X linked myotubular myopathy (MTM1) maps between DXS304 and DXS305, closely linked to the DXS455 VNTR and a new, highly informative microsatellite marker (DXS1684).

The locus for X linked recessive myotubular myopathy (MTM1) has previously been mapped to Xq28 by linkage analysis. We report two new families that show recombination between MTM1 and either DXS304 or DXS52. These families and a third previously described recombinant family were analysed with two highly polymorphic markers in the DXS304-DXS52 interval, the DXS455 VNTR and a newly characterised microsatellite, DXS1684 (82% heterozygosity). These markers did not recombine with MTM1 in the three families. Together with the recent mapping of an interstitial X chromosome deletion in a female patient with moderate signs of myotubular myopathy, our data suggest the following order of loci in Xq28: cen-DXS304-(DXS455, MTM1)-DXS1684-DXS305-DXS52-tel. This considerably refined localisation of the MTM1 locus should facilitate positional cloning of the gene. The availability of highly polymorphic and very closely linked markers will markedly improve carrier and prenatal diagnosis of MTM1.     

Identification of a highly polymorphic marker within intron 7 of the ALAS2 gene and suggestion of at least two loci for X-linked sideroblastic anemia.

We have identified a compound dinucleotide repeat within intron 7 of the human erythroid 5-aminolevulinate synthase (ALAS2) gene with a minimum of 9 alleles and heterozygosity of 78%. ALAS2 was placed on the multipoint linkage map of the X chromosome in the pericentromeric region with the locus order: pter-(DXS255, TFE3, DXS146)-(DXS14, ALAS2, DXZ1)-AR-(DXS153, DXS159)-qter. No recombination was observed between ALAS2 and the centromere marker DXZ1. As ALAS2 has recently been shown to be the defective locus in X-linked pyridoxine-responsive sideroblastic anemia (PRSA), the ALAS2 marker has allowed placement of the gene for PRSA into the multipoint linkage map of the X chromosome. With the previous exclusion of close linkage between DXS14 and sideroblastic anemia with ataxia, our data show that there are at least two loci for X-linked sideroblastic anemia.     

Fragile X syndrome: genetic localisation by linkage mapping of two microsatellite repeats FRAXAC1 and FRAXAC2 which immediately flank the fragile site.

We report the genetic localisation of the fragile site at Xq27.3 associated with fragile X syndrome. The position of the fragile site within the multipoint linkage map was determined using two polymorphic microsatellite AC repeat markers FRAXAC1 and FRAXAC2. These markers were physically located within 10 kilobases and on either side of the p(CCG)n repeat responsible for the fragile site. FRAXAC1 has five alleles with heterozygosity of 44% and is in strong linkage disequilibrium with FRAXAC2 which has eight alleles and a heterozygosity of 71%. No recombination was observed either between these markers in 40 normal CEPH pedigrees or with the fragile X in affected pedigrees. These markers provide the means for accurate diagnosis of the fragile X genotype in families by rapid polymerase chain reaction analysis and were used to position the fragile X within the multipoint map of the X chromosome to a position 3.7 cM distal to DXS297 and 1.2 cM proximal to DXS296.     

Assessment of new markers for the rapid detection of aneuploidies by quantitative fluorescent PCR (QF–PCR)

Rapid prenatal diagnoses of major chromosome aneuploidies have been achieved successfully using quantitative fluoresent PCR (QF–PCR) assays and small tandem repeat (STR) markers. Here we report the results of evaluating the use of previously untested X-linked STRs, (DXS6803) and (DXS6809), together with modified amelogenin (AMXY) sequences and the X22 marker that maps in the pseudoautosomal region PAR2 on the long arm of the X and Y chromosomes. These markers will allow prenatal diagnoses of sex chromosome aneuploidies such as 45,X (pure Turner Syndrome), 47,XXY and 47,XYY, while assessing the sex of the fetuses. Data are also presented concerning the difficulties associated with the evaluation of the frequencies of the various types of sub-populations of cells in amniotic fluid samples collected from fetuses with sex chromosome mosaicism. The results of evaluating the use of new markers for the rapid diagnosis of aneuploidies affecting chromosomes 21,18 and 13 are also presented. Three chromosome 21 specific STRs have been found to produce trisomic triallelic or diallelic patterns from all amniotic samples retrieved from fetuses with Down Syndrome. Since all samples tested were amplified and no false positive or negative results were observed, the present results confirm the diagnostic value of QF–PCR for the prenatal detection of major numerical chromosome disorders.     

X-linked retinoschisis is closely linked to DXS41 and DXS16 but not DXS85

A linkage study was carried out in nine families with 24 males affected by X-linked recessive retinoschisis (RS), using three polymorphic DNA probes from the distal segment of Xp. Close linkage of the disease locus with markers DXS41 (probe p99-6) and DXS16 (pXUT23) was found, confirming the location of the RS gene on the distal short arm of the X chromosome. Lod scores for linkage with DXS85 (probe 782) were negative.     

