Comparison of immunogenic potentials of bovine thrombin preparations.

Using a membrane filtration step, bovine crude thrombin was purified into thrombin 4A and 4B preparations. The purpose of this study was to determine whether the improved purity of a bovine thrombin preparation can reduce its overall immunogenic potential and lower the risk of development of factor V antibodies. Bovine crude thrombin and its purified versions, thrombin 4A and 4B, were administered to individual groups of rabbits on days 0, 21, 42, 91, 123, and 151 using standard immunologic methods. Blood was drawn from each rabbit on days 30, 50, 105, 137, and 165, and the pooled antisera from individual groups were purified to obtain the Ig Gs using protein G affinity columns. Using Western blotting, the specificity of each immunoglobulin G collected at the first time point (day 30) and last time point (day 165) was determined. The results of Western blotting using the Ig Gs collected on days 30 and 165 were consistent; both demonstrating that thrombin 4B has the least immunogenic potential among the 3 thrombin preparations tested. Compared with the immunoglobulin Gs collected on day 30, the Ig Gs from day 165 did not show obvious difference regarding their ability to detect antigens in bovine thrombin samples. Neither showed cross-reactivity with human coagulation factors nor the recognition of bovine factor Va antigens. These results suggest that despite the presence of a trace amount of bovine factor Va antigen in bovine thrombin preparations, these contaminants failed to elicit the generation of antibodies against factor Va light chain in rabbit.

Further removal of factor v related antigen from bovine thrombin by utilizing a membrane-filtration step.

Topical bovine thrombin is commonly used during surgery to maintain hemostasis and is rarely associated with abnormalities in hemostasis, including coagulopathies and bleeding. Coagulopathies may be related to the formation of cross-reactive antibodies to bovine factor V. Effectiveness of a new filtration step to remove factor V/Va from bovine thrombin was evaluated. A highly sensitive and specific Western blot capable of detecting minute amounts of factor V/Va and/or its fragments was developed. Samples were evaluated for bovine factor V related antigens using the Western blot method and a competitive enzyme-linked immunosorbent assay. Factor Va light chain fragment levels were detectable in crude thrombin and chromatographically purified thrombin but not in chromatographically purified and virally filtered preparations. Therefore, inclusion of the viral-filtration step during purification of thrombin is effective in reducing factor V or its fragments to undetectable levels, thus enhancing product purity.

Comparative analysis of prothrombin activators from the venom of Australian elapids.

A key component of the venom of many Australian snakes belonging to the elapid family is a toxin that is structurally and functionally similar to that of the mammalian prothrombinase complex. In mammals, this complex is responsible for the cleavage of prothrombin to thrombin and is composed of factor Xa in association with its cofactors calcium, phospholipids, and factor Va. The snake prothrombin activators have been classified on the basis of their requirement for cofactors for activity. The two major subgroups described in Australian elapid snakes, groups C and D, are differentiated by their requirement for mammalian coagulation factor Va. In this study, we describe the cloning, characterization, and comparative analysis of the factor X- and factor V-like components of the prothrombin activators from the venom glands of snakes possessing either group C or D prothrombin activators. The overall domain arrangement in these proteins was highly conserved between all elapids and with the corresponding mammalian clotting factors. The deduced protein sequence for the factor X-like protease precursor, identified in elapids containing either group C or D prothrombin activators, demonstrated a remarkable degree of relatedness to each other (80%-97%). The factor V-like component of the prothrombin activator, present only in snakes containing group C complexes, also showed a very high degree of homology (96%-98%). Expression of both the factor X- and factor V-like proteins determined by immunoblotting provided an additional means of separating these two groups at the molecular level. The molecular phylogenetic analysis described here represents a new approach for distinguishing group C and D snake prothrombin activators and correlates well with previous classifications.

Trp2063 and Trp2064 in the factor Va C2 domain are required for high-affinity binding to phospholipid membranes but not for assembly of the prothrombinase complex.

