CpG-depleted adeno-associated virus vectors evade immune detection
Susan M. Faust, … , Joseph E. Rabinowitz, James M. Wilson
Susan M. Faust, … , Joseph E. Rabinowitz, James M. Wilson
Published June 17, 2013
Citation Information: J Clin Invest. 2013;123(7):2994-3001. https://doi.org/10.1172/JCI68205.
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Research Article Immunology

CpG-depleted adeno-associated virus vectors evade immune detection

Abstract

Due to their efficient transduction potential, adeno-associated virus (AAV) vectors are leading candidates for gene therapy in skeletal muscle diseases. However, immune responses toward the vector or transgene product have been observed in preclinical and clinical studies. TLR9 has been implicated in promoting AAV-directed immune responses, but vectors have not been developed to circumvent this barrier. To assess the requirement of TLR9 in promoting immunity toward AAV-associated antigens following skeletal muscle gene transfer in mice, we compared immunological responses in WT and Tlr9-deficient mice that received an AAV vector with an immunogenic capsid, AAVrh32.33. In Tlr9-deficient mice, IFN-γ T cell responses toward capsid and transgene antigen were suppressed, resulting in minimal cellular infiltrate and stable transgene expression in target muscles. These findings suggest that AAV-directed immune responses may be circumvented by depleting the ligand for TLR9 (CpG sequences) from the vector genome. Indeed, we found that CpG-depleted AAVrh32.33 vectors could establish persistent transgene expression, evade immunity, and minimize infiltration of effector cells. Thus, CpG-depleted AAV vectors could improve outcome of clinical trials of gene therapy for skeletal muscle disease.

Authors

Susan M. Faust, Peter Bell, Benjamin J. Cutler, Scott N. Ashley, Yanqing Zhu, Joseph E. Rabinowitz, James M. Wilson

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Figure 5

Biology of CpG-depleted AAVrh32.33LacZ in skeletal muscle.

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Biology of CpG-depleted AAVrh32.33LacZ in skeletal muscle. (A) HeLa cell...
(A) HeLa cells were transfected with CpG+ and CpG AAV expression plasmids. Four days after transfection, cells were assayed for β-gal activity using the Mammalian β-Galactosidase Assay Kit as instructed for adherent cells. Absorbance was measured at 405 nm on a TECAN Infinite M1000 PRO plate reader. WT mice were injected i.m. with 1 × 1011 GC of RhCpG+ or CpG vectors and muscle harvested on day 35 (B and C) and day 60 (D and E) and stained for X-gal. Representative sections are shown. n = 7 mice per group. Original magnification, ×10. (F) Lymphocytes were isolated form whole blood and subsequently stained using the PE-conjugated H-2Kb–ICPMYARV tetramer together with FITC-conjugated anti-CD8 Abs to determine the percentage of LacZ-specific CD8+ T cells in the total CD8+ T cell population. Results represent the mean ± SD of tetramer-positive cells from n = 4 recipients per group. *P < 0.05. (G) Splenocytes were harvested and processed for ELISPOT assays to quantify primed CD8+ AAVrh32.33 capsid and LacZ T cell immunodominant peptides. Results represent the mean ± SD of CD8+ LacZ-reactive T cells or cytokine-producing cells from at least n = 7 recipients per group. *P < 0.05.