Phenotype-genotype correlations in X linked retinitis pigmentosa.

Retinitis pigmentosa (RP) represents a group of clinically heterogeneous retinal degenerations in which all modes of inheritance have been described. We have previously found two different clinical profiles in X linked RP as a function of age and mode of onset. The first clinical form has very early onset with severe myopia. The second form starts later with night blindness with mild myopia or none. At least two genes have been identified in X linked forms, namely RP2 (linked to DXS7, DXS255, and DXS14) and RP3 (linked to DXS84 and OTC) on the short arm of the X chromosome. In order to contribute to phenotype-genotype correlations in X linked RP, we tested the hypothesis that the two clinical profiles could be accounted for by the two different gene loci. The present study provides evidence for linkage of the clinical form with early myopia as the onset symptom with the RP2 gene (pairwise linkage to DXS255: Z = 3.13 at theta = 0), while the clinical form with later night blindness as the onset symptom is linked to the RP3 gene (pairwise linkage to OTC: Z = 4.16 at theta = 0).     

Severe manifestations in carrier females in X linked retinitis pigmentosa.

Retinitis pigmentosa (RP) is a group of progressive hereditary disorders of the retina in which various modes of inheritance have been described. Here, we report on X linked RP in nine families with constant and severe expression in carrier females. In our series, however, the phenotype was milder and delayed in carrier females compared to hemizygous males. This form of X linked RP could be regarded therefore as partially dominant. The disease gene maps to chromosome Xp2.1 in the genetic interval encompassing the RP3 locus (Zmax=13.71 at the DXS1100 locus). Single strand conformation polymorphism and direct sequence analysis of the retinitis pigmentosa GTPase regulator (RPGR) gene, which accounts for RP3, failed to detect any mutation in our families. Future advances in the identification of X linked RP genes will hopefully help to elucidate the molecular basis of this X linked dominant RP.     

Genetic localisation of the RP2 type of X linked retinitis pigmentosa in a large kindred.

Genetic linkage and deletion studies have led to the proposal that there are at least two loci on the X chromosome which are responsible for X linked retinitis pigmentosa (XLRP). One locus (RP3) has been closely defined by genetic linkage and deletion analyses and localised to the region between the ornithine transcarbamylase (OTC) and chronic granulomatous disease (CYBB) loci in Xp21.1-p11.4. The other locus (RP2) has been assigned by linkage analysis alone to region Xp11.4-p11.2, but its localisation is less well defined. The results of a multipoint linkage analysis of a single large XLRP kindred using eight informative loci provide further evidence on the localisation of RP2 to this region. The maximum likelihood location of this locus shows a multipoint lod score of 7.17 close to DXS255 (in Xp11.22) and TIMP (in Xp11.3-p11.23), neither of which show recombination with RP2, in an area extending from 2 cM proximal to DXS7 to 1 cM distal to DXS14 (approximate 95% confidence limits).     

Linkage analysis of five pedigrees affected with typical autosomal dominant retinitis pigmentosa.

Five pedigrees (including an expanded version of a previously reported pedigree) exhibited typical autosomal dominant retinitis pigmentosa were analysed for linkage of RP to 29 genetic markers. No significant lod scores resulted. The largest lod score is +1.51 and suggests linkage between RP and Rh blood group at an estimated recombination fraction of 20% in males and 40% in females. Further studies are needed to confirm or refute this suggested linkage.     

Mapping a new genetic locus for X linked retinitis pigmentosa to Xq28

We have defined a new genetic locus for an X linked form of retinitis pigmentosa (RP) on chromosome Xq28. We examined 15 members of a family in which RP appeared to be transmitted in an X linked manner. Ocular examinations were performed, and fundus photographs and electroretinograms were obtained for selected patients. Blood samples were obtained from all patients and an additional seven family members who were not given examinations. Visual acuity in four affected individuals ranged from 20/40 to 20/80+. Patients described the onset of night blindness and colour vision defects in the second decade of life, with the earliest at 13 years of age. Examined affected individuals had constricted visual fields and retinal findings compatible with RP. Based on full field electroretinography, cone function was more severely reduced than rod function. Female carriers had no ocular signs or symptoms and slightly reduced cone electroretinographic responses. Affected and non‐affected family members were genotyped for 20 polymorphic markers on the X‐chromosome spaced at 10 cM intervals. Genotyping data were analysed using GeneMapper software. Genotyping and linkage analyses identified significant linkage to markers DXS8061, DXS1073, and DXS1108 with two point LOD scores of 2.06, 2.17, and 2.20, respectively. Haplotype analysis revealed segregation of the disease phenotype with markers at Xq28.     

