The absence of an adequate reversal strategy to prevent and stop potential life-threatening bleeding complications is a major drawback to the clinical use of the direct oral inhibitors of blood coagulation factor Xa. Here we show that specific modifications of the substrate-binding aromatic S4 subpocket within the factor Xa active site disrupt high-affinity engagement of the direct factor Xa inhibitors. These modifications either entail amino-acid substitution of S4 subsite residues Tyr99 and/or Phe174 (chymotrypsinogen numbering), or extension of the 99-loop that borders the S4 subsite. The latter modifications led to the engineering of a factor Xa variant that is able to support coagulation in human plasma spiked with (supra-)physiological concentrations of direct factor Xa inhibitors. As such, this factor Xa variant has the potential to be employed to bypass the direct factor Xa inhibitor-mediated anticoagulation in patients that require restoration of blood coagulation.
Fabry disease is an X-linked lysosomal storage disorder caused by loss of alpha-galactosidase A (α-Gal A) activity and is characterized by progressive accumulation of glycosphingolipids in multiple cells and tissues. FLT190, an investigational gene therapy, is currently being evaluated in a Phase 1/2 clinical trial in patients with Fabry disease (NCT04040049). FLT190 consists of a potent, synthetic capsid (AAVS3) containing an expression cassette with a codon-optimized human GLA cDNA under the control of a liver-specific promoter FRE1 (AAV2/S3-FRE1-GLAco). For mouse studies FLT190 genome was pseudotyped with AAV8 for efficient transduction. Preclinical studies in a murine model of Fabry disease (Gla-deficient mice), and non-human primates (NHPs) showed dose-dependent increases in plasma α-Gal A with steady-state observed 2 weeks following a single intravenous dose. In Fabry mice, AAV8-FLT190 treatment resulted in clearance of globotriaosylceramide (Gb3) and globotriaosylsphingosine (lyso-Gb3) in plasma, urine, kidney, and heart; electron microscopy analyses confirmed reductions in storage inclusion bodies in kidney and heart. In NHPs, α-Gal A expression was consistent with the levels of hGLA mRNA in liver, and no FLT190-related toxicities or adverse events were observed. Taken together, these studies demonstrate preclinical proof-of-concept of liver-directed gene therapy with FLT190 for the treatment of Fabry disease.
BackgroundObesity is associated with a hypercoagulable state and increased risk for thrombotic cardiovascular events.ObjectiveEstablish the onset and reversibility of the hypercoagulable state during the development and regression of nutritionally-induced obesity in mice, and its relation to transcriptional changes and clearance rates of coagulation factors as well as its relation to changes in metabolic and inflammatory parameters.MethodsMale C57BL/6J mice were fed a low fat (10% kcal as fat; LFD) or high fat diet (45% kcal as fat; HFD) for 2, 4, 8 or 16 weeks. To study the effects of weight loss, mice were fed the HFD for 16 weeks and switched to the LFD for 1, 2 or 4 weeks. For each time point analyses of plasma and hepatic mRNA levels of coagulation factors were performed after overnight fasting, as well as measurements of circulating metabolic and inflammatory parameters. Furthermore, in vivo clearance rates of human factor (F) VII, FVIII and FIX proteins were determined after 2 weeks of HFD-feeding.ResultsHFD feeding gradually increased the body and liver weight, which was accompanied by a significant increase in plasma glucose levels from 8 weeks onwards, while insulin levels were affected after 16 weeks. Besides a transient rise in cytokine levels at 2 weeks after starting the HFD, no significant effect on inflammation markers was present. Increased plasma levels of fibrinogen, FII, FVII, FVIII, FIX, FXI and FXII were observed in mice on a HFD for 2 weeks, which in general persisted throughout the 16 weeks of HFD-feeding. Interestingly, with the exception of FXI the effects on plasma coagulation levels were not paralleled by changes in relative transcript levels in the liver, nor by decreased clearance rates. Switching from HFD to LFD reversed the HFD-induced procoagulant shift in plasma, again not coinciding with transcriptional modulation.ConclusionsChanges in dietary fat content rapidly alter the mouse plasma coagulation profile, thereby preceding plasma metabolic changes, which cannot be explained by changes in relative expression of coagulation factors or decreased clearance rates.
Functional implications of the unique disulfide bond in venom factor V from the Australian common brown snakePseudonaja textilis
The venom of the Australian brown snake Pseudonaja textilis contains a prothrombinase-like initiator of blood coagulation, which has evolved into a potent weapon through several gainof-function adaptations. Here we examined the functional implications of a disulfide bond exclusively found in the factor (F)Va-like cofactor component, ptFV. We found that this remarkable structural feature is not required for the procoagulant properties of ptFV. The nearly identical liver-derived plasma ptFV that lacks this disulfide link displayed a similar procoagulant profile. Whether the unique disulfide bond imposes conformational constraints essential to other aspects of the venom FV life cycle remains to be determined.
