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Precise Manipulation of the Site and Stoichiometry of Capsid Modification Enables Optimization of Functional Adeno-Associated Virus Conjugates.

Sarah B EricksonQuan PhamXiaofu CaoJake GlicksmanRachel E KelemenSeyed S ShahraeiniSebastian BodkinZainab KiyamAbhishek Chatterjee
Published in: Bioconjugate chemistry (2023)
The ability to engineer adeno-associated virus (AAV) vectors for targeted transduction of specific cell types is critically important to fully harness their potential for human gene therapy. A promising approach to achieve this objective involves chemically attaching retargeting ligands onto the virus capsid. Site-specific incorporation of a bioorthogonal noncanonical amino acid (ncAA) into the AAV capsid proteins provides a particularly attractive strategy to introduce such modifications with exquisite precision. In this study, we show that using ncAA mutagenesis, it is possible to systematically alter the attachment site of a retargeting ligand (cyclic-RGD) on the AAV capsid to create diverse conjugate architectures and that the site of attachment heavily impacts the retargeting efficiency. We further demonstrate that the performance of these AAV conjugates is highly sensitive to the stoichiometry of capsid labeling (labels per capsid), with an intermediate labeling density providing optimal activity for cRGD-mediated retargeting. Finally, we developed a technology to more precisely control the number of attachment sites per AAV capsid by selectively incorporating an ncAA into the minor capsid proteins with high fidelity and efficiency, such that AAV conjugates with varying stoichiometry can be synthesized. Together, this platform provides unparalleled control over the site and stoichiometry of capsid modification, which will enable the development of next-generation AAV vectors tailored with desirable attributes.
Keyphrases
  • gene therapy
  • cancer therapy
  • stem cells
  • endothelial cells
  • high throughput
  • single cell
  • mass spectrometry
  • drug delivery
  • crispr cas
  • cell therapy
  • climate change
  • single molecule
  • smoking cessation