Physical mapping of DXS134 close to the DXS52 locus

Summary The locus DXS134 (cpX67) has been physically linked to the cluster of polymorphic loci DXS52, DXS15, and DXS33. A comparison of physical and genetic distance indicates a high rate of recombination in this region.     

Genetic mapping of two loci,DXS454 and DXS458, with respect to the X-linked agammaglobulinemia gene locus

The dinucleotide repeat sequences at the DXS454 and DXS458 loci have been mapped genetically to Xq22, to the interval between DXS3 and DXS17. We have now mapped them with respect to XLA and five other loci, to within the DXS3 to XLA interval. The more precise localisation of these polymorphic loci will be useful for the fine-mapping of disease loci on the long arm of the X chromosome and enable these probes to be used for prenatal diagnosis and carrier status determination in families with XLA.     

Identification of CpG islands around the DXS178 locus in the region of the X-linked agammaglobulinaemia gene locus in Xq22

The X-linked agammaglobulinaemia (XLA) gene locus has previously been mapped to Xq22. Genetic linkage analysis has shown tight linkage between the disease and the DXS178 locus and that DXS3 and DXS94 are the closest proximal and distal flanking markers, respectively, separated by a genetic distance of 10–12 cM. We attempted to construct a physical map of Xq22 using pulsed field gel electrophoresis (PFGE) and rare-cutting restriction enzymes in order to obtain a finite physical value for the distance between DXS3 and DXS94. However, these attempts were hampered by the large number of rare-cutting restriction enzyme sites around the DXS178 locus, indicative of the presence of CpG rich regions of DNA. We were able to construct a physical map of the sites close to DXS178 that suggests the presence of at least three, and perhaps as many as five, CpG islands. These are arranged on either side of DXS178, extending over about 550kb of genomic DNA. Each of these regions must be considered as being associated with a potential candidate gene sequence for the XLA gene and we have initiated a chromosome walk from DXS178 to the nearest of these islands.     

Identification of a closely linked DNA marker, DXS178, to further refine the X-linked agammaglobulinemia locus

X-linked agammaglobulinemia (XLA) is an inherited recessive disorder in which the primary defect is not known and the gene product has yet to be identified. Utilizing genetic linkage analysis, we previously localized the XLA gene to the map region of Xq21.3-Xq22 with DNA markers DXS3 and DXS17. In this study, further mapping was performed with two additional DNA probes, DXS94 and DXS178, by means of multipoint analysis of 20 families in which XLA is segregating. Thirteen of these families had been previously analyzed with DXS3 and DXS17. Three crossovers were detected with DXS94 and no recombinations were found between DXS178 and the XLA locus in 9 informative families. Our results show that XLA is closely linked to DXS178 with a two-point lod score of 4.82 and a multipoint lod score of 10.24. Thus, the most likely gene order is DXS3-(XLA,DXS178)-DXS94-DXS17, with the confidence interval for location of XLA lying entirely between DXS3 and DXS94. In 2 of these families, we identified recombinants with DXS17, a locus with which recombination had not previously been detected by others in as many as 40 meiotic events. Furthermore, DXS178 is informative in both of these families and does not show recombination with the disease locus. Therefore, our results indicate that DXS178 is linked tightly to the XLA gene.     

Anderson Fabry disease,a close linkage with highly polymorphic DNA markers DXS17, DXS87 and DXS88

Summary Anderson Fabry disease is an X-linked lysosomal storage disorder caused by α-galactosidase A deficiency. Hemizygous males and some heterozygous females develop renal failure and cardiovacular complications in early adult life. We have investigated six large UK families to assess the possible linkage of five polymorphic DNA probes to the Anderson Fabry locus, previously localised to Xq21-24. No recombination was found between Anderson Fabry disease and DXS87, DXS88 and DXS17, which gave lod_max=6.4,6.4 and 5.8 respectively at θ=0.00, (upper confidence limit 0.10). DXS3 gave lod_max 2.9 at θ=0.10 (upper confidence limit 0.25). DXYS1 was excluded from linkage. The best fit map (DXYS1/DXS3) θ=0.192 (DXS17/DXS87/DXS88/Anderson Fabry locus) provided no information about the order of loci in parentheses due to the absence of recombinants. The close linkage of DXS17, DXS87 and DXS88, together with α-galactosidade A estimation, can be used for antenatal diagnosis and carrier detection until the application of a gene specific probe has been evaluated.     

