Protease-Activatable Adeno-Associated Virus Vector for Gene Delivery to Damaged Heart Tissue.

Adeno-associated virus (AAV) has emerged as a promising gene delivery vector because of its non-pathogenicity, simple structure and genome, and low immunogenicity compared to other viruses. However, its adoption as a safe and effective delivery vector for certain diseases relies on altering its tropism to deliver transgenes to desired cell populations. To this end, we have developed a protease-activatable AAV vector, named provector, that responds to elevated extracellular protease activity commonly found in diseased tissue microenvironments. The AAV9-based provector is initially inactive, but then it can be switched on by matrix metalloproteinases (MMP)-2 and -9. Cryo-electron microscopy and image reconstruction reveal that the provector capsid is structurally similar to that of AAV9, with a flexible peptide insertion at the top of the 3-fold protrusions. In an in vivo model of myocardial infarction (MI), the provector is able to deliver transgenes site specifically to high-MMP-activity regions of the damaged heart, with concomitant decreased delivery to many off-target organs, including the liver. The AAV provector may be useful in the future for enhanced delivery of transgenes to sites of cardiac damage.

AAV6 K531 serves a dual function in selective receptor and antibody ADK6 recognition.

Adeno-associated viruses (AAVs) are being developed as vectors for the treatment of genetic disorders. However, pre-existing antibodies present a significant limitation to achieving optimal efficacy for the AAV gene delivery system. Efforts aimed at engineering vectors with the ability to evade the immune response include identification of residues on the virus capsid important for these interactions and changing them. Here K531 is identified as the determinant of monoclonal antibody ADK6 recognition by AAV6, and not the closely related AAV1. The AAV6-ADK6 complex structure was determined by cryo-electron microscopy and the footprint confirmed by cell-based assays. The ADK6 footprint overlaps previously identified AAV antigenic regions and neutralizes by blocking essential cell surface glycan attachment sites. This study thus expands the available repertoire of AAV-antibody information that can guide the design of host immune escaping AAV vectors able to maintain capsid functionality.