Leila Tiab

Mutations in PIP5K3 Are Associated with François-Neetens Mouchetée Fleck Corneal Dystrophy

François-Neetens fleck corneal dystrophy (CFD) is a rare, autosomal dominant corneal dystrophy characterized by numerous small white flecks scattered in all layers of the stroma. Linkage analysis localized CFD to a 24-cM (18-Mb) interval of chromosome 2q35 flanked by D2S2289 and D2S126 and containing PIP5K3. PIP5K3 is a member of the phosphoinositide 3-kinase family and regulates the sorting and traffic of peripheral endosomes that contain lysosomally directed fluid phase cargo, by controlling the morphogenesis and function of multivesicular bodies. Sequencing analysis disclosed missense, frameshift, and/or protein-truncating mutations in 8 of 10 families with CFD that were studied, including 2256delA, 2274delCT, 2709C-->T (R851X), 3120C-->T (Q988X), IVS19-1G-->C, 3246G-->T (E1030X), 3270C-->T (R1038X), and 3466A-->G (K1103R). The histological and clinical characteristics of patients with CFD are consistent with biochemical studies of PIP5K3 that indicate a role in endosomal sorting.

Mutation in the Human Homeobox Gene NKX5-3 Causes an Oculo-Auricular Syndrome

Several dysmorphic syndromes affect the development of both the eye and the ear, but only a few are restricted to the eye and the external ear. We describe a developmental defect affecting the eye and the external ear in three members of a consanguineous family. This syndrome is characterized by ophthalmic anomalies (microcornea, microphthalmia, anterior-segment dysgenesis, cataract, coloboma of various parts of the eye, abnormalities of the retinal pigment epithelium, and rod-cone dystrophy) and a particular cleft ear lobule. Linkage analysis and mutation screening revealed in the first exon of the NKX5-3 gene a homozygous 26 nucleotide deletion, generating a truncating protein that lacked the complete homeodomain. Morpholino knockdown expression of the zebrafish nkx5-3 induced microphthalmia and disorganization of the developing retina, thus confirming that this gene represents an additional member implicated in axial patterning of the retina.

Mutations in NR2E3 can cause dominant or recessive retinal degenerations in the same family

NR2E3, a photoreceptor‐specific nuclear receptor (PNR), represses cone‐specific genes and activates several rod‐specific genes. In humans, mutations in NR2E3 have been associated with the recessively‐inherited enhanced short‐wavelength sensitive S‐cone syndrome (ESCS) and, recently, with autosomal dominant (ad) retinitis pigmentosa (RP) (adRP). In the present work, we describe two additional families affected by adRP that carry a heterozygous c.166G>A (p.G56R) mutation in the NR2E3 gene. Functional analysis determined the dominant negative activity of the p.G56R mutant protein as the molecular mechanism of adRP. Interestingly, in one pedigree, the most common causal variant for ESCS (p.R311Q) cosegregated with the adRP‐linked p.G56R mutation, and the compound heterozygotes exhibited an ESCS‐like phenotype, which in 1 of the 2 cases was strikingly “milder” than the patients carrying the p.G56R mutation alone. Impaired repression of cone‐specific genes by the corepressors atrophin‐1 (dentatorubral‐pallidoluysian atrophy [DRPLA] gene product) and atrophin‐2 (arginine‐glutamic acid dipeptide repeat [RERE] protein) appeared to be a molecular mechanism mediating the beneficial effect of the p.R311Q mutation. Finally, the functional dominance of the p.R311Q variant to the p.G56R mutation is discussed. Hum Mutat 0,1–10, 2008.

The PROM1 Mutation p.R373C Causes an Autosomal Dominant Bull's Eye Maculopathy Associated with Rod, Rod–Cone, and Macular Dystrophy

PURPOSE To characterize in detail the phenotype of five unrelated families with autosomal dominant bulls eye maculopathy (BEM) due to the R373C mutation in the PROM1 gene. METHODS Forty-one individuals of five families of Caribbean (family A), British (families B, D, E), and Italian (family C) origin, segregating the R373C mutation in PROM1, were ascertained. Electrophysiological assessment, fundus autofluorescence (FAF) imaging, fundus fluorescein angiography (FFA), and optical coherence tomography (OCT) were performed in available subjects. Mutation screening of PROM1 was performed. RESULTS The R373C mutant was present heterozygously in all affected patients. The age at onset was variable and ranged between 9 and 58 years, with most of the individuals presenting with reading difficulties. Subjects commonly had a mild to moderate reduction in visual acuity except for members of family C who experienced markedly reduced central vision. The retinal phenotype was characterized by macular dystrophy, with retinal pigment epithelial mottling in younger subjects, progressing to typical BEM over time, with the development of macular atrophy in older patients. In addition, all members of family C had typical features of RP. The electrophysiological findings were variable both within and between families. CONCLUSIONS Mutations in PROM1 have been described to cause a severe form of autosomal recessive RP in two families of Indian and Pakistani descent. The results of this study have demonstrated that a distinct redundant PROM1 mutation (R373C) can also produce an autosomal dominant, fully penetrant retinopathy, characterized by BEM with little inter- and intrafamilial variability, and retinal dystrophy with variable rod or rod-cone dysfunction and marked intra- and interfamilial variability, ranging from isolated maculopathy without generalized photoreceptor dysfunction to maculopathy associated with very severe rod-cone dysfunction.

