Improved carrier detection of haemophilia A using novel RFLPs at the DXS115 (767) locus

Summary Two novel restriction fragment length polymorphisms (RFLPs) around the DXS115 (767) locus, detectable with the restriction enzymes MspI, are described. Since DXS115 is closely linked to the factor VIII gene (F8C), the MspI RFLP was employed in haemophilia A carrier detection. The utility of these RFLPs lies in the increased applicability and accuracy of diagnoses carried out in cases where available intragenic markers are uninformative.     

Genetic and physical mapping of a novel region close to the fragile X site on the human X chromosome

We report the isolation and characterization of a novel DNA marker (1A1) in Xqter in the region of the fragile X. Genetic studies in families segregating for the fragile X syndrome suggest that 1A1 lies between the disease mutation and the distal locus, DXS52. Studies in normal and fragile X families show that 1A1 is tightly linked to DXS52 (Zmax = 17.20; theta max = 0.03) and F8 (Zmax = 7.01; theta max = 0.08). Multipoint mapping of families supports the order Xcen-DXS105-FRAXA-1A1-DXS52-(F8, DXS115)-Xqter. Pulsed-field gel electrophoresis (PFGE) studies demonstrate that 1A1 defines a new region of at least 2 Mb of DNA not physically linked to DXS52 or F8, thus extending the physical map of Xq27-qter to over 4 Mb. Complex partial digestion PFGE patterns, probably due to differing degrees of methylation, are observed with 1A1 in unrelated normal and fragile-X-positive individuals, whereas other distal markers give uniform digestion profiles. Physical data suggest that 1A1 lies in a region less CpG rich than other distal markers in Xq27-qter.     

Toward a physical map of the Xq28 region in man: Linking color vision, G6PD, and coagulation factor VIII genes to an X-Y homology region

We are using pulsed-field gel electrophoresis (PFGE) to establish a physical map of the human Xq28 region. We have identified a new probe 35.239 (DXYS64), localized in Xq28 by somatic hybrid mapping and belonging to a region of greater than 99% homology between the X and the Y chromosomes. PFGE data show that probes 35.239 and the polymorphic locus DXS115 (probe 767) map within a common 300-kb BssHII fragment. Both probes, in addition, hybridize to 575-kb BssHII and 590-kb ClaI fragments that contain the gene coding for coagulation factor VIII (F8C). The order F8C-DXS115-DXYS64 could be determined. Our results also provide evidence for linkage between the red/green color vision locus (RCP,GCP) and probes MD13 and T1.7 (GdX, DXS254) within a 750-kb ClaI fragment. Although the latter two probes are located within 50 kb of the 3' end of the G6PD gene, a G6PD cDNA probe did not hybridize to this fragment. G6PD, on the other hand, could be linked to F8C on a 290-kb BssHII fragment. All these data allow us to propose the order (RCP,GCP)-MD13-GdX-G6PD-F8C-DXS115-DXYS 64. We also linked probes St14 (DXS52), MN12 (DXS33), and DX13 (DXS15) to a member of a small family of X-linked dispersed sequences (DNF22S3) within a 575-kb BssHII fragment. The preliminary physical map presented here should be useful for further fine mapping of disease genes in the Xq28 region and should be helpful in orientating efforts toward the cloning of sequences close to the fragile X syndrome.     

Evidence supporting tight linkage of X-linked Emery-Dreifuss muscular dystrophy to the factor VIII:C gene.

In a large German family with Emery-Dreifuss muscular dystrophy (EDMD) linkage analysis was performed using the factor IX gene (F9), the factor VIII:C gene (F8), the anonymous DNA probe DXS52, and DXS15 as markers. Tight linkage was found between the EDMD locus and the F8 probe (Zmax = 1.19; theta max = 0.00), DXS15 (Zmax = 1.75; theta max = 0.00) and DXS52 (Zmax = 2.26; theta max = 0.00). Weak linkage was found to F9 (Zmax = 0.02; theta max = 0.43). The data from the literature and our results suggest that the gene locus of EDMD is close to F8 (confidence interval theta = 0-0.07). The new linkage data are useful for carrier detection and diagnosis of EDMD patients before onset of major clinical signs.     

Physical mapping studies on the human X chromosome in the region Xq27-Xqter

We have characterized three terminal deletions of the long arm of the X chromosome. Southern analysis using Xq27/q28 probes suggests that two of the deletions have breakpoints near the fragile site at Xq27.3. Flow karyotype analysis provides an estimate of 12 X 10(6) bp for the size of the deleted region. We have not detected the deletion breakpoints by pulsed-field gel electrophoresis (PFGE) using the closet DNA probes, proximal to the fragile site. The physical distance between the breakpoints and the probes may therefore be several hundred kilobases. The use of the deletion patients has allowed a preliminary physical map of Xq27/28 to be constructed. Our data suggest that the closest probes to the fragile site on the proximal side are 4D-8 (DXS98), cX55.7 (DXS105), and cX33.2 (DXS152). PFGE studies provide evidence for the physical linkage of 4D-8, cX55.7, and cX33.2. We have also found evidence for the physical linkage of F8C, G6PD, and 767 (DXS115), distal to the fragile site.     

