Linkage disequilibrium and physical mapping of X-linked juvenile retinoschisis.

X-linked juvenile retinoschisis (RS) is a recessively inherited disorder resulting in poor visual acuity. Affected males typically show retinal degeneration and intraretinal splitting. The prevalence of RS is 1:15,000-1:30,000. Elsewhere we have mapped the RS gene between the markers DXS43 and DXS274 in Xp22.1-p22.2. To narrow the RS region, we analyzed 31 Finnish RS families with the markers DXS418, DXS999, DXS7161, and DXS365 and a new polymorphic microsatellite marker, HYAT1. Multipoint linkage analysis allowed us to localize the RS gene between the markers DXS418 and DXS7161 (LOD score = 31.3). We have covered this region with nine YAC clones. On the basis of the sizes of the YACs, sequence-tagged site (STS) content mapping, and restriction mapping, the physical distance between DXS418 and DXS7161 is approximately 0.9 Mb. A total of five potential CpG islands could be identified. For haplotype analysis, eight additional Finnish RS families were analyzed with the markers DXS1195, DXS418, HYAT1, DXS999, DXS7161, and DXS365. On the basis of the linkage-disequilibrium data that were derived from the genetically isolated Finnish population, the critical region for RS could be narrowed to 0.2-0.3 cM, between the markers DXS418 and HYAT1.     

Evidence for a Turner syndrome locus or loci at Xp11.2-p22.1.

Turner syndrome is the complex human phenotype associated with complete or partial monosomy X. Principle features of Turner syndrome include short stature, ovarian failure, and a variety of other anatomic and physiological abnormalities, such as webbed neck, lymphedema, cardiovascular and renal anomalies, hypertension, and autoimmune thyroid disease. We studied 28 apparently nonmosaic subjects with partial deletions of Xp, in order to map loci responsible for various components of the Turner syndrome phenotype. Subjects were carefully evaluated for the presence or absence of Turner syndrome features, and their deletions were mapped by FISH with a panel of Xp markers. Using a statistical method to examine genotype/phenotype correlations, we mapped one or more Turner syndrome traits to a critical region in Xp11.2-p22.1. These traits included short stature, ovarian failure, high-arched palate, and autoimmune thyroid disease. The results are useful for genetic counseling of individuals with partial monosomy X. Study of additional subjects should refine the localization of Turner syndrome loci and provide a rational basis for exploration of candidate genes.     

Genetic mapping of 12 marker loci in the Xp22.3-p21.2 region

Summary To provide a more precise genetic map of the p22.3–p21.2 region on the short arm of the human X chromosome, we performed multilocus linkage studies in an expanded database including 31 retinoschisis families and 40 normal families. Twelve loci from this region were examined. Although significant lod scores were observed between various pairs of markers by two-point linkage analysis, the confidence limits were found to be broad. The most likely gene order on the basis of multilocus analysis was Xpter-DXS89-DXS85-DXS16-(DXS207, DXS43)-DXS274-(DXS41, DXS92)-ZFX-DXS164-Xcen. All other alternative orders were excluded by odds of at least 401.     

Linkage relationships and gene order around the locus for X-linked retinoschisis.

X-linked recessive retinoschisis (RS) is a hereditary disorder with variable clinical features. The main symptoms are poor sight; radial, cystic macula degeneration; and peripheral superficial retinal detachment. The disease is quite common in Finland, where at least 300 hemizygous males have been diagnosed. We used nine polymorphic DNA markers to study the localization of RS on the short arm of the X chromosome in 31 families comprising 88 affected persons. Two-point linkage results confirmed close linkage of the RS gene to the marker loci DXS43, DXS16, DXS207, and DXS41 and also revealed close linkage to the marker loci DXS197 and DXS9. Only one recombination was observed between DXS43 and RS in 59 informative meioses, giving a maximum lod score of 13.87 at the recombination fraction .02. No recombinations were observed between the RS locus and DXS9 and DXS197 (lods between 3 and 4), but at neither locus was the number of informative meioses sufficient to provide reliable estimates of recombination fractions. The most likely gene order on the basis of multilocus analysis was Xpter-DXS85-(DXS207,DXS43)-RS-DXS41-DXS 164-Xcen. Because multilocus linkage analysis indicated that the most probable location of RS is proximal to DXS207 and DXS43 and distal to DXS41, these three flanking markers are the closest and most informative markers currently available for carrier detection.     