Interactions between factor Va and membrane phosphatidylserine (PS) regulate activity of the prothrombinase complex. Two solvent-exposed hydrophobic residues located in the C2 domain, Trp(2063) and Trp(2064), have been proposed to contribute to factor Va membrane interactions by insertion into the hydrophobic membrane bilayer. However, the prothrombinase activity of rHFVa W(2063, 2064)A was found to be significantly impaired only at low concentrations of PS (5 mol %). In this study, we find that 10-fold higher concentrations of mutant factor Va are required for half-maximal prothrombinase activity on membranes containing 25% PS. The ability of the mutant factor Va to interact with factor Xa on a membrane was also impaired since 4-fold higher concentrations of factor Xa were required for half-maximal prothrombinase activity. The interaction of factor Va with 25% PS membranes was also characterized using fluorescence energy transfer and surface plasmon resonance. We found that the affinity of mutant factor Va for membranes containing 25% PS was reduced at least 400-fold with a K(d) > 10(-7) M. The binding of mutant factor Va to 25% PS membranes was markedly enhanced in the presence of factor Xa, indicating stabilization of the factor Va-factor Xa-membrane complex. Our findings indicate that Trp(2063) and Trp(2064) play a critical role in the high-affinity binding of factor Va to PS membranes. It remains to be determined whether occupancy of this PS binding site in factor Va is also required for high-affinity binding to factor Xa.

Active site-independent recognition of substrates and product by bovine prothrombinase: a fluorescence resonance energy transfer study.

The conversion of prothrombin to thrombin is catalyzed by prothrombinase, an enzyme complex composed of the serine proteinase factor Xa and a cofactor protein, factor Va, assembled on membranes. Kinetic studies indicate that interactions with extended macromolecular recognition sites (exosites) rather than the active site of prothrombinase are the principal determinants of binding affinity for substrate or product. We now provide a model-independent evaluation of such ideas by physical studies of the interaction of substrate derivatives and product with prothrombinase. The enzyme complex was assembled using Xa modified with a fluorescent peptidyl chloromethyl ketone to irreversibly occlude the active site. Binding was inferred by prethrombin 2-dependent perturbations in the fluorescence of Oregon Green(488) at the active site of prothrombinase. Active site-independent binding was also unequivocally established by fluorescence resonance energy transfer between 2,6-dansyl tethered to the active site of Xa and eosin tethered to the active sites of either thrombin or meizothrombin des fragment 1. Comparable interprobe distances obtained from these measurements suggest that substrate and product interact equivalently with the enzyme. Competition established the ability of a range of substrate or product derivatives to bind in a mutually exclusive fashion to prothrombinase. Equilibrium dissociation constants obtained for the active site-independent binding of prothrombin, prethrombin 2, meizothrombin des fragment 1 and thrombin to prothrombinase were comparable with their affinities inferred from kinetic studies using active enzyme. Our findings directly establish that binding affinity is principally determined by the exosite-mediated interaction of either the substrate, both possible intermediates, or product with prothrombinase. A single type of exosite binding interaction evidently drives affinity and binding specificity through the stepwise reactions necessary for the two cleavage reactions of prothrombin activation and product release.

Identification of a binding site for blood coagulation factor Xa on the heavy chain of factor Va. Amino acid residues 323-331 of factor V represent an interactive site for activated factor X.

We have recently shown that amino acid region 307-348 of factor Va heavy chain (42 amino acids, N42R) is critical for cofactor activity and may contain a binding site for factor Xa and/or prothrombin [(2001) J. Biol. Chem. 276, 18614-18623]. To ascertain the importance of this region for factor Va cofactor activity, we have synthesized eight overlapping peptides (10 amino acid each) spanning amino acid region 307-351 of the heavy chain of factor Va and tested them for inhibition of prothrombinase activity. The peptides were also tested for the inhibition of the binding of factor Va to membrane-bound active site fluorescent labeled Glu-Gly-Arg human factor Xa ([OG488]-EGR-hXa). Factor Va binds specifically to membrane-bound [OG488]-EGR-hXa (10nM) with half-maximum saturation reached at approximately 6 nM. N42R was also found to interact with [OG488]-EGR-hXa with half-maximal saturation observed at approximately 230 nM peptide. N42R was found to inhibit prothrombinase activity with an IC50 of approximately 250 nM. A nonapeptide containing amino acid region 323-331 of factor Va (AP4') was found to be a potent inhibitor of prothrombinase. Kinetic analyses revealed that AP4' is a noncompetitive inhibitor of prothrombinase with respect to prothrombin, with a K(i) of 5.7 microM. Thus, the peptide interferes with the factor Va-factor Xa interaction. Displacement experiments revealed that the nonapeptide inhibits the direct interaction of factor Va with [OG488]-EGR-hXa (IC50 approximately 7.5 microM). The nonapeptide was also found to bind directly to [OG488]-EGR-hXa and to increase the catalytic efficiency of factor Xa toward prothrombin in the absence of factor Va. In contrast, a peptadecapeptide from N42R encompassing amino acid region 337-351 of factor Va (P15H) had no effect on either prothrombinase activity or the ability of the cofactor to interact with [OG488]-EGR-hXa. Our data demonstrate that amino acid sequence 323-331 of factor Va heavy chain contains a binding site for factor Xa.

