An SNX31 variant underlies dominant familial exudative vitreoretinopathy-like pathogenesis
Ningda Xu, Yi Cai, Jiarui Li, Tianchang Tao, Caifei Liu, Yan Shen, Xiaoxin Li, Leiliang Zhang, Mingwei Zhao, Xuan Shi, Jing Li, Lvzhen Huang
Ningda Xu, Yi Cai, Jiarui Li, Tianchang Tao, Caifei Liu, Yan Shen, Xiaoxin Li, Leiliang Zhang, Mingwei Zhao, Xuan Shi, Jing Li, Lvzhen Huang
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Research Article Genetics Ophthalmology

An SNX31 variant underlies dominant familial exudative vitreoretinopathy-like pathogenesis

Abstract

Familial exudative vitreoretinopathy (FEVR) is a complex hereditary eye disorder characterized by incomplete development of the retinal vasculature, which thereby affects retinal angiogenesis. But the genetic factors contributing to FEVR’s development or pathogenesis remain elusive. In a Chinese family with FEVR with 19 members, by using whole-exome sequencing, we identified a candidate disease-causing DNA variant in sorting nexin 31 (SNX31) (c.963delG; p. Trp321Cys), which results in a frameshift mutation. We studied the biochemical mechanism of this mutation and determined that it is deficient in β1-integrin binding and stability. The SNX31 c.963delG point mutation mouse model (SNX31m/m) was constructed with CRISPR/Cas9 technology. At 2–4 months of age, SNX31m/m mice showed fundus phenotypes similar to FEVR-like changes, including vascular leakage and retinal atrophy. Moreover, we found that VEGF and apoptotic pathways were involved in these ocular phenotypes. Hence, our study extended the FEVR mutation spectrum to include SNX31. These findings expanded our understanding of the molecular pathogenesis of FEVR and may facilitate the development of methods for the diagnosis and prevention of FEVR.

Authors

Ningda Xu, Yi Cai, Jiarui Li, Tianchang Tao, Caifei Liu, Yan Shen, Xiaoxin Li, Leiliang Zhang, Mingwei Zhao, Xuan Shi, Jing Li, Lvzhen Huang

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Figure 3

Validation of the construction of SNX31m/m mice from DNA, mRNA, and protein levels.

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Validation of the construction of SNX31m/m mice from DNA, mRNA, and prot...
(A) Genotype Sanger sequencing of WT, SNX31 heterozygous mutant mice (SNX31w/m), and SNX31m/m mice. WT: Sanger sequencing showed that the G base at position 963 of SNX31 was not deleted. SNX31w/m showed overlapping peaks, indicating a heterozygous deletion of G. SNX31m/m G base was successfully deleted and presented as a single peak, proving that the genotype was homozygous. (B) The relative expression of SNX31 mRNA in WT and SNX31m/m mice at different ages. The mRNA expression of SNX31 in SNX31m/m mice was significantly decreased. (C and D) The protein expression of SNX31 in WT and SNX31m/m mice at different ages. The expression of SNX31 in 2-month-old and 4-month-old SNX31m/m mice was significantly lower than that in the WT group. Statistical analysis was performed via unpaired parametric t test. Data are shown as mean ± SEM. m, mutant; mo, age in months; w, wild. *P < 0.05. See complete unedited blots in the supplemental material.