Genetic mapping of the Xq27-q28 region: new RFLP markers useful for diagnostic applications in fragile-X and hemophilia-B families.

We have characterized and genetically mapped new polymorphic DNA markers in the q27-q28 region of the X chromosome. New informative RFLPs have been found for DXS105, DXS115, and DXS152. In particular, heterozygosity at the DXS105 locus has been increased from 25% to 52%. We have shown that DXS105 and DXS152 are contained within a 40-kb region. A multipoint linkage analysis was performed in fragile-X families and in large normal families from the Centre d'Etudes du Polymorphisme Humain (CEPH). This has allowed us to establish the order centromere-DXS144-DXS51-DXS102-F9-DXS105-FRAX A-(F8, DXS15, DXS52, DXS115). DXS102 is close to the hemophilia-B locus (z[theta] = 13.6 at theta = .02) and might thus be used as an alternative probe for diagnosis in Hemophila-B families not informative for intragenic RFLPs. DXS105 is 8% recombination closer to the fragile-X locus than F9 (z[theta] = 14.6 at theta = .08 for the F9-DXS105 linkage) and should thus be a better marker for analysis of fragile-X families. However, the DXS105 locus appears to be still loosely linked to the fragile-X locus in some families. The multipoint estimation for recombination between DXS105 and FRAXA is .16 in our set of data. Our data indicate that the region responsible for the heterogeneity in recombination between F9 and the fragile-X locus is within the DXS105-FRAXA interval.     

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.     

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.     

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.     

Linkage analysis in X-linked adrenoleukodystrophy and application in post-and prenatal diagnosis

Summary We have performed linkage analysis with the DNA markers DXS52 and the clotting factor VIII gene (F8C), in several large families with X-linked adrenoleukodystrophy (ALD). The tight linkage to DXS52 could be extended giving a maximal LOD score of 22.5 at 1 cM. F8C was also tightly linked to ALD with a maximal LOD score of 7.8 without recombination. Multipoint linkage analysis with the markers DXS304, DXS52, and F8C indicated that both the gene for ALD and for F8C are distal to DXS52. In four patients with ALD, no major structural rearrangement in the Xqter region was observed; in particular, there were no abnormalities in the vision blindness genes. DNA analysis appeared to be of use in determination of the carrier status of females at risk, for the determination of the origin of the mutation in a particular family, and for prenatal diagnosis.     

Investigation of factor VIII:C gene restriction fragment length polymorphisms and search for deletions in hemophiliac subjects in Algeria

Summary The frequency of alleles for intragenic (intron 17 and intron 25) and extragenic (DXS15 and DXS52) F8C RFLPs was investigated in the Algerian population. Altogether 287 X chromosomes (97 males and 95 females) were studied. The allele frequencies found with the two intragenic F8C RFLPs were not substantially different from those reported in a Mediterranean population. At the highly polymorphic extragenic DXS52 locus the distribution in Algeria differed from that found in France. A new allele (14kb), called 1 DZ, was found in 3.1% of the chromosomes. Fifty-one families with hemophilia A were studied with the same probes (374 subjects). Of the females, 94% were informative for at least one intra- or extragenic RFLP. Two recombinations were found between DXS52 and F8C, of which one occurred between the DXS15, DXS52 block and F8C, indicating that the two anonymous loci are on the same side of the F8C gene. Only two obvious gene deletions were observed in 73 unrelated hemophiliacs: one encompassed exons 14–22 (about 4.3 kb of cDNA and 36kb of genomic DNA); the other removed the last exon (exon 26, representing 2 kb of cDNA).     

A new polymorphic marker very closely linked to DXS52 in the q28 region of the human X chromosome

Summary We have isolated an X chromosome probe, St35.691 (DXS305), which detects two RFLPs with TaqI and PstI, whose combined heterozygosity is about 60%. This probe has been assigned to Xq28 by physical and genetic mapping and is very closely linked to DXS52, DXS15, and the coagulation factor VIII gene (F8C). The best estimate of the recombination fraction for the DXS52-DXS305 interval is 0.014, with a lod score of 50.1. Multipoint analysis places DXS305 on the same side of F8C as DXS52, but complete ordering of the three loci was not possible with our present data. This highly informative marker should be useful in the precise mapping of the many disease genes that have been assigned to the Xq28 band.     

Waisman syndrome, a human X-linked recessive basal ganglia disorder with mental retardation: localization to Xq27.3-qter.

