Further localization of X-linked hydrocephalus in the chromosomal region Xq28

X-linked hydrocephalus (HSAS) is the most frequent genetic form of hydrocephalus. Clinical symptoms of HSAS include hydrocephalus, mental retardation, clasped thumbs, and spastic paraparesis. Recently we have assigned the HSAS gene to Xq28 by linkage analysis. In the present study we used a panel of 18 Xq27-q28 marker loci to further localize the HSAS gene in 13 HSAS families of different ethnic origins. Among the Xq27-q28 marker loci used, DXS52, DXS15, and F8C gave the highest combined lod scores, of 14.64, 6.53 and 6.33, respectively, at recombination fractions of .04, 0, and .05, respectively. Multipoint linkage analysis localizes the HSAS gene in the telomeric part of the Xq28 region, with a maximal lod score of 20.91 at 0.5 cM distal to DXS52. Several recombinations between the HSAS gene and the Xq28 markers DXS455, DXS304, DXS305, and DXS52 confirm that the HSAS locus is distal to DXS52. One crossover between HSAS and F8C suggests that HSAS gene to be proximal to F8C. Therefore, data from multipoint linkage analysis and the localization of key crossovers indicate that the HSAS gene is most likely located between DXS52 and F8C. This high-resolution genetic mapping places the HSAS locus within a region of less than 2 Mb in length, which is now amenable to positional cloning.     

Myotubular Myopathy in a Girl with a Deletion at Xq27-q28 and Unbalanced X Inactivation Assigns the MTMI Gene to a 600-kb Region

A young girl with a clinically moderate form of myotubular myopathy was found to carry a cytogenetically detectable deletion in Xq27-q28. The deletion had occurred de novo on the paternal X chromosome. It encompasses the fragile X (FRAXA) and Hunter syndrome (IDS) loci, and the DXS304 and DXS455 markers, in Xq27.3 and proximal Xq28. Other loci from the proximal half of Xq28 (DXS49, DXS256, DXS258, DXS305, and DXS497) were found intact. As the X-linked myotubular myopathy locus (MTM1) was previously mapped to Xq28 by linkage analysis, the present observation suggested that MTM1 is included in the deletion. However, a significant clinical phenotype is unexpected in a female MTM1 carrier. Analysis of inactive X-specific methylation at the androgen receptor gene showed that the deleted X chromosome was active in ~80% of leukocytes. Such unbalanced inactivation may account for the moderate MTM1 phenotype and for the mental retardation that later developed in the patient. This observation is discussed in relation to the hypothesis that a locus modulating X inactivation may lie in the region. Comparison of this deletion with that carried by a male patient with a severe Hunter syndrome phenotype but no myotubular myopathy, in light of recent linkage data on recombinant MTM1 families, led to a considerable refinement of the position of the MTM1 locus, to a region of ~600 kb, between DXS304 and DXS497.     

Multipoint genetic mapping of the Xq26-q28 region in families with fragile X mental retardation and in normal families reveals tight linkage of markers in q26–q27

Summary The q26–q28 region of the human X chromosome contains several important disease loci, including the locus for the fragile X mental retardation syndrome. We have characterized new polymorphic DNA markers useful for the genetic mapping of this region. They include a new BclI restriction fragment length polymorphism (RFLP) detected by the probe St14-1 (DXS52) and which may therefore be of diagnostic use in hemophilia A families. A linkage analysis was performed in fragile X families and in large normal families from the Centre d'Etude du Polymorphisme Humain (CEPH) by using seven polymorphic loci located in Xq26-q28. This multipoint linkage study allowed us to establish the order centromere-DXS100-DXS86-DXS144-DXS51-F9-FRAX-(DXS52-DXS15). Together with other studies, our results define a cluster of nine loci that are located in Xq26-q27 and map within a 10 to 15 centimorgan region. This contrasts with the paucity of markers (other than the fragile X locus) between the F9 gene in q27 and the G6PD cluster in q28, which are separated by about 30% recombination.     

