Noninvasive gene delivery to foveal cones for vision restoration
Hanen Khabou, … , José-Alain Sahel, Deniz Dalkara
Hanen Khabou, … , José-Alain Sahel, Deniz Dalkara
Published January 25, 2018
Citation Information: JCI Insight. 2018;3(2):e96029. https://doi.org/10.1172/jci.insight.96029.
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Resource and Technical Advance Ophthalmology Therapeutics

Noninvasive gene delivery to foveal cones for vision restoration

Abstract

Intraocular injection of adeno-associated viral (AAV) vectors has been an evident route for delivering gene drugs into the retina. However, gaps in our understanding of AAV transduction patterns within the anatomically unique environments of the subretinal and intravitreal space of the primate eye impeded the establishment of noninvasive and efficient gene delivery to foveal cones in the clinic. Here, we establish new vector-promoter combinations to overcome the limitations associated with AAV-mediated cone transduction in the fovea with supporting studies in mouse models, human induced pluripotent stem cell–derived organoids, postmortem human retinal explants, and living macaques. We show that an AAV9 variant provides efficient foveal cone transduction when injected into the subretinal space several millimeters away from the fovea, without detaching this delicate region. An engineered AAV2 variant provides gene delivery to foveal cones with a well-tolerated dose administered intravitreally. Both delivery modalities rely on a cone-specific promoter and result in high-level transgene expression compatible with optogenetic vision restoration. The model systems described here provide insight into the behavior of AAV vectors across species to obtain safety and efficacy needed for gene therapy in neurodegenerative disorders.

Authors

Hanen Khabou, Marcela Garita-Hernandez, Antoine Chaffiol, Sacha Reichman, Céline Jaillard, Elena Brazhnikova, Stéphane Bertin, Valérie Forster, Mélissa Desrosiers, Céline Winckler, Olivier Goureau, Serge Picaud, Jens Duebel, José-Alain Sahel, Deniz Dalkara

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Figure 7

Performance of AAV2-7m8-PR1.7 vector–promoter combination in human cones.

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Performance of AAV2-7m8-PR1.7 vector–promoter combination in human cones...
(A–C) GFP expression in human induced pluripotent stem cell–derived (iPSC-derived) retinal organoids (n = 10 organoids) infected with AAV2-7m8-PR1.7-GFP. (A) Brighfield, (B) epifluorescence, and (C) confocal images of 43-day-old whole mount organoids infected with AAV2.7m8-PR1.7-GFP at day 28 with a dose of 5 × 1010 vg/organoid. Scale bar: 200 μm in A and B, and 250 μm in C. Outline in C represents the edges of the organoids (D–F) Retinal organoid cryosections for visualization of GFP expression (cyan). Transduced cones are visualized by superimposition of GFP (cyan) and human cone arrestin (hCAR) immunostaining (magenta). Scale bar: 20 μm in D–F. Arrows represent colocalization of GFP and hCAR stainings. (G–I) Efficient and specific transduction of human cones in postmortem retinal explants. (G) Postmortem human retinal explant placed in culture. Dashed circle shows the approximate area where 1 × 1010 viral particles were deposited onto the explant (n = 2 explants from 2 eyes of a single donor). (H) Close-up of the transduced area showing high-level GFP fluorescence in region of the explant in contact with the vector. Scale bar: 100 μm. (I) GFP expression (cyan) is restricted to the photoreceptor layer as shown by DAPI (blue) staining. (J) GFP is expressed in cones as shown by colocalization of GFP staining of cone markers, namely M/L opsin. Scale bar: 50 μm in I–J. Arrows represent colocalization of GFP and M/L opsin stainings. AAV, adeno-associated virus; vg, viral genome; PR1.7, promoter of 1.7 kilobases in length, based on the human red opsin gene enhancer and promoter sequences.