Raffaella Toso

Factor V Leiden improves in vivo hemostasis in murine hemophilia models

Summary.  The role of factor V Leiden (FVL) as a modifier of the severe hemophilia phenotype is still unclear. We used mice with hemophilia A or B crossed with FVL to elucidate in vivo parameters of hemostasis. Real‐time thrombus formation in the microcirculation was monitored by deposition of labeled platelets upon laser‐induced endothelial injury using widefield microscopy in living animals. No thrombi formed in hemophilic A or B mice following vascular injuries. However, hemophilic mice, either heterozygous or homozygous for FVL, formed clots at all injured sites. Injection of purified activated FV into hemophilic A or B mice could mimic the in vivo effect of FVL. In contrast to these responses to a laser injury in a microvascular bed, FVL did not provide sustained hemostasis following damage of large vessels in a ferric chloride carotid artery injury model, despite of the improvement of clotting times and high circulating thrombin levels. Together these data provide evidence that FVL has the ability to improve the hemophilia A or B phenotype, but this effect is principally evident at the microcirculation level following a particular vascular injury. Our observations may partly explain the heterogeneous clinical evidence of the beneficial role of FVL in hemophilia.

A zymogen-like factor Xa variant corrects the coagulation defect in hemophilia

Effective therapies are needed to control excessive bleeding in a range of clinical conditions. We improve hemostasis in vivo using a conformationally pliant variant of coagulation factor Xa (FXaI16L) rendered partially inactive by a defect in the transition from zymogen to active protease. Using mouse models of hemophilia, we show that FXaI16L has a longer half-life than wild-type FXa and does not cause excessive activation of coagulation. Once clotting mechanisms are activated to produce its cofactor FVa, FXaI16L is driven to the protease state and restores hemostasis in hemophilic animals upon vascular injury. Moreover, using human or murine analogs, we show that FXaI16L is more efficacious than FVIIa, which is used to treat bleeding in hemophilia inhibitor patients. FXaI16L may provide an effective strategy to enhance blood clot formation and act as a rapid pan-hemostatic agent for the treatment of bleeding conditions.Effective therapies are needed to control excessive bleeding in a range of clinical conditions. We describe a surprisingly useful approach to improve hemostasis in vivo using a variant of coagulation factor Xa (FXaI16L). This conformationally pliant derivative is partially inactive due to a defect in transitioning from zymogen to protease 1,2. Using mouse models of hemophilia, we show that FXaI16L has a prolonged half-life, relative to wild-type FXa and does not cause excessive activation of coagulation. Once clotting mechanisms are activated to produce its cofactor FVa, FXaI16L is driven to the protease state and restores hemostasis in hemophilic animals upon vascular injury. Moreover, using human or murine analogs, we show that FXaI16L is more efficacious than FVIIa which is used to treat bleeding in hemophilia inhibitor patients3. Because of its underlying mechanism of action, FXaI16L may provide an effective strategy to enhance blood clot formation and act as a rapid pan-hemostatic agent for the treatment of bleeding conditions.

Zymogen-like factor Xa variants restore thrombin generation and effectively bypass the intrinsic pathway in vitro

Inhibitory antibodies to factors VIII or IX represent a serious complication for hemophilia patients. Treatment involves products that bypass the intrinsic pathway and promote thrombin generation. Direct infusion of factor Xa should also restore hemostasis; however, it has a short half-life in plasma and could activate systemic coagulation in an uncontrolled fashion. Here we show that factor Xa mutants with zymogen-like properties (FXa(I16L) and FXa(V17A)) circumvent these limitations. In the absence of factor Va, the FXa variants are poor enzymes for a range of physiological ligands and are resistant to inactivation by antithrombin III and tissue factor pathway inhibitor. Notably, assembly of FXa(I16L) and FXa(V17A) on activated platelets with factor Va to form prothrombinase completely restores biologic activity. In hemophilic plasma, FXa(I16L) and FXa(V17A) have prolonged half-lives compared with wild-type factor Xa (approximately 60 minutes vs approximately 1 minute) and promote robust thrombin generation that bypasses the intrinsic pathway. The variants require factor Va generated in situ for procoagulant function, and cofactor inactivation by the protein C pathway regulates their activity. The efficacy, extended half-life, and mechanism of action suggest that novel zymogen-like forms of factor Xa might prove useful as new therapeutic procoagulants to treat deficiencies upstream of the common pathway.

