A team of scientists from Children’s Medical Research Institute (CMRI) in Sydney have developed a new way to improve targeting of specific organs and tissue types in gene therapy—making this innovative gene delivery technology more efficient and described as having “massive potential” for the field.
The work is featured in the journal Human Gene Therapy, published this week.
Tools based on adeno-associated virus (AAV), a non-pathogenic virus, are used as a delivery system for gene therapeutics. To convert the virus into a delivery tool, the researchers have removed all viral genes, which turns the virus into a very efficient gene delivery vehicle, called a vector. The vector can then be used to deliver a working copy of a gene to specific cells in the patient to correct a disease caused by a faulty gene. With one injection, patients could potentially be cured of their disease.
However, this system is still in the early stages of development for many conditions. One of the major limitations is the ability to safely and effectively deliver the therapeutic gene to the specific (diseased) cells inside the patient’s body; something the current generation of viral vectors are not able to achieve. Novel bioengineered AAV vectors developed with the clinical application in mind, offer a promising alternative. The CMRI team specializes in the development of novel AAV vectors. The first bioengineered AAV vector to enter clinical development (currently in number of a commercial and academic trials, including Phase III for a genetic liver condition) was developed by the CMRI team in collaboration with Stanford University.
In this publication, the CMRI team reports a new method that enables the development of more functional and improved AAV vectors. In contrast to other commonly used vector bioengineering methods, the technology developed by the CMRI team allows the researchers to select the best novel vector, based on how well it is likely to restore gene function in a therapeutic application.
“We successfully optimized an existing technology to generate new AAV capsids to be able to target new organs, or target organs that are already accessible to gene therapy, more efficiently,”‘ says the lead author Adrian Westhaus who is part of CMRI’s Translational Vectorology Research Unit.
“The optimization was achieved by understanding an existing promoter element in the AAV genome and repurposing it for viral capsid engineering.” A promoter is an engine that drives expression of genes.
Head of the Translational Vectorology Research Unit, Associate Professor Leszek Lisowski, said it was an exciting new platform technology.
“This will allow us to develop, right here in Australia, even better novel AAVs that will enter translational development pathways, with the promise of being better carriers of gene therapeutics.”
“It will bring hope of effective treatment to millions of kids affected by genetic disorders. The technology has enormous potential, and while its full impact is difficult to predict, it could form the foundation of a revolution in biomedical and translational research.”
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