Carrier detection of the fragile X syndrome using flanking loci DXS98, DXS105, and DXS304.

Diagnosis of the carrier status of the fragile X [fra(X)] syndrome was made in 2 unrelated women who did not express the fragile site. Both were related to several individuals with a typical fra(X) phenotype and the marker X chromosome. A restriction fragment length polymorphism (RFLP) approach was used with probes that flank the fra(X) locus (FRAXA). The loci used for risk calculations of the fra(X) genotype were DXS98 and DXS105 on the centromeric side and a recently characterized locus, DXS304, on the telomeric side. Coincidence correction for the distances between marker loci and FRAXA was made according to the Kosambi function. The DNA marker test gave the risk for one female to be a carrier of 99.7-99.9%. In another family a female was excluded from being a carrier with a probability of greater than 99.7%. The DNA marker U6.2, defining the locus DXS304, has increased the reliability of DNA based diagnosis of carrier status for females-at-risk. It is concluded that DNA analysis can serve as a valuable complement to chromosome analysis in families informative for the more closely linked flanking markers.     

A non-syndromal form of X-linked mental retardation (XLMR) is linked to DXS14

An analysis of the linkage of a non-syndromal form of X-linked mental retardation (MRX1) with a number of markers on the X chromosome was performed in a large pedigree. The affected males had moderate mental retardation; in all other clinical respects and cytogenetically they were normal. No recombinants were observed between the MRX1 gene and the marker DXS14 (p58.1) located at Xp11-cen (Z (max.) = 2.12 at theta = 0.00). Recombination was observed between the MRX1 gene and the markers DXS7 and DXYS1 which flank DXS14. This form of XLMR maps to the centromeric portion of the X-chromosome.     

FRAXAC1 and DXS548 polymorphisms in the Chinese population.

The fragile X syndrome is the most common inherited form of mental retardation. Haplotype studies using FRAXAC1 and DXS548 polymorphic markers flanking the fragile site have demonstrated linkage disequilibrium at the FMR1 locus. We investigated the association of the FRAXAC1, DXS548 and CGG alleles between normal subjects and mentally retarded (MR) patients of unspecified cause who do have fragile X syndrome. We have evaluated the FRAXAC1 site in 390 normal subjects and 321 MR patients and the DXS548 site in 146 normal and 319 MR subjects. Both FRAXAC1 and DXS548 alleles were determined by application of the polymerase chain reaction. When compared with Caucasians, the normal Chinese population has a different FRAXAC1 allele distribution. There are more AC18 repeat alleles and fewer AC19 repeat alleles. The DXS548 allele distributions were similar between Chinese and Caucasians. The same distribution pattern of FRAXAC1 alleles was found in both normal subjects and MR patients, but there were significant differences in the distribution patterns of DXS548 alleles. The FMR1 CGG-DXS548 and FRAXAC1-DXS548 haplotype distribution between normal subjects and MR patients also differed significantly. Our results suggest a possible association between DXS548 alleles and non-FRAXA mental retardation.     

Deletion mapping of the DXS986, DXS995, and DXS1002 loci defines their order within Xq21.

The three microsatellite repeat loci, DXS986, DXS995, and DXS1002, have been mapped to Xq13.2-21.1. We report here their relative order and their localisation within Xq21. These loci will be useful for the genetic mapping of disease loci in this region, in particular X linked deafness, as DXS995 lies in the region critical for this disorder.     

中国人群DXS102座位多态性鉴定及其应用

目的探讨中国人群中ＤＸＳ１０２座位的多态分布。方法应用ＰＣＲ扩增片段长度多态性（Ａｍｐ－ＦＬＰ）研究了无亲缘关系的２３４条Ｘ染色体。结果ＤＸＳ１０２座位等位片段有８个，核心单元ＡＣ二核苷酸重复数为１３～２１，频率分布在０．０１３～０．１５６之间，杂合度观察值和无偏估测值分别为０．８７和０．８０，多态信息含量（ＰＩＣ）０．８０，女性基因型数为２２个，男性基因型数为８个，该座位多态分布符合Ｈａｒｄｙ－Ｗｅｉｎｂｅｒｇ平衡定律。ＤＸＳ１０２座位在中国人群和欧洲人群的分布有明显的种族差异，在中国人群中发现了两个新的等位片段。应用ＤＸＳ１０２座位的短串联重复序列多态性对一接受基因治疗的血友病Ｂ家系进行分析和携带者筛查。结论ＤＸＳ１０２座位连锁分析有望成为一种有效的血友病Ｂ基因诊断的方法。     

Partial Xq25 deletion in a family with the X-linked lymphoproliferative disease (XLP)

X-linked lymphoproliferative disease (XLP) results in exquisite vulnerability to EBV infection: fatal infectious mononucleosis (IM), acquired hypogammaglobulinemia and/or malignant lymphoma occur invariably following infection with the virus. We have identified the XLP locus using the DXS42 DNA probe having restriction length polymorphisms (RFLP). We report an interstitial deletion involving a portion of the Xq25 region in the X chromosome of an affected male, one sister, and their mother. Concordance has been established between the presence of a deletion and RFLP linkage analysis with the DXS42 probe in the kindred. This finding will contribute substantially to the mapping, cloning, and sequencing of the gene responsible for XLP.     

