Regulation and functions of the protein C anticoagulant pathway

The protein C pathway plays a critical role in the negative regulation of the blood clotting process. We recently identified an endothelial cell receptor for protein C/activated protein C (APC). The receptor is localized almost exclusively on endothelial cells of large vessels and is present at only trace levels or indeed absent from capillaries in most tissues. Patients with sepsis or lupus erythematosus exhibit elevated levels of plasma EPCR which migrates on gels as a single band and is fully capable of binding protein C/APC. There is no correlation with thrombomodulin levels, probably due to different vascular localizations and/or cellular release mechanisms. To understand the mechanisms by which EPCR plasma levels are elevated, we examined EPCR mRNA expression in a rat endotoxin shock model. The EPCR mRNA gene exhibited an early immediate gene response to endotoxin with the mRNA levels increasing nearly 4 fold in the first 3-6 hrs, before returning toward baseline. Plasma levels of EPCR also rose about 4 fold with little change in tissue EPCR levels. Both processes were markedly attenuated by hirudin suggesting that thrombin was responsible for increases in mRNA and plasma EPCR levels. At the level of mRNA, the induction is mediated by a thrombin response element in the 5' flanking region of the gene. Direct thrombin infusion and cell culture experiments support this contention. On endothelium, thrombin is capable of releasing cell surface EPCR and this process is blocked by the metalloproteinase inhibitor orthophenanthroline. Taken together these studies indicate that elevation in soluble plasma EPCR reflects endothelial cell activation in the larger vessels and is likely to be an indication of local thrombin generation near these vessel surfaces.     

Inflammation and the activated protein C anticoagulant pathway

After a coagulation stimulus, the blood clotting cascade amplifies largely unchecked until very high levels of thrombin are generated. Natural anticoagulant mechanisms (for example, the protein C anticoagulant pathway) are amplified to prevent excessive thrombin generation. Thrombin binds to thrombomodulin (TM) and this complex and then activates protein C approximately 1000 times faster than free thrombin. Protein C activation is enhanced approximately 20-fold further by the endothelial cell protein C receptor (EPCR). Activated protein C proteolytically inactivates factor Va (FVa) and FVIIIa, thereby blocking the amplification of the coagulation system, a process that is accelerated by protein S. TM not only accelerates protein C activation, but also decreases endothelial cell activation by blocking high-mobility group protein-B1 inflammatory functions and suppressing both nuclear factor-kappa B nuclear translocation and the mitogen-activated protein kinase pathways. The thrombin-TM complex also activates thrombin-activatable fibrinolysis inhibitor, a procarboxypeptidase that renders fibrin resistant to clot lysis and neutralizes vasoactive molecules such as complement C5a. Activated protein C has a variety of antiinflammatory activities. It suppresses inflammatory cytokine elevation in animal models of severe sepsis, inhibits leukocyte adhesion, decreases leukocyte chemotaxis, reduces endothelial cell apoptosis, helps maintain endothelial cell barrier function through activation of the sphingosine-1 phosphate receptor, and minimizes the decrease in blood pressure associated with severe sepsis. Most of these functions are dependent on binding to EPCR. Overall this pathway is critical to both regulation of the blood coagulation process, and control of the innate inflammatory response and some of its associated downstream pathologies.     

Exosite-dependent regulation of the protein C anticoagulant pathway

Activated protein C (APC) is a vitamin K-dependent anticoagulant serine protease in plasma that downregulates the coagulation cascade by degrading cofactors Va and VIIIa by limited proteolysis. In addition to its anticoagulant function, APC also exhibits potent profibrinolytic and anti-inflammatory properties. The proteolytic activity of APC in plasma is slowly inhibited by three serpins: protein C inhibitor, plasminogen activator inhibitor-1, and alpha(1)-antitrypsin. Recent structural and mutagenesis data have indicated that basic residues of three exposed surface loops known as the 39-loop (Lys(37)-Lys(39)), 60-loop (Lys(62), Lys(63)), and 70-80-loop (Arg(74), Arg(75), and Lys(78)) (chymotrypsin numbering) constitute an anion-binding exosite in APC that interacts with these macromolecular substrates and inhibitors. Moreover, this exosite plays a critical role in the thrombomodulin-dependent activation of the zymogen protein C by thrombin. This article briefly reviews how the binding of physiological protein and polysaccharide cofactors on this exosite modulates the protein C anticoagulant pathway in plasma.     