Refined localization of the gene causing X-linked juvenile retinoschisis

Previous linkage studies in X-linked juvenile retinoschisis (RS) placed the gene between the loci DXS43 and DXS41 in the region Xp22.2-p22.1. Here we have extended our earlier studies by analyzing 31 RS families with the markers DXS16 (pSE3.2-L), DXS274, DXS92, and ZFX. Pairwise linkage analysis revealed significant linkage of the RS gene to all markers used; locus DXS274 (probe CRI-L1391) was tightly-linked to the disorder, with a lod score of 9.02 at a recombination fraction of 0.05. The genetic map around the RS locus was refined by multilocus linkage studies in an expanded database including a large set of normal families (40 CEPH families). The results indicated that the RS gene locus lies between (DXS207, DXS43) and DXS274 with odds of 1.8 x 10(4):1 favoring this most likely location over the second most likely location, i.e., distal to DXS43. Analysis by LINKMAP gave a maximum location score of 136.4 with the order Xpter-DXS16-(DXS207,DXS43)-RS-DXS274-(D XS41,DXS92)-Xcen. To assess the diagnostic value of the markers in Finnish patients, a total of 12 markers were tested for allele frequencies in 126 Finnish unrelated blood donors. With the exception of the markers DXS207, DXS43, and DXS92, allele frequencies did not show any significant deviation from the data published elsewhere. Haplotype analysis was performed with five DNA markers flanking the RS locus. Patients from southwest Finland had a haplotype association that differed from the haplotype association found in the patients from north central Finland, favoring the hypothesis that the mutations in the two groups arose independently.     

Exclusion of PPEF as the gene causing X-linked juvenile retinoschisis

X-linked juvenile retinoschisis (RS) is a progressive vitreoretinal degeneration localised in Xp22.1-p22.2. A human homologue of the retinal degeneration gene C (rdgC), a gene that in Drosophila melanogaster prevents light-induced retinal degeneration, was localised in the RS obligate gene region. We have tested the gene, designated PPEF in humans, as a candidate gene in RS patients using RT-PCR and the protein truncation test on RNA and SSCP on DNA. No mutations were identified, making it highly unlikely that PPEF is the gene implicated in RS. The data presented facilitate mutation analysis of the PPEF gene in other diseases which have been or will be localised to this region. Received: 20 May 1997 / Accepted: 30 July 1997     

The mouse X-linked juvenile retinoschisis cDNA: expression in photoreceptors

Retinal photoreceptor cells are particularly vulnerable to degenerations that can eventually lead to blindness. Our purpose is to identify and characterize genes expressed specifically in photoreceptors in order to increase our understanding of the biochemistry and function of these cells, and then to use these genes as candidates for the sites of mutations responsible for degenerative retinal diseases. We have characterized a cDNA, a fragment of which (SR3.1) was originally isolated by subtractive hybridization of adult, photoreceptorless rd mouse retinal cDNAs from the cDNAs of normal mouse retina. The full-length sequence of this cDNA was determined from clones obtained by screening mouse retinal and eye cDNA libraries and by using the 5'- and 3'-RACE methods. Both Northern blot analysis and in situ hybridization showed that the corresponding mRNA is expressed in rod and cone photoreceptors. The gene encoding this cDNA was mapped to the X chromosome using an interspecific cross. Based on the nucleotide and amino acid sequences, as well as chromosome mapping, we determined that this gene is the mouse ortholog (Xlrs1) of the human X-linked juvenile retinoschisis gene (XLRS1). Analysis of the predicted amino acid sequence indicates that the Xlrs1 mRNA may encode a secretable, adhesion protein. Therefore, our data suggest that X-linked juvenile retinoschisis originates from abnormalities in a photoreceptor-derived adhesion protein.     

