An Evolved Adeno-associated Viral Variant Enhances Gene Delivery and Gene Targeting in Neural Stem Cells.
Publication Year:
2011
PubMed ID:
21224831
Funding Grants:
- Directed Evolution of Novel AAV Variants for Enhanced Gene Targeting in Pluripotent Human Stem Cells and Investigation of Dopaminergic Neuron Differentiation
- Interdisciplinary Training in Stem Cell Biology, Engineering and Medicine
- Human Stem Cell Training at UC Berkeley and Childrens Hospital of Oakland
Public Summary:
The development of better methods to carry genes into stem cells would enable a number of applications, including investigating the role of key genes in the behavior of the stem cell, delivery of specific genes to control stem cell proliferation or differentiation, delivery factors to enhance the therapeutic efficacy of stem cells and their progeny, and genetically modifying the cells to serve as models of human disease. Gene delivery vehicles based on adeno-associated virus, i.e. AAV vectors, have demonstrated the capacity for efficient delivery to numerous cells, but their application to stem cells has been limited by low delivery efficiency. Due to their considerable advantages, however, engineering AAV delivery systems to enhance gene delivery to stem cells may have an impact in stem cell biology and therapy. Therefore, we have used a high throughput protein engineering technique to improve the efficiency of AAV gene delivery to neural stem cells (NSCs). A novel AAV variant, carrying an insertion of a selected peptide sequence on the viral surface, emerged from this approach. Importantly, this evolved AAV variant mediated efficient gene delivery to rat, mouse, and human NSCs, as well as the capacity to edit endogenous genes within adult NSCs, and it is thus promising for applications ranging from basic stem cell biology to clinical translation.
Scientific Abstract:
Gene delivery to, and gene targeting in, stem cells would be a highly enabling technology for basic science and biomedical application. Adeno-associated viral (AAV) vectors have demonstrated the capacity for efficient delivery to numerous cells, but their application to stem cells has been limited by low transduction efficiency. Due to their considerable advantages, however, engineering AAV delivery systems to enhance gene delivery to stem cells may have an impact in stem cell biology and therapy. Therefore, using several diverse AAV capsid libraries-including randomly mutagenized, DNA shuffled, and random peptide insertion variants-we applied directed evolution to create a "designer" AAV vector with enhanced delivery efficiency for neural stem cells (NSCs). A novel AAV variant, carrying an insertion of a selected peptide sequence on the surface of the threefold spike within the heparin-binding site, emerged from this evolution. Importantly, this evolved AAV variant mediated efficient gene delivery to rat, mouse, and human NSCs, as well as efficient gene targeting within adult NSCs, and it is thus promising for applications ranging from basic stem cell biology to clinical translation.