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 5

Higher AAV efficacy in homozygous iRPE cells carrying deletion mutation than iRPE of homozygous missense mutations.

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Higher AAV efficacy in homozygous iRPE cells carrying deletion mutation ...
(A) Correlation of AAV transduction rate and cell death rate of iRPE cells with homozygous mutation in CYP4V2 gene. P1, P4, P5, and P6 are BCD iRPE of homozygous mutations. P1, carries homozygous 17 bp deletion mutation, while P4, P5, and P6 each carry a distinct homozygous missense mutation. For each chart, red linear regression lines contain 4 samples of BCD-P1, -P4, -P5, and -P6, while black linear regression lines contain 3 samples of BCD-P4, -P5, and -P6. r2 values are shown within each chart. (B) Oxidative-induced cell death rate after AAV2 and AAV5 treatment among iRPE cells from patients with homozygous mutation BCD. (CE) Changes of ROS (C), 4-HNE level (D), and cell death rate measurements (E) due to AAV2 and AAV5 treatment, normalized by transduction rate, among iRPE cells from patients with BCD with homozygous mutations. In BE, data are presented as mean ± SD, n = 6–23. Significance was calculated by 1-way ANOVA with multiple comparisons. **P < 0.005, ***P < 0.0005, ****P < 0.0001.