Joel L. Frandsen scite author profile

The Sleeping Beauty (SB) transposon system can integrate foreign sequences of DNA in the genome of mouse somatic cells eliciting long-term expression in vivo. This technology holds great promise for human gene therapy as a nonviral technology to deliver therapeutic genes. SB also provides a means to study the effects of defined genetic elements, such as oncogenes, on somatic cells in mice. Here, we test the ability of the SB transposon system to facilitate somatic integration of a transposon containing an activated NRAS oncogene in mouse hepatocytes to elicit tumor formation. NRAS oncogene-driven tumors developed when such vectors were delivered to the livers of p19Arf-null or heterozygous mice. Delivery of the NRAS transposon cooperates with Arf loss to cause carcinomas of hepatocellular or biliary origin. These tumors allowed characterization of transposon integration and expression at the single-cell level, revealing robust NRAS expression and both transposase-mediated and random insertion of delivered vectors. Random integration and expression of the SB transposase plasmid was also observed in one instance. In addition, studies using effector loop mutants of activated NRAS provide evidence that mitogen-activated protein kinase activation alone cannot efficiently induce liver carcinomas. This system can be used to rapidly model tumors caused by defined genetic changes.cancer ͉ gene therapy ͉ Nras ͉ p19Arf

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Phenotypic correction and long-term expression of factor VIII in hemophilic mice by immunotolerization and nonviral gene transfer using the Sleeping Beauty transposon system

Ohlfest

et al. 2005

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Hemophilia A is a lead candidate for treatment by gene therapy because small increments in the missing secreted protein product, coagulation factor VIII (FVIII), would result in substantial clinical amelioration. Clinically relevant therapy might be achieved by stably delivering a human FVIII cDNA to correct the bleeding disorder. We used the Sleeping Beauty (SB) transposon, delivered as naked plasmid DNA by tail-vein injection, to integrate B-domain-deleted FVIII genes into the chromosomes of hemophilia A mice and correct the phenotype. Since FVIII protein is a neoantigen to these mice, sustaining therapeutic plasma FVIII levels was problematic due to inhibitory antibody production. We circumvented this problem by tolerizing 82% of neonates by a single facial-vein injection of recombinant FVIII within 24 hours of birth (the remaining 18% formed inhibitors). Achievement of high-level (10%-100% of normal) FVIII expression and phenotypic correction required co-injection of an SB transposaseexpressing plasmid to facilitate transgene integration in immunotolerized animals. Linker-mediated polymerase chain reaction was used to clone FVIII transposon insertion sites from liver genomic DNA, providing molecular evidence of transposition. Thus, SB provides a nonviral means for sustained IntroductionHemophilia A is an X-linked, recessive, genetic disorder that is caused by insufficient coagulation factor (F) VIII synthesis resulting in sustained bleeding after trauma or injury. 1 Recombinant FVIII protein is currently used to treat bleeding episodes at the cost of approximately $55 000 per person year and is not available in many parts of the world. 2 Gene therapy for hemophilia has recently been an intense area of study because even modest levels (2%-5% normal) of FVIII or FIX can improve clinical outcomes. Considerable progress has been made in developing both nonviral and viral vectors to this end. Viral vectors have been extremely effective in delivering FVIII and FIX transgenes, in some cases curing animal models of hemophilia A and B, respectively (reviewed in Nathwani et al 3 ).However, problems related to triggering of the host inflammatory response have resulted in cessation of clinical trials with both adenovirus 4 and adeno-associated virus. 5 Accordingly, improved adenoviral vectors are being developed that may be less immunogenic (reviewed in Ritter et al 6 ), and the use of alternative serotypes also has shown promise in adeno-associated virus re-administration. 7 Nevertheless, these kinds of problems, along with large-scale vector production challenges, have fueled intense interest in development of nonviral approaches for the treatment of hemophilia by gene therapy.The benefits of nonviral vectors include simplicity, ease of storage, and amenability to large-scale manufacture. 3,8 They are also potentially less immunogenic than viral vectors, which could allow for safer administration and/or re-administration. Integrating and nonintegrating plasmid-based vectors have been developed and successfully tested...