Linkage analysis of seven kindreds with the X-linked lymphoproliferative syndrome (XLP) confirms that the XLP locus is near DXS42 and DXS37

Summary Analysis of seven kindreds indicates that the XLP locus exhibits 1% recombination with DXS42 (lod = 17.5) and no recombination with DXS37 (lod = 13.3).     

Localization of the microsatellite probe DXS426 between DXS7 and DXS255 on Xp and linkage to X-linked retinitis pigmentosa.

The microsatellite marker DXS426 maps to the interval Xp21.1-Xp11.21, the chromosomal region which contains two loci for X-linked retinitis pigmentosa (XLRP; RP2 and RP3). We have refined the localization of DXS426 both physically, by mapping it to a deletion which spans the interval Xp21.3-Xp11.23, and genetically, by studying multiply informative crossovers which indicate that DXS426 lies between DXS7 and DXS255 (i.e., Xp11.4-Xp11.22). As this is the region which contains the RP2 gene, RP2 families could be identified on the basis of linkage of XLRP to DXS426. Multiply informative crossovers in two RP2 families indicate that the most likely location of the RP2 gene is between DXS426 and DXS7. DXS426 is therefore an important highly informative marker for the purposes of carrier detection and early diagnosis of RP2 and for the localization of the disease gene.     

The polymorphic marker DXS304 is within 5 centimorgans of the fragile X locus

The fragile X syndrome, which is the most common cause of inherited mental retardation, poses important diagnostic problems for genetic counseling. The development of diagnostic strategies based on DNA analysis has been impaired by the lack of polymorphic markers very close to the disease locus. Here we report that the polymorphic probe U6.2 (locus DXS304) is much closer to the fragile X locus than all the previously reported markers. A recombination fraction of 0.02 between DXS304 and the fragile X locus was estimated by multipoint linkage analysis (confidence interval 0.002 to 0.05). Our data suggest that DXS304 is distal to the fragile X locus. This marker thus represents a major improvement for carrier detection and prenatal diagnosis in fragile X families.     

Molecular-genetic analysis of polymorphism of the DXS532 locus in people from the Volga-Ural region]

The DXS52 polymorphic locus mapping to the 5'-region of the blood-clotting factor VIII gene on the X chromosome was genotyped in seven Volga-Ural ethnic groups (Bashkirs, Tatars, Chuvashes, Maris, Mordovians, Udmurts, and Komis). A total of 47 different genotypes and 15 allelic variants of this locus were described. Substantial intra- and interpopulation heterogeneity of the ethnic groups studied in respect to frequency and distribution of the DXS52 alleles and genotypes was demonstrated. The unimodal DXS52 allele frequency distribution pattern with the peak at 1690 bp was typical to Mordovians and Komis. Chuvashes and Maris, as well as Udmurts, were characterized by bimodal frequency distribution patterns, with the peaks at 1690 and 670 bp, and 1690 and 1390 bp, respectively. Moreover, Bashkirs and Tatars displayed trimodal DXS52 allele frequency distribution patterns with the peaks at 1690, 1390, and 670 bp. The DXS52 allele frequency distribution patterns described in populations of the Volga-Ural region were found to be remarkably different from those established for the mixed Moscow population and the population of Western Europe. These data indicate that the DXS52 locus is highly informative, and this polymorphic system can serve as a molecular marker for population genetic studies.     

Mapping of locus for X-linked congenital stationary night blindness (CSNB1) proximal to DXS7.

A recombinant chromosome in a male affected with X-linked congenital stationary night blindness (CSNB1) provides new information on the location of the CSNB1 locus. A four-generation family with five males affected with X-linked CSNB was analyzed with five polymorphic markers for four X-chromosome loci spanning the region OTC (Xp21.1) to DXS255 (Xp11.22). Four of the males inherited the same X chromosome; one male inherited a chromosome that from OTC to DXS7, inclusive, was derived from the normal X chromosome of his unaffected grandfather and that from a location between DXS7 and DXS426 proximally was derived from the chromosome carrying the CSNB1 locus. This recombinant maps the CSNB1 locus in this family to a region on the short arm of the X chromosome proximal to the DXS7 locus.     