Progress in the understanding of the protein C anticoagulant pathway

A natural anticoagulant pathway denoted the protein C system provides specific and efficient control of blood coagulation. Protein C is the key component of the system and circulates in the blood as a zymogen to an anticoagulant serine protease. Activation of protein C is achieved on the surface of endothelial cells by thrombin bound to the membrane protein thrombomodulin. The endothelial protein C receptor stimulates the activation of protein C on the endothelium. Activated protein C (APC) modulates blood coagulation by cleaving a limited number of peptide bonds in factor VIIIa (FVIIIa) and factor Va (FVa), cofactors in the activation of factor X and prothrombin, respectively. Vitamin K-dependent protein S stimulates the APC-mediated regulation of coagulation. Not only is protein S involved in the degradation of FVIIIa, but so is FV, which in recent years has been found to be a Janus-faced protein with both procoagulant and anticoagulant potentials. A number of genetic defects affecting the anticoagulant function of the protein C system, eg, APC resistance (Arg506Gln or FV Leiden) and deficiencies of protein C and protein S constitute major risk factors of venous thrombosis. The protein C system also has anti-inflammatory and antiapoptotic potentials, the molecular mechanisms of which are beginning to be unraveled. APC has emerged in recent years as a useful therapeutic compound in the treatment of severe septic shock. The beneficial effect of APC is believed be due to both its anticoagulant and its anti-inflammatory properties.     

New insights into how blood clots: implications for the use of APTT and PT as coagulation screening tests and in monitoring of anticoagulant therapy.

Blood coagulation occurs efficiently on cell surfaces such as activated platelets and monocytes, and fibroblasts. It is initiated by limited amounts of tissue factor (TF) exposed at the sites of vascular injury that complexes with trace amounts of circulating factor VIIa (FVIIa). Additional FVIIa-TF complexes are formed from FVII-TF involving positive feedback loops, including FVIIa-TF as well as factors Xa and IXa as they are formed in subsequent steps. For sustained normal coagulation to proceed, effective in vivo activation of factor X requires the participation of factor IXa generated via the FVIIa-TF complex. This may, in part, be due to effective inhibition of factor Xa and FVIIa-TF complex by tissue factor pathway inhibitor that results in blockage of direct activation of factor X by the FVIIa-TF complex. Additional generation of factor Xa at injury sites may then proceed via the FIXa-VIIIa pathway. Thrombin generated from prothrombin via complex formation of prothrombin with FXa and FVa on phospholipid surfaces (prothrombinase complex) powerfully accelerates coagulation by activation of FVIII and FV, and sustains coagulation through activation of FXI. Thus, in light of our current understanding of how blood clots in vivo, it is clear that both prothrombin time (PT) and activated partial thromboplastin time (APTT) are highly artificial in vitro systems with major limitations. Nevertheless, these tests are quite useful as global screening tests for abnormalities in the intrinsic or extrinsic, as well as common, pathways of coagulation and for monitoring of anticoagulant therapy.     

An update on clinical and basic aspects of the protein C anticoagulant pathway

The protein C anticoagulant pathway provides a mechanism for regulating the coagulation process through the selective inactivation of factors Va and VIIIa. Recent studies have suggested that factor V may facilitate this process and that a mutation at one of the inactivation sites can contribute to resistance to activated protein C (APC) inactivation of factor Va. This appears to be a common cause of familial thrombophilia. The control mechanisms involved in factor Va inactivation have also begun to become more clear. Membrane surfaces seem to be critical to complete factor Va inactivation, and the membrane composition requirements for optimal anticoagulant activity are distinct from those of procoagulant reactions. Specifically, the APC anticoagulant activity requires phosphatidylethanolamine, whereas the prothrombin activation complex does not. These observations may partially explain thrombotic complications with antiphospholipid antibodies in which the some antibodies have been shown to react preferentially with phosphatidylethanolamine and could, therefore, selectively block APC function. Clinically, more complete studies on partial protein C deficiency indicate that, at least within families, the deficiency is a significant risk factor for thrombosis. The impact of deficiencies on thrombotic risk suggests that protein C or other components of the pathway may be useful therapeutic agents. The limited clinical experience in treating meningococcemia, warfarin-induced skin necrosis, and homozygous protein C deficiency with protein C concentrates suggests that this approach is safe and effective.     

