The anticoagulant and antithrombotic mechanisms of heparin.

The molecular basis for the anticoagulant action of heparin lies in its ability to bind to and enhance the inhibitory activity of the plasma protein antithrombin against several serine proteases of the coagulation system, most importantly factors IIa (thrombin), Xa and IXa. Two major mechanisms underlie heparin's potentiation of antithrombin. The conformational changes induced by heparin binding cause both expulsion of the reactive loop and exposure of exosites of the surface of antithrombin, which bind directly to the enzyme target; and a template mechanism exists in which both inhibitor and enzyme bind to the same heparin molecule. The relative importance of these two modes of action varies between enzymes. In addition, heparin can act through other serine protease inhibitors such as heparin co-factor II, protein C inhibitor and tissue factor plasminogen inhibitor. The antithrombotic action of heparin in vivo, though dominated by anticoagulant mechanisms, is more complex, and interactions with other plasma proteins and cells play significant roles in the living vasculature.

Heparin cofactor II: discovery, properties, and role in controlling vascular homeostasis.

Heparin cofactor II (HCII) is a serine protease inhibitor (serpin) found in high concentrations in human plasma. Despite its discovery >30 years ago, its physiological function is still poorly understood. It is known to inhibit thrombin, the predominant coagulation protease, and HCII-thrombin complexes have been found in plasma, yet it is thought to contribute little to normal hemostasis. However, thrombin has several other physiological functions, and therefore many biological roles for HCII need consideration. The unique structure and mechanism of action of HCII have helped guide our understanding of HCII. In particular, HCII binds many glycosaminoglycans (GAGs) such as heparin and heparin sulfate as well as several different polyanions to enhance its inhibition of thrombin. Distinctly, HCII is able to use the GAG dermatan sulfate for accelerated thrombin inhibition. Dermatan sulfate is found in high concentrations in the walls of blood vessels as well as in placental tissue. This knowledge has led to research indicating that HCII may play a protective role in atherosclerosis and placental thrombosis. Additionally, pharmaceuticals are being developed that use the dermatan sulfate activation of HCII for anticoagulation. Although much research is still needed to fully understand HCII, this humble protein may have significant impact in our medical future. This article reviews the laboratory history, protein characteristics, structure-activity relationships, protease inhibition, physiological function, and medical relevance of HCII in hopes of regenerating interest in this sometimes forgotten serpin.

Shape-shifting serpins--advantages of a mobile mechanism.

Serpins use an extraordinary mechanism of protease inhibition that depends on a rapid and marked conformational change and causes destruction of the covalently linked protease. Serpins thus provide stoichiometric, irreversible inhibition, and their dependence on conformational change is exploited for signalling and clearance. The regulatory advantages provided by structural mobility are best illustrated by the heparin activation mechanisms of the plasma serpins antithrombin and heparin cofactor II. This mechanistic complexity, however, renders serpins highly susceptible to disease-causing mutations. Recent crystal structures reveal the intricate conformational rearrangements involved in protease inhibition, activity modulation and the unique molecular pathology of the remarkable shape-shifting serpins.

Heparin cofactor II attenuates vascular remodeling in humans and mice.

Heparin cofactor II (HCII), a serine protease inhibitor (serpin), inactivates thrombin action in the subendothelial layer of the vascular wall. Because a congenitally HCII-deficient patient has been shown to have multiple atherosclerotic lesions, it is hypothesized that HCII plays a pivotal role in the development of vascular remodeling, including atherosclerosis. To clarify this issue, 3 clinical studies concerning plasma HCII activity and atherosclerosis were carried out, and results demonstrated that a higher incidence of in-stent restenosis after percutaneous coronary intervention, maximum carotid arterial plaque thickness, and prevalence of peripheral arterial disease occurred in subjects with low plasma HCII activity. Furthermore, HCII-deficient mice were generated by a gene targeting method to determine the mechanism of the vascular protective action of HCII. Because HCII(-/-) mice were embryonically lethal, we used HCII(+/-) mice and found that they manifested augmentation of intimal hyperplasia and increased thrombosis after cuff or wire injury to the femoral arteries. HCII(+/-) mice with vascular injury showed augmentation of inflammatory cytokines and chemokines and oxidative stress. These abnormal phenotypes of vascular remodeling observed in HCII(+/-) mice were almost restored by human HCII protein supplementation. HCII protects against vascular remodeling, including atherosclerosis, in both humans and mice, and plasma HCII activity might be a predictive biomarker and novel therapeutic target for the prevention of cardiovascular diseases.