Role of proexosite I in factor Va-dependent substrate interactions of prothrombin activation.

Regulatory exosite I of thrombin is present on prothrombin in a precursor state (proexosite I) that specifically binds the Tyr(63)-sulfated peptide, hirudin(54-65) (Hir(54-65)(SO(3)(-))) and the nonsulfated analog. The role of proexosite I in the mechanism of factor Va acceleration of prothrombin activation was investigated in kinetic studies of the effects of peptide binding. The initial rate of human prothrombin activation by factor Xa was inhibited by the peptides in the presence of factor Va but not in the absence of the cofactor. Factor Xa and factor Va did not bind the peptide with significant affinity compared with prothrombin. Maximum inhibition reduced the factor Va-accelerated rate to a level indistinguishable from the rate in the absence of the cofactor. The effect of Hir(54-65)(SO(3)(-)) on the kinetics of prothrombin activation obeyed a model in which binding of the peptide to proexosite I prevented productive prothrombin interactions with the factor Xa-factor Va complex. Comparison of human and bovine prothrombin as substrates demonstrated a similar correlation between peptide binding and inhibition of factor Va acceleration. Inhibition of prothrombin activation by hirudin peptides was opposed by assembly on phospholipid vesicles of the membrane-bound factor Xa-factor-Va-prothrombin complex. Factor Va interactions of human and bovine prothrombin activation are concluded to share a common mechanism in which proexosite I participates in productive interactions of prothrombin as the substrate of the factor Xa-factor Va complex, possibly by directly mediating productive prothrombin-factor Va binding.

Partial glycosylation at asparagine-2181 of the second C-type domain of human factor V modulates assembly of the prothrombinase complex.

Thrombin-activated factor Va exists as two isoforms, factor Va(1) and factor Va(2), which differ in the size of their light chains and their affinity for biological membranes. The heterogeneity of the light chain remained following incubation of factor Va with N-glycanase. However, we found that the factor V C2 domain, which contains a single potential glycosylation site at Asn-2181, was partially glycosylated when expressed in COS cells. To confirm the structural basis for factor Va(1) and factor Va(2), we mutated Asn-2181 to glutamine (N2181Q) and expressed this mutant using a B domain deletion construct (rHFV des B) in COS cells. Thrombin activation of N2181Q released a light chain with mobility identical to that of factor Va(2) on SDS-PAGE. The functional properties of purified N2181Q were similar to those of factor Va(2) in prothrombinase assays carried out in the presence of limiting concentrations of phosphatidylserine. The binding of human factor Va(1) and factor Va(2) to 75:25 POPC/POPS vesicles was also investigated in equilibrium binding assays using proteins containing a fluorescein-labeled heavy chain. The affinity of human factor Va(2) binding to POPC/POPS vesicles was approximately 3-fold higher than that of factor Va(1). These results indicate that partial glycosylation of factor V at asparagine-2181 is the structural basis of the light chain doublet and that the presence of this oligosaccharide reduces the affinity of factor Va for biological membranes.

Factor VIIa/tissue factor generates a form of factor V with unchanged specific activity, resistance to activation by thrombin, and increased sensitivity to activated protein C.

