视网膜色素变性患者中视网膜色素变性1基因点突变的研究

目的 研究中国视网膜色素变性（retinitis pigmentosa，RP)患者RP1基因的突变频率、特征及其在RP发病机理中所起的作用。方法 运用构象敏感凝胶电泳（conformation sensitive gel electrophoresis,CSGE)和DNA直接测序方法对101例香港地区RP患者的RP1基因全编码区进行突变的筛选与检测。结果 101例RP患者中检出1例患者携带常见的RP1致病突变－R677X，另外在3名正常个体及1例Stargardt患者中检出非致病的无义突变－R1933X。RP1基因在所有RP患者中的突变检出率为1／101。突变最终导致RP1蛋白严重截短。此外，在本研究人群中还发现10个错义突变，除M479I的病理意义未确定之外，其余均系RP1基因的多态现象。结论 R1933X无致病意义，提示羧基端224个氨基酸的区域可能为RP1蛋白非功能区，结合最近发现的RP1羧基端的移码突变－Y1053（1bp del)的病理意义，推测RP1蛋白中相应片段（密码子1052－1933）的缺失会导致RP的发生。为证实这种推测，大范围的RP1基因分型工作是有必要的，并且可同时发现更多的RP致病突变以及不同于其他种族人群的RP1基因多态变化。     

Genetic mapping of loci for X-linked retinitis pigmentosa

Linkage analysis was performed in three Swedish families segregating for X-linked retinitis pigmentosa (XLRP), using five polymorphic DNA markers assigned to Xp. Individual recombination events were analyzed and two- and five-point linkage analysis was undertaken. In one family, a XLRP locus was mapped to the same position as OTC corresponding to RP3. In two families, a disease locus linked to OTC was excluded. In one family, recombination events indicate a locus for XLRP outside the interval (DXS84-OTC-DXS255-DXS14), most likely on the centromeric side of DXS14.     

A novel mutation of RPGR gene in an X-linked Chinese family with retinitis pigmentosa

PurposeTo localize and identify the gene and mutations causing an X-linked Chinese family with retinitis pigmentosa.MethodsAn XLRP Chinese family was ascertained and patients underwent ophthalmological examinations. Blood samples were collected and genomic DNA was extracted. Linkage scan was performed on genomic DNA from affected and unaffected family members using microsatellite markers flanking 17 known autosomal dominant loci and markers covering the entire X chromosome. Mutation screening of RPGR gene was carried out by direct DNA sequence analysis.ResultsA genome wide scan yielded a lod score of 2.7 at θ = 0 with DXS1068 and 3.29 at θ = 0 with DXS993. This region harbors the RPGR gene. Direct DNA sequence analysis reveals one base pair deletion, gORF15 + 556delA, in all affected individuals. The deletion results in the frameshift change of RPGR gene and produces a truncated protein.ConclusionsWe identified a novel mutation, gORF15 + 556delA (p.Lys184fs), in a Han Chinese family with retinitis pigmentosa. This mutation expands the mutation spectrum of RPGR and helps to study molecular pathogenesis of RP further.     

一个X-连锁视网膜色素变性中国家系的RPGR基因的新突变

目的 对中国人X-连锁视网膜色素变性一家系进行分子遗传学检测，报告RPGR基因突变。方法 首先对该家系X染色体进行致病基因的连锁分析，然后用单链构象多态性技术和直接DNA测序方法进行基因突变分析。结果 连锁分析在多态性微卫星遗传标记DXSS012和DXS8025产生正的Lod值分别为2．41（Zmax=2．40，θ=0）和1．26。进一步单倍型分析确定该家系致病基因位于Xp21．1，与RP3连锁。用RPGR基因突变分析，在外显子ORF15＋483－484发现GA缺失，引起阅读框架的改变，该基因缺失突变在家系中共分离。结论 报告了中国人X-连锁视网膜色素变性RPGR基因外显子ORF15＋483-484的GA缺失突变，丰富了中国人RPGR基闪突变谱，为今后研究X-连锁视网膜色素变性的基因奠定基础。     

Mutation analysis of the ROM1 gene in retinitis pigmentosa

The publishers wish to apologise for the misprinting of thenucleotide changes involved in the ROM1 amino acid substitutionspresented in the above paper. The correct nucleotide changefor each mutation is given below. P60T (CCTACT) T108M (ACGATG) G75D (GGCGAC) R242Q (CGACAA)     