用复合PCR检测DXS7132和DXS6804的单倍型

建立X染色体短串联重复基因座DXS7132和DXS6804的复合扩增系统,并用聚丙烯酰胺凝胶电泳和银染技术进行分型,调查广东汉族人群该二基因座的多态性。结果发现DXS7132有7个等位基因,扩增产物的生长在276-300bp;DXS6804有6个等位基因,扩增产物的长度在177-201bp。序列分析揭示这两个基因座的重复单位均为四核苷酸重复。由于基因组作图信息显示DXS7132和DXS6804之间存在紧密连锁,故用家系分析法确定女性的单体型。在827条染色体（男性211,女性616）中,共发现了33种单体型,女性的二倍体数据符合Hardy-Weinberg平衡。基因多样性、多态性信息量和女孩非父排除率分别达0.9999、0.9440和0.9411。对308个三联体的家系调查表明这两个基因座符合X染色体共显性遗传,未发现突变。结果表明,DXS7231和DXS6804在女孩的亲权认定,特别是缺乏双亲检验的案件中有重要的应用价值。     

Isolation and characterization of a highly polymorphic human locus (DXS455) in proximal Xq28

Human Xq28 is highly gene dense with over 27 loci. Because most of these genes have been mapped by linkage to polymorphic loci, only one of which (DXS52) is informative in most families, a search was conducted for new, highly polymorphic Xq28 markers. From a cosmid library constructed using a somatic cell hybrid containing human Xq27.3----qter as the sole human DNA, a human-insert cosmid (c346) was identified and found to reveal variation on Southern blot analyses with female DNA digested with any of several different restriction endonucleases. Two subclones of c346, p346.8 and p346.T, that respectively identify a multiallelic VNTR locus and a frequent two-allele TaqI polymorphism were isolated. Examination of 21 unrelated females showed heterozygosity of 76 and 57%, respectively. These two markers appeared to be in linkage equilibrium, and a combined analysis revealed heterozygosity in 91% of unrelated females. Families segregating the fragile X syndrome with key Xq28 crossovers position this locus (designated DXS455) between the proximal Xq28 locus DXS296 (VK21) and the more distal locus DXS374 (1A1), which is proximal to DXS52. DXS455 is therefore the most polymorphic locus identified in Xq28 and will be useful in the genetic analysis of this gene dense region, including the diagnosis of nearby genetic disease loci by linkage.     

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.     

DXS28 (C7) maps centromeric to DXS68 (L1-4) and DXS67 (B24) by deletion analysis

Complex glycerol kinase deficiency (CGKD) is a contiguous gene syndrome consisting of glycerol kinase deficiency together with Duchenne muscular dystrophy (DMD), congenital adrenal hypoplasia, and/or Aland Island eye disease. Deletion mapping of genomic DNA from patients with CGKD was carried out and allowed definitive ordering of loci DXS28 (C7), DXS68 (L1-4), and DXS67 (B24). Most reports have placed DXS68 centromeric to DXS28 and DXS67 on the basis of the initial mapping of the Iowa patient 3, but others have presented evidence consistent with the placement of DXS28 telomeric to DXS68 and DXS67. Through the use of DNA from CGKD patients with a variety of genomic deletions, this controversy is resolved and the order Xcen...DMD-DXS28-DXS68-DXS67...pter is definitively demonstrated.     

Linkage analysis of two cloned DNA sequences, DXS197 and DXS207, in hypophosphatemic rickets families

The human X-linked hypophosphatemic rickets gene locus (HYP, formerly HPDR) has been previously localized by linkage analysis to Xp22.31-Xp21.3 and the locus order Xpter-DXS43-HYP-DXS41-Xcen established. Recombination between HYP and these flanking markers is frequently observed and additional markers have been sought. The polymorphic loci DXS197 and DXS207 have been localized to Xpter-Xp11 and Xp22-Xp21, respectively. We have further localized DXS197 to Xpter-Xp21.3 by using a panel of rodent-human hybrid cells and have established the map positions of DXS197 and DXS207 in relation to HYP by linkage studies of hypophosphatemic rickets families. Linkage between DXS197 and the loci DXS43, DXS85, and DXS207 was established with peak lod score values of 6.19, 0 = 0.032; 4.14, 0 = 0.000; and 3.01, 0 = 0.000, respectively. Multilocus linkage analysis mapped the DXS197 and DXS207 loci distal to HYP and demonstrated the locus order Xpter-DXS85-(DXS207, DXS43, DXS197)-HYP-DXS41-Xcen. These additional genetic markers DXS197 and DXS207 will be useful as alternative markers in the genetic counseling of some families.     

