The available data of AAV vectors in the clinic emphasize the importance of continued optimization efforts at the levels of the AAV capsid, genome and transgenic cassette. A focus of this proposal is to derive clinical AAV vector best suited for systemic disorders (MPS, Hurlers, etc.). At the capsid level, it is apparent that animal models do not always predict the human outcome and that more efficient human specific capsids are required to achieve a lower administered dose.
In Aim 1, we seek to create a new paradigm of AAV vector selection for human transduction by generating the first AAV receptor expression map on tissues of mouse, primate and human origin. This tissue specific AAV receptor Atlas will be overlaid with AAV binding and transduction data in an effort to tease out regions of the capsid important for tissue specific interactions in varied backgrounds. In addition novel chimeric capsids isolated from a directed evolution strategy on primate and human livers established in a mouse model will be triaged against our receptor/binding atlas to determine if in vitro binding correlates to in vivo results. Then, capsid isolates from a primatized-liver mouse model will be investigated for primate liver transduction in vivo to determine if this strategy represents a valid method to derive primate (human & non human) liver specific AAV capsids. At the level of the AAV genome, we have assembled a panel of DNA repair dependent AAV substrates that report critical aspects of genome persistence including circularization, concatemerization and homology directed annealing. Investigations of these reagents in mutant backgrounds defective in different DNA repair pathways will offer insights into the preferred reliance on homologous recombination and non-homologous end joining mechanisms in vitro and in vivo providing a better prediction of vector performance in diseased settings (Aim 2). At the level of the vector transgene, we demonstrate in mouse liver, heart and eye a novel method to induce transgene synthesis using the IVS2- 654 intron and an anti-sense oligonucleotide. The work herein seeks to generate smaller synthetic variants that exhibit tighter control as well as altered transgene expression levels, thus providing a panel of regulatory switches which can be tailored for specific applications. Finally, a strategy is proposed to engineer an off switch for the induced transgene synthesis from IVS2-654, which may also allow the precise tuning of transgene synthesis at a fixed vector dose. Collectively, the results of the proposed experiments seek to address the observed clinical deficiencies in AAV gene therapy applications for diseases of systemic nature by our continued optimization efforts at the levels of the capsid and genome as well as the transgenic DNA cassette.

Public Health Relevance

The proposed experiments seek to enhance viral based DNA delivery vectors for the treatment of human disease. To do this we will establish a new paradigm in which the observed variations in delivery efficiency between humans and animal models are better understood. In addition we seek to enhance AAV vectors at the DNA level for enhanced delivery efficiency, by further understanding the mechanism of genome persistence and expression. Finally, a molecular 'on- off' switch will be engineered and incorporated into our viral delivery format to control therapeutic protein expression in the clinical setting.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
5R01AI072176-10
Application #
9266298
Study Section
Gene and Drug Delivery Systems Study Section (GDD)
Program Officer
Natarajan, Ramya
Project Start
2007-12-01
Project End
2019-04-30
Budget Start
2017-05-01
Budget End
2019-04-30
Support Year
10
Fiscal Year
2017
Total Cost
Indirect Cost
Name
University of North Carolina Chapel Hill
Department
Pharmacology
Type
Schools of Medicine
DUNS #
608195277
City
Chapel Hill
State
NC
Country
United States
Zip Code
27599
Chai, Zheng; Samulski, R Jude; Li, Chengwen (2018) Nab Escaping AAV Mutants Isolated from Mouse Muscles. Bio Protoc 8:
Song, Liujiang; Llanga, Telmo; Conatser, Laura M et al. (2018) Serotype survey of AAV gene delivery via subconjunctival injection in mice. Gene Ther 25:402-414
Chai, Zheng; Zhang, Xintao; Rigsbee, Kelly Michelle et al. (2018) Cryoprecipitate augments the global transduction of the adeno-associated virus serotype 9 after a systemic administration. J Control Release 286:415-424
Shao, Wenwei; Chen, Xiaojing; Samulski, Richard J et al. (2018) Inhibition of antigen presentation during AAV gene therapy using virus peptides. Hum Mol Genet 27:601-613
Shao, Wenwei; Earley, Lauriel F; Chai, Zheng et al. (2018) Double-stranded RNA innate immune response activation from long-term adeno-associated virus vector transduction. JCI Insight 3:
Brown, Nolan; Song, Liujiang; Kollu, Nageswara R et al. (2017) Adeno-Associated Virus Vectors and Stem Cells: Friends or Foes? Hum Gene Ther 28:450-463
Llanga, Telmo; Nagy, Nadia; Conatser, Laura et al. (2017) Structure-Based Designed Nano-Dysferlin Significantly Improves Dysferlinopathy in BLA/J Mice. Mol Ther 25:2150-2162
Hirsch, Matthew L; Conatser, Laura M; Smith, Sara M et al. (2017) AAV vector-meditated expression of HLA-G reduces injury-induced corneal vascularization, immune cell infiltration, and fibrosis. Sci Rep 7:17840
Nagy, Nadia; Nonneman, Randal J; Llanga, Telmo et al. (2017) Hip region muscular dystrophy and emergence of motor deficits in dysferlin-deficient Bla/J mice. Physiol Rep 5:
Liang, Katharine J; Woodard, Kenton T; Weaver, Mark A et al. (2017) AAV-Nrf2 Promotes Protection and Recovery in Animal Models of Oxidative Stress. Mol Ther 25:765-779

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