Factor VIIa, in complex with tissue factor (TF), is the serine protease responsible for initiating the clotting cascade. This enzyme complex (TF/VIIa) has extremely restricted substrate specificity, recognizing only three previously known macromolecular substrates (serine protease zymogens, factors VII, IX, and X). In this study, we found that TF/VIIa was able to cleave multiple peptide bonds in the coagulation cofactor, factor V. SDS-PAGE analysis and sequencing indicated the factor V was cleaved at Arg679, Arg709, Arg1018, and Arg1192, resulting in a molecule with a truncated heavy chain and an extended light chain. This product (FVTF/VIIa) had essentially unchanged activity in clotting assays when compared to the starting material. TF reconstituted into phosphatidylcholine vesicles was ineffective as a cofactor for the factor VIIa cleavage of factor V. However, incorporation of phosphatidylethanolamine in the vesicles had little effect over the presence of 20% phosphatidylserine. FVTF/VIIa was as sensitive to inactivation by activated protein C (APC) as thrombin activated factor V as measured in clotting assays or by the appearance of the expected heavy chain cleavage products. The FVTF/VIIa could be further cleaved by thrombin to release the normal light chain, albeit at a significantly slower rate than native factor V, to yield a fully functional product. These studies thus reveal an additional substrate for the TF/VIIa complex. They also indicate a new potential regulatory pathway of the coagulation cascade, i.e., the production of a form of factor V that can be destroyed by APC without the requirement for full activation of the cofactor precursor.

Contribution of the prothrombin fragment 2 domain to the function of factor Va in the prothrombinase complex.

The prothrombinase complex assembles through reversible interactions between factor Xa, factor Va and acidic phospholipid-containing membranes in the presence of calcium ions. This complex catalyses the conversion of prothrombin to thrombin through two proteolytic steps. We have used prethrombin 2 as a substrate analog for the first cleavage reaction of prothrombin activation (cleavage at Arg323-Ile324) catalyzed by the prothrombinase complex and have also relied on the known ability of prethrombin 2 to interact tightly but reversibly with fragment 2 or fragment 1.2. The kinetics of cleavage at Arg323-Ile324 have been assessed with these substrate analogs to investigate the contribution of cofactor-substrate interactions mediated by the fragment 2 domain to the ability of factor Va to enhance the catalytic efficiency of factor Xa within the prothrombinase complex. Initial velocity measurements indicated that the rate of prethrombin 2 cleavage by the factor Xa-PCPS binary complex was increased by a factor of approximately 1300 upon the addition of saturating concentrations of factor Va to assemble prothrombinase. Although the measured initial velocity was higher when either fragment 2 or fragment 1.2 was present, the factor Va-dependent enhancement in initial rate (2600- and 1500-fold) was comparable in each case. Steady state kinetic constants were obtained using prethrombin 2, prethrombin 2 plus fragment 2, and prethrombin 2 plus fragment 1.2 as substrates. For each substrate, the addition of saturating concentrations of factor Va to the Xa-PCPS binary complex led to increases in catalytic efficiency of between 1000 and 9000-fold. The kcat/Km for prethrombin 2 cleavage by prothrombinase was essentially identical to that obtained for prethrombin 2 saturated with fragment 2. Thus, comparable accelerating effects of factor Va are observed independent of the presence of the fragment 2 domain in the substrate. The results indicate that interactions between factor Va and the substrate mediated by the fragment 2 domain do not contribute in a dominant way to the ability of factor Va to enhance the catalytic efficiency of factor Xa within the prothrombinase complex.

Human factor Va1 and factor Va2: properties in the procoagulant and anticoagulant pathways.