Linkage relationship between retinoschisis and four marker loci

Summary The linkage relationship between the locus for juvenile retinoschisis (RS) and four X-chromosomal marker loci DXS9 (RC8), DXS16 (XUT23), DXS41 (99-6), and DXS43 (D2) has been studied in six families showing a history of this disease. Recombination with RS was found for all marker loci except DXS9. The maximum lod score is =2.66 for RS vs. SXS9 at a recombination fraction of =0.0. Multipoint linkage analysis was performed and the locus order best supported by our data is: RS-DXS9-DXS43-DXS16-DXS41.     

An interstitial deletion in Xp22.3 in a family with X-linked recessive chondrodysplasia punctata and short stature

Summary In a four-generation family, chondrodysplasia punctata was found in a boy and one of his maternal uncles. These two patients also have short stature, as do all female members of the family. DNA molecular analysis of the pseudoautosomal and Xp22.3-specific loci revealed the presence of an interstitial deletion that cosegregates with the phenotypic abnormalities. The proximal breakpoint of this deletion was located distal to the DXS31 locus and the distal breakpoint in the pseudoautosomal region between DXYS59 and DXYS17. This maps the recessive X-linked form of chondrodysplasia punctata between the proximal boundary of the pseudoautosomal region and DXS31, and an Xp gene controlling growth between DXYS59 and DXS31.     

Confirmation and refinement of the genetic localization of the Coffin-Lowry syndrome locus in Xp22.1-p22.2

The Coffin-Lowry syndrome (CLS) is an X-linked inherited disease of unknown pathogenesis characterized by severe mental retardation, typical facial and digital anomalies, and progressive skeletal deformations. Our previous linkage analysis, based on four pedigrees with the disease, suggested a localization for the CLS locus in Xp22.1-p22.2, with the most likely position between the marker loci DXS41 and DXS43. We have now extended the study to 16 families by using seven RFLP marker loci spanning the Xp22.1-p22.2 region. Linkage has been established with five markers from this part of the X chromosome: DXS274 (lod score [Z] (theta) = 3.53 at theta = .08), DXS43 (Z(theta) = 3.16 at theta = .08), DXS197 (Z(theta) = 3.03 at theta = .05), DXS41 (Z(theta) = 2.89 at theta = .08), and DXS207 (Z(theta) = 2.73 at theta = .13). A multipoint linkage analysis further placed, with a maximum multipoint Z of 7.30, the mutation-causing CLS within a 7-cM interval defined by the cluster of tightly linked markers (DXS207-DXS43-DXS197) on the distal side and by DXS274 on the proximal side. Thus, these further linkage data confirm and refine the map location for the gene responsible for CLS in Xp22.1-p22.2. As no linkage heterogeneity was detected, this validates the use of the Xp22.1-p22.2 markers for carrier detection and prenatal diagnosis in CLS families.     

Linkage studies of X-linked recessive spastic paraplegia using DNA probes

Summary A family with six males affected by X-linked spastic paraplegia (McKusick No. 31290) is described. The disease was accompanied by mental retardation in all patients (severe in four cases with IQ of 40) and by absence of extensor pollicis longus (in four cases). The following X chromosome DNA probes were used in linkage studies: 782, RC8, 99-6, 754, OTC, L128, pDP34, p43-15, DX13, and St14. The mutation is closely linked to the loci DX13 (DXS15) and Stl4 (DXS52) (no recombinants in 11 meioses) and therefore localised to the telomeric region of the long arm of the human X chromosome.     

X-linked recessive combined pituitary hormone deficiency is mapped to Xp22.3-Xp11 in a Chinese family

Genetic mutations have been identified in a modest proportion of patients with combined pituitary hormone deficiency (CPHD). We reported a 3-generation family consisting of 18 members, including 5 affected males (the proband, his 2 brothers, his cousin, and his maternal uncle; III1–III4, II8) suffered with CPHD. MRI of the pituitary gland showed hypoplasia of the pituitary gland in affected members. By 19 STR markers and linkage analysis, we found that the disease gene localized between the DXS987 and DXS1226 markers (LOD score = 2.408, θ = 0). All affected male patients inherited the same haplotype from the female carrier (I4). The proband's mother (II4) and her sister (II3, II6) were obligate female carriers. However, the unaffected males (II₇, II₉) in the family did not have this haplotype. These observations confirm a new X-linked recessive inherited disease in a Chinese family with CPHD and the pathogenic gene is mapped to Xp22.1–Xp11.     

