Utilization of automated cilia analysis to characterize novel INPP5E variants in patients with non-syndromic retinitis pigmentosa.

INPP5E encodes inositol polyphosphate-5-phosphatase E, an enzyme involved in regulating the phosphatidylinositol (PIP) makeup of the primary cilium membrane. Pathogenic variants in INPP5E hence cause a variety of ciliopathies: genetic disorders caused by dysfunctional cilia. While the majority of these disorders are syndromic, such as the neuronal ciliopathy Joubert syndrome, in some cases patients will present with an isolated phenotype-most commonly non-syndromic retinitis pigmentosa (RP). Here, we report two novel variants in INPP5E identified in two patients with non-syndromic RP: patient 1 with compound heterozygous variants (c.1516C > T, p.(Q506*), and c.847G > A, p.(A283T)) and patient 2 with a homozygous variant (c.1073C > T, p.(P358L)). To determine whether these variants were causative for the phenotype in the patients, automated ciliary phenotyping of patient-derived dermal fibroblasts was performed for percent ciliation, cilium length, retrograde IFT trafficking, and INPP5E localization. In both patients, a decrease in ciliary length and loss of INPP5E localization in the primary cilia were seen. With these molecular findings, we can confirm functionally that the novel variants in INPP5E are causative for the RP phenotypes seen in both patients. Additionally, this study demonstrates the usefulness of utilizing ciliary phenotyping as an assistant in ciliopathy diagnosis and phenotyping.

CRISPR-Cas9 correction of a nonsense mutation in LCA5 rescues lebercilin expression and localization in human retinal organoids.

Mutations in the lebercilin-encoding gene LCA5 cause one of the most severe forms of Leber congenital amaurosis, an early-onset retinal disease that results in severe visual impairment. Here, we report on the generation of a patient-specific cellular model to study LCA5-associated retinal disease. CRISPR-Cas9 technology was used to correct a homozygous nonsense variant in LCA5 (c.835C>T; p.Q279∗) in patient-derived induced pluripotent stem cells (iPSCs). The absence of off-target editing in gene-corrected (isogenic) control iPSCs was demonstrated by whole-genome sequencing. We differentiated the patient, gene-corrected, and unrelated control iPSCs into three-dimensional retina-like cells, so-called retinal organoids. We observed opsin and rhodopsin mislocalization to the outer nuclear layer in patient-derived but not in the gene-corrected or unrelated control organoids. We also confirmed the rescue of lebercilin expression and localization along the ciliary axoneme within the gene-corrected organoids. Here, we show the potential of combining precise single-nucleotide gene editing with the iPSC-derived retinal organoid system for the generation of a cellular model of early-onset retinal disease.