Evaluating precision medicine approaches for gene therapy in patient-specific cellular models of Bietti crystalline dystrophy
Yao Li, Richard R. Yang, Yong-Shi Li, Chun-Wei Hsu, Laura A. Jenny, Yang Kong, Merry Z.C. Ruan, Janet R. Sparrow, Stephen H. Tsang
Yao Li, Richard R. Yang, Yong-Shi Li, Chun-Wei Hsu, Laura A. Jenny, Yang Kong, Merry Z.C. Ruan, Janet R. Sparrow, Stephen H. Tsang
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Research Article Ophthalmology Therapeutics

Evaluating precision medicine approaches for gene therapy in patient-specific cellular models of Bietti crystalline dystrophy

Abstract

Patient-specific induced pluripotent stem cell–derived (iPSC-derived) cell lines allow for therapies to be tailored to individual patients, increasing therapeutic precision and efficiency. Bietti crystalline dystrophy (BCD) is a rare blinding disease estimated to affect about 67,000 individuals worldwide. Here, we used iPSC-derived retinal pigment epithelium (iRPE) cells from patients with BCD to evaluate adeno-associated virus–mediated (AAV-mediated) gene augmentation therapy strategies. We found that BCD iRPE cells were vulnerable to blue light–induced oxidative stress and that cellular phenotype can be quantified using 3 robust biomarkers: reactive oxygen species (ROS), 4-hydroxy 2-nonenal (4-HNE) levels, and cell death rate. Additionally, we demonstrated that AAV-mediated gene therapy can significantly reduce light-induced cell death in BCD iRPE cells. This is the first proof-of-concept study to our knowledge to show that AAV-CYP4V2 gene therapy can be used to treat light-induced RPE damage in BCD. Furthermore, we observed significant variability in cellular phenotypes among iRPE from patients with BCD of divergent mutations, which outlined genotype-phenotype correlations in BCD patient–specific cell disease models. Our results reveal that patient-specific iRPE cells retained personalized responses to AAV-mediated gene therapy. Therefore, this approach can advance BCD therapy and set a precedent for precision medicine in other diseases, emphasizing the necessity for personalization in healthcare to accommodate individual diversity.

Authors

Yao Li, Richard R. Yang, Yong-Shi Li, Chun-Wei Hsu, Laura A. Jenny, Yang Kong, Merry Z.C. Ruan, Janet R. Sparrow, Stephen H. Tsang

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Figure 1

BCD iRPE cells are susceptible to shortwave light–induced (blue light–induced) oxidative stress, and this phenotype can be quantified by monitoring ROS, 4-HNE and cell death rate.

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BCD iRPE cells are susceptible to shortwave light–induced (blue light–in...
(A) Schematic showing the establishment of the patient-specific iPSC-derived cell-based BCD disease platform. Scale bar: 50 μm. (B) Immunoblot showing CYP4V2 expression levels are lower in iRPE cells from all 6 patients with BCD compared with iRPE cells from WT donors. GAPDH serves as a loading control. (C) Scheme of blue light induced oxidative stress application: 430 nm blue light exposure. Quantification chart of ROS, 4-HNE level, and cell death rate of iRPE from WT donors and patients with BCD. (D) Relative fold change of ROS, 4-HNE level, and cell death rate in WT and BCD iRPE cells. Data are presented as mean ± SD, n = 6 biological replicates in all groups, except n = 4 biological replicates in WT group of 4-HNE. **P < 0.01, ***P < 0.001.