Viral Vectors for Gene Therapy: Translational and Clinical Outlook.

In a range of human trials, viral vectors have emerged as safe and effective delivery vehicles for clinical gene therapy, particularly for monogenic recessive disorders, but there has also been early work on some idiopathic diseases. These successes have been enabled by research and development efforts focusing on vectors that combine low genotoxicity and immunogenicity with highly efficient delivery, including vehicles based on adeno-associated virus and lentivirus, which are increasingly enabling clinical success. However, numerous delivery challenges must be overcome to extend this success to many diseases; these challenges include developing techniques to evade preexisting immunity, to ensure more efficient transduction of therapeutically relevant cell types, to target delivery, and to ensure genomic maintenance.

Enhanced selective gene delivery to neural stem cells in vivo by an adeno-associated viral variant.

Neural stem cells (NSCs) are defined by their ability to self-renew and to differentiate into mature neuronal and glial cell types. NSCs are the subject of intense investigation, owing to their crucial roles in neural development and adult brain function and because they present potential targets for gene and cell replacement therapies following injury or disease. Approaches to specifically genetically perturb or modulate NSC function would be valuable for either motivation.

Engineered AAV vectors for improved central nervous system gene delivery.

Adeno-associated viruses (AAV) are non-pathogenic members of the Parvoviridae family that are being harnessed as delivery vehicles for both basic research and increasingly successful clinical gene therapy. To address a number of delivery shortcomings with natural AAV variants, we have developed and implemented directed evolution-a high-throughput molecular engineering approach to generate novel biomolecules with enhanced function-to create novel AAV vectors that are designed to preferentially transduce specific cell types in the central nervous system (CNS), including astrocytes, neural stem cells, and cells within the retina. These novel AAV vectors-which have enhanced infectivity in vitro and enhanced infectivity and selectivity in vivo-can enable more efficient studies to further our understanding of neurogenesis, development, aging, and disease.

Engineering adeno-associated viruses for clinical gene therapy.

Clinical gene therapy has been increasingly successful owing both to an enhanced molecular understanding of human disease and to progressively improving gene delivery technologies. Among these technologies, delivery vectors based on adeno-associated viruses (AAVs) have emerged as safe and effective and, in one recent case, have led to regulatory approval. Although shortcomings in viral vector properties will render extension of such successes to many other human diseases challenging, new approaches to engineer and improve AAV vectors and their genetic cargo are increasingly helping to overcome these barriers.