Linkage of the gene responsible for an X-linked early onset parkinsonism disorder with mental retardation (McKusick 311510) to DNA probes that detect restriction fragment length polymorphisms is described. The disease gene is linked to the F8C gene, and to DNA probes detecting polymorphic loci DXS52, DXS15, DXS134, and DXS374 with maximum lod scores at theta = 0 of 5.08, 5.19, 5.00, 5.03, and 4.46, respectively. Multipoint linkage analysis gives a maximum multipoint lod score of 6.75 at the F8C gene. This places the disease gene in chromosomal region Xq27.3-qter.     

Linkage studies in a large fragile X family.

We have analyzed the segregation of five loci in the region Xq27/28 in a large family affected by the fragile X syndrome. The marker DXS115 (767) is shown to be polymorphic with the enzyme PstI, as well as with BstXI. This marker will be useful in the analysis of both fragile X and haemophilia A families. The data presented here are consistent with the following order of loci: Xcen-F9-DXS105(cX55.7,55E)-DXS98(4D-8)- FRAXA-DXS52(St14)-DXS115(767)-qter.     

Linkage to Xq28 in a family with nonspecific X-linked mental retardation

Linkage analysis was performed in a family with nonspecific X-linked mental retardation (MRX). Affected individuals had no clinical characteristics other than mental retardation. Linkage was detected to the marker loci DXS477, DXS465, DXS52, DXS15 and F8C with maximum lod scores of 1.70, 1.32, 2.52, 1.70, and 1.09, respectively ( = 0.0). The results strongly indicate that the gene for mental retardation in the family studied maps close to DXS52.     

A 1.6-Mb contig of yeast artificial chromosomes around the human factor VIII gene reveals three regions homologous to probes for the DXS115 locus and two for the DXYS64 locus.

Two yeast artificial chromosome (YAC) libraries were screened for probes in Xq28, around the gene for coagulation factor VIII (F8). A set of 30 YACs were recovered and assembled into a contig spanning at least 1.6 Mb from the DXYS64 locus to the glucose 6-phosphate dehydrogenase gene (G6PD). Overlaps among the YACs were determined by several fingerprinting techniques and by additional probes generated from YAC inserts by using Alu-vector or ligation-mediated PCR. Analysis of more than 30 probes and sequence-tagged sites (STSs) made from the region revealed the presence of several homologous genomic segments. For example, a probe for the DXYS64 locus, which maps less than 500 kb 5' of F8, detects a similar but not identical locus between F8 and G6PD. Also, a probe for the DXS115 locus detects at least three identical copies in this region, one in intron 22 of F8 and at least two more, which are upstream of the 5' end of the gene. Comparisons of genomic and YAC DNA suggest that the multiple loci are not created artifactually during cloning but reflect the structure of uncloned human DNA. On the basis of these data, the most likely order for the loci analyzed is tel-DXYS61-DXYS64-(DXS115-3-DXS115-2)-5'F8-(D XS115-1)-3'F8-G6PD.     

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.     

The gene for incontinentia pigmenti is assigned to Xq28

A linkage study of eight families with incontinentia pigmenti (IP) has been performed, and linkage to site DXS52 has been established. We suggest that the IP locus lies in the Xq terminal region on the long arm of the X chromosome.     

Nephrogenic diabetes insipidus: close linkage with markers from the distal long arm of the human X chromosome

Summary Ten families with nephrogenic diabetes insipidus (NDI) have been analysed for restriction fragment length polymorphisms (RFLPs). A search for linkage was performed using various chromosome-specific single-copy DNA probes of known regional assignment to the human X chromosome. Close linkage was found between the disease locus and the markers DXS52, DXS15, DXS134 and the F8 gene. This result assigns the NDI gene to the subtelomeric region of the long arm of the X chromosome. The regional localization of the gene by the identification of closely linked markers should have repercussions for genetic counselling and prevention in NDI families.     

Ethnic polymorphism of DXS52 (St 14) locus linked to coagulation factor VIII gene in Argentina

Sixty-five individuals belonging to 16 argentinian families of hemophilia A were studied using the St 14 probe (DXS52 locus). This probe is widely used for carrier detection and prenatal diagnosis, despite the risk of recombination between the factor VIII gene and the DXS52 locus, because of its high informativity. The families are divided in two groups: one group constituted only of metis of Indians according to interview and morphotype and a second group of caucasoids (Spanish essentially and Italian). In this study we have shown some ethnic variations of the TaqI RFLPs in the DXS52 locus. In the allelic system I, (which alleles are numbered from 1 to 8) we have noted an over representation of the larger alleles (2 and 3) and of the allele 8 in both Argentinian groups when compared to the caucasian population already studied in our laboratory. The additional polymorphic TaqI site giving the beta band in the system II (alpha and beta bands) is found more frequently in the Argentinian families than in Caucasians. Some other additional polymorphic sites have been found in generally constant bands giving additional allelic systems, in metis families.