Genome wide association study for plasma levels of natural anticoagulant inhibitors and protein C anticoagulant pathway: the MARTHA project

Deficiencies of antithrombin (AT), protein C (PC) and protein S (PS) or an impaired PC anticoagulant pathway increase the risk of venous thrombosis (VT). By conducting a genome-wide association study (GWAS) on two independent samples of VT patients totalling 951 subjects typed for 472 173 single nucleotide polymorphisms (SNPs), we observed that common SNPs explain 21% and 27% of the genetic variance of plasma AT and PS levels, even though no SNP reached genome-wide significance. For PC, we showed that two PROCR SNPs, rs867186 (Ser219Gly) and rs6060278, additionally explained c. 20% (P = 1·19 × 10(-31)) of the variance of plasma PC levels. We also observed that c. 40% of the remaining genetic variance of PC levels could be due to yet unidentified common SNPs. The PROCR locus was also found to explain c. 8% (P < 10(-10)) of agkistrodon contortrix venom (ACV) (exploring the PC pathway) variability which was under the main control of the F5 and F2 loci that further explained about 40% and 10%, respectively. We presented here the first GWAS for plasma AT and free-PS levels and ACV in Caucasian samples. We identified three independent loci associated with ACV (F2, F5 and PROCR) and replicated two independent effects on plasma PC levels at the PROCR locus.     

Dominant-negative suppression of HCN1- and HCN2-encoded pacemaker currents by an engineered HCN1 construct: insights into structure-function relationships and multimerization

I(f), a diastolic depolarizing current activated by hyperpolarization, is a key player in cardiac pacing. Despite the fact that I(f) has been known for over 20 years, the encoding genes, namely HCN1 to 4, have only recently been identified. Functional data imply that different HCN isoforms may coassemble to form heteromeric channel complexes, but little direct evidence is available. Subunit stoichiometry is also unknown. Although the pore region of HCN channels contains the glycine-tyrosine-glycine (GYG) signature motif found in K+-selective channels, they permeate both Na+ and K+. In the present study, we probed the functional importance of the GYG selectivity motif in pacemaker channels by replacing this triplet in HCN1 with alanines (GYG(349-351)AAA or HCN1-AAA). HCN1-AAA did not yield functional currents; coexpression of HCN1-AAA with wild-type (WT) HCN1 suppressed normal channel activity in a dominant-negative manner (55.2+/-3.2%, 68.3+/-4.3%, 78.7+/-1.6%, 91.7+/-0.8%, and 97.9+/-0.2% current reduction at -140 mV for WT:AAA cRNA ratios of 4:1, 3:1, 2:1, 1:1, and 1:2, respectively) without affecting gating (steady-state activation, activation and deactivation kinetics) or permeation (reversal potential) properties. HCN1-AAA coexpression, however, did not alter the expressed current amplitudes of Kv1.4 and Kv2.1 channels, indicating that its suppressive effect was channel-specific. Statistical analysis reveals that a single HCN channel is composed of 4 monomeric subunits. Interestingly, HCN1-AAA also inhibited HCN2 in a dominant-negative manner with the same efficacy. We conclude that the GYG motif is a critical determinant of ion permeation for HCN channels, and that HCN1 and HCN2 readily coassemble to form heterotetrameric complexes.     

Regulation of blood coagulation and thrombosis

The syndrome of the hereditary tendency to venous thrombosis or thrombophilia has been recognized only after the discovery of regulatory mechanisms of the haemostatic system. At present, several distinct defects are known as causes of this syndrome: antithrombin III deficiency, protein C deficiency, protein S deficiency, dysfibrinogenaemia and dysplasminogenaemia. It is likely that several additional defects will be found in the near future. Consequently, it is important that a family history be taken in all cases of 'spontaneous' venous thrombosis and that laboratory studies be done to identify any underlying defect in the regulation of the blood coagulation system. We present preliminary data, which suggest that the incidence of the thrombophilia syndrome is higher than that of the haemophilias.     

Coagulopathy after successful cardiopulmonary resuscitation following cardiac arrest: implication of the protein C anticoagulant pathway

