Objective: Obesity is characterized by chronic low-grade inflammation and consequentially a hypercoagulable state, associating with an increased incidence of venous thromboembolism. Increased VWF (von Willebrand factor) plasma concentration and procoagulant function are independent risk factors for venous thromboembolism and are elevated in obese patients. Here, we explore the pathobiological role of VWF in obesity-associated venous thrombosis using murine models. Approach and Results: We first showed that diet-induced obese mice have increased VWF plasma levels and FVIII (factor VIII) activity compared with littermate controls. Elevated VWF levels appeared to be because of both increased synthesis and impaired clearance. Diet-induced obesity-associated venous thrombosis was assessed using the inferior vena cava-stenosis model of deep vein thrombosis. Diet-induced obese mice developed larger venous thrombi that were rich in VWF, erythrocytes, and leukocytes. Administering a polyclonal anti-VWF antibody or an anti-VWF A1 domain nanobody was protective against obesity-mediated thrombogenicity. Delayed administration (3 hours post–inferior vena cava stenosis) similarly reduced thrombus weight in diet-induced obese mice. Conclusions: This study demonstrates the critical role of VWF in the complex, thrombo-inflammatory state of obesity. It adds to the growing rationale for targeting VWF-specific interactions in thrombotic disease.
Background von Willebrand factor (VWF) and factor VIII (FVIII) circulate as a non-covalent complex, with VWF serving as the carrier for FVIII. VWF indirectly influences secondary hemostasis by stabilizing FVIII and transporting it to the site of primary hemostasis. Type 2N von Willebrand disease involves impaired binding of VWF to FVIII, resulting in decreased plasma levels of FVIII. Objectives In these studies, we characterize the impact of three type 2N VWD variants (R763A, R854Q, R816W) on VWF secretion, FVIII stabilization and thrombus formation in a murine model. Methods Type 2N VWD mice were generated by hydrodynamic injections of mutant murine VWF cDNAs and the influence of these variants on VWF secretion and FVIII binding was evaluated. In vivo hemostasis and the dynamics of thrombus formation and embolization were assessed using a murine tail vein transection hemostasis model and an intravital thrombosis model in the cremaster arterioles. Results Type 2N VWD variants were associated with decreased VWF secretion using cell and animal-based models. FVIII-binding to type 2N variants was impaired in vitro and was variably stabilized in vivo by expressed or infused 2N variant VWF protein. Both transgenic type 2N VWD and FVIII knockout (KO) mice demonstrated impaired thrombus formation associated with decreased thrombus stability. Conclusions The type 2N VWD phenotype can be recapitulated in a murine model and is associated with both quantitative and qualitative VWF deficiencies and impaired thrombus formation. Patients with type 2N VWD may have normal primary hemostasis formation but decreased thrombus stability related to ineffective secondary hemostasis.
Background Stabilin‐2 is an endocytic scavenger receptor that mediates the clearance of glycosaminoglycans, phosphatidylserine‐expressing cells, and the von Willebrand factor‐factor VIII (FVIII) complex. In a genome‐wide screening study, pathogenic loss‐of‐function variants in the human STAB2 gene associated with an increased incidence of unprovoked venous thromboembolism (VTE). However, the specific mechanism(s) by which stabilin‐2 deficiency influences the pathogenesis of VTE is unknown. Objectives The aim of this study was to assess the influence of stabilin‐2 on deep vein thrombosis (DVT) and to characterize the underlying prothrombotic phenotype of stabilin‐2 deficiency in a mouse model. Methods DVT was induced using the inferior vena cava (IVC) stenosis model in two independent cohorts (littermates and non‐littermates) of wild‐type (Stab2+/+) and stabilin‐2 (Stab2−/−)–deficient mice. Thrombus structure and contents were quantified by immunohistochemistry. Plasma procoagulant activity was assessed and complete blood counts were performed. Results Incidence of thrombus formation was not altered between Stab2+/+ and Stab2−/− mice. When thrombi were formed, Stab2−/− mice developed significantly larger thrombi than Stab2+/+ controls. Thrombi from Stab2−/− mice contained significantly more leukocytes and citrullinated histone H3 than Stab2+/+ thrombi. Stab2−/− mice had increased FVIII activity. Circulating levels of monocytes and granulocytes were significantly elevated in Stab2−/− mice, and Stab2−/− mice had elevated plasma cell‐free DNA 24 hours post‐IVC stenosis compared to their Stab2+/+ counterparts. Conclusions These data suggest that stabilin‐2 deficiency associates with a prothrombotic phenotype involving elevated levels of neutrophil extracellular trap‐releasing leukocytes coupled with endogenous procoagulant activity, resulting in larger and qualitatively distinct venous thrombi.
