The nuclear receptor protein NR2E3 is postulated to play an important role in rod and cone photoreceptor development. NR2E3 gene mutational analyses were carried out in 103 unrelated subjects with different retinal diseases. A total of 14 different sequence variants were identified, including 3 mutations, 6 rare sequence variants and five polymorphisms. One of three mutations is novel (a frameshift mutation: c.1034_1038del5bp). Five of the six rare sequence variants and one of the polymorphisms identified are novel. Splice prediction programs and functional splicing assays were performed to study three of these variants. The c.119-2 A>C mutant allele construction produces, in addition to the normal one, an abnormal transcript of 180 bp resulting from an aberrant splicing with skipping of exon 2 and the generation of a premature stop codon in exon 3. These experimental data confirm the splice predictions made by the computer programs. The obtained results reinforce the idea that NR2E3 gene is involved in several retinal diseases without a clear genotype-phenotype correlation.
Autosomal recessive retinitis pigmentosa (ARRP) is a degenerative disease of photoreceptors in which defects in the rhodopsin and phosphodiesterase beta-subunit (PDEB) loci have been reported. To assess the involvement of PDEB in ARRP families from Spain, we screened a panel of 19 families for linkage to markers within or close to the PDEB gene. Homozygosity was also tested in cases of consanguinity. This combined approach ruled out PDEB as the cause of the disease in all but one of the families. Molecular characterization of the gene in that family (a consanguineous pedigree) revealed a homozygous 71-bp tandem duplication in exon 1 of the affected member, the parents being heterozygous. This defect causes a frameshift mutation which leads to a premature stop codon, suggesting that this mutant allele is the underlying cause of ARRP in this patient. According to the data presented here, the PDEB gene is not the main gene responsible for ARRP, but accounts for about 5% of the cases.
Patients with Usher syndrome type II (USH2) show moderate-to-severe hearing loss (HL), retinitis pigmentosa and normal vestibular function. The progression of HL remains controversial. To evaluate whether a phenotype-genotype correlation exists regarding the issue of progression of HL, only USH2 patients with a defined genotype were selected. Ophthalmologic, vestibular and audiometric examination along with a mutation analysis of the USH2A gene (exons 1--21) was performed in twenty-eight Spanish USH2 patients. Ten different pathogenic mutations and 17 sequence variants not associated with the disease were found. Six of the 10 mutations are novel. Disease alleles were identified in 13 of the 28 families tested. Eight of these 13 families had a mutation found in both alleles. In the other five families, only one mutation was identified. The phenotypic data provide evidence for the existence of phenotypic differences between patients with the same genotype. These differences were observed at both the interfamilial and intrafamilial levels.
Autosomal recessive retinitis pigmentosa (ARRP) is a genetically heterogeneous disease. To date, mutations in four members of the phototransduction cascade have been implicated in ARRP. Additionally, linkage of the disease to three loci on lp, lq, and 6p has been described. However, the majority of cases are still uncharacterised. We have performed linkage analysis in a large nuclear ARRP family with five affected sibs. After exclusion of several regions of the genome known to contain loci for retinal dystrophies, a genomic search for linkage to ARRP was undertaken. Positive lod scores were obtained with markers on 2q31-q33 (Zmax at 0=0.00 of 4.03, 4.12, and 4.12 at D2S364, D2S118, and D2S389, respectively) defining an interval of about 7 cM for this new ARRP locus, between D2S148 and D2S161. Forty-four out of 47 additional ARRP families, tested with markers on 2q32, failed to show linkage, providing evidence of further genetic heterogeneity.
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