Adeno-associated virus (AAV) gene therapy has the potential to functionally cure hemophilia B by restoring factor (F)IX levels into the normal range. Next-generation AAV therapies express a naturally occurring gain-of-function FIX variant, FIX-Padua (R338L-FIX), that increases FIX activity (FIX:C) by approximately 8-fold compared to wild-type FIX (FIX-WT). Previous studies have shown that R338L-FIX activity varies dramatically across different clinical FIX:C assays, which complicates the monitoring and management of patients. To better understand mechanisms that contribute to R338L-FIX assay discrepancies, we characterized the performance of R338L-FIX in 13 one-stage clotting (OSA) and two chromogenic substrate (CSA) FIX:C assays in a global field study. This study produced the largest R338L-FIX assay dataset to date and confirmed that clinical FIX:C assay results vary over 3-fold. Both phospholipid and activating reagents play a role in OSA discrepancies. CSA generated the most divergent FIX:C results. Manipulation of FIX:C CSA kits demonstrated that specific activity gains for R338L-FIX were most profound at lower FIX:C levels and that these effects were enhanced during the early phases of FXa generation. Supplementing FX into CSA had the effect of dampening FIX-WT activity relative to R338L-FIX activity, suggesting that FX impairs WT tenase formation to a greater extent than R338L-FIX tenase. Our data describe the scale of R338L-FIX assay discrepancies and provide insights into the causative mechanisms that will help establish best practices for the measurement of R338L-FIX activity in patients after gene therapy.
The venom of the Australian Elapid snake Pseudonaja textilis contains a prothrombin-activating complex that consists of factor Xa (FXa) and factor Va (FVa) homologs which are evolutionary adapted to derail the hemostatic system of its prey, leading to runaway coagulation. These adaptations include functional resistance to inactivation by the main inhibitors of coagulation, antithrombin and activated protein C. Further studies revealed that venom FXa, unlike other FXa species, is also resistant to inhibition by direct oral FXa-inhibitors such as rivaroxaban and apixaban (Ki >1000 nM for venom FXa vs. 1 nM for human FXa). Accordingly, venom FXa is able to support thrombin generation (TG) in FX-depleted plasma spiked with pharmacological concentrations (0.4-2 μM) of these FXa-inhibitors. While human FXa-initiated TG resulted in a 8-fold prolonged lag time and a 70% reduced thrombin peak, those parameters were within normal range in venom FXa-triggered TG. Venom FX homologs produced by Elapid snakes comprise a heterogeneous insertion between His91-Tyr99 (chymotrypsin numbering) in the serine protease domain. A recent crystal structure of one of these homologs shows that this insertion is in close proximity of the active site pocket. In contrast, P. textilis liver-derived plasma FX, which, when activated, is fully inhibited by the FXa-inhibitors (Ki10 nM), lacks this structural feature. We investigated whether the His91-Tyr99 insertion is at the basis of the reduced sensitivity of venom FXa towards FXa-inhibitors. To do so, we constructed and stably expressed human-snake FX chimeras (FX-A, -B, -C) that incorporate His91-Tyr99 insertions from three venom FXa homologs. The chimeric FX variants were purified by successive ion-exchange and hydrophobic interaction chromatography steps, and FXa was generated following RVV-X-activation and size-exclusion chromatography. Evaluation of the kinetic parameters of prothrombin conversion in the presence of saturating amounts of FVa and anionic phospholipids revealed that the chimeric FXa variants exhibit an up to ~4-fold enhanced affinity for prothrombin (Km 0.11-0.29 μM) as compared to recombinant human FXa (rhFXa; Km 0.41 μM). The rate of prothrombin activation was 3-10-fold reduced (kcat 118-370 min-1 vs. 1243 min-1 for rhFXa), which may be indicative of a modified active site conformation. Consistent with this, the rate of chimeric FXa inhibition by antithrombin was impaired (kapp 0.12-0.95 x 103 M-1 s-1 vs. 4.07 x 103 M-1 s-1 for rhFXa). Furthermore, the variant that was most poorly inhibited by antithrombin (variant A) also exhibited the lowest catalytic rate of prothrombin conversion and vice versa (variant C). Conversely, apixaban or edoxaban inhibition of the FXa variants assembled into prothrombinase led to the highest Ki for chimeric variant C (2.3 or 0.3 µM), followed by variants B (1.4 or 0.2 µM), and A (0.2 or 0.006 µM) compared to rhFXa (0.004 or 0.0005 µM). Evaluation of the inhibition of uncomplexed FXa variants employing peptidyl substrate conversion revealed a similar decrease in sensitivity to the FXa-inhibitors (≤500-fold). These data suggest that insertion of the snake venom His91-Tyr99 regions indeed results in impaired engagement of the FXa active site pocket. We next assessed whether chimeric variant C, which is most resistant to inhibition by the direct FXa-inhibitors, is able to restore thrombin generation in a plasma system in the presence of apixaban or edoxaban. While rhFXa-triggered (5 nM) thrombin formation in FX-depleted plasma was inhibited by 2 μM apixaban, initiation with FXa-C (5 nM) resulted in normal thrombin generation parameters (peak thrombin 98%). In addition, the zymogen form of variant C also supported tissue factor-initiated (2 pM) thrombin generation in FX-depleted plasma with inhibitor concentrations up to 6 μM (apixaban) or 2 μM (edoxaban). Under these conditions, little if any thrombin was formed with rhFX present (peak thrombin 5%). We obtained similar results when performing these experiments in normal pooled plasma. Taken together, these results show that chimeric FX is able to restore hemostasis in plasma inhibited by the direct FXa-inhibitors, both in the zymogen as well as protease state. As such, these variants have the potential to serve as rescue therapeutic agents to overcome the effect of FXa-inhibitors in case of potential life-threatening bleeding events or emergency surgical interventions. Disclosures Bos: Bayer Hemophilia Awards: Research Funding.
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