Heparin cofactor II inhibits arterial thrombosis after endothelial injury.

Heparin cofactor II (HCII) is a plasma protein that inhibits thrombin rapidly in the presence of dermatan sulfate, heparan sulfate, or heparin. HCII has been proposed to regulate coagulation or to participate in processes such as inflammation, atherosclerosis, and wound repair. To investigate the physiologic function of HCII, about 2 kb of the mouse HCII gene, encoding the N-terminal half of the protein, was deleted by homologous recombination in embryonic stem cells. Crosses of F1 HCII(+/-) animals produced HCII(-/-) offspring at the expected mendelian frequency. Biochemical assays confirmed the absence of dermatan sulfate-dependent thrombin inhibition in the plasma of HCII(-/-) animals. Crosses of HCII(-/-) animals produced litters similar in size to those obtained from heterozygous matings. At 1 year of age, HCII-deficient animals were grossly indistinguishable from their wild-type littermates in weight and survival, and they did not appear to have spontaneous thrombosis or other morphologic abnormalities. In comparison with wild-type animals, however, they demonstrated a significantly shorter time to thrombotic occlusion of the carotid artery after photochemically induced endothelial cell injury. This abnormality was corrected by infusion of purified HCII but not ovalbumin. These observations suggest that HCII might inhibit thrombosis in the arterial circulation.

Thrombin-activated thrombelastography for evaluation of thrombin interaction with thrombin inhibitors.

For intravenous anticoagulation, heparin has been the mainstay drug, but its use may be contraindicated in heparin-induced thrombocytopenia and thrombosis. Heparin alternatives including direct thrombin inhibitors are available, but clotting assays (e.g. partial thromboplastin time) measure the time required to form fibrin gel when only a small amount of thrombin is generated. It was hypothesized that the extent of thrombin inhibition varies among inhibitors, and thrombin-activated thrombelastography would provide useful data on therapeutic responses to thrombin inhibitors. Thrombin was added (0-100 nmol/l final concentration) to nonrecalcified whole blood to evaluate clot formation on thrombelastography. Effects of direct thrombin inhibitors (argatroban 3.75 microg/ml, bivalirudin 15 microg/ml, and lepirudin 3.0 microg/ml), and heparin cofactor II activator and dermatan disulfate (20 microg/ml) were evaluated in the presence of 100 nmol/l thrombin. The interactions of thrombin and respective inhibitors were also compared by fluorogenic thrombin substrate cleavage. Increasing concentrations of thrombin progressively shortened the lag time and increased viscoelasticity on thrombelastography. Only 20 nmol/l thrombin caused instantaneous clotting, but maximal viscoelastic force was obtained at 50-100 nmol/l thrombin. All thrombin inhibitors prolonged the lag time (lepirudin > bivalirudin > argatroban = dermatan disulfate), but full recovery of thrombelastography viscoelasticity was observed with argatroban and bivalirudin. Lepirudin abrogated clotting, and dermatan disulfate suppressed clot development on thrombelastography. Thrombin substrate cleavage was observed only for bivalirudin, and heparin cofactor II without dermatan disulfate. The modified thrombelastography technique using nonrecalcified whole blood may be useful in evaluating the extent and reversibility of thrombin blockade with direct or indirect thrombin inhibitors.

The Role of Heparin Cofactor â ¡ in the Regulation of Insulin Sensitivity and Maintenance of Glucose Homeostasis in Humans and Mice.

AIM: Accelerated thrombin action is associated with insulin resistance. It is known that upon activation by binding to dermatan sulfate proteoglycans, heparin cofactor Ⅱ(HCⅡ) inactivates thrombin in tissues. Because HCⅡ may be involved in glucose metabolism, we investigated the relationship between plasma HCⅡ activity and insulin resistance. METHODS AND RESULTS: In a clinical study, statistical analysis was performed to examine the relationships between plasma HCⅡ activity, glycosylated hemoglobin (HbA1c), fasting plasma glucose (FPG), and homeostasis model assessment-insulin resistance (HOMA-IR) in elderly Japanese individuals with lifestyle-related diseases. Multiple regression analysis showed significant inverse relationships between plasma HCⅡ activity and HbA1c (p=0.014), FPG (p=0.007), and HOMA-IR (p= 0.041) in elderly Japanese subjects. In an animal study, HCⅡ＋/＋ mice and HCⅡ＋/- mice were fed with a normal diet or high-fat diet (HFD) until 25 weeks of age. HFD-fed HCⅡ＋/- mice exhibited larger adipocyte size, higher FPG level, hyperinsulinemia, compared to HFD-fed HCⅡ＋/＋ mice. In addition, HFD-fed HCⅡ＋/- mice exhibited augmented expression of monocyte chemoattractant protein-1 and tumor necrosis factor, and impaired phosphorylation of the serine/threonine kinase Akt and AMP-activated protein kinase in adipose tissue compared to HFD-fed HCⅡ＋/＋ mice. The expression of phosphoenolpyruvate carboxykinase and glucose-6-phosphatase was also enhanced in the hepatic tissues of HFD-fed HCⅡ＋/- mice. CONCLUSIONS: The present studies provide evidence to support the idea that HCⅡ plays an important role in the maintenance of glucose homeostasis by regulating insulin sensitivity in both humans and mice. Stimulators of HCⅡ production may serve as novel therapeutic tools for the treatment of type 2 diabetes.

