma samples from 214 patients with various malignancies. In a second cohort of 83 patients, total and free
TFPI
antigen,
protein C
, antithrombin, fibrin monomer and D-dimer were also measured. Elevated
TFPI
activity and antigens were found in about half of the patients with solid tumours. In contrast, elevated
TFPI
was rare in haematological malignancies (12%). In the 18 patients with acute nonlymphocytic leukaemia (ANLL), elevated free
TFPI
was found only in patients who also had DIC. No correlation was found between
TFPI
levels and fibrin monomer or D-dimer levels. Only four out of 20 patients with solid tumours had normal levels of fibrin monomer and D-dimer, yet three out of these four had elevated
TFPI
. In conclusion, elevated
TFPI
in ANLL is related to the coexistence of DIC. In solid tumour disease increased
TFPI
may reduce protective fibrin formation, but the pathogenic mechanism is as yet unknown.
...
PMID:Elevated TFPI in malignant disease: relation to cancer type and hypercoagulation. 973 35
In a recent randomized, double-blind, placebo-controlled trial of women with a history of venous thromboembolism (VTE), we found that hormone replacement therapy (HRT) was associated with an early excess risk of recurrent thrombosis. The aims of the present study were to characterize the effects of HRT on coagulation in these women to elucidate the mechanism(s) by which HRT increases the risk of thrombosis. The study comprised 140 women who were randomized to receive continuous treatment for 24 months with once daily 2 mg 17-beta-estradiol plus 1 mg norethisterone acetate (n = 71) or placebo (n = 69). HRT caused significant increases in prothrombin fragments 1+2, thrombin-antithrombin complex, and D-Dimer after 3 months, but these changes were less pronounced on prolonged treatment. The increases in markers of activated coagulation was higher in those women who subsequently developed recurrent thrombosis, but was similar in carriers and non-carriers of the factor V Leiden mutation. HRT had no effects on fibrinogen and factor VIII. Activated factor VII, but not factor VII antigen, decreased significantly on HRT as compared with placebo. The coagulation inhibitors antithrombin,
protein C
, and
TFPI
, but not protein S, all showed significant sustained decreases in the HRT group as compared with placebo. Antithrombin and
protein C
decreased by 8-12% on HRT, whereas
TFPI
activity decreased by 12-17% and
TFPI
free antigen by 29-30%. In multivariate analysis, only
TFPI
activity was a significant predictor for the increased activation of coagulation. We conclude that HRT was associated with early activation of coagulation, which corroborates the finding of an early risk of recurrent VTE. This activation may in part be explained by reduction in circulating anticoagulants.
...
PMID:The effects of hormone replacement therapy (HRT) on hemostatic variables in women with previous venous thromboembolism--results from a randomized, double-blind, clinical trial. 1137 67
Thromboregulatory physiology is essentially a function of the blood vessel wall. Constitutive endothelial cell activities maintain blood fluidity by down regulating the initiation as well as, the propagation of blood coagulation. The major systems involved include: the
Protein C
,
TFPI
, plasmin generating and antithrombin pathways, all of which are focused on the cell membrane. Altered regulation of these endothelial functions forms the basis of the pathophysiologic events associated with the inherited primary hypercoagulable states. Secondary hypercoagulable syndromes occurring in various clinical states with conversion to a vascular thrombogenic phenotype reflect non constitutive activated endothelial cell functions with concomitant down regulation of the constitutive anticoagulant surface activity. So called idiopathic clinical thrombosis in most circumstances represents multi hit events in which specific genetic abnormalities or polymorphisms together with specific acquired alterations in geographically distinct endothelial cell beds culminate in a recognizable coagulation phenotype.
...
PMID:The Jeremiah Metzger Lecture. Hypercoagulable states: challenges and opportunities. 1141 75
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