High-resolution mapping of the X-linked hypohidrotic ectodermal dysplasia (EDA) locus

The X-linked hypohidrotic ectodermal dysplasia (EDA) locus has been previously localized to the subchromosomal region Xq11-q21.1. We have extended our previous linkage studies and analyzed linkage between the EDA locus and 10 marker loci, including five new loci, in 41 families. Four of the marker loci showed no recombination with the EDA locus, and six other loci were also linked to the EDA locus with recombination fractions of .009-.075. Multipoint analyses gave support to the placement of the PGK1P1 locus proximal to the EDA locus and the DXS453 and PGK1 loci distal to EDA. Further ordering of the loci could be inferred from a human/rodent somatic cell hybrid derived from an affected female with EDA and an X;9 translocation and from studies of an affected male with EDA and a submicroscopic deletion. Three of the proximal marker loci, which showed no recombination with the EDA locus, when used in combination, were informative in 92% of females. The closely linked flanking polymorphic loci DXS339 and DXS453 had heterozygosities of 72% and 76%, respectively, and when used jointly, they were doubly informative in 52% of females. The human DXS732 locus was defined by a conserved mouse probe pcos169E/4 (DXCrc169 locus) that cosegregates with the mouse tabby (Ta) locus, a potential homologue to the EDA locus. The absence of recombination between EDA and the DXS732 locus lends support to the hypothesis that the DXCrc169 locus in the mouse and the DXS732 locus in humans may contain candidate sequences for the Ta and EDA genes, respectively.     

Linkage studies in X-linked Alport's syndrome

Summary Four kindreds segregating for Alport's syndrome (ASLN) compatible with a X-linked inheritance were studied for linkage with polymorphic markers of the human X chromosome. No recombinant was observed between the ASLN locus and the DXS101 and DXS94 loci, the maximum lod scores were z=3.93 and 3.50 respectively. Linkage data between the ASLN locus and the other genetic markers used in the present study are in keeping with the assignment of the mutation to the proximal Xq arm.     

Linkage relationship between incontinentia pigmenti (IP2) and nine terminal X long arm markers

Summary Linkage data for familial incontinentia pigmenti (IP2) and nine X chromosomal markers are reported. Previously found linkage between IP2 and the DXS52 locus is confirmed with the maximum lod score of 6.19 at a recombination fraction of 0.03. Linkage is also established with loci DXS134, DXS15 and DXS33. Multipoint analysis allows us to localize the IP2 locus outside a block of seven linked markers of the Xq28 region.     

New informative polymorphism at the DXS304 locus,a close distal marker for the fragile X locus

Summary The polymorphic DNA marker DXS304 detected by probe U6.2 has recently been shown to be closer to the fragile X locus than previously available markers. Its usefulness has however been limited by its relatively low heterozygosity. We have isolated, by cosmid cloning, a 67 kilobase region around probe U6.2 and have characterized a new probe (U6.2-20E) that detects BanI and BstEII restriction fragment length polymorphisms (RFLPs). The BanI RFLP has a heterozygosity of 0.49 and is in partial linkage disequilibrium with the previously described polymorphism, with a combined heterozygosity of 0.63. Furthermore, we have found that the U6.2 original probe, which probably detects an insertion-deletion polymorphism, is also informative in BanI digests. Thus, the two informative RFLPs at the DXS304 locus can be conveniently tested in a single hybridization with a single digest. An updated linkage analysis confirms that DXS304 is distal to the fragile X locus. This informative locus can now be used effectively for genetic mapping of the Xq27–q28 region, and for diagnostic applications in fragile X or Hunter syndrome families.     

New polymorphisms at the DXS98 locus and confirmation of its location proximal to FRAXA by in situ hybridization.

The locus DXS98, detected with the 1.5-kb anonymous probe p4D-8, was recently shown to be closely linked and proximal to the locus for the fragile X syndrome, with theta = .05 at lod = 3.406, by utilizing a limited number of meioses informative for a two-allele MspI RFLP. Because DXS98 may be the closest available marker to the fragile X locus (FRAXA), we sought to increase its utility for linkage studies by extending its PIC and confirming its localization to Xq27, proximal to FRAXA. We have isolated 15 kb of genomic DNA (lambda 4D8-3) from the DXS98 locus by using p4D-8 to screen a genomic phage library containing partial Sau3A-digested human DNA. Three additional RFLPs for the enzymes BglII and XmnI were found by using the entire lambda 4D8-3 as probe. Combined heterozygosity for the four RFLPs in 25 unrelated females was 48%, as compared with only 28% when the MspI RFLP alone was used. In situ hybridization of unique sequences from lambda 4D8-3 was performed on metaphase chromosomes of lymphocytes and lymphoblasts from patients with the fragile X syndrome. Grains on the X chromosome were significantly clustered at band Xq27. Following fragile site induction, all nine grains in the q27-28 region were proximal to the fragile site. Confirmation of the location of DXS98 proximal to FRAXA and the new RFLPs at this locus make DXS98 more useful for linkage analysis and physical mapping in the region of the fragile X mutation.     