Dermatan sulfate is the predominant antithrombotic glycosaminoglycan in vessel walls: implications for a possible physiological function of heparin cofactor II.

The role of different glycosaminoglycan species from the vessel walls as physiological antithrombotic agents remains controversial. To further investigate this aspect we extracted glycosaminoglycans from human thoracic aorta and saphenous vein. The different species were highly purified and their anticoagulant and antithrombotic activities tested by in vitro and in vivo assays. We observed that dermatan sulfate is the major anticoagulant and antithrombotic among the vessel wall glycosaminoglycans while the bulk of heparan sulfate is a poorly sulfated glycosaminoglycan, devoid of anticoagulant and antithrombotic activities. Minor amounts of particular a heparan sulfate (< 5% of the total arterial glycosaminoglycans) with high anticoagulant activity were also observed, as assessed by its retention on an antithrombin-affinity column. Possibly, this anticoagulant heparan sulfate originates from the endothelial cells and may exert a significant physiological role due to its location in the interface between the vessel wall and the blood. In view of these results we discuss a possible balance between the two glycosaminoglycan-dependent anticoagulant pathways present in the vascular wall. One is based on antithrombin activation by the heparan sulfate expressed by the endothelial cells. The other, which may assume special relevance after vascular endothelial injury, is based on heparin cofactor II activation by the dermatan sulfate proteoglycans synthesized by cells from the subendothelial layer.

Polyphenolic-polysaccharide conjugates of Sanguisorba officinalis L. with anticoagulant activity mediated mainly by heparin cofactor II.

A macromolecular complex has been isolated from the dried flowering parts of medicinal plant Sanguisorba officinalis L. (So) by multi-step extraction procedure, including that with extraction by organic solvents to degrease the plant material, then with hot alkali, followed by neutralization, partitioning with organic solvents and dialysis. The complex was purified by size-exclusion chromatography into five fractions labeled as So1-So5. Individual fractions differed in the chemical composition and molecular weight distribution patterns. In vitro anticoagulant activity tests showed in all fractions more or less important inhibition of plasma clots, however, So3 and So4 were the most active. The anticoagulant activity of So3 was even more significant than that of the unfractionated complex So. These S. officinalis conjugates were able to inhibit mainly the activity of thrombin when they were mediated by heparin cofactor II, but what was unexpected they were the non-direct inhibitors of factor Xa, mediated by antitrombin, where such mechanism of action is typical for a highly sulphated glycosaminoglycans.

Heparin cofactor II is a novel protective factor against carotid atherosclerosis in elderly individuals.

BACKGROUND: Thrombin plays a crucial role in atherothrombotic changes. Because heparin cofactor II (HCII) inhibits thrombin actions after binding to dermatan sulfate at injured arterial walls, HCII may negatively regulate thrombin actions in vascular walls. We hypothesized that plasma HCII activity is a preventive factor against atherosclerotic changes, especially in elderly individuals who already have atherosclerotic vascular injuries. METHODS AND RESULTS: Maximum plaque thickness (MPT) in the carotid artery was measured by ultrasonography in 306 Japanese elderly individuals (154 men and 152 women; age, 40 to 91 years; 68.9+/-11.1 years, mean+/-SD). The relevance of cardiovascular risk factors including plasma HCII activity to the severity of MPT was statistically evaluated. Plasma HCII activity decreased with age. Simple linear regression analysis after adjustments for age and sex showed that lipoprotein(a), glycosylated hemoglobin A1c, and presence of diabetes mellitus significantly contributed to an increase in MPT values (r=0.119, P<0.05; r=0.196, P<0.001; and r=0.227, P<0.0001, respectively). In contrast, high-density lipoprotein (HDL) cholesterol and HCII activity were negatively correlated with MPT values (r=-0.117, P<0.05, and r=-0.202, P<0.0005, respectively). Multiple regression analysis revealed that plasma HCII activity and HDL cholesterol independently contributed to the suppression of MPT values and that the antiatherogenic contribution of HCII activity was stronger than that of HDL cholesterol (P<0.001 and P<0.05, respectively). CONCLUSIONS: These results suggest that HCII can be a novel and independent antiatherogenic factor. Moreover, HCII is a stronger predictive factor than HDL cholesterol against carotid atherosclerosis in elderly individuals.

