Defining the factor Xa-binding site on factor Va by site-directed glycosylation

Activated Factor V (FVa) functions as a membrane-bound cofactor to the enzyme Factor Xa (FXa) in the conversion of prothrombin to thrombin, increasing the catalytic efficiency of FXa by several orders of magnitude. To map regions on FVa that are important for binding of FXa, site-directed mutagenesis resulting in novel potential glycosylation sites on FV was used as strategy. The consensus sequence for N-linked glycosylation was introduced at sites, which according to a computer model of the A domains of FVa, were located at the surface of FV. In total, thirteen different regions on the FVa surface were probed, including sites that are homologous to FIXa-binding sites on FVIIIa. The interaction between the FVa variants and FXa and prothrombin were studied in a functional prothrombin activation assay, as well as in a direct binding assay between FVa and FXa. In both assays, the four mutants carrying a carbohydrate side chain at positions 467, 511, 652, or 1683 displayed attenuated FXa binding, whereas the prothrombin affinity was unaffected. The affinity toward FXa could be restored when the mutants were expressed in the presence of tunicamycin to inhibit glycosylation, indicating the lost FXa affinity to be caused by the added carbohydrates. The results suggested regions surrounding residues 467, 511, 652, and 1683 in FVa to be important for FXa binding. This indicates that the enzyme:cofactor assembly of the prothrombinase and the tenase complexes are homologous and provide a useful platform for further investigation of specific structural elements involved in the FVa.FXa complex assembly.     

Thrombin-mediated proteolysis of factor V resulting in gradual B-domain release and exposure of the factor Xa-binding site

To investigate the relationship between the individual thrombin cleavages in factor V (FV) and the generation of activated factor X (FXa) cofactor activity, recombinant FV mutants having the cleavage sites eliminated separately or in combination were used. After thrombin incubation, the ability of the FV variants to bind FXa and support prothrombin activation was tested. The interaction between FVa and FXa on the surface of phospholipid was investigated with a direct binding assay as well as in a functional prothrombin activation assay. FV mutated at all cleavage sites functioned poorly as FXa cofactor in prothrombin activation, the apparent K(d) for FXa being approximately 10 nm. Fully activated wild type FVa, yielded an apparent K(d) of around 0.2 nm. The Arg(709) and Arg(1018) cleavages occurred at low thrombin concentrations and decreased the K(d) for FXa binding 5- and 3-fold, respectively. The Arg(1545) cleavage, being less sensitive to thrombin, decreased the K(d) for FXa binding approximately 20-fold. The K(m) for prothrombin was the same for all FV variants, demonstrating B-domain dissociation to result in exposure of binding site for FXa but not for prothrombin. In conclusion, we demonstrate FV activation to be associated with the stepwise release of the B-domain, which results in a gradual exposure of the FXa-binding site.     

Characterization of a factor Xa binding site on factor Va near the Arg-506 activated protein C cleavage site

Prothrombin is proteolytically activated by the prothrombinase complex comprising the serine protease Factor (F) Xa complexed with its cofactor, FVa. Based on inhibition of the prothrombinase complex by synthetic peptides, FVa residues 493-506 were proposed as a FXa binding site. FVa is homologous to FVIIIa, the cofactor for the FIXa protease, in the FX-activating complex, and FVIIIa residues 555-561 (homologous to FVa residues 499-506) are recognized as a FIXa binding sequence. To test the hypothesis that FVa residues 499-505 contribute to FXa binding, we created the FVa loop swap mutant (designated 499-505(VIII) FV) with residues 499-505 replaced by residues 555-561 of FVIIIa, which differ at five of seven positions. Based on kinetic measurements and spectroscopic titrations, this FVa loop swap mutant had significantly reduced affinity for FXa. The fully formed prothrombinase complex containing this FVa mutant had fairly normal kinetic parameters (k(cat) and K(m)) for cleavage of prothrombin at Arg-320. However, small changes in both Arg-320 and Arg-271 cleavage rates result together in a moderate change in the pathway of prothrombin activation. Although residues 499-505 directly precede the Arg-506 cleavage site for activated protein C (APC), the 499-505(VIII) FVa mutant was inactivated entirely normally by APC. These results suggest that this A2 domain sequence of the FVa and FVIIIa cofactors evolved to have different specificity for binding FXa and FIXa while retaining compatibility as substrate for APC. In an updated three-dimensional model for the FVa structure, residues 499-505, along with Arg-506, Arg-306, and other previously suggested FXa binding sequences, delineate a continuous surface on the A2 domain that is strongly implicated as an extended FXa binding surface in the prothrombinase complex.     