Ancestral sequence reconstruction provides a unique platform for investigating the molecular evolution of single gene products and recently has shown success in engineering advanced biological therapeutics. To date, the coevolution of proteins within complexes and protein–protein interactions is mostly investigated in silico via proteomics and/or within single-celled systems. Herein, ancestral sequence reconstruction is used to investigate the molecular evolution of 2 proteins linked not only by stabilizing association in circulation but also by their independent roles within the primary and secondary hemostatic systems of mammals. Using sequence analysis and biochemical characterization of recombinant ancestral von Willebrand factor (VWF) and coagulation factor VIII (FVIII), we investigated the evolution of the essential macromolecular FVIII/VWF complex. Our data support the hypothesis that these coagulation proteins coevolved throughout mammalian diversification, maintaining strong binding affinities while modulating independent and distinct hemostatic activities in diverse lineages.
Hemophilia A, which is caused by a mutation in the Factor 8 (F8) gene resulting in a deficiency or lack of the Factor VIII (FVIII) protein, is the most common inherited bleeding disorder in humans with an estimated worldwide incidence of half a million people. The disorder is X-linked and occurs in approximately 1 in 5,000 males; however there is also a growing appreciation of the impact on carrier females having a single mutant allele, with at least 10% of hemophilia A female carriers having less than normal clotting activity. Even modest increases in Factor V III activity (>1% of normal) can have a positive impact on patient lives, thus making the disease an ideal candidate for liver-directed gene therapy. Recombinant AAV (rAAV) has been used extensively for nearly 20 years as a gene therapy vector in preclinical and clinical studies where rAAV delivery to non-dividing tissues such as liver, brain and muscle affords stable, long-term transgene expression. However, there has been a lag in the clinical translation of a rAAV gene therapy approach for Hemophilia A/human F8 (hF8) compared to Hemophilia B/human Factor 9 due to poor yields of rAAV encoding a F8 transgene at clinical scale, and a requirement for large doses of rAAV F8 vector to achieve therapeutically relevant levels of circulating human FVIII (hFVIII), with the attendant risk of inducing an AAV-directed immune response requiring transient immunosuppression. To address these issues we optimized a rAAV F8 cDNA vector cassette to improve both virus yields and liver-specific hFVIII expression. The rAAV F8 cDNA vector cassette optimization required multi-factorial modifications to the liver-specific promoter module, hF8 transgene, synthetic polyadenylation signal and vector backbone sequence. This iterative process resulted in improved vector yields at research scale and greater than five-fold improvement in vector yields at clinical scale using our proven manufacturing process. Administration of the optimized rAAV hF8 cDNA packaged in serotype AAV2/6 at a dose of ~7.2E+12 vg/kg to both wild type and Hemophilia A mice resulted in robust circulating hFVIII levels and activity (levels in wild type mice were 241.6% of normal, and activity in Hemophilia A mice were 330.9% of normal). An analysis of hF8 mRNA levels in different tissues following dosage with our optimized vector demonstrated that hF8 expression from the modified promoter module was restricted to the liver. Notably there was a striking impact on hemostasis in the Hemophilia A mice treated with the optimized rAAV hF8 cDNA, with a reduction in bleeding time from 38.3 minutes to 2.5 minutes in treated mice (n = 12, p-value < 0.0001), which is in line with bleeding times in wild type mice. Initial studies in non-human primates (NHPs) resulted in supraphysiological levels of circulating hFVIII with mean peak values of 400-600% of normal levels. A follow up dose-ranging study was performed in NHPs with a rAAV2/6 F8 cDNA vector manufactured using our GMP clinical manufacturing process. Administration of vector doses ranging from 6E+11 vg/kg to 6E+12 vg/kg resulted in therapeutic circulating levels of hFVIII that were 5% - 229% of normal levels. The peak circulating hFVIII levels achieved in this dose-ranging study using GMP clinical-scale vector exceeds the levels previously reported in NHPs by several fold on an AAV vector dose basis. The high potency of this enhanced rAAV F8 cDNA cassette could significantly reduce the dose required to achieve therapeutically relevant levels in human subjects and reduce the potential of developing immune responses to AAV capsid requiring immunosuppression. Disclosures Riley: Sangamo BioSciences Inc: Employment. Boonsripisal:Sangamo BioSciences Inc: Employment. Goodwin:Sangamo BioSciences Inc: Employment. Garces:Sangamo BioSciences Inc: Employment. Ballaron:Sangamo BioSciences Inc: Employment. Tran:Sangamo BioSciences Inc: Employment. Kang:Sangamo BioSciences Inc: Employment. Zhang:Sangamo BioSciences Inc: Employment. Meyer:Sangamo BioSciences Inc: Employment. Greengard:Sangamo BioSciences Inc: Employment. Surosky:Sangamo BioSciences Inc: Employment. Ando:Sangamo BioSciences Inc: Employment. Lillicrap:bayer: Research Funding; biogen: Research Funding; CSL: Research Funding; Octapharma: Research Funding; Sangamo Biosciences Inc: Research Funding. Nichol:Sangamo BioSciences Inc: Employment. Holmes:Sangamo BioSciences Inc: Employment.
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