High plasma heparin cofactor II activity protects from restenosis after femoropopliteal stenting.

High heparin cofactor II (HCII) activity has recently been described to protect from coronary instent restenosis, presumably by inactivating thrombin in injured arteries. In this study, we investigated the association of HCII activity and restenosis after femoropopliteal stenting. We studied 63 consecutive patients with peripheral artery disease who underwent femoropopliteal stent implantation after initial failure of plain balloon angioplasty due to a significant residual stenosis (>30% lumen diameter reduction) or a flow limiting dissection. HCII activity was measured before stenting and patients were followed for median 10 months (interquartile range 6 to 17) for the occurrence of a first instent restenosis, defined as a >50% lumen diameter reduction by color coded duplex sonography and confirmed by angiography. Cumulative freedom from restenosis at 6 and 12 months in patients with lower HCII activity (100%, lower tertile, n=20) was 84% and 35% as compared to 93% and 72% in patients with high HCII activity (>100%, middle and upper tertile, n=43; p=0.024 by Log Rank test). Adjusting for the material of the implanted stents (nitinol vs. Wallstents), patients with a high HCII activity had a 0.39-fold reduced risk for instent restenosis (95% CI 0.17 to 0.90, p=0.028), additional adjustment for diabetes mellitus, poor run-off, critical limb ischemia and cumulative length of the stented segment did not alter the observed effect. Higher activity of heparin cofactor II may exert a protective effect against instent restenosis also in the femoropopliteal vessel area, confirming a prior observation after coronary stenting.

Inhibition of thrombin by antithrombin III and heparin cofactor II in vivo.

The critical role of thrombin in the pathogenesis of venous and arterial thrombosis, and the effectiveness of glycosaminoglycans as antithrombotic drugs are well known. Antithrombin III is a major inhibitor of thrombin and augmentation of its inhibitory actions by heparin is the basis for the clinical uses of heparin. Recent clinical and experimental studies have demonstrated that another glycosaminoglycan, dermatan sulfate, is an effective antithrombotic drug. Dermatan sulfate catalyses the inhibition of thrombin by heparin cofactor II. The concentrations of heparin cofactor II are higher in the plasmas of individuals with congenital antithrombin III deficiency and pregnant women than controls. The role of heparin cofactor II as a physiologic thrombin inhibitor is unknown. Enzyme-linked immunosorbent assays were used to quantify thrombin-heparin cofactor II and thrombin-antithrombin III endogenous to the plasmas of adult antithrombin III-Hamilton deficient subjects, their siblings with normal antithrombin III levels, pregnant women at term and 3 to 5 days after delivery. Both thrombin-antithrombin III and thrombin-heparin cofactor II complexed with vitronectin were detected in all the plasmas. Significantly, the concentrations of thrombin-heparin cofactor II-vitronectin were higher in the plasmas of congenital antithrombin III deficient subjects and in pre- and post-delivery plasmas than those of normal subjects. In addition, the concentrations of thrombin-heparin cofactor II decreased 3 to 5 days after delivery, reflecting the disappearance of the catalytically active dermatan sulfate elaborated by the placenta. Thus, heparin cofactor II normally inactivates thrombin in vivo, with its role increasing in conditions associated with high levels of heparin cofactor II and/or dermatan sulfate.

The influence of molecular weight on the biological activity of heparin like sulphated hyaluronic acids.

Sulphated hyaluronic acids having a sulphation degree of 3.5 per disaccharide unit, HyalS3.5, were prepared with different molecular weights corresponding to 21 x 10(3), 320 x 10(3) and 3500 x 10(3). The thrombin inhibition in plasma and in the presence of purified molecules, i.e. fibrinogen, antithrombin III (AT III) and heparin cofactor II (HC II), were studied for the three different MW compounds at different concentrations. The thrombin time in plasma depended on the length of the chain, and the two lower MW HyalS3.5 inhibited thrombin both by direct aspecific interaction and via HC II, whereas the activity of the highest MW compound was mainly related to the electrostatic interaction with HC II. The inactivation of FXa serine protease was only attributed to HyalS3.5-AT III complex.

