Sustained expression from DNA vectors.

DNA vectors have the potential to become powerful medical tools for treatment of human disease. The human body has, however, developed a range of defensive strategies to detect and silence foreign or misplaced DNA, which is more typically encountered during infection or chromosomal damage. A clinically relevant human gene therapy vector must overcome or avoid these protections whilst delivering sustained levels of therapeutic gene product without compromising the vitality of the recipient host.

Treatment of phenylketonuria using minicircle-based naked-DNA gene transfer to murine liver.

Unlabelled: Host immune response to viral vectors, persistence of nonintegrating vectors, and sustained transgene expression are among the major challenges in gene therapy. To overcome these hurdles, we successfully used minicircle (MC) naked-DNA vectors devoid of any viral or bacterial sequences for the long-term treatment of murine phenylketonuria, a model for a genetic liver defect. MC-DNA vectors expressed the murine phenylalanine hydroxylase (Pah) complementary DNA (cDNA) from a liver-specific promoter coupled to a de novo designed hepatocyte-specific regulatory element, designated P3, which is a cluster of evolutionary conserved transcription factor binding sites.

Minimal-length Synthetic shRNAs Formulated with Lipid Nanoparticles are Potent Inhibitors of Hepatitis C Virus IRES-linked Gene Expression in Mice.

We previously identified short synthetic shRNAs (sshRNAs) that target a conserved hepatitis C virus (HCV) sequence within the internal ribosome entry site (IRES) of HCV and potently inhibit HCV IRES-linked gene expression. To assess in vivo liver delivery and activity, the HCV-directed sshRNA SG220 was formulated into lipid nanoparticles (LNP) and injected i.v.

Genetic modification of cancer cells using non-viral, episomal S/MAR vectors for in vivo tumour modelling.

The development of genetically marked animal tumour xenografts is an area of ongoing research to enable easier and more reliable testing of cancer therapies. Genetically marked tumour models have a number of advantages over conventional tumour models, including the easy longitudinal monitoring of therapies and the reduced number of animals needed for trials. Several different methods have been used in previous studies to mark tumours genetically, however all have limitations, such as genotoxicity and other artifacts related to the usage of integrating viral vectors.

Vector systems for prenatal gene therapy: principles of non-viral vector design and production.

Gene therapy vectors based on viruses are the most effective gene delivery systems in use today and although efficient at gene transfer their potential toxicity (Hacein-Bey-Abina et al., Science 302:415-419, 2003) provides impetus for the development of safer non-viral alternatives. An ideal vector for human gene therapy should deliver sustainable therapeutic levels of gene expression without affecting the viability of the host at either the cellular or somatic level.

Corneal gene delivery: chitosan oligomer as a carrier of CpG rich, CpG free or S/MAR plasmid DNA.

Background: Corneal gene therapy can potentially treat acquired and inherited corneal disorders that otherwise lead to blindness. In a previous study on the development of effective vectors for corneal gene delivery, we showed that a particular formulation of chitosan-DNA nanoparticles, based on ultrapure chitosan oligomers injected into rat corneas, led to transgene expression that was 5.4-fold higher than that obtained using polyethylenimine-DNA nanoparticles.

Development of S/MAR minicircles for enhanced and persistent transgene expression in the mouse liver.

We have previously described the development of a scaffold/matrix attachment region (S/MAR) episomal vector system for in vivo application and demonstrated its utility to sustain transgene expression in the mouse liver for at least 6 months following a single administration. Subsequently, we observed that transgene expression is sustained for the lifetime of the animal. The level of expression, however, does drop appreciably over time.

Systemic gene transfer of polyethylenimine (PEI)-plasmid DNA complexes to neonatal mice.

Non-viral vectors have not been extensively investigated in neonatal mice due to the poor efficiency of the delivery methods available. Understanding the effects of non-viral vectors during early development is vital to develop safe gene therapy treatments where irreversible pathological processes may be avoided by early gene reconstitution. Here we describe a simple and effective method for the systemic administration of non-viral vectors via the superior temporal vein of mouse pups at 1.

Strategies for the episomal modification of cells.

The clinical application of gene therapy has become a reality with the treatment of patients with X-linked SCID (SCID-X1) using a modified retrovirus. This success has been tempered by the toxicity of the vector used in this trial, which led to oncogenesis in several of the treated patients. The development of safer, alternative vectors, which remain episomal and are therefore less genotoxic, is currently an area of active research.