Mutation analysis of the ROM1 gene in retinitis pigmentosa

To examine the role of ROM1, a homologue of peripherin/RDS,in autosomal dominant retinitis pigmentosa (adRP), we screened224 adRP and 29 simplex RP probands for ROM1 mutations. FourROM1 alleles were designated as potentially pathogenic becausethey were found only in RP patients but not in 50–100controls nor in 249 other RP probands. The substitutions P60Tand T108M were present in a single alleie in a subject withtypical adRP, and this allele cosegregated with the diseasein the small family. The putative null allele L114 [     

Two novel mutations in the retinitis pigmentosa GTPase regulator (RPGR) gene in X-linked retinitis pigmentosa (RP3). Mutations in brief no. 172. Online

Recently a new gene called RPGR (retinitis pigmentosa GTPase regulator) was isolated in Xp21.1 and found to be mutated in patients with RP3 type X-linked retinitis pigmentosa. Two new mutations, the first a single base pair deletion and the other a two base pairs deletion, have been found in one Spanish and one Italian family.     

A patient homozygous for the SCA6 gene with retinitis pigmentosa

The present authors studied a 55-year-old-patient homozygous for the SCA6 gene who experienced frequent attacks of positional vertigo at 37 years of age with subsequent staggering gait and night blindness. Retinitis pigmentosa (RP), as well as cerebellar ataxia and vertical antidirectional nystagmus, were detected. The subject's parents were first cousins, and two of his three male cousins, whose parents were also first cousins, had RP without ataxia or nystagmus. The numbers of CAG repeats in the expanded alleles of the SCA6 gene found by molecular analysis were 21 and 21. The genetic results were negative for SCA1, SCA2, SCA3, SCA7 and dentatorubral pallidoluysian atrophy. The retinal degeneration in this patient is most likely to be secondary to a genetic disorder of autosomal or X-linked recessive inheritance rather than SCA6. Other reported cases of patients homozygous for the SCA6 gene are also reviewed.     

Localization of a novel X-linked congenital stationary night blindness locus: close linkage to the RP3 type retinitis pigmentosa gene region

X-linked congenital stationary night blindness (CSNBX) is anon-progressive retinal disorder characterized by decreasedvisual acuity and loss of night vision. CSNBX Is clinicallyheterogeneous with respect to the involvement of retinal rodsand/or cones in the disease. in this study, we localize a newlocus for CSNBX to Xp21.1, thus providing evidence that CSNBXis also genetically heterogeneous. A clear correlation betweendifferent genotypes and phenotypes cannot be found yet. Thenew CSNBX gene described here is closely linked to the X-linkedretinitis pigmentosa type 3 gene region, which supports thehypothesis that there may be a functional relationship betweencongenital stationary night blindness and retinitis pigmentosa.     

Three novel mutations of the RPGR gene exon ORF15 in three Japanese families with X-linked retinitis pigmentosa.

We describe three new mutations in a recently identified exon, ORF15, of the retinitis pigmentosa GTPase regulator gene (RPGR) in three unrelated Japanese families (Families 1-3) with X-linked retinitis pigmentosa (XLRP). The affected males had typical retinitis pigmentosa (RP), whereas the obligate carrier females showed a wide clinical spectrum, ranging from minor symptoms to severe visual disability. Some carrier females in Families 1 and 2 showed typical RP, most carriers manifested high myopia and astigmatism, and their corrected visual acuity was insufficient. They showed an impairment of cone function following the rod dysfunction and accompanied by refractive errors. Microsatellite analysis of Family 1 revealed that the RP in the family was linked to the RP3 locus. Although one patient in the family had no mutation in the previously published exons 1-19 including exon 15a, he had a single-nucleotide insertion in exon ORF15 (g.ORF15 + 753-754 insG). Likewise, patients in Families 2 and 3 had two-base insertion/deletion in the exon, i.e., g.ORF15 + 833-834delGG and g.ORF15 + 861-862insGG, respectively. These insertional/deletional mutations observed in the three families are all different and new, and are predicted to lead to a frameshift, resulting in a truncated protein. These findings may support the previous hypothesis that RPGR-ORF15 is a mutational hot spot.     