Human plasma factor V is heterogeneous and yields two forms of activated factor V that bind with low (factor Va1) and high affinity (factor Va2) to phospholipids. The properties of factor Va1 and factor Va2 in the anticoagulant and procoagulant pathways were evaluated by comparing their sensitivity for inactivation by APC and their ability to act as cofactor in prothrombin activation. At low phospholipid concentrations and on membranes containing low amounts of phosphatidylserine (PS), factor Va1 was inactivated by APC at 15-fold lower rates than factor Va2, both in the absence and in the presence of protein S. At high phospholipid concentrations and on membranes with more than 15 mol % PS, factor Va1 and factor Va2 were inactivated with equal efficiency. Differences between cofactor activities of factor Va1 and factor Va2 in prothrombin activation were only observed on membranes with less than 7.5 mol % PS. Due to the different phospholipid requirements of APC-catalyzed factor Va inactivation and of expression of factor Va cofactor activity in prothrombin activation, the thrombin-forming capacity of factor V1 was 7-fold higher than that of factor V2 in a reaction system containing factor Xa, prothrombin, APC, protein S, vesicles with a phospholipid composition resembling that of activated platelets, and traces of thrombin to initiate prothrombin activation. This shows that in the process of generation, expression, and down-regulation of factor Va cofactor activity on physiological membranes, the overall procoagulant activity of factor V1 can considerably exceed that of factor V2.

Effects of protein S and factor Xa on peptide bond cleavages during inactivation of factor Va and factor VaR506Q by activated protein C.

Inactivation of membrane-bound factor Va by activated protein C (APC) proceeds via a biphasic reaction that consists of a rapid and a slow phase, which are associated with cleavages at Arg506 and Arg306 of the heavy chain of factor Va, respectively. We have investigated the effects of protein S and factor Xa on APC-catalyzed factor Va inactivation. Protein S accelerates factor Va inactivation by selectively promoting the slow cleavage at Arg306 (20-fold). Factor Xa protects factor Va from inactivation by APC by selectively blocking cleavage at Arg506. Inactivation of factor VaR506Q, which was isolated from the plasma of a homozygous APC-resistant patient and which lacks the Arg506 cleavage site, was also stimulated by protein S but was not affected by factor Xa. This confirms that the target sites of protein S and factor Xa involve Arg306 and Arg506, respectively. Factor Xa completely blocked APC-catalyzed cleavage at Arg506 in normal factor Va (1 nM) with a half-maximal effect (K1/2Xa) at 1.9 nM factor Xa. Expression of cofactor activity of factor Va in prothrombin activation required much lower factor Xa concentrations (K1/2Xa = 0.08 nM). When the ability of factor Xa to protect factor Va from inactivation by APC was determined at low factor Va concentrations during prothrombin activation much lower amounts of factor Xa were required (K1/2Xa = 0.03 nM). This indicates 1) that factor Va is optimally protected from inactivation by APC by incorporation into the prothrombinase complex during ongoing prothrombin activation, and 2) that the formation of a catalytically active prothrombinase complex and protection of factor Va from inactivation by APC likely involves the same interaction of factor Xa with factor Va. In accordance with the proposed mechanisms of action of protein S and factor Xa, we observed that the large differences between the rates of APC-catalyzed inactivation of normal factor Va and factor VaR506Q were almost annihilated in the presence of factor Xa and protein S. This observation may explain why, in the absence of other risk factors, APC resistance only results in a weak prothrombotic condition.

Inhibition of prothrombinase at macroscopic lipid membranes: competition between antithrombin and prothrombin.

The kinetics of inhibition of prothrombinase during prothrombin conversion by antithrombin and antithrombin-heparin complexes was studied in a tubular flow reactor. Prothrombinase was assembled at a macroscopic phospholipid membrane, composed of 25 mol % phosphatidylserine and 75 mol % phosphatidylcholine, deposited on the inner wall of a glass capillary, by perfusion with a factor Xa-factor Va mixture. Measurement of thrombin production allowed estimation of the amount of prothrombinase present at the capillary wall. Perfusion with a mixture of prothrombin and antithrombin or antithrombin-heparin complexes caused a progressive decline of the prothrombinase activity. The rate of inactivation steeply decreased with increasing prothrombin concentrations, indicating competitive inhibition. Analysis of competitive inhibition data requires estimation of the time-dependent substrate concentration, Co, near the prothrombin converting surface using earlier developed transport theory [Billy, D., et al. (1995) J. Biol. Chem. 270, 1029-1034]. It appears that the inhibition rate is proportional to the fraction of enzyme, Km/(Km+Co), not occupied by substrate. The value of Km of prothrombinase estimated from the dependence of the inhibition rate on the prothrombin concentration (Km = 2-3 nM) is in excellent agreement with the value estimated from the substrate conversion rate (Km = 3 nM). Therefore inhibition of prothrombinase by antithrombin and antithrombin-heparin complexes is fully competitive with the substrate: prothrombin. Our results show that prothrombinase assembled on macroscopic lipid surfaces by virtue of its low Km value is protected for inhibition due to highly effective competition of prothrombin with antithrombin for the active site of factor Xa.

