Development Of Therapeutically Useful Human Artificial Chromosomes For Gene Delivery And Optimal Gene Expression
Funder
National Health and Medical Research Council
Funding Amount
$496,986.00
Summary
Gene therapy is an exciting new form of treatment for genetic disorders aimed at providing long-term correction of the problems at source - namely the affected gene. The biggest technical hurdle facing gene therapy is to be able to deliver the therapeutic genes efficiently and safely into patient cells. Many gene therapy protocols are currently being trialled clinically. These protocols, based mostly on the use of attenuated viruses to deliver the genes, carry potential risks to the patients in ....Gene therapy is an exciting new form of treatment for genetic disorders aimed at providing long-term correction of the problems at source - namely the affected gene. The biggest technical hurdle facing gene therapy is to be able to deliver the therapeutic genes efficiently and safely into patient cells. Many gene therapy protocols are currently being trialled clinically. These protocols, based mostly on the use of attenuated viruses to deliver the genes, carry potential risks to the patients in terms of infection, immune response, and germline modification. We have developed the first stage of a new technology for gene delivery that does not require the use of viruses. This technology is based on the generation of human artificial chromosomes, which are smaller versions of the naturally occurring chromosomes that carry all the genes inside our cells. Safety in these artificial chromosomes comes from the use of entirely human materials for their engineering. These artificial chromosomes also have other advantages over the viral approaches, including allowing large genes to be carried, and providing a permanent cure in a single treatment. We have already successfully constructed, published, and patented a number of first-generation human artificial chromosomes. The current project aims to complete the next proof-of-concept milestone towards the further development of this technology. Specifically, we propose to demonstrate the ability of the artificial chromosomes to carry genes and provide sustainable expression of these genes in cells and in animal models. Success in this study will allow the technology to proceed rapidly into commercialisation and clinical trial as a new improved tool for gene delivery and gene therapy.Read moreRead less
Chromosomes are structures that carry genes in all our cells. Every human cell has 46 chromosomes. In the nucleus of eukaryotic cells, DNA is highly folded and compacted with specific proteins into a dynamic polymer called chromatin. Gene expression, chromosome division, DNA replication, and repair all act, not on DNA alone, but on this chromatin template. The discovery that enzymes can (re)organise chromatin into accessible and inaccessible configurations revealed mechanisms that considerably e ....Chromosomes are structures that carry genes in all our cells. Every human cell has 46 chromosomes. In the nucleus of eukaryotic cells, DNA is highly folded and compacted with specific proteins into a dynamic polymer called chromatin. Gene expression, chromosome division, DNA replication, and repair all act, not on DNA alone, but on this chromatin template. The discovery that enzymes can (re)organise chromatin into accessible and inaccessible configurations revealed mechanisms that considerably extend the information potential of the genetic code. In addition, it is now established that chromatin structural features can influence gene expression. In vitro studies support a model in which chromatin functions as a barrier for the access to DNA. Therefore this organization has to be tighly regulated and dynamic to allow the protein-DNA interactions critical for nuclear functions. Importantly genome organisation provides in addition to genetic information another layer of information, so called epigenetic, which by definition means that it is stably inherited throughout cellular divisions, yet it is not encoded genetically. Thus each cell type will display a specific epigenome. We have recently constructed small human minichromosomes, which are much easier to study than the much larger normal chromosomes. The present project proposes to define the epigenetic feature across an entire human chromosome using our minichhromosomes as working models. The outcome will be a significant gain in our knowledge on the processes underlying epigenetic regulation, the organisation of specialised chromatin domain, and behaviour of the chromosomes.Read moreRead less