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。     

Linkage analysis of two Canadian families segregating for X linked spondyloepiphyseal dysplasia.

X linked spondyloepiphyseal dysplasia (SED) is caused by a growth defect of the vertebral bodies leading to characteristic changes in the vertebral bodies and a short trunk. The gene responsible for this disorder has previously been mapped to Xp22, with a maximum likelihood location between markers DXS16 and DXS92. We present linkage data using microsatellite markers on two Canadian X linked SED families, one of Norwegian descent and the other from Great Britain. In the Xp22 region, three recombination events have occurred in these families, two between markers DXS996 and DXS1043 and one between DXS999 and DXS989. One family shows a maximal lod score of 3.0 at theta = 0 with marker DXS1043 and the other family has a maximal lod score of 1.2 at theta = 0 with markers DXS1224 and DXS418. Both families therefore support the previously reported gene localisation.     

Linkage analysis in a large Spanish family with X-linked retinitis pigmentosa: phenotype—genotype correlation

X-linked retinitis pigmentosa (XLRP) accounts for 10–25% of RP families and causes the most severe form of the disease in terms of onset and progression. Although three different loci (RP3, RP2 and RP15) have been proposed on the short arm of the X-chromosome by linkage analysis, RP3 represents the disease locus in the majority of XLRP families.
The identification of female carriers of X-linked RP is important for genetic counselling. The presence of fundus and electroretinogram (ERG) abnormalities have been reported to be as high as 87 and 90%, respectively. However, in clinical practice it has not always been possible to know the carrier state of females at risk.
Thirty-five members of a Spanish family with X-linked RP were evaluated by linkage analysis using nine polymorphic markers (CYBB, DXS1110, M6, DXS6679, DXS1068, DXS1058, MAOA, MAOB and DXS6849) that map to the X-chromosome region Xp21.1 to Xp11.3, in an attempt to determine the carrier state of these females at risk. It was possible to establish that a RP3 mutation is, most likely, segregating in this family.     

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 [     

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)     

Linkage of a medium sized Scottish autosomal dominant retinitis pigmentosa family to chromosome 7q.

Retinitis pigmentosa is a group of hereditary retinopathies which is both clinically and genetically heterogeneous. Autosomal dominant (ADRP), autosomal recessive (ARRP), and X linked recessive (XLRP), as well as digenic forms of inheritance have been reported. ADRP has been linked to 3q, 6p, 7p, 7q, 8cen, 17p, 17q, and 19q. Three unrelated ADRP families have been reported to show linkage to 7q. We tested a Scottish ADRP family with microsatellite markers mapping within the 7q31-q35 region, and found three markers (D7S487, D7S514, D7S530) showing statistically significant evidence of linkage. A maximum two point lod score of 3.311 at 0% recombination was obtained for D7S514.     

Prevalence of retinitis pigmentosa in Slovenia

Two hundred and twenty-nine symptomatic patients with retinitis pigmentosa were ascertained in Slovenia between 1986 and 1990. Twenty-three further patients were identified while data from 63 families (82 patients) were being collected. After correction for underascertainment, a prevalence of 1 in 6023 was estimated in the Slovene population (1,999,477 in 1990). The highest prevalence of 1 in 1902 was found in the age group 65 years and older. Of 63 analysed families, 17 (27%) showed autosomal dominant, 13 (21%) autosomal recessive, and one family (1.5%) X-linked inheritance; in 30 families (47.5%) isolated cases were found; and in two families the mode of inheritance was impossible to determine.     

Non-allelic mutations in X-linked retinitis pigmentosa

Using RFLP studies, the disease locus in two X-linked retinitis pigmentosa families was found to be centromeric to DXS7 in one family and telomeric to DXS7 in another, suggesting non-allelic heterogeneity.