Effects of Ca2+ binding on the protease module of factor Xa and its interaction with factor Va. Evidence for two Gla-independent Ca(2+)-binding sites in factor Xa.

The assembly of macromolecular complexes containing factors Xa and Va on suitable phospholipid surfaces is crucial for rapid activation of prothrombin. We have used quantitative affinity chromatography to characterize the interaction between factor Va and intact factor Xa on the one hand and between factor Va and factor Xa lacking the gamma-carboxyglutamic acid (Gla)-containing module on the other. The dissociation constants were found to be 1.0 +/- 0.1 and 9.5 +/- 1.8 microM, respectively. There was good agreement between these dissociation constants and the concentrations of active site-inhibited factor Xa and Gla-domainless factor Xa that caused half-maximal inhibition of prothrombin activation. To investigate whether the noncatalytic modules of factor Xa interacted directly with factor Va, intact modules were isolated from proteolytic digests of factor X and used as inhibitors of prothrombin activation. The inhibitory effect observed with the isolated Gla module in the absence of phospholipid was due to inhibition of the amidolytic activity of factor Xa rather than to an interaction with factor Va. The epidermal growth factor-like modules did not inhibit prothrombin activation. Using antibodies specific for calcium-dependent epitopes in the serine protease module of factor Xa we demonstrated that Ca2+ binding to the Gla module alters the conformation of the catalytic module. Half-maximal binding was observed at approximately 0.8 mM Ca2+. Evidence was also obtained for the presence of two Gla-independent Ca(2+)-binding sites in factor Xa. One of these sites, located in the NH2-terminal epidermal growth factor-like module, was half-saturated at approximately 60 microM Ca2+ in intact factor Xa and at approximately 1.2 mM Ca2+ in Gla-domainless factor Xa. This site appeared not to influence the conformation of the protease module. The second site, which was half-saturated at approximately 0.16 mM Ca2+, appeared to reside in the serine protease module and to alter its conformation as judged by binding of antibodies specific for calcium-dependent epitopes.

Characterization of two forms of human factor Va with different cofactor activities.

Factor Va is an essential cofactor in factor Xa-catalyzed prothrombin activation. Purified human factor Va appears to consist of a heavy chain (M(r) approximately 105,000) and a light chain doublet with M(r) approximately 74,000 and approximately 71,000. We separated factor Va by chromatography on a Mono-S column into two fractions, designated factors Va1 and Va2. Factor Va1 contains the light chain with M(r) approximately 74,000, and factor Va2 exclusively contains the light chain with M(r) approximately 71,000. The two forms of factor Va express different cofactor activities when prothrombin is activated at low phospholipid concentrations or on membranes containing low amounts of phosphatidylserine in phosphatidylcholine. Compared with factor Va2, much higher amounts of factor Va1 are required for factor Xa. Va complex formation at the membrane surface. Once incorporated into the prothrombinase complex, factors Va1 and Va2 are equally active in prothrombin activation. This indicates that the two forms of factor Va do not differ in their ability to promote the catalytic activity of factor Xa or to interact with prothrombin. Direct binding experiments show that the different cofactor activities are explained by a greatly impaired ability of factor Va1 to bind to negatively charged membranes. Factor V is also separated into two protein peaks after chromatography on a Mono-S column. Upon incubation with thrombin, the first peak yields factor Va1 and the second peak factor Va2. The same two forms of factor Va were generated when freshly prepared plasma samples or platelet suspensions were treated with thrombin. This shows that the heterogeneity of the light chain domain is an intrinsic property of both plasma and platelet factor V. It is hypothesized that the heterogeneity is caused by small differences in the carboxylterminal C2 domain of factor V that are introduced as the result of post-ribosomal processing.

Phosphorylation of factor Va and factor VIIIa by activated platelets.

