Inhibitory antibodies to factor VIII (FVIII) are a major complication in the treatment of hemophilia A, affecting approximately 20% to 30% of patients. Current treatment for inhibitors is based on long-term, daily injections of large amounts of FVIII protein. Liver-directed gene therapy has been used to induce antigen-specific tolerance, but there are no data in hemophilic animals with pre-existing inhibitors. To determine whether sustained endogenous expression of FVIII could eradicate inhibitors, we injected adeno-associated viral vectors encoding canine FVIII (cFVIII) in 2 strains of inhibitor hemophilia A dogs. In 3 dogs, a transient increase in inhibitor titers (up to 7 Bethesda Units [BU]) at 2 weeks was followed by continuous decline to complete disappearance within 4-5 weeks. Subsequently, an increase in cFVIII levels (1.5%-8%), a shortening of clotting times, and a reduction (> 90%) of bleeding episodes were observed. Immune tolerance was confirmed by lack of antibody formation after repeated challenges with cFVIII protein and normal protein half-life. A fourth dog exhibited a strong early anamnestic response (216 BU), with slow decline to 0.8 BU and cFVIII antigen detection by 18 months after vector delivery. These data suggest that liver gene therapy has the potential to eradicate inhibitors and could improve the outcomes of hemophilia A patients. (Blood. 2010;116(26): 5842-5848) IntroductionThe development of neutralizing antibodies to replacement protein is a major complication of protein and enzyme replacement therapies for several genetic diseases. Hemophilia A is an X-linked bleeding disorder characterized by deficiency in the activity of factor VIII (FVIII), a key component of the coagulation cascade. The disease occurs in approximately 1 in 10 000 live births worldwide, and Ͼ 40% of these patients have severe disease, with FVIII activity Ͻ 1% of normal. 1 Infusion of plasma-derived or recombinant FVIII is the standard treatment. Alloantibodies (inhibitors) that neutralize the protein-replacement therapy develop in 20% to 30% of young patients with severe and moderate hemophilia A, resulting in high morbidity and mortality, 2,3 and this is a growing problem for adults as well. 4,5 Risk factors for inhibitor formation include both genetic and environmental factors. Underlying mutations in the FVIII gene, such as large gene deletions, nonsense mutations, and the most common mutation in severe hemophilia A patients, the inversion of intron 22, are all associated with inhibitor formation; however, it is not possible to predict with certainty which patients will develop inhibitors. For this reason, preventive strategies are not currently feasible. [6][7][8] Patients with high titers of inhibitors, defined as Ͼ 5 Bethesda units (BU), cannot usually be treated with FVIII replacement, necessitating the use of products that bypass the procoagulant effect of FVIII and are extremely expensive. 1 Thus, strategies for the eradication of inhibitors are of fundamental clinical relevance.Currently, the only pro...
Despite proven benefits, prophylactic treatment for hemophilia A is hampered by the short half-life of factor VIII. A recombinant factor VIII-Fc fusion protein (rFVIIIFc) was constructed to determine the potential for reduced frequency of dosing. rFVIIIFc has an ϳ 2-fold longer half-life than rFVIII in hemophilia A (HemA) mice and dogs. The extension of rFVIIIFc half-life requires interaction of Fc with the neonatal Fc receptor (FcRn). In FcRn knockout mice, the extension of rFVIIIFc half-life is abrogated, and is restored in human FcRn transgenic mice. The Fc fusion has no impact on FVIII-specific activity. rFVIIIFc has comparable acute efficacy as rFVIII in treating tail clip injury in HemA mice, and fully corrects whole blood clotting time (WBCT) in HemA dogs immediately after dosing. Furthermore, consistent with prolonged half-life, rFVIIIFc shows 2-fold longer prophylactic efficacy in protecting HemA mice from tail vein transection bleeding induced 24-48 hours after dosing. In HemA dogs, rFVIIIFc also sustains partial correction of WBCT 1.5-to 2-fold longer than rFVIII. rFVIIIFc was well tolerated in both species. Thus, the rescue of FVIII by Fc fusion to provide prolonged protection presents a novel pathway for FVIII catabolism, and warrants further investigation. (Blood. 2012;119(13):3024-3030) IntroductionHemophilia A is an X-linked bleeding disorder caused by deficiency of factor VIII (FVIII) activity. 