Factor Va is inactivated by activated protein C in the absence of cleavage sites at Arg-306, Arg-506, and Arg-679

ptFVa (Pseudonaja Textilis Venom-Derived Factor Va) Retains Structural Integrity Following Proteolysis by Activated Protein C

Supplemental Digital Content is available in the text.

Objective:

The Australian snake venom ptFV (Pseudonaja textilis venom-derived factor V) variant retains cofactor function despite APC (activated protein C)-dependent proteolysis. Here, we aimed to unravel the mechanistic principles by determining the role of the absent Arg306 cleavage site that is required for the inactivation of FVa (mammalian factor Va).

Approach and Results:

Our findings show that in contrast to human FVa, APC-catalyzed proteolysis of ptFVa at Arg306 and Lys507 does not abrogate ptFVa cofactor function. Remarkably, the structural integrity of APC-proteolyzed ptFVa is maintained indicating that stable noncovalent interactions prevent A2-domain dissociation. Using Molecular Dynamics simulations, we uncovered key regions located in the A1 and A2 domain that may be at the basis of this remarkable characteristic.

Conclusions:

Taken together, we report a completely novel role for uniquely adapted regions in ptFVa that prevent A2 domain dissociation. As such, these results challenge our current understanding by which strict regulatory mechanisms control FVa activity.

Coagulation factor V mediates inhibition of tissue factor signaling by activated protein C in mice

The key effector molecule of the natural protein C pathway, activated protein C (aPC), exerts pleiotropic effects on coagulation, fibrinolysis, and inflammation. Coagulation-independent cell signaling by aPC appears to be the predominant mechanism underlying its highly reproducible therapeutic efficacy in most animal models of injury and infection. In this study, using a mouse model of Staphylococcus aureus sepsis, we demonstrate marked disease stage-specific effects of the anticoagulant and cell signaling functions of aPC. aPC resistance of factor (f)V due to the R506Q Leiden mutation protected against detrimental anticoagulant effects of aPC therapy but also abrogated the anti-inflammatory and mortality-reducing effects of the signaling-selective 5A-aPC variant that has minimal anticoagulant function. We found that procofactor V (cleaved by aPC at R506) and protein S were necessary cofactors for the aPC-mediated inhibition of inflammatory tissue-factor signaling. The anti-inflammatory cofactor function of fV involved the same structural features that govern its cofactor function for the anticoagulant effects of aPC, yet its anti-inflammatory activities did not involve proteolysis of activated coagulation factors Va and VIIIa. These findings reveal a novel biological function and mechanism of the protein C pathway in which protein S and the aPC-cleaved form of fV are cofactors for anti-inflammatory cell signaling by aPC in the context of endotoxemia and infection.

Cleavage at both Arg306 and Arg506 is required and sufficient for timely and efficient inactivation of factor Va by activated protein C

Activated protein C (APC) inactivates membrane-bound factor Va following cleavages of the heavy chain at Arg, Arg, and Arg. The objective of this study is to examine which cleavage is most important for inactivation. The recombinant factor V molecules were constructed as follows: factor V (mutations R→Q), factor V (mutations R→Q), and factor V (mutations R→Q and R→Q). The recombinant molecules were expressed in mammalian cells, purified, and assayed prior and after incubation with APC and lipids for 30 min (factor Vai) in clotting assays and in an assay using purified reagents and saturating concentrations of factor Va. Clotting assays demonstrated that wild-type factor Vai (Vai), factor Vai, and factor Vai were devoid of activity, whereas factor Vai maintained approximately 70% activity following a 30 min incubation with APC. Prothrombinase assembled with all mutant cofactor molecules before and after treatment with APC had kinetic constant (Km) values similar to values found with prothrombinase assembled with factor Va. Prothrombinase assembled with factor Vai demonstrated a 20-fold reduction in kcat, whereas prothrombinase assembled with factor Vai had a two-fold reduction in kcat as compared with prothrombinase assembled with factor Va. In contrast, factor Vai and factor Vai did not show any loss in kcat under similar experimental conditions. In conclusion, our data demonstrate that the activity of an APC-treated factor Va molecule bearing a single mutation at Arg or Arg depends on the assay used; and regardless of the assay employed, in the absence of the APC-cleavage sites at Arg and Arg, the active cofactor is unable to be significantly inactivated by APC in the presence of a membrane surface.