Linkage analysis of keratosis follicularis spinulosa decalvans, and regional assignment to human chromosome Xp21.2-p22.2.

Keratosis follicularis spinulosa decalvans (KFSD) is a rare X-chromosomal disorder. It consists of follicular hyperkeratosis of the skin, scarring alopecia of the scalp, absence of the eyebrows, and corneal degeneration. There is photophobia in childhood, but the symptoms tend to diminish after puberty, and prognosis for vision is good. Some heterozygotes do show clinical symptoms. In a large Dutch pedigree we performed DNA analysis in order to localize the KFSD gene. In 54 individuals, including 21 affected males, RFLP analysis was done using DNA probes covering the X chromosome. Two-point linkage analyses with 19 informative DNA markers revealed significant linkage to DNA probes on Xp21.1-p22.3. The highest lod scores of 5.70 and 4.38 were obtained with DXS41 and DXS16 at a recombination fraction of zero and 4 cM, respectively. Multipoint linkage data place KFSD between DXS16 and DXS269. Our data confirm X linkage of KFSD in this family and tentatively map the gene on Xp22.2-p21.2. Combined with clinical investigation, RFLP analysis may become an important tool in carrier detection.     

CRX controls retinal expression of the X-linked juvenile retinoschisis (RS1) gene

X-linked juvenile retinoschisis is a heritable condition of the retina in males caused by mutations in the RS1 gene. Still, the cellular function and retina-specific expression of RS1 are poorly understood. To address the latter issue, we characterized the minimal promoter driving expression of RS1 in the retina. Binding site prediction, site-directed mutagenesis, and reporter assays suggest an essential role of two nearby cone-rod homeobox (CRX)-responsive elements (CRE) in the proximal −177/+32 RS1 promoter. Chromatin immunoprecipitation associates the RS1 promoter in vivo with CRX, the coactivators CBP, P300, GCN5 and acetylated histone H3. Transgenic Xenopus laevis expressing a green fluorescent protein (GFP) reporter under the control of RS1 promoter sequences show that the −177/+32 fragment drives GFP expression in photoreceptors and bipolar cells. Mutating either of the two conserved CRX binding sites results in strongly decreased RS1 expression. Despite the presence of sequence motifs in the promoter, NRL and NR2E3 appear not to be essential for RS1 expression. Together, our in vitro and in vivo results indicate that two CRE sites in the minimal RS1 promoter region control retinal RS1 expression and establish CRX as a key factor driving this expression.     

A member of a gene family on Xp22.3, VCX-A, is deleted in patients with X-linked nonspecific mental retardation

X-linked nonspecific mental retardation (MRX) has a frequency of 0.15% in the male population and is caused by defects in several different genes on the human X chromosome. Genotype-phenotype correlations in male patients with a partial nullisomy of the X chromosome have suggested that at least one locus involved in MRX is on Xp22.3. Previous deletion mapping has shown that this gene resides between markers DXS1060 and DXS1139, a region encompassing approximately 1.5 Mb of DNA. Analyzing the DNA of 15 males with Xp deletions, we were able to narrow this MRX critical interval to approximately 15 kb of DNA. Only one gene, VCX-A (variably charged, X chromosome mRNA on CRI-S232A), was shown to reside in this interval. Because of a variable number of tandem 30-bp repeats in the VCX-A gene, the size of the predicted protein is 186-226 amino acids. VCX-A belongs to a gene family containing at least four nearly identical paralogues on Xp22.3 (VCX-A, -B, -B1, and -C) and two on Yq11.2 (VCY-D, VCY-E), suggesting that the X and Y copies were created by duplication events. We have found that VCX-A is retained in all patients with normal intelligence and is deleted in all patients with mental retardation. There is no correlation between the presence or absence of VCX-B1, -B, and VCX-C and mental status in our patients. These results suggest that VCX-A is sufficient to maintain normal mental development.