Binding sites for blood coagulation factor Xa and protein S involving residues 493-506 in factor Va.

Inactivation due to cleavage of Factor Va (FVa) at Arg 506 by activated protein C (APC) helps to downregulate blood coagulation. To identify potential functional roles of amino acids near Arg 506, synthetic overlapping pentadecapeptides comprising FVa heavy chain residues 481-525 were tested for their ability to inhibit prothrombin activation by prothrombinase complexes [Factor Xa (FXa):FVa:phospholipids:Ca2+]. The most potent inhibition was observed for peptide VP493 (residues 493-506), with 50% inhibition at 2.5 microM. VP493 also inhibited FXa in plasma in FXa-1-stage clotting assays by 50% at 3 microM. When the C-terminal carboxamide group of VP493 was replaced by a carboxyl group, most prothrombinase inhibitory activity was lost. VP493 preincubated with FXa inhibited prothrombinase with a pattern of mixed inhibition. Homologous peptides from Factor VIII sequences did not inhibit prothrombinase. Affinity-purified antibodies to VP493 inhibited prothrombinase activity and prolonged FXa-1-stage clotting times. VP493 also blocked the ability of protein S to inhibit prothrombinase independently of APC. Immobilized VP493 bound specifically with similar affinity to both FXa and protein S (Kd approximately 40 nM), but did not measurably bind prothrombin or APC. These studies suggest that FVa residues 493-506 contribute to binding sites for both FXa and protein S, providing a rationale for the ability of protein S to negate the protective effect of FXa toward APC cleavage of FVa. Possible loss of this FVa binding site for FXa due to cleavage at Arg 506 by APC may help explain why this cleavage causes 40% decrease in FVa activity and facilitates inactivation of FVa.     

Effects of prothrombin on the individual activated protein C-mediated cleavages of coagulation factor Va

The factor Va (FVa) inactivation by activated protein C (APC), mediated by cleavages at Arg306 and Arg506 in FVa, is inhibited by both factor Xa (FXa) and prothrombin. Although FXa is known to specifically inhibit the Arg506 cleavage, the effect of prothrombin has not been confined to one cleavage site. We used recombinant FV variants, FV:R506Q/R679Q and FV:R306Q/R679Q, to investigate the effect of prothrombin on the individual cleavage sites. The APC-mediated FVa inhibition was monitored by a prothrombinase-based FVa assay, and apparent first order rate constants were calculated for each of the cleavage sites both in the presence and absence of prothrombin. Prothrombin impaired cleavages at both Arg306 and Arg506 and the inhibition correlated with a delayed appearance of proteolytic products on Western blots. Almost complete inhibition was obtained at around 3 microm prothrombin, whereas half-maximal inhibition was obtained at 0.7 microm prothrombin. After cleavage of prothrombin by thrombin, the inhibitory activity was lost. The inhibitory effect of prothrombin on APC-mediated inhibition of FVa was seen both in the presence and absence of protein S, but in particular for the Arg306 sites, it was more pronounced in the presence of protein S. Thus, prothrombin inhibition of APC inactivation of FVa appears to be due to both impaired APC function and decreased APC cofactor function of protein S. In conclusion, FVa, being part of the prothrombinase complex, is protected from APC by both FXa and prothrombin. Release of products of prothrombin activation from the prothrombinase complex would alleviate the protection, allowing APC-mediated inactivation of FVa.     