The R306G and R506Q mutations in coagulation Factor V reveals additional cleavage sites for Activated Protein C in the R313-R321 region and at R505

The procoagulant function of activated factor V (FVa) is inhibited by activated Protein C (APC) through proteolytic cleavages at R306, R506 and R679. Recombinant FVa mutated at all three APC-cleavage sites, FVa-GQA, was still inactivated by APC through at least two cleavages in the heavy chain of FVa; relatively rapid cleavage at R(x1) close to residue 506 and slower cleavage at R(x2) nearby residue 306. We investigated the exact location of these two cleavages, by substitution of arginines by glutamine within the R(x1)-region (R501, R505 or R510) and the R(x2)-region (R313, R316, R317 or R321). Immunoblot and kinetic analyses of the inactivation of activated R(x1)-mutants by APC revealed that using mutant FVa-GQA-505Q no R(x2)-R(x1) fragment was formed and that the inactivation reaction was first order with a rate constant of 1.0 x 10(4) M(-1) s(-1), similar to the rate constant of R(x2) cleavage (k(2)=1.3 x 10(4) M(-1) s(-1)). No single arginine could be pinpointed identified as R(x2). Individual replacement of arginine by glutamine at positions 313, 316, 317 or 321 in FV-GQA-505Q did not result in the disappearance of R(x2) as judged from kinetic and immunoblot analyses. However, replacement of all four arginines by glutamine completely prevented formation of the R(x2)-R(709) fragment. We conclude that substitution of arginine 506 by glutamine as in FV-Leiden, leads to the detection of a novel cleavage site at arginine 505 (R(x1)). Substitution of arginine 306 by glycine, like in FV-Cambridge, reveals several alternative cleavage sites near arginine 306, which together constitute a secondary cleavage site.

Novel APC-cleavage sites in FVa provide insights into mechanisms of action of APC and its cofactor protein S

BACKGROUND

Activated protein C (APC) inhibits factor Va (FVa) by cleaving at Arg306, Arg506 and Arg679. Protein S serves as cofactor, in particular for the Arg306 site, and a protein S-mediated relocation of the active site of APC closer to the membrane has been proposed as a mechanism. Recently, it was demonstrated that FVa, which was mutated at all three APC-cleavage sites (FVa-306Q/506Q/679Q), could still be cleaved by APC. These sites were close to Arg306 and Arg506 but not further defined.

OBJECTIVE

To identify and characterize the additional APC-cleavage sites in FVa.

METHODS

The cDNA for FV-306Q/506Q/679Q was used as a template to create FV variants with one or more possible cleavage sites being mutated. The FV variants were expressed and their sensitivity for APC characterized functionally and with Western blotting.

RESULTS

The additional APC-cleavage sites were located at Lys309, Arg313, Arg316, Arg317 and Arg505. FVa-306Q/309Q/313Q/316Q/317Q/505Q/506Q/679Q (denoted 8M-FVa) was APC resistant. To investigate individual sites, they were mutated back using 8M-FV as a template. The kinetics of APC-degradation of these variants demonstrated that protein S was equally efficient in enhancing the APC effect for all the novel sites.

CONCLUSIONS

Multiple APC-cleavage sites close to Arg306 and a single site close to Arg506 were identified. Protein S was equally efficient as APC cofactor for all novel sites. The stimulation by protein S of the Arg505 cleavage argues against a specific protein S-mediated stimulation of cleavage at Arg306 due to relocation of the APC active site closer to the membrane.

Identification of surface epitopes of human coagulation factor Va that are important for interaction with activated protein C and heparin

Inactivation of factor Va (FVa) by activated protein C (APC) is a key reaction in the down-regulation of thrombin formation. FVa inactivation by APC is correlated with a loss of FXa cofactor activity as a result of three proteolytic cleavages in the FVa heavy chain at Arg306, Arg506, and Arg679. Recently, we have shown that heparin specifically inhibits the APC-mediated cleavage at Arg506 and stimulates cleavage at Arg306. Three-dimensional molecular models of APC docked at the Arg306 and Arg506 cleavage sites in FVa have identified several FVa amino acids that may be important for FVa inactivation by APC in the absence and presence of heparin. Mutagenesis of Lys320, Arg321, and Arg400 to Ala resulted in an increased inactivation rate by APC at Arg306, which indicates the importance of these residues in the FVa-APC interaction. No heparin-mediated stimulation of Arg306 cleavage was observed for these mutants, and stimulation by protein S was similar to that of wild type FVa. With this, we have now demonstrated that a cluster of basic residues in FVa comprising Lys320, Arg321, and Arg400 is required for the heparin-mediated stimulation of cleavage at Arg306 by APC. Furthermore, mutations that were introduced near the Arg506 cleavage site had a significant but modest effect on the rate of APC-catalyzed FVa inactivation, suggesting an extended interaction surface between the FVa Arg506 site and APC.

Inherited defects of coagulation Factor V: the thrombotic side

DNA variations in the Factor V gene have played a major role in thrombosis research ever since the discovery of Factor V Leiden. Here, all relatively common DNA variations in the coding regions of the Factor V gene are discussed. Many of them have been associated with venous thrombosis or related diseases. However, most variations have been studied separately, without taking the presence of other variations in the same gene into account. This means that their association with disease should be interpreted with caution, as it may reflect linkage with another variation. An approach in which a haplotype-based analysis of the Factor V gene is combined with in vitro assays of recombinant proteins is advocated. Finally, a possible reason for the relatively polymorphic nature of the Factor V protein is discussed.

Does activated protein C-resistant factor V contribute to thrombin generation in hemophilic plasma?