广西毛南族DXS7133、DXS8378、DXS6789和DXS7423基因座遗传多态性

采用PCR-STR及基因分型技术,对广西毛南族167名(女57,男110)健康无关个体4个X-STR基因座(DXS7133、DXS8378、DXS6789和DXS7423)的遗传多态性进行研究。结果显示4个X-STR基因座分别检出4、5、9、3个等位基因和5、9、18、5种基因型,4个X-STR基因座女性的基因型频率分布均符合Hardy-Weinberg平衡定律(P>0.05)。群体遗传多态性指标为:多态信息含量(PIC)0.9611、男性个体识别率(DPmale)0.9771、女性个体识别率(DPfemale)0.9980、父-母-女三联体非父排除率(MECtrio)0.9611、父-女二联体非父排除率(MECduo)0.8821,显示上述4个X-STR基因座均具有较高多态性,在法医学个人识别、亲权鉴定及群体遗传学研究中有重要应用价值,同时也为人类群体遗传学、法医学等研究提供了广西毛南族群体X-STR基因座的基础数据,丰富了中华民族基因数据库。     

Isolation of a random cosmid clone,cX5, which defines a new polymorphic locus DXS148 near the locus for Duchenne muscular dystrophy

Summary We have isolated a random cosmid cX5 (DXS148), which maps into a small Xp21 deletion associated with Duchenne muscular dystrophy (DMD), chronic granulomatous disease (CGD), retinitis pigmentosa (RP) and McLeod syndrome. cX5 maps proximally outside several other deletions associated with DMD, glycerol kinase deficiency (GK) and adrenal hypoplasia (AHC). The following order of loci is proposed: centromere-OTC-cX5 (DXS148)-754 (DXS84)-PERT87 (DXS164)/DMD-telomere. A subclone cX5.7, isolated from this cosmid, identifies an MspI RFLP, with a minor allele frequency of 35%. This probe forms an important adjunct to the existing RFLPs for family studies in Duchenne muscular dystrophy.     

Localisation of the gene for Norrie disease to between DXS7 and DXS426 on Xp

Summary A highly informative microsatellite marker, DXS426, which maps proximal to DXS7 in the interval Xp11.4–Xp11.23, has been used to refine further the localisation of the gene for Norrie disease (NDP). The results from a multiply informative crossover localize the NDP gene proximal to DXS7. In conjunction with information from 2 NDP patients who have a deletion for DXS7 but not for DSX426, our data indicate that the NDP gene lies between DXS7 and DXS426 on proximal Xp.     

Isolation and mapping of discrete DXS101 loci in Xq22 near the X-linked agammaglobulinaemia gene locus

The X-linked agammaglobulinaemia (XLA) gene locus has previously been mapped to Xq22 in genetic linkage studies. The DXS101 locus has shown no recombinations with XLA in the ten informative meioses investigated so far. The DXS101 sequence, recognised by the cX52.5 plasmid, is moderately repeated in Xq22. We have isolated cosmids which contain this sequence; two copies of which have been found to lie near DXS178 and XLA, and a third copy which lies near the PLP gene, distal to these loci. We have used the cosmids to generate probes which should be of use for RFLP analysis, and thus in both prenatal diagnosis and carrier testing for XLA, and in constructing a genetic map of this region. These probes will also be used to complement the genetic map in the construction of a complete physical map of Xq22.     

Physical and genetic mapping of polymorphic loci in Xq28 (DXS15, DXS52, and DXS134): analysis of a cosmid clone and a yeast artificial chromosome.

Sequences corresponding to the Xq28 loci DXS15, DXS52, DXS134, and DXS130 were shown to be present in a 140-kb yeast artificial chromosome (YAC XY58, isolated by Little et al.). This YAC clone appears to contain a faithful copy of this genomic region, as shown by comparison with human DNA and with a cosmid clone that contains probes St14c (part of the DXS52 sequences) and cpX67 (DXS134). cpX67 and St14c are contained in 11 kb and detect the same MspI RFLP polymorphism. A comparison of the YAC restriction map and pulsed-field gel electrophoresis data leads us to propose the following order of loci: DXS52(VNTR)-DXS33-DXF22S3-DXS130-DXS134 -DXS52-DXS15-DXS52, this whole cluster being comprised within 575 kb. The physical proximity of the DXS15, DXS52, and DXS134 loci led us to reinvestigate recombination events that had been reported between these loci in families from the Centre d'Etude du Polymorphisme Humain. Our results do not support the assumption that this region shows increased recombination.