A homozygous p.Glu150Lys mutation in the opsin gene of two Pakistani families with autosomal recessive retinitis pigmentosa.

PURPOSE: To identify the gene mutations responsible for autosomal recessive retinitis pigmentosa (arRP) in Pakistani families. METHODS: A cohort of consanguineous families with typical RP phenotype in patients was screened by homozygosity mapping using microsatellite markers that mapped close to 21 known arRP genes and five arRP loci. Mutation analysis was performed by direct sequencing of the candidate gene. RESULTS: In two families, RP21 and RP53, homozygosity mapping suggested RHO, the gene encoding rhodopsin, as a candidate disease gene on chromosome 3q21. In six out of seven affected members from the two families, direct sequencing of RHO identified a homozygous c.448G>A mutation resulting in the p.Glu150Lys amino acid change. This variant was first reported in PMK197, an Indian arRP family. Single nucleotide polymorphism analysis in RP21, RP53, and PMK197 showed a common disease-associated haplotype in the three families. CONCLUSIONS: In two consanguineous Pakistani families with typical arRP phenotype in the patients, we identified a disease-causing mutation (p.Glu150Lys) in the RHO gene. Single nucleotide polymorphism analysis suggests that the previously reported Indian family (PMK197) and the two Pakistani families studied here share the RHO p.Glu150Lys mutation due to a common ancestry.

Mutations in TOPORS: a rare cause of autosomal dominant retinitis pigmentosa in continental Europe?

Mutations in TOPORS cause autosomal dominant retinitis pigmentosa (adRP). Examination of 160 adRP patients from continental Europe revealed nine exonic single nucleotide variants, eight of which reside in the coding region; three synonymous single nucleotide polymorphisms (SNPs; c.2319T > C, c.2991T > C and c.1560A > G), three nonsynonymous SNPs (c.58C > T/p.P20S, c.74C >G/p.S25W and c.1730C > A/p.S577Y) and two novel missense mutations (c.1205A > C/p.Q402P and c.1818T > G/p.S606R). Whether the latter two variants represent adRP causing mutations awaits further analysis.

Identification of novel mutations in X-linked retinitis pigmentosa families and implications for diagnostic testing.

PURPOSE: The goal of this study was to identify mutations in X-chromosomal genes associated with retinitis pigmentosa (RP) in patients from Germany, The Netherlands, Denmark, and Switzerland. METHODS: In addition to all coding exons of RP2, exons 1 through 15, 9a, ORF15, 15a and 15b of RPGR were screened for mutations. PCR products were amplified from genomic DNA extracted from blood samples and analyzed by direct sequencing. In one family with apparently dominant inheritance of RP, linkage analysis identified an interval on the X chromosome containing RPGR, and mutation screening revealed a pathogenic variant in this gene. Patients of this family were examined clinically and by X-inactivation studies. RESULTS: This study included 141 RP families with possible X-chromosomal inheritance. In total, we identified 46 families with pathogenic sequence alterations in RPGR and RP2, of which 17 mutations have not been described previously. Two of the novel mutations represent the most 3'-terminal pathogenic sequence variants in RPGR and RP2 reported to date. In exon ORF15 of RPGR, we found eight novel and 14 known mutations. All lead to a disruption of open reading frame. Of the families with suggested X-chromosomal inheritance, 35% showed mutations in ORF15. In addition, we found five novel mutations in other exons of RPGR and four in RP2. Deletions in ORF15 of RPGR were identified in three families in which female carriers showed variable manifestation of the phenotype. Furthermore, an ORF15 mutation was found in an RP patient who additionally carries a 6.4 kbp deletion downstream of the coding region of exon ORF15. We did not identify mutations in 39 sporadic male cases from Switzerland. CONCLUSIONS: RPGR mutations were confirmed to be the most frequent cause of RP in families with an X-chromosomal inheritance pattern. We propose a screening strategy to provide molecular diagnostics in these families.

Mother and daughter with a terminal Xp deletion: implication of chromosomal mosaicism and X-inactivation in the high clinical variability of the microphthalmia with linear skin defects (MLS) syndrome.

The microphthalmia with linear skin defects (MLS or MIDAS) syndrome is a rare X-linked dominant inherited disorder with male lethality, associated with segmental aneuploidy of the Xp22.2 region in most of the cases. However, we recently described heterozygous sequence alterations in a single gene, HCCS, in females with MLS. Beside the classical MLS phenotype, occasional features such as sclerocornea, agenesis of the corpus callosum, and congenital heart defects can occur. Although the majority of cases are sporadic, mother-to-daughter transmission has been observed and a high intra- and interfamilial phenotypic variability exists. We describe an asymptomatic mother and her daughter presenting with the typical features of MLS syndrome. By cytogenetic analysis both females were found to have a terminal Xp deletion with the breakpoint in Xp22.2, mapping near to or within the MSL3L1 gene which is located centromeric to HCCS. FISH analysis revealed that the mother is a mosaic with 45,X(11)/46,X,del(X)(p22.2)(89), while in all cells of the MLS-affected daughter a hybridization pattern consistent with a 46,X,del(X)(p22.2) karyotype was detected. By haplotype analysis we identified the paternal X chromosome of the mother to carry the terminal Xp deletion. X-inactivation studies showed a completely skewed pattern in mother and daughter with the deleted X chromosome to be preferentially inactivated in their peripheral blood cells. We suggest that both chromosomal mosaicism as well as functional X chromosome mosaicism could contribute to the lack of any typical MLS feature in individuals with a heterozygous MLS-associated mutation. The 45,X cell population, that most likely is also present in other tissues of the mother, might have protected her from developing MLS. Nonetheless, a non-random X-inactivation pattern in favor of activity of the wild-type X chromosome in the early blastocyte could also account for the apparent lack of any disease sign in this female.