Role of Hirudin-like factor Va heavy chain sequences in prothrombinase function

Proexosite I on prothrombin has been implicated in providing a recognition site for factor Va within prothrombinase. To examine whether hirudin-like sequences (659-698) on the cofactor contribute to this interaction, we expressed and purified two-chain FVa derivatives that were intracellularly truncated at the C terminus of the heavy chain: FVa709 (des710-1545), FVa699 (des700-1545), FVa(692 (des693-1545), FVa678 (des679-1545), and FVa658 (des659-1545). We found that FVa709, FVa699, FVa692, and FVa678 exhibited specific clotting activities that were comparable with plasma-derived and recombinant FVa. Additionally, kinetic studies using prothrombin revealed that the Km and kcat values for these derivatives were unaltered. Fluorescent measurements and chromatography studies indicated that FVa709, FVa699, FVa692, and FVa678 bound to FXa membranes and thrombin-agarose in a manner that was comparable with the wild-type cofactors. In contrast, FVa658 had an approximately 1% clotting activity and reduced affinity for FXa membranes (approximately 20-fold) and did not bind to thrombin-agarose. Surprisingly, however, FVa(658) exhibited essentially normal kinetic parameters for prothrombin when the variant was fully saturated with FXa membranes. Overall our results are consistent with the interpretation that any possible binding interactions between prothrombin and the C-terminal region of the FVa heavy chain do not contribute in a detectable way to the enhanced function of prothrombinase.     

Functional properties of recombinant factor V mutated in a potential calcium-binding site

Activated coagulation factor V (FVa) is a cofactor of activated factor X (FXa) in prothrombin activation. FVa is composed of a light chain (LC) and a heavy chain (HC) that are noncovalently associated in a calcium-dependent manner. We constructed a recombinant FV Asp111Asn/Asp112Asn mutant (rFV-NN) to abolish calcium binding to a potential calcium-binding site in FVa in order to study the specific role of these residues in the expression of FVa activity. Whereas thrombin-activated recombinant FV wild type (rFV-wt) presented with stable FVa activity, incubation of rFV-NN with thrombin resulted in a temporary increase in FVa activity, which was rapidly lost upon prolonged incubation. Loss of FVa activity was most likely due to dissociation of HC and LC since, upon chromatography of rFVa-NN on a SP-Sepharose column, the HC did not bind significantly to the resin whereas the LC bound and could be eluted at high ionic strength. In contrast, rFVa-wt adhered to the column, and both the HC and LC coeluted at high ionic strength. In the presence of phospholipid vesicles, the loss of rFVa-NN activity was partially prevented by FXa, active site inhibited FXa, and prothombin in a dose-dependent manner. We conclude that the introduced amino acid substitutions result in a loss of the high-affinity (calcium-dependent) interaction of the HC and LC of FVa. We propose that the introduced substitutions disrupt the calcium-binding site in FV, thereby yielding a FV molecule that rapidly loses activity following thrombin-catalyzed activation most likely via dissociation of the HC and LC.     

Interdomain engineered disulfide bond permitting elucidation of mechanisms of inactivation of coagulation factor Va by activated protein C

Procoagulant factor Va (FVa) is inactivated via limited proteolysis at three Arg residues in the A2 domain by the anticoagulant serine protease, activated protein C (APC). Cleavage by APC at Arg306 in FVa causes dissociation of the A2 domain from the heterotrimeric A1:A2:A3 structure and complete loss of procoagulant activity. To help distinguish inactivation mechanisms involving A2 domain dissociation from inactivation mechanisms involving unfavorable changes in factor Xa (FXa) affinity, we used our FVa homology model to engineer recombinant FVa mutants containing an interdomain disulfide bond (Cys609-Cys1691) between the A2 and A3 domains (A2-SS-A3 mutants) in addition to cleavage site mutations, Arg506Gln and Arg679Gln. SDS-PAGE analysis showed that the disulfide bond in A2-SS-A3 mutants prevented dissociation of the A2 domain. In the absence of A2 domain dissociation from the A1:A2:A3 trimer, APC cleavage at Arg306 alone caused a sevenfold decrease in affinity for FXa, whereas APC cleavages at Arg306, Arg506, and Arg679 caused a 70-fold decrease in affinity for FXa and a 10-fold decrease in the k(cat) of the prothrombinase complex for prothrombin without any effect on the apparent K(m) for prothrombin. Therefore, for FVa inactivation by APC, dissociation of the A2 domain may provide only a modest final step, whereas the critical events are the cleavages at Arg506 and Arg306, which effectively inactivate FVa before A2 dissociation can take place. Nonetheless, for FVa Leiden (Gln506-FVa) inactivation by APC, A2 domain dissociation may become mechanistically important, depending on the ambient FXa concentration.     

