ADVIRC is caused by distinct mutations in BEST1 that alter pre-mRNA splicing.

Autosomal dominant vitreoretinochoroidopathy (ADVIRC), a retinal dystrophy often associated with glaucoma and cataract, forms part of a phenotypic spectrum of 'bestrophinopathies'. It has been shown previously that ADVIRC results from BEST1 mutations that cause exon skipping and lead to the production of shortened and internally deleted isoforms. This study describes a novel ADVIRC mutation and show that it disrupts an exonic splice enhancer (ESE) site, altering the binding of a splicing-associated SR protein. As with previous ADVIRC mutations, the novel c.704T-->C mutation in exon 6 altered normal splicing in an ex vivo splicing assay. Both this and another exon 6 ADVIRC-causing mutation (c.707G-->A) either weakened or abolished splicing in an ESE-dependent splice assay compared with a nearby exon 6 mutation associated with Best disease (c.703G-->C). Gel shift assays were undertaken with RNA oligonucleotides encompassing the ADVIRC and Best disease mutations with four of the most commonly investigated SR proteins. Although SC35, SRp40 and SRp55 proteins all bound to the wild-type and mutated sequences with similar intensities, there was increased binding of ASF/SF2 to the two ADVIRC-mutated sequences compared with the wild-type or Best disease-mutated sequences. The exon skipping seen for these two exon 6 ADVIRC mutations and their affinity for ASF/SF2 suggests that the region encompassing these mutations may form part of a CERES (composite exonic regulatory elements of splicing) site.

Intrafamilial phenotypic variability in families with RDS mutations: exclusion of ROM1 as a genetic modifier for those with retinitis pigmentosa.

OBJECTIVES: To identify suspected RDS mutations in families in which different people have been identified with either generalised retinal dystrophy or macular dystrophy. METHODS: Two families with a retinal dystrophy were extensively phenotyped and blood was taken for mutation analysis of the RDS (all) and ROM1 (retinitis pigmentosa patients only) genes. RESULTS: A novel p.Trp94X mutation in RDS was found in all three affected members of a two-generation family that was associated with retinitis pigmentosa in the son, pattern dystrophy in the daughter and fundus flavimaculatus in the mother. In the second family, the proband with retinitis pigmentosa carried a p.Arg220Trp mutation. The mother, who was unavailable for mutation screening, had adult vitelliform macular dystrophy. No ROM1 mutations were found in those with retinitis pigmentosa in either family. CONCLUSION: Mutations in RDS can be associated with an intrafamilial variation in retinal disease. The phenotypes range from Stargardt-like macular dystrophy to classic retinitis pigmentosa. CLINICAL RELEVANCE: Intrafamilial phenotypic variation may be due to the presence of environmental or genetic modifying factors. The presence of a modifying-sequence change in the coding region of ROM1 for two people with retinitis pigmentosa from two families with intrafamilial variation in RDS mutation phenotype has been excluded in this study.

RPGR ORF15 isoform co-localizes with RPGRIP1 at centrioles and basal bodies and interacts with nucleophosmin.

The ORF15 isoform of RPGR (RPGR(ORF15)) and RPGR interacting protein 1 (RPGRIP1) are mutated in a variety of retinal dystrophies but their functions are poorly understood. Here, we show that in cultured mammalian cells both RPGR(ORF15) and RPGRIP1 localize to centrioles. These localizations are resistant to the microtubule destabilizing drug nocodazole and persist throughout the cell cycle. RPGR and RPGRIP1 also co-localize at basal bodies in cells with primary cilia. The C-terminal (C2) domain of RPGR(ORF15) (ORF15(C2)) is highly conserved across 13 mammalian species, suggesting that it is a functionally important domain. Using matrix-assisted laser desorption ionization time-of-flight mass spectrometry, we show that this domain interacts with a 40 kDa shuttling protein nucleophosmin (NPM). The RPGR(ORF15)-NPM interaction was confirmed by (i) yeast two-hybrid analyses; (ii) binding of both recombinant and native HeLa cell NPM to RPGR(ORF15) fusion proteins in vitro; (iii) co-immunoprecipitation of native NPM, RPGR(ORF15) and RPGRIP1 from bovine retinal extracts and of native HeLa cell NPM and transfected RPGR(ORF15) from cultured cells and (iv) co-localization of NPM and RPGR(ORF15) at metaphase centrosomes in cultured cells. NPM is a multifunctional protein chaperone that shuttles between the nucleoli and the cytoplasm and has been associated with licensing of centrosomal division. RPGR and RPGRIP1 join a growing number of centrosomal proteins involved in human disease.