Linkage analysis of families with fragile-X mental retardation, using a novel RFLP marker (DXS 304).

A new polymorphic DNA marker U6.2, defining the locus DXS304, was recently isolated and mapped to the Xq27 region of the X chromosome. In the previous communication we describe a linkage study encompassing 16 fragile-X families and using U6.2 and five previously described polymorphic markers at Xq26-q28. One recombination event was observed between DXS304 and the fragile-X locus in 36 informative meioses. Combined with information from other reports, our results suggest the following order of the examined loci on Xq: cen-F9-DXS105-DXS98-FRAXA-DXS304-(DXS52-F8 -DXS15). The locus DXS304 is closely linked to FRAXA, giving a peak lod score of 5.86 at a corresponding recombination fraction of .00. On the basis of the present results, it is apparent that U6.2 is a useful probe for carrier and prenatal diagnosis in fragile-X families.     

Genetic mapping of two new DNA markers in Xq26-q28 relative to the fragile-X syndrome locus.

We have characterized and genetically mapped two new DNA markers (DXS311 and DXS312) with respect to 10 existing loci in Xq26----Xq28 in a set of 15 families in which the fragile-X [fra(X)] syndrome was segregating. Two-point and multipoint linkage analyses were performed taking into account the incomplete penetrance of the fra(X) mutation. The most likely order on the basis of these data is centromere-DXS79-DXS10-DXS311-DXS86-(F9-DXS99 )-(DXS98-DXS312)-fra(X)-DXS52- DXS15-F8C-telomere. DXS98 and one of the new loci, DXS312, were found to be the proximal markers closest to the fra(X) locus. The order F9-(DXS98-DXS312)-fra(X) was found to be 5.9 x 10(4) times more likely than the order (DXS98-DXS312)-F9-fra(X).     

Genetic mapping of new RFLPs at Xq27-q28.

The development of the human gene map in the region of the fragile X mutation (FRAXA) at Xq27 has been hampered by a lack of closely linked polymorphic loci. The polymorphic loci DXS369 (detected by probe RN1), DXS296 (VK21A, VK21C), and DXS304 (U6.2) have recently been mapped to within 5 cM of FRAXA. The order of loci near FRAXA has been defined on the basis of physical mapping studies as cen-F9-DXS105-DXS98-DXS369-DXS297-FRAXA-++ +DXS296-IDS-DXS304-DXS52-qter. The probe VK23B detected HindIII and XmnI restriction fragment length polymorphisms (RFLPs) at DXS297 with heterozygote frequencies of 0.34 and 0.49, respectively. An IDS cDNA probe, pc2S15, detected StuI and TaqI RFLPs at IDS with heterozygote frequencies of 0.50 and 0.08, respectively. Multipoint linkage analysis of these polymorphic loci in normal pedigrees indicated that the locus order was F9-(DXS105, DXS98)-(DXS369, DXS297)-(DXS293,IDS)-DXS304-DXS52. The recombination fractions between adjacent loci were F9-(0.058)-DXS105-(0.039)-DXS98-(0.123)-DXS369-(0.00)- DXS297-(0.057)-DXS296- (0.00)-IDS-(0.012)-DXS304-(0.120)-DXS52. This genetic map will provide the basis for further linkage studies of both the fragile X syndrome and other disorders mapped to Xq27-q28.     

Multipoint linkage analysis of loci in the proximal long arm of the human X chromosome: application to mapping the choroideremia locus.