Expression of allosteric linkage between the sodium ion binding site and exosite I of thrombin during prothrombin activation

The specificity of thrombin for procoagulant and anticoagulant substrates is regulated allosterically by Na+. Ordered cleavage of prothrombin (ProT) at Arg320 by the prothrombinase complex generates proteolytically active, meizothrombin (MzT), followed by cleavage at Arg271 to produce thrombin and fragment 1.2. The alternative pathway of initial cleavage at Arg271 produces the inactive zymogen form, the prethrombin 2 (Pre 2).fragment 1.2 complex, which is cleaved subsequently at Arg320. Cleavage at Arg320 of ProT or prethrombin 1 (Pre 1) activates the catalytic site and the precursor form of exosite I (proexosite I). To determine the pathway of expression of Na+-(pro)exosite I linkage during ProT activation, the effects of Na+ on the affinity of fluorescein-labeled hirudin-(54-65) ([5F]Hir-(54-65)(SO-3)) for the zymogens, ProT, Pre 1, and Pre 2, and for the proteinases, MzT and MzT-desfragment 1 (MzT(-F1)) were quantitated. The zymogens showed no significant linkage between proexosite I and Na+, whereas cleavage at Arg320 caused the affinities of MzT and MzT(-F1) for [5F]Hir-(54-65)(SO-3) to be enhanced by Na+ 8- to 10-fold and 5- to 6-fold, respectively. MzT and MzT(-F1) showed kinetically different mechanisms of Na+ enhancement of chromogenic substrate hydrolysis. The results demonstrate for the first time that MzT is regulated allosterically by Na+. The results suggest that the distinctive procoagulant substrate specificity of MzT, in activating factor V and factor VIII on membranes, and the anticoagulant, membrane-modulated activation of protein C by MzT bound to thrombomodulin are regulated by Na+-induced allosteric transition. Further, the Na+ enhancement in MzT activity and exosite I affinity may function in directing the sequential ProT activation pathway by accelerating thrombin formation from the MzT fast form.     

Importance of individual activated protein C cleavage site regions in coagulation factor V for factor Va inactivation and for factor Xa activation.

Activated protein C (APC) cleavage of Factor Va (FVa) at residues R506 and R306 correlates with its inactivation. APC resistance and increased thrombotic risk are due to the mutation R506Q in Factor V (FV). To study the effects of individual cleavages in FVa by APC and the importance of regions near the cleavage sites, the following recombinant (r) human FVs were prepared and purified: wild-type, Q306-rFV, Q506-rFV, and Q306Q506-rFV. All had similar time courses for thrombin activation. Q506-rFVa was cleaved by APC at R306 and was moderately resistant to APC in plasma-clotting assays and in prothrombinase assays measuring FVa residual activity, in agreement with studies of purified plasma-derived Q506-FVa. Q306-rFVa was cleaved by APC at R506 and gave a low APC-resistance ratio similar to Q506-rFVa in clotting assays, whereas unactivated Q306-rFV gave a near-normal APC-resistance ratio. When FVa residual activity was measured after long exposure to APC, Q306-rFVa was inactivated by only < or = 40% under conditions where Q506-rFVa was inactivated > 90%, supporting the hypothesis that efficient inactivation of normal FVa by APC requires cleavage at R306. In addition, the heavy chain of Q306-rFVa was cleaved at R506 much more rapidly than activity was lost, suggesting that FVa cleaved at only R506 is partially active. Under the same conditions, Q306Q506-rFVa lost no activity and was not cleaved by APC. Therefore, cleavage at either R506 or R306 appears essential for significant inactivation of FVa by APC. Modest loss of activity, probably due to cleavage at R679, was observed for the single site rFVa mutants, as evidenced by a second phase of inactivation. Q306Q506-rFVa had a low activity-to-antigen ratio of 0.50-0.77, possibly due to abnormal Factor Xa (FXa) binding. Furthermore, Q306Q506-rFV was very resistant to cleavage and activation by FXa. Q306Q506-rFV appeared to bind FXa and inhibit FXa's ability to activate normal FV. Thus, APC may downregulate FV/Va partly by impairing FXa-binding sites upon cleavage at R306 and R506. This study shows that R306 is the most important cleavage site for normal efficient inactivation of FVa by APC and supports other studies suggesting that regions near R306 and R506 provide FXa-binding sites and that FVa cleaved at only R506 retains partial activity.     