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RNA as a Source of Transposase for Sleeping Beauty-Mediated Gene Insertion and Expression in Somatic Cells and Tissues

et al. 2006

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Sleeping Beauty (SB) is a DNA transposon capable of mediating gene insertion and long-term expression in vertebrate cells when co-delivered with a source of transposase. In all previous reports of SB-mediated gene insertion in somatic cells, the transposase component has been provided by expression of a co-delivered DNA molecule that has the potential for integration into the host cell genome. Integration and continued expression of a gene encoding SB transposase could be problematic if it led to transposon re-mobilization and reintegration. We addressed this potential problem by supplying the transposase-encoding molecule in the form of mRNA. We show that transposase-encoding mRNA can effectively mediate transposition in vitro in HT1080 cells and in vivo in mouse liver following co-delivery with a recoverable transposon or with a luciferase transposon. We conclude that in vitro-transcribed mRNA can be used as an effective source of transposase for SB-mediated transposition in mammalian cells and tissues.

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Correction of metabolic, craniofacial, and neurologic abnormalities in MPS I mice treated at birth with adeno-associated virus vector transducing the human α-l-iduronidase gene

et al. 2004

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Murine models of lysosomal storage diseases provide an opportunity to evaluate the potential for gene therapy to prevent systemic manifestations of the disease. To determine the potential for treatment of mucopolysaccharidosis type I using a gene delivery approach, a recombinant adeno-associated virus (AAV) vector, vTRCA1, transducing the human iduronidase (IDUA) gene was constructed and 1 x 10(10) particles were injected intravenously into 1-day-old Idua(-/-) mice. High levels of IDUA activity were present in the plasma of vTRCA1-treated animals that persisted for the 5-month duration of the study, with heart and lung of this group demonstrating the highest tissue levels of gene transfer and enzyme activity overall. vTRCA1-treated Idua(-/-) animals with measurable plasma IDUA activity exhibited histopathological evidence of reduced lysosomal storage in a number of tissues and were normalized with respect to urinary GAG excretion, craniofacial bony parameters, and body weight. In an open field test, vTRCA1-treated Idua(-/-) animals exhibited a significant reduction in total squares covered and a trend toward normalization in rearing events and grooming time compared to control-treated Idua(-/-) animals. We conclude that AAV-mediated transduction of the IDUA gene in newborn Idua(-/-) mice was sufficient to have a major curative impact on several of the most important parameters of the disease.

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Messenger RNA as a Source of Transposase for Sleeping Beauty Transposon–mediated Correction of Hereditary Tyrosinemia Type I

et al. 2007

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The Sleeping Beauty (SB) transposon system mediates chromosomal integration and stable gene expression when an engineered SB transposon is delivered along with transposase. One concern in the therapeutic application of the SB system is that persistent expression of transposase could result in transposon instability and genotoxicity. Here, we tested the use of transposase-encoding RNA plus transposon DNA for correction of murine fumarylacetoacetate hydrolase (FAH) deficiency. A bi-functional transposon containing both mouse FAH and firefly luciferase sequences was used to track the growth of genetically corrected liver tissue by in vivo bioluminescence imaging after delivery of DNA or RNA as a source of transposase. Supplying SB transposase in the form of RNA resulted in selective repopulation of corrected hepatocytes with stable expression of FAH and luciferase. Plasma succinylacetone and amino acid levels were normalized, suggesting normal liver metabolism of catabolized protein products. Secondary FAH-deficient animals transplanted with hepatocytes (250,000) isolated from primary treated animals survived 2-(2-nitro-4-trifluoro-methylbenzoyl)-1,3-cyclohexanedione (NTBC) withdrawal, gained weight consistently, and demonstrated stable expression of luciferase. We conclude that transposase-encoding messenger RNA (mRNA) can be used to mediate stable non-viral gene therapy, resulting in complete phenotypic correction, and is thus an effective source of recombinase activity for use in human gene therapy.

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Joel L. Frandsen

Somatic integration of an oncogene-harboring Sleeping Beauty transposon models liver tumor development in the mouse

Phenotypic correction and long-term expression of factor VIII in hemophilic mice by immunotolerization and nonviral gene transfer using the Sleeping Beauty transposon system

RNA as a Source of Transposase for Sleeping Beauty-Mediated Gene Insertion and Expression in Somatic Cells and Tissues

Correction of metabolic, craniofacial, and neurologic abnormalities in MPS I mice treated at birth with adeno-associated virus vector transducing the human α-l-iduronidase gene

Messenger RNA as a Source of Transposase for Sleeping Beauty Transposon–mediated Correction of Hereditary Tyrosinemia Type I

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