Whole-exome sequencing reveals ZNF408 as a new gene associated with autosomal recessive retinitis pigmentosa with vitreal alterations.

Retinitis pigmentosa (RP) is a group of progressive inherited retinal dystrophies that cause visual impairment as a result of photoreceptor cell death. RP is heterogeneous, both clinically and genetically making difficult to establish precise genotype-phenotype correlations. In a Spanish family with autosomal recessive RP (arRP), homozygosity mapping and whole-exome sequencing led to the identification of a homozygous mutation (c.358_359delGT; p.Ala122Leufs*2) in the ZNF408 gene. A screening performed in 217 additional unrelated families revealed another homozygous mutation (c.1621C>T; p.Arg541Cys) in an isolated RP case. ZNF408 encodes a transcription factor that harbors 10 predicted C2H2-type fingers thought to be implicated in DNA binding. To elucidate the ZNF408 role in the retina and the pathogenesis of these mutations we have performed different functional studies. By immunohistochemical analysis in healthy human retina, we identified that ZNF408 is expressed in both cone and rod photoreceptors, in a specific type of amacrine and ganglion cells, and in retinal blood vessels. ZNF408 revealed a cytoplasmic localization and a nuclear distribution in areas corresponding with the euchromatin fraction. Immunolocalization studies showed a partial mislocalization of the p.Arg541Cys mutant protein retaining part of the WT protein in the cytoplasm. Our study demonstrates that ZNF408, previously associated with Familial Exudative Vitreoretinopathy (FEVR), is a new gene causing arRP with vitreous condensations supporting the evidence that this protein plays additional functions into the human retina.

[1]  Bill Bynum,et al.  Lancet , 2015, The Lancet.

[2]  Francisco Salavert,et al.  A web-based interactive framework to assist in the prioritization of disease candidate genes in whole-exome sequencing studies , 2014, Nucleic Acids Res..

[3]  M. Trese,et al.  High prevalence of peripheral retinal vascular anomalies in family members of patients with familial exudative vitreoretinopathy. , 2014, Ophthalmology.

[4]  Christian Gilissen,et al.  ZNF408 is mutated in familial exudative vitreoretinopathy and is crucial for the development of zebrafish retinal vasculature , 2013, Proceedings of the National Academy of Sciences.

[5]  J. Pastor,et al.  Time course modifications in organotypic culture of human neuroretina. , 2012, Experimental eye research.

[6]  F. Cremers,et al.  Mutation analysis of 272 Spanish families affected by autosomal recessive retinitis pigmentosa using a genotyping microarray , 2010, Molecular vision.

[7]  Joaquín Dopazo,et al.  Mutation Spectrum of EYS in Spanish Patients with Autosomal Recessive Retinitis Pigmentosa , 2010, Human mutation.

[8]  W. Berger,et al.  The molecular basis of human retinal and vitreoretinal diseases , 2010, Progress in Retinal and Eye Research.

[9]  A. D. den Hollander,et al.  Lighting a candle in the dark: advances in genetics and gene therapy of recessive retinal dystrophies. , 2010, The Journal of clinical investigation.

[10]  Carmen Ayuso,et al.  Retinitis pigmentosa and allied conditions today: a paradigm of translational research , 2010, Genome Medicine.

[11]  T. Lai,et al.  Association of NR2E3 but not NRL mutations with retinitis pigmentosa in the Chinese population. , 2010, Investigative ophthalmology & visual science.

[12]  Shomi S. Bhattacharya,et al.  Photoreceptor degeneration: genetic and mechanistic dissection of a complex trait , 2010, Nature Reviews Genetics.

[13]  Anand Swaroop,et al.  A comprehensive analysis of sequence variants and putative disease-causing mutations in photoreceptor-specific nuclear receptor NR2E3 , 2009, Molecular vision.

[14]  P. Gouras,et al.  Mutations in NR2E3 can cause dominant or recessive retinal degenerations in the same family , 2009, Human mutation.

[15]  P. Gouras,et al.  Phenotypic features of patients with NR2E3 mutations. , 2009, Archives of ophthalmology.

[16]  M. Bach,et al.  ISCEV Standard for full-field clinical electroretinography (2008 update) , 2009, Documenta Ophthalmologica.

[17]  G. Martínez-Navarrete,et al.  Gradual morphogenesis of retinal neurons in the peripheral retinal margin of adult monkeys and humans , 2008, The Journal of comparative neurology.

[18]  Wing Hung Wong,et al.  Inferring Loss-of-Heterozygosity from Unpaired Tumors Using High-Density Oligonucleotide SNP Arrays , 2006, PLoS Comput. Biol..

[19]  Cheng Li,et al.  dChipSNP: significance curve and clustering of SNP-array-based loss-of-heterozygosity data , 2004, Bioinform..

[20]  A. Sudarshan Vitreous change in retinitis pigmentosa. , 1999, Ophthalmology.

[21]  R. Y. Tsai,et al.  Identification of DNA Recognition Sequences and Protein Interaction Domains of the Multiple-Zn-Finger Protein Roaz , 1998, Molecular and Cellular Biology.

[22]  B. Morgan,et al.  Aiolos, a lymphoid restricted transcription factor that interacts with Ikaros to regulate lymphocyte differentiation , 1997, The EMBO journal.

[23]  P. Onori,et al.  Vitreal alterations in retinitis pigmentosa: biomicroscopic appearance and statistical evaluation. , 1996, Ophthalmologica. Journal international d'ophtalmologie. International journal of ophthalmology. Zeitschrift fur Augenheilkunde.

[24]  Rappold,et al.  Human Molecular Genetics , 1996, Nature Medicine.

[25]  G. Antiñolo,et al.  Retinitis pigmentosa in Spain , 1995 .

[26]  G. Antiñolo,et al.  Retinitis pigmentosa in Spain. The Spanish Multicentric and Multidisciplinary Group for Research into Retinitis Pigmentosa. , 1995, Clinical genetics.

[27]  T. Hikichi,et al.  Prevalence of posterior vitreous detachment in retinitis pigmentosa. , 1995, Ophthalmic surgery.

[28]  C. Pabo,et al.  Crystal structure of a five-finger GLI-DNA complex: new perspectives on zinc fingers. , 1993, Science.