IROme, a New High-Throughput Molecular Tool for the Diagnosis of Inherited Retinal Dystrophies

The molecular diagnosis of retinal dystrophies is difficult because of the very important number of genes implicated and is rarely helped by genotype-phenotype correlations. This prompted us to develop IROme, a custom designed in solution-based targeted exon capture assay (SeqCap EZ Choice library, Roche NimbleGen) for 60 retinitis pigmentosa-linked genes and three candidate genes (942 exons). Pyrosequencing was performed on a Roche 454 GS Junior benchtop high-throughput sequencing platform. In total, 23 patients affected by retinitis pigmentosa were analyzed. Per patient, 39.6 Mb were generated, and 1111 sequence variants were detected on average, at a median coverage of 17-fold. After data filtering and sequence variant prioritization, disease-causing mutations were identified in ABCA4, CNGB1, GUCY2D, PROM1, PRPF8, PRPF31, PRPH2, RHO, RP2, and TULP1 for twelve patients (55%), ten mutations having never been reported previously. Potential mutations were identified in 5 additional patients, and in only 6 patients no molecular diagnosis could be established (26%). In conclusion, targeted exon capture and next-generation sequencing are a valuable and efficient approach to identify disease-causing sequence variants in retinal dystrophies.

Mutation analysis of KIF21A in congenital fibrosis of the extraocular muscles (CFEOM) patients

Purpose: CFEOM type 1 refers to a group of congenital eye movement disorders that is characterized by nonprogressive ophthalmoplegia affecting all the extraocular muscles. Individuals with the classic form of CFEOM are born with bilateral ptosis, infraducted eyes, and impossibility to raise their eyes above midline. This phenotype is often inherited as an autosomal dominant trait. CFEOM1 maps to the FEOM1 locus on chromosome 12 and is the consequence of mutations in the KIF21A gene. We analyzed three families and one sproradic case for potential genetic heterogeneity. Methods: Blood samples were collected from members of three families (Swiss, Turkish, and French origin) and one sporadic case (Iranian origin). In families, haplotype was tested for linkage to the autosomal dominant CFEOM1 locus on chromosome 12. Linkage studies were conducted using 2 polymorphic DNA microsatellite markers, D12S331 and D12S1048. Mutation analysis was performed by PCR amplification and bidirectional direct sequencing. Results: Haplotype analysis was compatible with linkage to the CFEOM1 locus in all affected members. Mutation analysis revealed the classical mutation R954W in all affected cases, including the sporadic case, regardless of their ethnic origin. The c.2860C>T base change was not observed in 100 individuals from various ethnic origins. Conclusions: As reported, the classical c.2860C>T mutation represents a hotspot for mutation in various ethnic groups, including Swiss, Turkish, French, and Iranian patients. Sporadic cases are often due to neo-mutations as in our case. Mutation analysis is important, especially in sporadic cases, to correctly evaluate recurrence and transmission risks.

Clinical and genetic investigation of a large Tunisian family with complete achromatopsia: identification of a new nonsense mutation in GNAT2 gene

Complete achromatopsia is a rare autosomal recessive disease associated with CNGA3, CNGB3, GNAT2 and PDE6C mutations. This retinal disorder is characterized by complete loss of color discrimination due to the absence or alteration of the cones function. The purpose of the present study was the clinical and the genetic characterization of achromatopsia in a large consanguineous Tunisian family. Ophthalmic evaluation included a full clinical examination, color vision testing and electroretinography. Linkage analysis using microsatellite markers flanking CNGA3, CNGB3, GNAT2 and PDE6C genes was performed. Mutations were screened by direct sequencing. A total of 12 individuals were diagnosed with congenital complete achromatopsia. They are members of six nuclear consanguineous families belonging to the same large consanguineous family. Linkage analysis revealed linkage to GNAT2. Mutational screening of GNAT2 revealed three intronic variations c.119−69G>C, c.161+66A>T and c.875−31G>C that co-segregated with a novel mutation p.R313X. An identical GNAT2 haplotype segregating with this mutation was identified, indicating a founder mutation. All patients were homozygous for the p.R313X mutation. This is the first report of the clinical and genetic investigation of complete achromatopsia in North Africa and the largest family with recessive achromatopsia involving GNAT2; thus, providing a unique opportunity for genotype–phenotype correlation for this extremely rare condition.