In vivo evaluation of a novel epitope-tagged human factor VIII-encoding adenoviral vector.

Haemophilia A is caused by a deficiency in coagulation factor VIII (FVIII) and is an attractive target for gene therapy. Adenoviral vectors encoding a human B-domain deleted (BDD) FVIII cDNA have been shown previously to mediate expression of high levels of human FVIII and correct the bleeding defect in haemophiliac mice and dogs. While vector assessment in a non-human primate model would have a significant preclinical benefit, a haemophiliac non-human primate model is not available, and assays that distinguish human FVIII from monkey FVIII have not been developed successfully. As a first step to enable vector evaluation in non-human primates, we have constructed an epitope-tagged FVIII molecule by the addition of 16 amino-acids to the carboxy terminus of the BDD protein (BDD-E). Following vector administration to normal mice, therapeutic levels of BDD-E FVIII were expressed for at least 20 weeks. Treatment of haemophiliac mice revealed that the BDD-E protein was biologically active in vivo. To distinguish the BDD-E protein from non-human primate FVIII, a sensitive immunoprecipitation/Western assay was developed that reproducibly detected 1 ng mL-1 of the epitope-tagged human FVIII in the presence of monkey plasma. These data demonstrate that the addition of an epitope tag had no effect on FVIII function or immunogenicity, and suggest that the BDD-E vector will be an effective reagent for non-human primate studies.

In vivo evaluation of an adenoviral vector encoding canine factor VIII: high-level, sustained expression in hemophiliac mice.

Hemophilia A is the most common severe hereditary coagulation disorder and is caused by a deficiency in blood clotting factor VIII (FVIII). Canine hemophilia A represents an excellent large animal model that closely mimicks the human disease. In previous studies, treatment of hemophiliac dogs with an adenoviral vector encoding human FVIII resulted in complete correction of the coagulation defect and high-level FVIII expression [Connelly et al. (1996). Blood 88, 3846]. However, FVIII expression was short term, limited by a strong antibody response directed against the human protein. Human FVIII is highly immunogenic in dogs, whereas the canine protein is significantly less immunogenic. Therefore, sustained phenotypic correction of canine hemophilia A may require the expression of the canine protein. In this work, we have isolated the canine FVIII cDNA and generated an adenoviral vector encoding canine FVIII. We demonstrate expression of canine FVIII in hemophiliac mice at levels 10-fold higher than those of the human protein expressed from an analogous vector. Canine FVIII expression was sustained above human therapeutic levels (50 mU/ml) for at least 1 year in hemophiliac mice.

Sustained phenotypic correction of murine hemophilia A by in vivo gene therapy.

Hemophilia A is caused by a deficiency of blood coagulation factor VIII (FVIII) and has been widely discussed as a candidate for gene therapy. While the natural canine model of hemophilia A has been valuable for the development of FVIII pharmaceutical products, the use of hemophiliac dogs for gene therapy studies has several limitations such as expense and the long canine generation time. The recent creation of two strains of FVIII-deficient mice provides the first small animal model of hemophilia A. Treatment of hemophiliac mice of both genotypes with potent, human FVIII-encoding adenoviral vectors resulted in expression of biologically active human FVIII at levels, which declined, but remained above the human therapeutic range for over 9 months. The duration of expression and FVIII plasma levels achieved were similar in both hemophiliac mouse strains. Treated mice readily survived tail clipping with minimal blood loss, thus showing phenotypic correction of murine hemophilia A by in vivo gene therapy.

Adenovirus mediated expression of therapeutic plasma levels of human factor IX in mice.

Gene therapy strategies designed to combat haemophilia B, caused by defects in clotting factor IX, have so far concentrated on ex vivo approaches. We have now evaluated adenoviral vector-mediated expression of human factor IX in vivo. Injection of the vector Av1H9B, which encodes human factor IX cDNA, into the tail veins of mice resulted in efficient liver transduction and plasma levels of human factor IX that would be therapeutic for haemophilia B patients. However, levels slowly declined to baseline by nine weeks and were not re-established by a second vector injection. These results address both the advantages and obstacles to the use of adenoviral vectors for treatment of haemophilia B.