Abstract
Hemophilia A is a bleeding disease caused by loss of coagulation factor VIII (FVIII) function. Although prophylactic FVIII infusion prevents abnormal bleeding, disability and joint damage in hemophilia patients are common. The cost of treatment is among the highest for a single disease, and the adverse effects of repeated infusion are still an issue that has not been addressed. In this study, we established a nonviral gene therapy strategy to treat FVIII knockout (FVIII KO) mice. A novel gene therapy approach was developed using dipalmitoylphosphatidylcholine formulated with iron oxide (DPPC-Fe3O4) to carry the B-domain-deleted (BDD)-FVIII plasmid, which was delivered into the FVIII KO mice via tail vein injection. Here, a liver-specific albumin promoter-driven BDD-FVIII plasmid was constructed, and the binding ability of circular DNA was confirmed to be more stable than that of linear DNA when combined with DPPC-Fe3O4 nanoparticles. The FVIII KO mice that received the DPPC-Fe3O4 plasmid complex were assessed by staining the ferric ion of DPPC-Fe3O4 nanoparticles with Prussian blue in liver tissue. The bleeding of the FVIII KO mice was improved in a few weeks, as shown by assessing the activated partial thromboplastin time (aPTT). Furthermore, no liver toxicity, thromboses, deaths, or persistent changes after nonviral gene therapy were found, as shown by serum liver indices and histopathology. The results suggest that this novel gene therapy can successfully improve hemostasis disorder in FVIII KO mice and might be a promising approach to treating hemophilia A patients in clinical settings.
Highlights
Hemophilia is a genetic disorder caused by the loss of coagulation factor genes
Our results suggest that DPPC-Fe3 O4 nanoparticles can be a better material to conduct factor VIII (FVIII) gene delivery because of their high biocompatibility, low biotoxicity, and lack of size limitation for carrying DNA
We successfully developed a novel DPPC-Fe3 O4 -plasmid complex to deliver liver-specific albumin promoter-driven BDD-hFVIII gene expression for more than two weeks in a mouse model of hemophilia A
Summary
Hemophilia is a genetic disorder caused by the loss of coagulation factor genes. 30% of hemophilia patients have spontaneous mutations, and others have a family genetic history [1,2]. Hemophilia is diagnosed if the coagulation factor activity in plasma is less than 40% [3]. 1% of normal coagulation activity, and recurrent spontaneous bleeding episodes from subcutaneous tissues and joints will cause hematomas [4,5]. Hemophilia is divided into different types according to the lack of different coagulation factors; among them, approximately 70–80% of cases are hemophilia A. Hemophilia A is a recessive X-linked hereditary disease, and the most common mutation is the intron 22 inversion of the FVIII gene [6,7]
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