Molecular Therapy: Methods & Clinical Development (Mar 2024)

Mannose-coupled AAV2: A second-generation AAV vector for increased retinal gene therapy efficiency

  • Mathieu Mével,
  • Virginie Pichard,
  • Mohammed Bouzelha,
  • Dimitri Alvarez-Dorta,
  • Pierre-Alban Lalys,
  • Nathalie Provost,
  • Marine Allais,
  • Alexandra Mendes,
  • Elodie Landagaray,
  • Jean-Baptiste Ducloyer,
  • Estelle Toublanc,
  • Anne Galy,
  • Nicole Brument,
  • Gaëlle M. Lefevre,
  • Sébastien G. Gouin,
  • Carolina Isiegas,
  • Guylène Le Meur,
  • Thérèse Cronin,
  • Caroline Le Guiner,
  • Michel Weber,
  • Philippe Moullier,
  • Eduard Ayuso,
  • David Deniaud,
  • Oumeya Adjali

Journal volume & issue
Vol. 32, no. 1
p. 101187

Abstract

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Inherited retinal diseases are a leading and untreatable cause of blindness and are therefore candidate diseases for gene therapy. Recombinant vectors derived from adeno-associated virus (rAAV) are currently the most promising vehicles for in vivo therapeutic gene delivery to the retina. However, there is a need for novel AAV-based vectors with greater efficacy for ophthalmic applications, as underscored by recent reports of dose-related inflammatory responses in clinical trials of rAAV-based ocular gene therapies. Improved therapeutic efficacy of vectors would allow for decreases in the dose delivered, with consequent reductions in inflammatory reactions. Here, we describe the development of new rAAV vectors using bioconjugation chemistry to modify the rAAV capsid, thereby improving the therapeutic index. Covalent coupling of a mannose ligand, via the formation of a thiourea bond, to the amino groups of the rAAV capsid significantly increases vector transduction efficiency of both rat and nonhuman primate retinas. These optimized rAAV vectors have important implications for the treatment of a wide range of retinal diseases.

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