Role of the Gla and first epidermal growth factor-like domains of factor X in the prothrombinase and tissue factor-factor VIIa complexes

Factor X (FX) has high structure homology with other proteins of blood coagulation such as factor IX (FIX) and factor VII (FVII). These proteins present at their amino-terminal extremity a gamma-carboxyglutamic acid containing domain (Gla domain), followed by two epidermal growth factor-like (EGF1 and EGF2) domains, an activation peptide, and a serine protease domain. After vascular damage, the tissue factor-FVIIa (TF-FVIIa) complex activates both FX and FIX. FXa interacts stoichiometrically with tissue pathway inhibitor (TFPI), regulating TF-FVIIa activity by forming the TF-FVIIa-TFPI-FXa quaternary complex. Conversely, FXa boosts coagulation by its association with its cofactor, factor Va (FVa). To investigate the contribution of the Gla and EGF1 domains of FX in these complexes, FX chimeras were produced in which FIX Gla and EGF1 domains substituted the corresponding domains of FX. The affinity of the two chimeras, FX/FIX(Gla) and FX/FIX(EGF1), for the TF-FVIIa complex was markedly reduced compared with that of wild-type-FX (wt-FX) independently of the presence of phospholipids. Furthermore, the association rate constants of preformed FX/FIX(Gla)-TFPI and FX/FIX(EGF1)-TFPI complexes with TF-FVIIa were, respectively, 10- and 5-fold slower than that of wt-FXa-TFPI complex. Finally, the apparent affinity of FVa was 2-fold higher for the chimeras than for wt-FX in the presence of phospholipids and equal in their absence. These data demonstrate that FX Gla and EGF1 domains contain residues, which interact with TF-FVIIa exosites contributing to the formation of the TF-FVIIa-FX and TF-FVIIa-TFPI-FXa complexes. On the opposite, FXa Gla and EGF1 domains are not directly involved in FVa binding.     

Structural investigation of the A domains of human blood coagulation factor V by molecular modeling.

Factor V (FV) is a large (2,196 amino acids) nonenzymatic cofactor in the coagulation cascade with a domain organization (A1-A2-B-A3-C1-C2) similar to the one of factor VIII (FVIII). FV is activated to factor Va (FVa) by thrombin, which cleaves away the B domain leaving a heterodimeric structure composed of a heavy chain (A1-A2) and a light chain (A3-C1-C2). Activated protein C (APC), together with its cofactor protein S (PS), inhibits the coagulation cascade via limited proteolysis of FVa and FVIIIa (APC cleaves FVa at residues R306, R506, and R679). The A domains of FV and FVIII share important sequence identity with the plasma copper-binding protein ceruloplasmin (CP). The X-ray structure of CP and theoretical models for FVIII have been recently reported. This information allowed us to build a theoretical model (994 residues) for the A domains of human FV/FVa (residues 1-656 and 1546-1883). Structural analysis of the FV model indicates that: (a) the three A domains are arranged in a triangular fashion as in the case of CP and the organization of these domains should remain essentially the same before and after activation; (b) a Type II copper ion is located at the A1-A3 interface; (c) residues R306 and R506 (cleavage sites for APC) are both solvent exposed; (d) residues 1667-1765 within the A3 domain, expected to interact with the membrane, are essentially buried; (e) APC does not bind to FVa residues 1865-1874. Several other features of factor V/Va, like the R506Q and A221V mutations; factor Xa (FXa) and human neutrophil elastase (HNE) cleavages; protein S, prothrombin and FXa binding, are also investigated.     

