Dawn B. Kayda scite author profile

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.

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Sustained Human Factor VIII Expression in Hemophilia A Mice Following Systemic Delivery of a Gutless Adenoviral Vector

Reddy

et al. 2002

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Gutless adenoviral vectors are devoid of all viral coding regions and display reduced cytotoxicity, diminished immunogenicity, and an increased coding capacity compared with early generation vectors. Using hemophilia A, a deficiency in clotting factor VIII (FVIII), as a model disease, we generated and evaluated a gutless vector encoding human FVIII. The FVIII gutless vector grew to high titer and was reproducibly scaled-up from vector seed lots. Extensive viral DNA analyses revealed no rearrangements of the vector genome. A quantitative PCR assay demonstrated helper virus contamination levels of <2%, with the best preparation containing 0.3% helper virus. We compared the gutless vector with an E1/E2a/E3-deficient (Av3) early generation vector encoding an identical FVIII expression cassette following intravenous administration to hemophilia A mice. Gutless vector-treated mice displayed 10-fold higher FVIII expression levels that were sustained for at least 9 months. In contrast, mice treated with the Av3 vector displayed FVIII levels below the limit of sensitivity of the assay at 3 months. Assessment of hepatotoxicity by measuring the serum levels of liver enzymes demonstrated that the gutless vector was significantly less toxic than the Av3 vector at time points later than 7 days. At the highest dose used, both vectors caused a transient 10-fold increase in liver enzymes 1 day after vector administration, suggesting that this increase was caused by direct toxicity of the input capsid proteins. These data demonstrate that the gutless vector displayed increased duration and levels of FVIII expression, and was significantly less toxic than an analogous early generation vector.

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Optimization of the Generation and Propagation of Gutless Adenoviral Vectors

et al. 2003

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Adenoviral vectors devoid of all viral coding regions are referred to by many names, including gutless vectors. Gutless vectors display reduced toxicity and immunogenicity, increased duration of transgene expression, and increased coding capacity compared to early generation vectors, which contain the majority of the viral backbone genes. However, the production of gutless vectors at a scale and purity suitable for clinical use has limited the utility of this technology. In this work we describe the optimization of the production of gutless vectors. We constructed an improved helper virus and generated an alternative gutless vector producer cell line, PERC6-Cre. We demonstrated increased gutless vector yields, minimal helper virus contamination, and no replication-competent adenovirus contamination using the optimized system. Furthermore, the PERC6-Cre cells were adapted to serum-free suspension culture and high-titer gutless vector preparations were produced using bioreactor technology, suggesting the feasibility of gutless vector scale-up for clinical use. Finally, we observed that helper virus lacking a packaging signal could be packaged at a low frequency, revealing an inherent limitation to the differential packaging strategy for gutless vector propagation.

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Sustained Phenotypic Correction of Murine Hemophilia A by In Vivo Gene Therapy

et al. 1998

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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.

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Dawn B. Kayda

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

Sustained Human Factor VIII Expression in Hemophilia A Mice Following Systemic Delivery of a Gutless Adenoviral Vector

Optimization of the Generation and Propagation of Gutless Adenoviral Vectors

Sustained Phenotypic Correction of Murine Hemophilia A by In Vivo Gene Therapy

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