1 The disease is characterized by spontaneous hemorrhage and excessive bleeding after trauma. Over time, repeated bleeding into muscles and joints, which begins in early childhood, results in hemophilic arthropathy and irreversible joint damage. This damage is progressive and leads to pronounced musculoskeletal morbidity. 1 Prophylaxis significantly reduces joint damage and long-term sequelae, and improves quality of life in comparison to on-demand treatment. 2,3 However, the short half-life (10-12 hours) of FVIII necessitates dosing every other day or 3 times per week by IV injection for full prophylaxis. 2,4,5 Therefore, a longer-acting FVIII would represent a key advancement in the management of hemophilia A.We have developed a recombinant factor VIII-Fc (rFVIIIFc) fusion protein to extend the half-life of FVIII by leveraging a naturally occurring biologic pathway. rFVIIIFc is a heterodimeric protein comprising a single B-domain-deleted (BDD) FVIII linked recombinantly to the Fc domain of human IgG1 (IgG1). The Fc domain enables binding to the neonatal Fc receptor (FcRn), which is responsible for protection of IgG from degradation and facilitates its recycling, 6,7 resulting in a half-life for IgG of ϳ 3 weeks in humans. The Fc domain of IgG1 has been fused to growth factors, cytokines, enzymes, and ligand-binding regions of receptors [8][9][10] ; several of these fusion proteins have been approved as therapeutics (eg, etanercept, abatacept, belatacept, alefacept, rilonacept, aflibercept, and romiplostim). However, traditional dimeric Fc fusions, created through the fusion of the monomeric effector p...
Dogs with hemophilia A, hemophilia B, von Willebrand disease (VWD), and factor VII deficiency faithfully recapitulate the severe bleeding phenotype that occurs in humans with these disorders. The first rational approach to diagnosing these bleeding disorders became possible with the development of reliable assays in the 1940s through research that used these dogs. For the next 60 years, treatment consisted of replacement of the associated missing or dysfunctional protein, first with plasma-derived products and subsequently with recombinant products. Research has consistently shown that replacement products that are safe and efficacious in these dogs prove to be safe and efficacious in humans. But these highly effective products require repeated administration and are limited in supply and expensive; in addition, plasma-derived products have transmitted bloodborne pathogens. Recombinant proteins have all but eliminated inadvertent transmission of bloodborne pathogens, but the other limitations persist. Thus, gene therapy is an attractive alternative strategy in these monogenic disorders and has been actively pursued since the early 1990s. To date, several modalities of gene transfer in canine hemophilia have proven to be safe, produced easily detectable levels of transgene products in plasma that have persisted for years in association with reduced bleeding, and correctly predicted the vector dose required in a human hemophilia B liver-based trial. Very recently, however, researchers have identified an immune response to adeno-associated viral gene transfer vector capsid proteins in a human liver-based trial that was not present in preclinical testing in rodents, dogs, or nonhuman primates. This article provides a review of the strengths and limitations of canine hemophilia, VWD, and factor VII deficiency models and of their historical and current role in the development of improved therapy for humans with these inherited bleeding disorders.
Summary Dogs with haemophilia A or haemophilia B exhibit spontaneous bleeding comparable with the spontaneous bleeding phenotype that occurs in humans with severe haemophilia. The phenotypic and genotypic characteristics of haemophilic dogs have been well-described, and such dogs are suitable for testing prophylactic protein replacement therapy and gene transfer strategies. In dogs with haemophilia, long-term effects on spontaneous bleeding frequency (measured over years) can be used as an efficacy endpoint in such studies. Although complete correction of coagulopathy has not been achieved, published data show that prophylactic factor replacement therapy and gene transfer can markedly reduce the frequency of spontaneous bleeding in haemophilic dogs. Further studies are currently ongoing.
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