Positional cloning of the gene(WFS1) for Wolfram syndrome

Wolfram syndrome(DIDMOAD syndrome) is an autosomal recessive neurodegenerative disorder characterized by juvenile-onset, insulin-requiring diabetes mellitus and optic atrophy. Other symptoms including diabetes insipidus, neurosensory deafness, urinary tract and neurological abnormalities are often accompanied. In patients, beta-cells are selectively lost from their pancreatic islets of Langerhans. The gene was previously mapped to 4p16.1. By haplotype analysis and recombination mapping in 5 families, we localized the gene within a region less than 250 kb on chromosome 6p. In the region, we identified a novel gene(WFS1) encoding a putative transmembrane protein. Mutations were identified in all affected members of the families and these mutations were associated with disease phenotype. This finding was further confirmed by other investigators and to date, more than 50 mutations were identified in the WFS1 gene from the patients with Wolfram syndrome. The WFS1 gene encodes a protein of 100.3 kDa with 9 to 10 putative transmembrane domains. The protein appears to be important in the survival and maintenance of normal pancreatic beta-cells and neurons. Physiological function of the WFS1 protein and mechanisms by which defective WFS1 lead to the development of Wolfram syndrome need to be clarified.     

Identification of a 5' splice site mutation in the RPGR gene in a family with X-linked retinitis pigmentosa (RP3)

We have identified a novel RPGR gene mutation in a large Dutch family with X-linked retinitis pigmentosa (RP3). In affected members, a G-->T transversion was found at position +1 of the 5' splice site of intron 5 of the RPGR (retinitis pigmentosa GTPase regulator) gene. Analysis of this mutation at the RNA level showed cryptic splicing upstream of the mutation in exon 5 leading to a frameshift and downstream termination codon. Identification of the causative mutation in this family has facilitated the detection of females at risk of having an affected son.     

Identification of a gene disrupted by a microdeletion in a patient with X-linked retinitis pigmentosa (XLRP)

The gene for the most frequent from of X-linked retinitis pigmentosa (XLRP), RP3, has been assigned by genetic and physical mapping to a segment of less than 1000 kbp, which is flanked by the marker DXS1110 and the ornithine transcarbamylase (OTC) gene. In search of microdeletions, we have screened the DNA of 30 unrelated patients with XLRP by employing a representative set of YAC-derived DNA fragments that were generated by restriction enzyme digestion and PCR amplification. In one of these patients, a 6.4 kbp microdeletion was detected which was not present in the DNA of 444 male controls. A cosmid contig spanning the deletion was constructed and used to isolate cDNAs from retina-specific libraries. Exons corresponding to these expressed sequences as well as other putative exons were identified by sequencing more than 30 kbp of the critical region. So far, no point mutations in these putative exon sequences have been identified.      

Ten novel ORF15 mutations confirm mutational hot spot in the RPGR gene in European patients with X-linked retinitis pigmentosa

RGPR was the first gene found to be mutated in XLRP, the subtype of RP displaying the most severe form of retinal degeneration with partial or complete blindness in the third or fourth decade of life. Despite the RP3 locus on Xp21.1 accounting for 60-90% of XLRP, only 10-20% of identified RPGR mutations were reported in earlier analyses. This discrepancy appeared to be resolved when Vervoort et al. identified a mutational hot spot in a new purine-rich 3' exon (ORF15) that accounted for 60% of their XLRP patients [Vervoort et al., 2000]. In our mutation screening of 37 unrelated European XLRP patients we identified two recently described deletions and 10 novel mutations in exon ORF15 of RPGR, 4 of which were nonsense and 6 frameshift mutations. The latter included one duplication and 5 deletion mutations, all of which lead to a downstream premature termination. No mutations were detected in the additionally screened new exon ORF14. The data reported here, together with previous findings, document a significant clustering of mutations as well as polymorphisms in ORF15 of RPGR. In our unselected XLRP patient population, ORF15 mutations constitute 32% of cases, a finding that contradicts the results of Vervoort and coworkers [Vervoort et al., 2000] but is in agreement with a more recent study on North American XLRP patients [Breuer et al., 2002]. The observed prevalence is sufficient to justify an initial mutation screening of ORF15 in the genetically heterogeneous group of XLRP.