Restoring the Procofactor State of Factor Va-like Variants by Complementation with B-domain Peptides

Coagulation factor V (FV) circulates as an inactive procofactor and is activated to FVa by proteolytic removal of a large inhibitory B-domain. Conserved basic and acidic sequences within the B-domain appear to play an important role in keeping FV as an inactive procofactor. Here, we utilized recombinant B-domain fragments to elucidate the mechanism of this FV autoinhibition. We show that a fragment encoding the basic region (BR) of the B-domain binds with high affinity to cofactor-like FV(a) variants that harbor an intact acidic region. Furthermore, the BR inhibits procoagulant function of the variants, thereby restoring the procofactor state. The BR competes with FXa for binding to FV(a), and limited proteolysis of the B-domain, specifically at Arg¹⁵⁴⁵, ablates BR binding to promote high affinity association between FVa and FXa. These results provide new insight into the mechanism by which the B-domain stabilizes FV as an inactive procofactor and reveal how limited proteolysis of FV progressively destabilizes key regulatory regions of the B-domain to produce an active form of the molecule.     

A bipartite autoinhibitory region within the B-domain suppresses function in factor V

Activation of blood coagulation factor V (FV) is a key reaction of hemostasis. FV circulates in plasma as an inactive procofactor, and proteolytic removal of a large central B-domain converts it to an active cofactor (FVa) for factor Xa (FXa). Here we show that two short evolutionary conserved segments of the B-domain, together termed the procofactor regulatory region, serve an essential autoinhibitory function. This newly identified motif consists of a basic (963-1008) and an acidic (1493-1537) region and defines the minimal sequence requirements to maintain FV as a procofactor. Our data suggest that dismantling this autoinhibitory region via deletion or proteolysis is the driving force to unveil a high affinity binding site(s) for FXa. These findings document an unexpected sequence-specific role for the B-domain by negatively regulating FV function and preventing activity of the procofactor. These new mechanistic insights point to new ways in which the FV procofactor to cofactor transition could be modulated to alter hemostasis.     

The conformational switch from the factor X zymogen to protease state mediates exosite expression and prothrombinase assembly

Zymogens of the chymotrypsin-like serine protease family are converted to the protease state following insertion of a newly formed, highly conserved N terminus. This transition is accompanied by active site formation and ordering of several surface loops in the catalytic domain. Here we show that disruption of this transition in factor X through mutagenesis (FXa(I16L) and FXa(V17A)) not only alters active site function, but also significantly impairs Na(+) and factor Va binding. Active site binding was improved in the presence of high NaCl or with saturating amounts of factor Va membranes, suggesting that allosteric linkage exists between these sites. In line with this, irreversible stabilization of FXa(I16L) with Glu-Gly-Arg-chloromethyl ketone fully rescued FVa binding. Furthermore, the K(m) for prothrombin conversion with the factor Xa variants assembled into prothrombinase was unaltered, whereas the k(cat) was modestly reduced (3- to 4-fold). These findings show that intramolecular activation of factor X following the zymogen to protease transition not only drives catalytic site activation but also contributes to the formation of the Na(+) and factor Va binding sites. This structural plasticity of the catalytic domain plays a key role in the regulation of exosite expression and prothrombinase assembly.     

Effects of factor Xa and protein S on the individual activated protein C-mediated cleavages of coagulation factor Va

