Novel Stem Cell-Derived AAV Capsids for Gene Transfer to Human Embryonic Stem Cells
The ability to transfer therapeutic genes into human embryonic stem cells (hESC) has tremendous value for the permanent correction of genetic diseases. Gene-corrected hESC have the potential to be used for the treatment of inherited and acquired diseases. Adeno-associated virus (AAV) is human virus that does not cause any known disease. We and others have used AAV as a tool to deliver therapeutic genes to cells by replacing the viral genes with therapeutic genes. Only the virus backbone and shell is required for it to function as a gene delivery tool. Genes that are delivered by AAV can become part of the cells genome or remain as unincorporated DNA in the nucleus. Regardless, it is clear from collective experience over four decades that AAV is safe and does not harm the host. We recently found a new family of AAV viruses in human blood cells. We hypothesize that this family of AAV will make good vectors for the transfer of genes to hESC. We have also recently obtained a panel of next generation AAV vectors recently derived at the University of Florida that were shown to be highly efficient at gene transfer at lower doses with no associated toxicity. Here we propose to test these two families of novel AAV vectors for their ability to transfer genes to hESC. We shall compare members of these two AAV families to determine which is best for long-term gene transfer to hESC. Developing these gene transfer tools for therapeutic use requires making certain that the normal properties of hESC are not altered, including their primitive pluripotent status and their ability to differentiate normally into other cells. Moreover for treatment of specific diseases we shall evaluate members of these AAV families to transfer genes to progenitor cells of specific types derived from hESC. These will include cells that have the capacity to make nerve and muscle cells. It is also important to determine whether the genes transferred to the cells become a part of the cells genome or may be lost over time. We propose experiments designed to address this. Based upon our previous work with blood forming stem cells, we fully expect to identify one or more members of these AAV families that are able to mediate permanent genetic correction of hESC. We will also confirm that such gene-modification is safe. If some members of these families of AAV do not cause the transferred genes to become a permanent part of the cells’ genome, they will be identified as ideal candidates for future work on the transient gene transfer. When completed, this research will identify tools to introduce genes into hESC in a safe and effective manner.
This research develops genetic therapeutic tools for human embryonic stem cells (hESCs). We propose to develop novel gene transfer tools that can be used safely and efficiently in basic and clinical research employing hESCs. It is expected that tools developed from this research will eventually be used for treatment of a variety of genetic diseases that are currently incurable. Diseases addressable with these tools include a number of genetic diseases that are inherited or acquired through mutations which affect Californians, many of which exact a heavy social and economic toll. The tools that will come out of this proposal do not focus upon one specific disease; rather we propose to develop safe and efficient gene transfer tools for hESCs that could then be used for many conditions with an identifiable genetic basis. Moreover these new tools could also be used to study the processes involved in early human development, which in turn would provide insights into both normal and abnormal growth processes. Upon completion of this research, we expect to have a panel of safe and effective tools for the genetic modification of hESCs that will be available to researchers in the state. Thus the work proposed here should have an overall impact on public health in California in terms of advancing both therapeutic approaches and basic science of genetic medicine through the use of hESCs.