Choroideremia (McK30310), an X-linked retinal dystrophy, causes progressive night blindness, visual field constriction, and eventual central blindness in affected males by the third to fourth decade of life. The biochemical basis of the disease is unknown, and prenatal diagnosis is not available. Subregional localization of the choroideremia locus to Xq13-22 was accomplished initially by linkage to two restriction-fragment-length polymorphisms (RFLPs), DXYS1 (Xq13-q21.1) and DXS3 (Xq21.3-22). We have now extended our linkage analysis to 12 families using nine RFLP markers between Xp11.3 and Xq26. Recombination frequencies of 0%-4% were found between choroideremia and five markers (PGK, DXS3, DXYS12, DXS72, and DXYS1) located in Xq13-22. The families were also used to measure recombination frequencies between RFLP loci to provide parameters for the program LINKMAP. Multipoint analysis with LINKMAP provided overwhelming evidence for placing the choroideremia locus within the region bounded by DXS1 (Xq11-13) and DXS17 (Xq21.3-q22). At a finer level of resolution, multipoint analysis suggested that the choroideremia locus was proximal to DXS3 (384:1 odds) rather than distal to it. Data were insufficient, however, to distinguish between a gene order that puts choroideremia between DXS3 and DXYS1 and one that places choroideremia proximal to both RFLP loci. These results provide linkage mapping of choroideremia and RFLP loci in this region that will be of use for further genetic studies as well as for clinical applications in this and other human diseases.     

Assignment of Emery-Dreifuss muscular dystrophy to the distal region of Xq28: the results of a collaborative study.

Emery-Dreifuss muscular dystrophy (EDMD) is an X-linked humeroperoneal dystrophy associated with cardiomyopathy that is distinct from the Duchenne and Becker forms of X-linked muscular dystrophy. Linkage analysis has assigned EDMD to the terminal region of the human X chromosome long arm. We report here further linkage analysis in two multigenerational EDMD families using seven Xq28 marker loci. Cumulative lod scores suggest that EDMD is approximately 2 cM from DXS52 (lod = 15.67) and very close to the factor VIII (F8C) and the red/green color pigment (R/GCP) loci, with respective lod scores of 9.62 and 10.77, without a single recombinant. Several recombinations between EDMD and three proximal Xq28 markers suggest that the EDMD gene is located in distal Xq28. Multipoint linkage analysis indicates that the odds are 2,000:1 that EDMD lies distal to DXS305. These data substantially refine the ability to perform accurate carrier detection, prenatal diagnosis, and the presymptomatic diagnosis of at-risk males for EDMD by linkage analysis. The positioning of the EDMD locus close to the loci for F8C and R/GCP will assist in future efforts to identify and isolate the disease gene.     

Oto-palato-digital syndrome type I: further evidence for assignment of the locus to Xq28

Summary The oto-palado-digital syndrome (OPD) is a rare X-linked disease with diagnostic skeletal features, conduction deafness, cleft palate and mild mental retardation. Differences in clinical presentation between families have led investigators to classify OPD into two subtypes: type I and type II. A linkage study performed in one family segregating for OPD I has recently suggested linkage to three marker loci: DXS15, DXS52 at Xq28, and DXS86 at Xq26. We have investigated an additional OPD I family for linkage by using distal chromosome Xq DNA probes. The linkage data and the analysis of recombination events that have occurred in this family excluded, definitively, the Xq26 region for OPD I, and provide further support for mapping the mutant gene close to the cluster of tightly linked markers DXS15, DXS52 and DXS305 at Xq28.     

Genetic mapping of DNA segments relative to the locus for the fragile-X syndrome at Xq27.3.

We have tested linkage between the locus for the fragile-X [fra(X)] syndrome at Xq27.3 and five polymorphic restriction sites identified by four DNA probes mapping distal to Xq26.1. A maximum distance of approximately 15 centimorgans (cM) between Xq27.3 and the marker loci mapping to this region was predicted based on the physical chromosome length. Close linkage between the disease and marker loci was excluded for probes DXS19 and DXS37 (theta = .05, Z = -2.94 and Z = -4.17, respectively). These marker loci were estimated to be less than five cM apart but approximately 40 cM proximal to the fragile site, indicating that there is a significantly greater frequency of recombination in this region of the X chromosome than expected from the physical length. Linkage results for the other marker loci and the fra(X) syndrome were inconclusive. However, the pX45d probe locus appears very closely linked to the factor IX locus (Z = 1.94 at theta = 0) and is approximately 20 cM proximal to Xq27.3. A relative map of the polymorphic restriction sites, fra(X) syndrome locus, and factor IX locus was constructed by maximizing lod scores over the Xq26.1----q27.3 region.     