Platelet activation leads to the incorporation of 32[PO4(2-)] into bovine coagulation factor Va and recombinant human factor VIII. In the presence of the soluble fraction from thrombin-activated platelets and (gamma-32P) adenosine triphosphate, radioactivity is incorporated exclusively into the M(r) = 94,000 heavy chain (H94) of factor Va and into the M(r) = 210,000 to 90,000 heavy chains as well into the M(r) = 80,000 light chain of factor VIII. Proteolysis of the purified phosphorylated M(r) = 94,000 factor Va heavy chain by activated protein C (APC) gave products of M(r) = 70,000, 24,000, and 20,000. Only the intermediate M(r) = 24,000 fragment contained radioactivity. Because the difference between the M(r) = 24,000 and M(r) = 20,000 fragments is located on the COOH-terminal end of the bovine heavy chain, phosphorylation of H94 must occur within the M(r) = 4,000 peptide derived from the carboxyl-terminal end of H94 (residues 663 through 713). Exposure of the radioactive factor VIII molecule to thrombin ultimately resulted in a nonradioactive light chain and an M(r) = 24,000 radioactive fragment that corresponds to the carboxyl-terminal segment of the A1 domain of factor VIII. Based on the known sequence of human factor VIII, phosphorylation of factor VIII by the platelet kinase probably occurs within the acidic regions 337 through 372 and 1649 through 1689 of the procofactor. These acidic regions are highly homologous to sequences known to be phosphorylated by casein kinase II. Results obtained using purified casein kinase II gave a maximum observed stoichiometry of 0.6 mol of 32[PO4(2-)]/mol of factor Va heavy chain and 0.35 mol of 32[PO4(2-)]/mol of factor VIII. Phosphoamino acid analysis of phosphorylated factor Va by casein kinase II or by the platelet kinase showed only the presence of phosphoserine while phosphoamino acid analysis of phosphorylated factor VIII by casein kinase II showed the presence of phosphothreonine as well as small amounts of phosphoserine. The platelet kinase responsible for the phosphorylation of the two cofactors was found to be inhibited by several synthetic protein kinase inhibitors. Finally, partially phosphorylated factor Va was found to be more sensitive to APC inactivation than its native counterpart. Our findings suggest that phosphorylation of factors Va and VIIIa by a platelet casein kinase II-like kinase may downregulate the activity of the two cofactors.

Assembly of prothrombinase complex.

The approaches described in this article have resulted in an increased understanding of the reaction steps involved in the stabilization and assembly of the prothrombinase complex. Because prothrombinase is considered an archetype for some of the other coagulation complexes, the quantitative information derived from these studies (Table I) provides the framework for future studies of prothrombinase and suggests experimental approaches for studies of the other analogous coagulation reactions.

Prothrombinase complex assembly. Contributions of protein-protein and protein-membrane interactions toward complex formation.

Equilibrium binding studies of prothrombinase complex formation were undertaken using phospholipid vesicles composed of phosphatidylcholine and phosphatidylserine (PCPS), factor Va, and factor Xa modified with dansyl glutamylglycinylarginyl chloromethyl ketone (DEGR.Xa). The interaction between the Va.PCPS and DEGR.Xa.PCPS binary complexes was experimentally isolated using saturating concentrations of PCPS. Fluorescence titrations indicated that the membrane-bound proteins interact tightly (Kd approximately 10(-9) M) with a stoichiometry of 1 mol of Va bound/mol of DEGR.Xa at saturation. Complex formation was also investigated by kinetic studies of prothrombin activation using unmodified factor Xa. The kinetic studies yielded a Kd approximately 10(-9) M, which was independent of the concentration of prothrombin in the range of 0.5-5.0 microM. Fluorescence studies of complex assembly at limiting PCPS concentrations provided evidence for an altered DEGR.Xa-PCPS interaction when the enzyme was assembled into the complex. The data suggest that although both proteins are associated with PCPS when complexed with each other, the presence of factor Va on the membrane surface increases the affinity for the Xa-PCPS interaction by an estimated 100-fold. Prothrombinase complex assembly therefore proceeds independently of the availability of substrate and is stabilized by protein-protein and protein-phospholipid interactions. Linkage between the two protein-membrane combination events leads to the further stabilization of the complex on the vesicle surface.