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 (FXaI16L and FXaV17A) 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 FXaI16L with Glu-Gly-Arg-chloromethyl ketone fully rescued FVa binding. Furthermore, the Km for prothrombin conversion with the factor Xa variants assembled into prothrombinase was unaltered, whereas the kcat 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.

Inhibitory Sequences within the B-domain Stabilize Circulating Factor V in an Inactive State

Blood coagulation factor V circulates as a procofactor with little or no procoagulant activity. It is activated to factor Va by thrombin following proteolytic removal of a large central B-domain. Although this reaction is well studied, the mechanism by which bond cleavage and B-domain release facilitate the transition to the active cofactor state has not been defined. Here we show that deletion or substitution of specific B-domain sequences drives the expression of procoagulant function without the need for proteolytic processing. Conversion to the constitutively active cofactor state is related, at least in part, to a cluster of amino acids that is highly basic and well conserved across the vertebrate lineage. Our findings demonstrate that discrete sequences in the B-domain serve to stabilize the inactive procofactor state, with proteolysis primarily functioning to remove these inhibitory constraints. These unexpected results provide new insight into the mechanism of factor V activation.

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), FVa692 (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 ∼1% clotting activity and reduced affinity for FXa membranes (∼20-fold) and did not bind to thrombin-agarose. Surprisingly, however, FVa658 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.

A frequent human coagulation Factor VII mutation (A294V, c152) in loop 140s affects the interaction with activators, tissue factor and substrates

Activated Factor VII (FVIIa) is a vitamin-K-dependent serine protease that initiates blood clotting after interacting with its cofactor tissue factor (TF). The complex FVIIa-TF is responsible for the activation of Factor IX (FIX) and Factor X (FX), leading ultimately to the formation of a stable fibrin clot. Activated FX (FXa), a product of FVIIa enzymic activity, is also the most efficient activator of zymogen FVII. Interactions of FVII/FVIIa with its activators, cofactor and substrates have been investigated extensively to define contact regions and residues involved in the formation of the complexes. Site-directed mutagenesis and inhibition assays led to the identification of sites removed from the FVIIa active site that influence binding specificity and affinity of the enzyme. In this study we report the characterization of a frequent naturally occurring human FVII mutant, A294V (residue 152 in the chymotrypsin numbering system), located in loop 140s. This region undergoes major rearrangements after FVII activation and is relevant to the development of substrate specificity. FVII A294V shows delayed activation by FXa as well as reduced activity towards peptidyl and macromolecular substrates without impairing the catalytic efficiency of the triad. Also, the interaction of this FVII variant with TF was altered, suggesting that this residue, and more likely loop 140s, plays a pivotal role not only in the recognition of FX by the FVIIa-TF complex, but also in the interaction of FVII with both its activators and cofactor TF.

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.

Factor VII mutant V154G models a zymogen-like form of Factor VIIa

Proteolytic cleavage of the peptide bond between Arg(152) and Ile(153) converts the procoagulant protein Factor VII (FVII) to an activated two-chain form (FVIIa). The formation of a salt bridge between Ile(153) and Asp(343) drives the conversion of FVIIa from being zymogen-like to the active form. In the present paper, we describe the novel FVII mutant V154G (Val(154)-->Gly mutation; residue 17 in the chymotrypsin numbering system), found in three FVII-deficient patients, which models a zymogen-like form of FVIIa. Recombinant V154G FVIIa, although normally cleaved, shows markedly reduced activity towards peptidyl substrate and undetectable activity towards macromolecular substrates. Susceptibility of Ile(153) to chemical modification, in either the presence or the absence of tissue factor (TF), suggests that the reduced V154G FVIIa activity is caused by impaired salt-bridge formation, thus resulting in a zymogen-like FVIIa form. The TF-mediated protection from chemical modification of V154A indicated that Gly(154) is responsible for this peculiar feature, and suggests that this region, proximal to the heavy chain N-terminus, is directly involved in the conversion of FVII into FVIIa. V154G FVII was exploited to study the FVII-TF interaction, together with three additional FVII variants that were expressed to serve as models for different FVII forms. The comparison of binding affinities of full-length TF after relipidation in L-alpha-phosphatidylcholine for the zymogen FVII (Arg(152)-->Gln, K (d)=1.04+/-0.27 nM), inactive FVIIa (Ser(344)-->Ala, K (d)=0.27+/-0.06 nM) and a zymogen-like FVIIa (V154G, K (d)=1.15+/-0.16 nM) supports the hypothesis that preferential binding of TF to active FVIIa is insufficient to drive the 10(5)-fold enhancement of FVIIa activity. In addition, the inability of V154G FVIIa to accommodate an inhibitor in the active site, indicating an improperly shaped specificity pocket, would explain the low activity of the zymogen-like form of FVIIa, which is predominant in the absence of TF.