In this study we assessed the role of factor V (FV) inactivation in hemophilic plasma with particular reference to the activated protein C (APC)-resistant variants FV-R506Q (FV Leiden) and FV-R306T (FV Cambridge). Purified recombinant full-length FV carrying these single substitutions and FV-R306T/R506Q were used in thrombin generation experiments. Plasma was first immunodepleted of FV, and subsequently of factors VIII, IX, or combinations thereof. Thrombin generation was initiated by low concentrations of recombinant tissue factor. Recombinant soluble thrombomodulin (TM) was used to trigger the APC system. Surprisingly, TM concentrations that reduced thrombin generation in normal plasma by no more than 50% virtually abolished thrombin formation in plasma deficient in the factor VIII/IX complex. This was already apparent at TM levels as low as 0.1 nmol L(-1). By varying the concentrations of purified (activated) protein C to plasma that was additionally depleted of protein C, we confirmed that impaired thrombin generation indeed was the result of the action of APC. In contrast, this did not occur when FV-depleted plasma had been reconstituted with FV-R306T/R506Q. Addition of FV-R306T or FV-R506Q partially reduced prothrombin activation, demonstrating the involvement of both APC cleavage sites. FV inactivation also occurred on the surface of human microvascular endothelial cells. Apparently, these cells express sufficient TM to down-regulate thrombin production via the APC pathway. We further conclude that in hemophilic plasma this pathway can induce a secondary defect because of premature FV inactivation. It therefore seems conceivable that APC-resistant FV has the potential of alleviating hemophilic bleeding.

Enhanced Rate of Cleavage at Arg-306 and Arg-506 in Coagulation Factor Va by Gla Domain-mutated Human-activated Protein C

A Gla domain-mutated protein C variant, QGNSEDY, modified at positions 10-12, 23, 32-33, and 44, having enhanced affinity for negatively charged phospholipid and increased anticoagulant potential, was used to elucidate the importance of the interaction between the Gla domain and the phospholipid for the ability of activated protein C (APC) to inactivate factor Va (FVa). FVa degradation by wild type (WT)-APC and QGNSEDY-APC yielded similar fragments on Western blotting; QGNSEDY-APC was, however, considerably more efficient. The kinetic parameters for individual APC-mediated cleavages in FVa, i.e. at Arg-306 and Arg-506, were investigated at high and low phospholipid concentrations in the presence and absence of protein S. FVa variants 306Q679Q and 506Q679Q, which can only be cleaved at Arg-506 and Arg-306, respectively, were used. In the absence of protein S, QGNSEDY-APC was 17.8- and 4-fold more efficient than WT-APC in cleaving at Arg-306 and Arg-506, respectively, at high phospholipid. Similar values were obtained at low phospholipid. In the presence of protein S, QGNSEDYAPC was 6.8- and 3.2-fold more active than WT-APC in cleaving at Arg-306 and Arg-506, respectively, at high phospholipid. At low phospholipid, the corresponding values were 14- and 6.5-fold. In conclusion, the modification of the Gla domain in QGNSEDY-APC yielded increased rates of cleavage at both sites in FVa, the increase being particularly pronounced for the Arg-306 site in the absence of protein S. The results obtained with QGNSEDY-APC provide insights into the importance of the APC-phospholipid interaction for the APC-mediated cleavages at Arg-306 and Arg-506 in FVa.

Characterization of an immunologic polymorphism (D79H) in the heavy chain of factor V

BACKGROUND

During the study of a family with hereditary factor (F)V deficiency (FV Amersfoort, 1102 A > T in exon 7) we identified an individual with 5% FV heavy chain antigen (FV(HC)) and 50% FV light chain antigen (FV(LC)). Further testing revealed that apart from the FV Amersfoort allele a second variant FV allele was segregating in this family, which encodes for a FV molecule with a reduced affinity for mAb V-23 used in the FV heavy chain ELISA (ELISA(HC)).

OBJECTIVE

Identification and characterization of the molecular basis responsible for the reduced affinity of the variant FV for mAb V-23.

METHODS

Family members of the proband were screened for mutations in the exons coding for the heavy chain of FV, after which the recombinant variant FV could be generated and characterized. Next, the cases and controls of the Leiden Thrombophilia Study (LETS) were genotyped for carriership of the variant FV.

RESULTS

In the variant FV allele a polymorphism in exon 3 (409G > C) was identified, which predicts the replacement of aspartic acid 79 by histidin (D79H). Introduction of this mutation in recombinant FV confirmed that it reduces the affinity for binding to mAb V-23. The substitution has no effect on FV(a) stability and Xa-cofactor activity. In Caucasians the frequency of the FV-79H allele is approximately 5%. Analysis of the LETS revealed that the FV-79H allele is not associated with FV levels (FV(LC)), activated protein C sensitivity (using an activated partial thromboplastin time-based test) or risk of venous thrombosis (OR 1.07, CI 95: 0.7-1.7).

CONCLUSION

The D79H substitution in FV should be considered as a neutral polymorphism. The monoclonal antibody V-23, which has a strongly reduced affinity for FV-79H, is not suitable for application in diagnostic tests.