OBJECTIVES: We investigated coagulation abnormalities in out-of-hospital cardiac arrest (OHCA) patients, with special attention to the protein C anticoagulant pathway. BACKGROUND: Successfully resuscitated cardiac arrest is followed by a systemic inflammatory response and by activation of coagulation, both of which may contribute to organ failure and neurological dysfunction. METHODS: Coagulation parameters were measured in all patients admitted after successfully resuscitated OHCA. RESULTS: At admission, 67 patients had a systemic inflammatory response with increased interleukin-6 and coagulation activity (thrombin-antithrombin complex), reduced anticoagulation (antithrombin, protein C, and protein S), activated fibrinolysis (plasmin-antiplasmin complex), and, in some cases, inhibited fibrinolysis (increased plasminogen activator inhibitor-1 with a peak on day 1). These abnormalities were more severe in patients who died within two days (50 of 67, 75%) and were most severe in patients dying from early refractory shock. Protein C and S levels were low compared to healthy volunteers and discriminated OHCA survivors from nonsurvivors. Furthermore, a subgroup of patients had a transient increase in plasma-activated protein C at admission followed by undetectable levels. This, along with an increase in soluble thrombomodulin over time, suggests secondary endothelial injury and dysfunction of the protein C anticoagulant pathway similar to that observed in severe sepsis. CONCLUSIONS: Major coagulation abnormalities were found after successful resuscitation of cardiac arrest. These abnormalities are consistent with secondary down-regulation of the thrombomodulin-endothelial protein C receptor pathway.     

Evaluation of a global screening assay for the investigation of the protein C anticoagulant pathway

We have evaluated a global screening test for the protein C pathway, the 'ProC Global' (Dade Behring Ltd, Milton Keynes, UK). Patient groups tested included inherited protein C or S deficient and inherited/acquired activated protein C resistance. Results showed that protein C deficiencies and activated protein C resistance could be successfully detected with this test whereas deficiencies of protein S were less readily distinguished from the normal population. The ProC Global was unreliable in patients with antiphospholipid antibodies, raised plasma factor VIII:C and in those receiving oral anticoagulant therapy.     

Inhibition of activated protein C anticoagulant activity by prothrombin

In this study, we test the hypothesis that prothrombin levels may modulate activated protein C (APC) anticoagulant activity. Prothrombin in purified systems or plasma dramatically inhibited the ability of APC to inactivate factor Va and to anticoagulate plasma. This was not due solely to competition for binding to the membrane surface, as prothrombin also inhibited factor Va inactivation by APC in the absence of a membrane surface. Compared with normal factor Va, inactivation of factor Va Leiden by APC was much less sensitive to prothrombin inhibition. This may account for the observation that the Leiden mutation has less of an effect on plasma-based clotting assays than would be predicted from the purified system. Reduction of protein C levels to 20% of normal constitutes a significant risk of thrombosis, yet these levels are observed in neonates and patients on oral anticoagulant therapy. In both situations, the correspondingly low prothrombin levels would result in an increased effectiveness of the remaining functional APC of approximately 5-fold. Thus, while the protein C activation system is impaired by the reduction in protein C levels, the APC that is formed is a more effective anticoagulant, allowing protein C levels to be reduced without significant thrombotic risk. In situations where prothrombin is high and protein C levels are low, as in early stages of oral anticoagulant therapy, the reduction in protein C would result only in impaired function of the anticoagulant system, possibly explaining the tendency for warfarin-induced skin necrosis.     

Brothers and sisters: molecular insights into arterial-venous heterogeneity

The molecular differences between arteries and veins are genetically predetermined and are evident even before the first embryonic heart beat. Although ephrinB2 and EphB4 are expressed in cells that will ultimately differentiate into arteries and veins, respectively, many other genes have been shown to play a significant role in cell fate determination. The expression patterns of ephrinB2 and EphB4 are restricted to arterial-venous boundaries, and Eph/ephrin signaling provides repulsive cues at arterial-venous boundaries that are thought to prevent intermixing of arterial- and venous-fated cells. However, the maintenance of arterial-venous fate is susceptible to some degree of plasticity. Thus, in response to signals from the ambient microenvironment and shear stress, there is flow-mediated intercalation of the arteries and veins that ultimately leads to the formation of a functional, closed-loop circulation. In addition, cells in the blood vessels of each organ undergo epigenetic, morphological, and functional adaptive changes that are specific to the proximate function of their cognate organ(s). These adaptive changes result in an interorgan and intraorgan vessel heterogeneity that manifest clinically in a disparate response of different organs to identical risk factors and injury in the same animal. In this review, we focus on the molecular and physiological factors influencing arterial-venous heterogeneity between and within different organ(s). We explore arterial-venous differences in selected organs, as well as their respective endothelial cell architectural organization that results in their inter- and intraorgan heterogeneity.     

The mammalian fatty acid-binding protein multigene family: molecular and genetic insights into function.

Intracellular fatty acid-binding proteins associate with fatty acids and other hydrophobic biomolecules in an internal cavity, providing for solubilization and metabolic trafficking. Analyses of their in vivo function by molecular and genetic techniques reveal specific function(s) that fatty acid-binding proteins perform with respect to fatty acid uptake, oxidation and overall metabolic homeostasis.