52. Therapeutic Factor VIII Expression After AAV Delivery in Non-Human Primates

Adeno-associated viral (AAV) vector delivery of factor VIII (FVIII) has been challenging due to its intrinsic properties that result in inefficient expression compared to similarly sized proteins. Early studies of AAV delivery in hemophilia A mice and dogs suggested that the therapeutic vector dose for FVIII will be higher than for factor IX. However, higher vector loads may induce stronger immune responses against capsid antigens, as evidenced in the clinical studies of AAV delivery for hemophilia B. The use of codon-optimization and novel FVIII variants with enhanced biological properties may provide strategies to increase FVIII expression or secretion to support clinical studies for hemophilia A. One published study has reported clinically relevant levels of hFVIII following AAV-hFVIII delivery in non-human primates (NHPs). This study utilized a hFVIII variant that included a 17 amino acid synthetic sequence within the 14 amino acid B-domain region that increased hFVIII expression compared to the parental B-domain deleted FVIII-SQ transgene (McIntosh, 2013). While this and other variants may increase expression after AAV delivery, the use of non-native FVIII sequences may also increase the risk of development of neutralizing antibodies to potential neoantigens. In order to generate an AAV-hFVIII vector capable of expressing therapeutic levels of FVIII at a clinically relevant vector dose without introduction of any neoantigens, 28 hFVIII-SQ sequences were generated and introduced into our optimized expression cassette containing a modified transthyretin (TTRm) promoter. The constructs were initially screened by hydrodynamic delivery of plasmid DNA which identified 11 candidates that expressed FVIII 2-7 fold higher than our first generation codon optimized construct, CO3. AAV vectors (n=9) were generated using a novel AAV capsid, Spark100, with the best performing FVIII constructs. Hem A/CD4 KO mice were administered the vectors alongside CO3 (4×10e12vg/kg). At 8 weeks post vector administration, 2/9 expressed hFVIII similar to CO3, 5/9 were 4-8 fold higher than CO3 while 2/9 (SPK-8003 and SPK-8005) were >10 fold more potent than CO3. SPK-8005 was then evaluated in a dose escalation study in cynomologus macaques (n=3/group) treated with 3 doses: 2×10e12, 5×10e12 and 1×10e13 vg/kg and compared to vehicle controls (n=2). At 2 weeks post AAV administration, average hFVIII levels in the low, mid and high dose cohorts were 12.7 ± 2.1, 22.6 ± 0.8 and 54.1 ± 15.6 percent of normal, respectively. By 3-4 weeks, hFVIII expression started to decline in most of the animals concomitant with generation of antibodies against human FVIII. Of note, this is an expected and well-described observation that occurs in immune competent animal models due to differences between human and endogenous FVIII protein sequences. The 2 macaques that did not develop anti-hFVIII antibodies had sustained FVIII expression through the last time point evaluated. Finally, no vector-related toxicity events were observed. In summary, extensive codon-optimization identified novel AAV-hFVIII constructs capable of achieving therapeutic FVIII levels in macaques at clinically relevant doses. To our knowledge, the hFVIII levels observed in this study are the highest reported in a large animal model after treatment with an AAV vector expressing an unmodified FVIII-SQ protein. These safety and efficacy results in NHPs support the use of SPK-8005 hepatic gene transfer for the potential treatment of hemophilia A.