Mutations of the mitochondrial holocytochrome c-type synthase in X-linked dominant microphthalmia with linear skin defects syndrome.

The microphthalmia with linear skin defects syndrome (MLS, or MIDAS) is an X-linked dominant male-lethal disorder almost invariably associated with segmental monosomy of the Xp22 region. In two female patients, from two families, with MLS and a normal karyotype, we identified heterozygous de novo point mutations--a missense mutation (p.R217C) and a nonsense mutation (p.R197X)--in the HCCS gene. HCCS encodes the mitochondrial holocytochrome c-type synthase that functions as heme lyase by covalently adding the prosthetic heme group to both apocytochrome c and c(1). We investigated a third family, displaying phenotypic variability, in which the mother and two of her daughters carry an 8.6-kb submicroscopic deletion encompassing part of the HCCS gene. Functional analysis demonstrates that both mutant proteins (R217C and Delta 197-268) were unable to complement a Saccharomyces cerevisiae mutant deficient for the HCCS orthologue Cyc3p, in contrast to wild-type HCCS. Moreover, ectopically expressed HCCS wild-type and the R217C mutant protein are targeted to mitochondria in CHO-K1 cells, whereas the C-terminal-truncated Delta 197-268 mutant failed to be sorted to mitochondria. Cytochrome c, the final product of holocytochrome c-type synthase activity, is implicated in both oxidative phosphorylation (OXPHOS) and apoptosis. We hypothesize that the inability of HCCS-deficient cells to undergo cytochrome c-mediated apoptosis may push cell death toward necrosis that gives rise to severe deterioration of the affected tissues. In summary, we suggest that disturbance of both OXPHOS and the balance between apoptosis and necrosis, as well as the X-inactivation pattern, may contribute to the variable phenotype observed in patients with MLS.

Seventeen novel PLP1 mutations in patients with Pelizaeus-Merzbacher disease.

Pelizaeus-Merzbacher disease (PMD) is a rare X-chromosomal neurodegenerative disorder that affects primarily the white matter of the central nervous system and is caused by mutations of the PLP1 (proteolipid protein 1) gene. We performed mutation analysis of 133 male patients with suspected PMD. Following SSCP analysis of all coding exons of PLP1, we found most likely pathogenic mutations (single base substitutions and small rearrangements) including 17 novel sequence variants in 21 (15.8%) patients. Most patients with missense mutations had a severe phenotype. Twelve patients (9.0%) carried a duplication of the entire gene, as demonstrated by quantitative real-time PCR, and presented with a variable clinical phenotype including mild, classical, and severe courses of disease. Two patients had large deletions, spanning approximately 115 kb, that included the PLP1 gene. In total, we identified pathogenic mutations involving PLP1 in 35 (26.3%) of the 133 patients analyzed.

[Hereditary foveal hypoplasia - clinical differentiation]. / Familiäre Foveahypoplasie - Klinische Einordnung.

BACKGROUND: In a family cataract, esotropia and foveal hypoplasia is dominantly transmitted. PATIENTS AND METHOD: Besides the physical examination visual evoked potentials and PAX6 mutation analysis were performed on five of six affected persons and on two who were not. RESULTS: A man of the first generation, deceased before this study, was known to have low vision. His two daughters and their children and grandchildren suffer from cataract, esotropia and foveal hypoplasia. In two cases accompanied by aniridia and atypical iris coloboma respectively. The best visual acuity is 0.5. The VEPs taken of three of the affected people were normal. The PAX6 mutation analysis demonstrated a T to A translocation in the Intron 8 at the position + 2 (= IVS8 + 2T --> A). CONCLUSION: 1) This study confirms that foveal hypoplasia in the so-called isolated form have a similar origin as in aniridia namely PAX6 mutation and that it is a symptom in all cases while the iris anomaly may be variable. 2) In contrast to this foveal hypoplasia in albinism may occur variably in a family while the asymmetry of VEP is a constant finding. 3) Therefore the VEP alone is helpful to differentiate clinically wether a foveal hypoplasia belongs to the albino or to the aniridia group.

Characterization of breakpoint sequences of five rearrangements in L1CAM and ABCD1 (ALD) genes.

Mutations in L1CAM are responsible for X-linked hydrocephalus, whereas those in the ALD gene (ABCD1) cause adrenoleukodystrophy. In both genes, most of the mutations reported so far are short-length mutations and only a few patients with larger rearrangements have been documented. We have characterized three intragenic deletions of the ALD gene at the molecular level and describe here the first two L1CAM rearrangements resulting in deletion of several exons in one case and about 50 kb, including the entire gene, in the second case. At both breakpoints of an ALD deletion, Alu repeats have been found and, additionally, a short Alu region of approximately 130 bp was inserted, suggesting that this rearrangement is the result of a more complex non-allelic homologous recombination event. Only one Alu element was present at the breakpoint of the second ALD rearrangement, including a 26-bp Alu core sequence that was suggested to be a recombinogenic hot spot. These data suggest the involvement of an Alu core sequence-stimulated non-homologous recombination as a possible cause for this rearrangement. Short direct repeats were identified at all putative mispaired sequences in the L1CAM breakpoints and at both breakpoints of the third ALD deletion characterized, suggesting non-homologous (illegitimate) recombination as the molecular mechanism by which these latter deletions occurred. In conclusion, our results indicate that highly repetitive elements as well as short direct repeats are frequently involved in the formation of ALD and L1CAM gene rearrangements.