Linkage relationships of the Wiskott-Aldrich syndrome to 10 loci in the pericentromeric region of the human X chromosome

Twelve families with Wiskott-Aldrich syndrome (WAS) were studied by linkage analysis using 10 polymorphic marker loci from the X-chromosome pericentromeric region. The results confirm close linkage of WAS to the DXS14, DXS7, TIMP, and DXZ1 loci and are consistent with previous data suggesting that WAS maps to the proximal Xp and is flanked by the DXS14 and DXS7 loci. The strongest linkage (Z = 10.19 at theta = 0.00) was found to be between WAS and the hypervariable DXS255 locus, a marker locus already mapped between DXS7 and DXS14 and which was informative for all meioses included in this analysis. Linkage of the WAS to two pericentromeric Xq loci, DXS1 and PGK1, was also established. On the basis of these results, accurate predictive testing should now be feasible in the majority of WAS families.     

Mapping of the Emery-Dreifuss gene through reconstruction of crossover points in two Italian pedigrees

Summary Two unrelated pedigrees, which show recurrence of Emery-Dreifuss muscular dystrophy (EDMD) in three generations, have been studied using 13 X-linked DNA polymorphisms and somatic cell hybrids to establish the phase of the corresponding alleles in some obligate carriers. The reconstruction of cross-over points on the X chromosomes carrying the EDMD gene excludes from mapping most regions of the X chromosome except for the terminal portion of Xq. Pooled linkage data from the two pedigrees confirm the linkage previously reported with locus DXS15. A cross-over in a carrier female suggests that the EDMD gene is probably located distally to DXS15. In addition the recombinant meioses from one of the two pedigrees suggest the following order for some Xq polymorphic loci: DXS1 (DXYS1-DXS178) DXS42 (F9-DXS15).     

Physical mapping of the factor VIII gene proximal to two polymorphic DNA probes in human chromosome band Xq28: implications for factor VIII gene segregation analysis

Genomic DNA segments for the coagulation factor VIIIc gene (F8C), which exhibits only limited restriction length polymorphism, map to the proximal region of band Xq28 by somatic cell hybridization analysis and in situ hybridization. Using somatic cell hybrids, we have obtained data which place probes DX13 (used to detect locus DXS15) and St14 (used to detect DXS52) distal to F8C, within band Xq28. Previous studies have mapped the factor IX gene (F9) and probe 52A (used to detect DXS51) proximal to F8C, in Xq26----q27 and Xq27, respectively (Camerino et al., 1984; Drayna et al., 1984; Mattei et al., 1985). Thus, the relative order of genetic marker loci in the Xq27----qter region is most likely cen-F9-DXS51-F8C-(DXS15, DXS52)-Xqter. The collection of these molecular probes is thus potentially useful in three-factor crosses of factor VIII gene segregation.     

A linkage study of Emery-Dreifuss muscular dystrophy

Summary We have searched for linkage between polymorphic loci defined by DNA markers on the X chromosome and X-linked Emery-Dreifuss muscular dystrophy (EDMD). There are high recombination rates between EDMD and the Xp loci known to be linked to Becker and Duchenne muscular dystrophy. There is a suggestion of linkage between EDMD and the loci DXS52 and DXS15, defined by probes St 14 and DX13 respectively, located at Xq28. for DXS15=1.14 at =0.15. This is in agreement with the previously reported linkage between a disorder strongly resembling EDMD and colour-blindness (Thomas et al. 1972), suggesting that there is a second locus on the X chromosome concerned with muscle integrity.     

The gene for X-linked hydrocephalus maps to Xq28, distal to DXS52.

We report the study of five independent X-linked hydrocephalus (HSAS1) families with polymorphic DNA markers of the Xq28 region. A total of 58 individuals, including 7 living affected males and 22 obligate carriers, have been studied. Maximum lod score was 7.21 at theta = 2.40% for DXS52 (St14-1). A single recombination event was observed between this marker and the HSAS1 locus. Other markers studied were DXS296 (Z = 2.02 at theta = 2.5%), DXS304 (Z = 4.37 at theta = 7.8%), DXS74 (Z = 3.50 at theta = 0%), DXS15 (Z = 1.96 at theta = 5.7%), DXS134 (Z = 3.31 at theta = 0%), and F8C (Z = 5.79 at theta = 0%). These data confirm the localization of the HSAS1 gene to Xq28 and provide evidence for genetic homogeneity of this syndrome. In addition, examination of two obligate recombinant meioses along with multipoint linkage analysis supports the distal localization of the HSAS1 locus with respect to the DXS52 cluster. These observations are of potential interest for future studies aimed at HSAS1 gene characterization.