Hypercoagulability and thrombosis.

This article has summarized known congenital and acquired alterations of hemostasis leading to thrombosis. Decreases in coagulation inhibitors, including antithrombin III, heparin cofactor II, and protein C and protein S, are of major importance in assessing patients with hypercoagulable states or patients with unexplained thrombosis. Newer assays for components of the fibrinolytic system, plasminogen, t-PA and t-PA inhibitor are also now readily available and are important for defining congenital or acquired fibrinolytic defects leading to hypercoagulability and thrombosis. By judicious use of these assays, combined with clinical evaluation, many patients with thrombosis will have an underlying etiologic blood protein defect defined. Delineating reasons for a thrombotic event is of obvious importance for planning long-term prophylactic therapy and for diagnosing and counseling afflicted family members. In this manner, newly found patients can be treated prophylactically before unalterable morbidity or mortality occurs.

Anticoagulant properties of a fucoïdan fraction.

Fucoïdans are a family of high molecular weight sulphated polysaccharides in the Mr range 8 x 10(5) -10(6), widely dispersed in brown seaweed cell wall. When extracted from several brown algae, they exhibit anticoagulant properties. The chemical degradation of a crude extract, from Pelvetia canaliculata, was undertaken to obtain a low molecular weight polysaccharide (Mr 20,000 +/- 5,000) with the purpose of a possible clinical use. Its anticoagulant potency was investigated through the inhibition of factor IIa and factor Xa in the presence of antithrombin III or heparin cofactor II. The degraded fucoïdan revealed a potent antithrombin activity: studied in an antithrombin III depleted plasma or in the presence of purified heparin cofactor II, the fucoïdan was as efficient as heparin and dermatan sulphate on heparin cofactor II potentiation, at the same concentration by weight. In whole plasma or in the presence of the purified inhibitor, an anti-factor IIa activity mediated by antithrombin III was detected (30 times less potent than for heparin, on a weight to weight basis). In contrast, no anti-factor Xa activity was detected in the presence of the degraded fucoïdan, under the same experimental conditions. These fucoïdans, by-products of alginates preparation in the food and cosmetologic industries, are obtained easily. Thus, they may represent a cheap and easy source of a new type of anticoagulants.

Heparin cofactor II significance for the inhibition of thrombin at the injured vessel wall.

The thrombin inhibitory role of antithrombin III (ATIII) and heparin cofactor II (HCII) was studied in vitro using intact and injured rabbit aortae. When intact vessels were loaded with thrombin and then exposed to either heat defibrinogenated human plasma (HDHP) or ATIII the same degree of thrombin inhibition was achieved demonstrating that ATIII was the only plasma component involved in thrombin inhibition on the intact vessel wall. When the media of the vessel wall was loaded with thrombin and then exposed to ATIII or HCII a significantly higher thrombin activity remained on the surface than when it was exposed to defibrinogenated plasma. A mixture of ATIII and HCII resulted in a greater inhibition of thrombin than ATIII or HCII alone. It is concluded that, contrary to what happens on the endothelium, HCII and ATIII inhibit additively thrombin on the injured vessel wall. HCII thus plays an essential role for the inhibition of thrombin at the injured vessel wall. It is also concluded that an additional plasma component participates in thrombin inhibition on the media but its contribution is negligible as compared with ATIII or HCII.

Thrombin-inhibitor complexes in the blood during and after delivery.

Activation of coagulation leads to generation of thrombin which in turn is inactivated by the formation of thrombin-antithrombin (TAT) complexes, and thrombin-heparin cofactor complexes (T-HCII). These complexes were measured in plasma by ELISA methods. During normal delivery, the median TAT level in ten women increased from 4.1 to 7.8 times the median normal reference level. There was great individual variation, and levels 42 and 56 times normal median were found in two women shortly after normal delivery. The median T-HCII levels increased only moderately from 2.3 to 3.1 times median normal reference. D-dimer values were elevated in 28 out of the 30 samples. In blood sampled 1-2 days after delivery, the median TAT level was 2.5 times the median normal reference. The median T-HCII level was now 5.6 times the median normal reference value. The values were stable during the first 4 days post partum, and there was little difference between those delivered vaginally or by Caesarean section (C-section). D-dimer values were above normal reference in all women, and higher in women delivered by C-section. In conclusion, increasing TAT levels during labour and delivery indicated generation of thrombin which was mainly inactivated by antithrombin. The T-HCII levels increased less during delivery. In the early post partum period, the T-HCII levels were relatively more increased than the TAT levels. These results suggest that intravascularly generated thrombin is preferably inactivated by antithrombin, even in parturient women. In the post partum period, formation of T-HCII complexes was more evident, possibly reflecting extravascular inactivation of thrombin.