Activated protein C inhibits the procoagulant function of activated factor V (FVa) through proteolytic cleavages at Arg-306, Arg-506, and Arg-679. The cleavage at Arg-506 is kinetically favored but protected by factor Xa (FXa). Protein S has been suggested to annihilate the inhibitory effect of FXa, a proposal that has been challenged. To elucidate the effects of FXa and protein S on the individual cleavage sites of FVa, we used recombinant FVa:Q306/Q679 and FVa:Q506/Q679 variants, which can only be cleaved at Arg-506 and Arg-306, respectively. In the presence of active site blocked FXa (FXa-1.5-dansyl-Glu-Gly-Arg), the FVa inactivation was followed over time, and apparent second order rate constants were calculated. Consistent with results on record, we observed that FXa-1.5-dansyl-Glu-Gly-Arg decreased the Arg-506 cleavage by 20-fold, with a half-maximum inhibition of approximately 2 nM. Interestingly and in contrast to the inhibitory effect of FXa on the 506 cleavage, FXa stimulated the Arg-306 cleavage. Protein S counteracted the inhibition by FXa of the Arg-506 cleavage, whereas protein S and FXa yielded additive stimulatory effect of the cleavage at Arg-306. This suggests that FXa and protein S interact with distinct sites on FVa, which is consistent with the observed lack of inhibitory effect on FXa binding to FVa by protein S. We propose that the apparent annihilation of the FXa protection of the Arg-506 cleavage by protein S is due to an enhanced rate of Arg-506 cleavage of FVa not bound to FXa, resulting in depletion of free FVa and dissociation of FXa-FVa complexes.     

A novel anticoagulant protein with high affinity to blood coagulation factor Va from Tegillarca granosa

A novel inhibitory protein against blood coagulation factor Va (FVa) was purified from muscle protein of granulated ark (Tegillarca granosa, order Arcoida, marine bivalvia) by consecutive FPLC method using anion exchange and gel permeation chromatography. In the results of ESIQTOF tandem mass analysis and database research, it was revealed that the purified T. granosa anticoagulant protein (TGAP) has 7.7 kDa of molecular mass and its partial sequence, HTHLQRAPHPNALGYHGK, has a high identity (64%) with serine/threonine kinase derived from Rhodopirellula baltica (order Planctomycetales, marine bacteria). TGAP could potently prolong thrombin time (TT), corresponding to inhibition of thrombin (FIIa) formation. Specific factor inhibitory assay showed that TGAP inhibits FVa among the major components of prothrombinase complex. In vitro assay for direct-binding affinity using surface plasmon resonance (SPR) spectrometer indicated that TGAP could be directly bound with FVa. In addition, the binding affinity of FVa to FII was decreased by addition of TGAP in dose-dependant manner (IC50 value = 77.9 nM). These results illustrated that TGAP might interact with a heavy chain of FVa (FVa(H)) bound to FII in prothrombin complex. The present study elucidated that non-cytotoxic T. granosa anticoagulant protein (TGAP) bound to FVa can prolong blood coagulation time by inhibiting conversion of FII to FIIa in blood coagulation cascade. In addition, TGAP did not significantly (P < 0.05) show fibrinolytic activity and cytotoxicity on venous endothelial cell line (ECV 304).     

Role of the alpha-helix 163-170 in factor Xa catalytic activity

Factor Xa (FXa) is a key protease of the coagulation pathway whose activity is known to be in part modulated by binding to factor Va (FVa) and sodium ions. Previous investigations have established that solvent-exposed, charged residues of the FXa alpha-helix 163-170 (h163-170), Arg(165) and Lys(169), participate in its binding to FVa. In the present study we aimed to investigate the role of the other residues of h163-170 in the catalytic functions of the enzyme. FX derivatives were constructed in which point mutations were made or parts of h163-170 were substituted with the corresponding region of either FVIIa or FIXa. Purified FXa derivatives were compared with wild-type FXa. Kinetic studies in the absence of FVa revealed that, compared with wild-type FXa, key functional parameters (catalytic activity toward prothrombin and tripeptidyl substrates and non-enzymatic interaction of a probe with the S1 site) were diminished by mutations in the NH(2)-terminal portion of h163-170. The defective amidolytic activity of these FXa derivatives appears to result from their impaired interaction with Na(+) because using a higher Na(+) concentration partially restored normal catalytic parameters. Furthermore, kinetic measurements with tripeptidyl substrates or prothrombin indicated that assembly of these FXa derivatives with an excess of FVa in the prothrombinase complex improves their low catalytic efficiency. These data indicate that residues in the NH(2)-terminal portion of the FVa-binding h163-170 are energetically linked to the S1 site and Na(+)-binding site of the protease and that residues Val(163) and Ser(167) play a key role in this interaction.     

Soluble phosphatidylserine triggers assembly in solution of a prothrombin-activating complex in the absence of a membrane surface

Factor X(a) (FX(a)) binding to factor V(a) (FV(a)) on platelet-derived membranes containing surface-exposed phosphatidylserine (PS) forms the "prothrombinase complex" that is essential for efficient thrombin generation during blood coagulation. There are two naturally occurring isoforms of FV(a), FV(a1) and FV(a2). These two isoforms differ by a 3-kDa polysaccharide chain (at Asn(2181) in human FV(a1) (Kim, S. W., Ortel, T. L., Quinn-Allen, M. A., Yoo, L., Worfolk, L., Zhai, X., Lentz, B. R., and Kane, W. H. (1999) Biochemistry 38, 11448-11454)) and have different coagulant activities. We examined the interaction of the two bovine isoforms with active site-labeled FX(a), finding no significant difference. A soluble form of PS (C6PS) bound to FV(a1) and FV(a2) with comparable affinities (K(d) = 11-12 microm) and changes in FV(a) intrinsic fluorescence. At concentrations well below its critical micelle concentration, C6PS binding to bovine FV(a2) enhanced its affinity for FX(a) in solution by nearly 3 orders of magnitude (K(d)(eff) = 40-2 nm over a C6PS range of 30-400 microm) but had no effect on the affinity of FV(a1) for FX(a) (K(d) = 1 microm). This results in a soluble complex between FX(a) and FV(a2), whose expected molecular weight was confirmed by calibrated native gel electrophoresis. This complex behaved as a normal Michaelis-Menten enzyme in its ability to produce thrombin from meizothrombin (apparent k(cat)/K(m) congruent with 10(9) m(-1) s(-1)). The ability of soluble PS to trigger formation of a soluble prothrombinase complex suggests that exposure of PS molecules during platelet activation is likely the key event responsible for the assembly of an active membrane-bound complex.     

Unique in vivo modifications of coagulation factor V produce a physically and functionally distinct platelet-derived cofactor: characterization of purified platelet-derived factor V/Va

Platelet- and plasma-derived factor Va (FVa) serve essential cofactor roles in prothrombinase-catalyzed thrombin generation. Platelet-derived FV/Va, purified from Triton X-100 platelet lysates was composed of a mixture of polypeptides ranging from approximately 40 to 330 kDa, mimicking those visualized by Western blotting of platelet lysates and releasates with anti-FV antibodies. The purified, platelet-derived protein expressed significant cofactor activity such that thrombin activation led to only a 2-3-fold increase in cofactor activity yet expression of a specific activity identical to that of purified, plasma-derived FVa. Physical and functional differences between the two cofactors were identified. Purified, platelet-derived FVa was 2-3-fold more resistant to activated protein C-catalyzed inactivation than purified plasma-derived FVa on the thrombin-activated platelet surface. The heavy chain subunit of purified, platelet-derived FVa contained only a fraction ( approximately 10-15%) of the intrinsic phosphoserine present in the plasma-derived FVa heavy chain and was resistant to phosphorylation at Ser(692) catalyzed by either casein kinase II or thrombin-activated platelets. MALDI-TOF mass spectrometric analyses of tryptic digests of platelet-derived FV peptides detected an intact heavy chain uniquely modified on Thr(402) with an N-acetylglucosamine or N-acetylgalactosamine, whereas Ser(692) remained unmodified. N-terminal sequencing and MALDI-TOF analyses of platelet-derived FV/Va peptides identified the presence of a full-length heavy chain subunit, as well as a light chain subunit formed by cleavage at Tyr(1543) rather than Arg(1545) accounting for the intrinsic levels of cofactor activity exhibited by native platelet-derived FVa. These collective data are the first to demonstrate physical differences between the two FV cofactor pools and support the hypothesis that, subsequent to its endocytosis by megakaryocytes, FV is modified to yield a platelet-derived cofactor distinct from its plasma counterpart.