Production of chemotactic peptides by neutrophil degradation of heparin cofactor II.

This study investigated the reaction of heparin cofactor II (HCII) with stimulated polymorphonuclear leukocytes (PMN). We have expanded upon previous studies showing that HCII can be degraded by stimulated PMN (Sie, P., Dupouy, D., Dol, F., and Boneu, B., Thromb. Res. 47, 657-664, 1987), and that chemotactic activity is produced when HCII is partially proteolyzed with purified leukocyte elastase or cathepsin G (Hoffman, M., Pratt, C.W., Brown, R.L., and Church, F.C., Blood, 73, 1682-1695, 1989). We found that HCII was proteolyzed by stimulated PMN, generating peptides with chemotactic activity. Both proteolysis and generation of chemotactic activity were inhibited by a specific leukocyte elastase inhibitor and by more general proteinase inhibitors. Leukocyte elastase activity was lost upon addition of either inhibitor. Heparin and dermatan sulfate altered the pattern of proteolysis. Our results suggest that HCII may be involved not only in functions related to thrombin inhibition but also in regulating acute inflammation.

[Heparin cofactor II, a thrombin inhibitor with a still not clarified physiologic role]. / Cofactor II de la heparina (HCII), un inhibidor de trombina cuyo rol fisiológico no está completamente esclarecido.

Heparin Cofactor II (HCII) is a glycoprotein in human plasma which inactivates thrombin rapidly in the presence of dermatan sulfate. Inhibition occurs by formation of a stable equimolar complex between HCII and thrombin. HCII association with thrombotic events has not always been observed, thus decreased HCII does not appear to be a strong risk factor for thromboembolic events. Reduced HCII levels have been detected in different clinical conditions, such as hepatic failure, disseminated intravascular coagulation, thalasemina, sickle cell anemia. Increased physiological levels have been found in pregnant women and oral contraception. In our laboratory, we measured HCII plasmatic levels in the normal Buenos Aires city population and in patients under different clinical conditions, such as sepsis, diabetis, burns, oral anticoagulation and in patients treated with heparin, hyperhomcysteinemia in whom septic and diabetic patients showed decreased values. HCII thrombin inhibition possibly takes place in extravascular sites where dermatan sulfate is present. HCII activity would be important in the regulation of wound healing, inflammation, or neuronal development.

[Protein C, protein S and heparin cofactor II--their significance as the regulatory factors in the blood coagulation cascade].

One of the major regulatory mechanisms operating in the blood coagulation cascade is the thrombomodulin-protein C anticoagulant pathway. It consists of thrombin, thrombomodulin, protein C (PC) and protein S (PS), and is initiated when the circulating zymogen PC is converted to activated PC (APC) by a thrombin-thrombomodulin complex on the surface of endothelial cells. The formed APC in the presence of its co-factor PS, downregulates the coagulation cascade by proteolytic inactivation of the procoagulant cofactors Va and VIIIa, and also enhances the fibrinolysis system by inhibition of plasminogen activator inhibitor 1. PS circulates in plasma in two forms in dynamic equilibrium. One is the free protein (approximately 40% of total PS in normal plasma) which has the APC cofactor activity; the other is the protein reversibly complexed to C4b-binding protein (C4bp), a regulatory component of the complement system. When bound to C4bp, PS can no longer function as a cofactor of APC. As complexing of PS with C4bp is regulated by the law of mass action, elevation of C4bp leads to reduced levels of free (active) PS. In comparison with antithrombin III, heparin cofactor II contributes less in neutralizing thrombin and has higher affinity to dermatan sulfate on the surface of vascular smooth muscle cells. Therefore, it is regarded as an extravascular antithrombin. Clinical evidence that these regulatory factors function as natural anticoagulants derives from the observation of patients with congenital deficiency of each factor suffering from severe venous and anterial thrombosis.(ABSTRACT TRUNCATED AT 250 WORDS)