Diagnosis of Wiskott-Aldrich syndrome by analysis of the X chromosome inactivation patterns in maternal leucocyte populations using the hypervariable DXS255 locus.

The Wiskott-Aldrich syndrome (WAS) is characterized by severe recurrent infections, petachiae and chronic eczema. The syndrome involves differentiation disorders in several haematopoietic cell lineages usually manifested as T lymphocyte deficiency, dysgammaglobulinaemia and thrombocytopenia. The defect is inherited in an X-linked recessive mode. A 1-year-old boy presented with otitis, upper respiratory infections, eczema, a persistent granulocytopenia and a dysgammaglobulinaemia. In his family five males in two generations had been shown to have WAS, which entailed a significant risk for the patient to have WAS. As the WAS gene or gene product is not delineated, the symptoms of the patient presented a diagnostic dilemma. If the boy had inherited the disease, his mother should be a WAS carrier. Segregation analysis in the family using the closely linked restriction fragment length polymorphisms (RFLP) DXS7, DXS255 and DXS14 did not exclude her carriership, although the probability was low. As a result of the differentiation arrest, obligate female WAS carriers manifest a unilateral X chromosome inactivation pattern in several haematopoietic cell lineages. Methylation analysis of the X chromosomal DXS255 loci exposed random X chromosome inactivation patterns in the peripheral blood granulocytes, T lymphocytes and B lymphocytes of the patient's mother. These findings excluded her WAS carriership and therefore excluded the diagnosis of WAS in the patient. This was further substantiated in a 1-year follow up with recovery from the haematological and immunological symptoms. These results demonstrated that X inactivation analysis in maternal leucocytes is decisive in the exclusion of the diagnosis of WAS.     

Homologous loci DXYS156X and DXYS156Y contain a polymorphic pentanucleotide repeat (TAAAA)n and map to human X and Y chromosomes

We report the isolation and characterization of a polymorphic pentanucleotide repeat (TAAAA)_n, which was mapped to human chromosomes X and Y (loci DXYS156X and DXYS156Y) by PCR amplification of DNA from a monochromosomal somatic cell hybrid panel (NIGMS panel 2). The (TAAAA)_n repeat of loci DXYS156 occurs within a human LINE element at a position where the consensus sequence contains a single TAAAA motif. In 72 unrelated CEPH individuals seven alleles were detected which ranged in size from 125 to 165 bp in 5 bp intervals. The two largest alleles (160 and 165 bp) were observed only in males, which suggests that they were amplified from the Y chromosome DXYS156Y locus. The other 5 alleles were present in two copies in females and in a single copy in males, which suggests that they were amplified from the X chromosome DXYS156X locus. Locus DXYS156X was polymorphic in CEPH families with an observed heterozygosity in females of 46% (27 of 59). Linkage analysis with DNA markers on the X chromosome revealed significant lod scores for a location of DXYS156X close to markers DXS1002 ( θ= 0.000; z = 8.43), DXYS1X (θ=0.015; z=17.3), DXS3, and PGK1 in the region of chromosome Xql3. The sequence of DXYS156Y derived from the 165 bp allele has been deposited in Genbank with accession number X71600. © 1994 Wiley-Liss, Inc.     

X-linked mental retardation exhibiting linkage to DXS255 and PGKP1: a new MRX family (MRX14) with localization in the pericentromeric region

Gene localization was determined by linkage analysis in a large French family with X-linked mental retardation (MRX). Seven living affected males were clinically studied and the clinical picture was characterized by moderate to severe mental handicap with poor secondary speech acquisition. Seizures, slight microcephaly, simian crease, anteverted pinnae, and macroorchidism were observed in some patients only. Linkage analysis revealed no recombination between the MRX gene and two loci: DXS255 at Xp11.22 (Zmax = 3.31 at θ= 0.00) and PGKP1 at Xq11.2-q12 (Zmax = 3.08 at 9 = 0.00). One recombination was observed between the gene and the two loci DXS164 at Xp21.2 and DXS441 at Xq13.3, respectively. These results suggested gene localization in the pericentromeric region of the X chromosome, and the LOD scores justified assignment of the symbol MRX14 to this family.     

Linkage between the fragile X and F9, DXS52 (St14), DXS98 (4D-8) and DXS105 (cX55.7)

Linkage data using the markers F9, DXS105 (cX55.7), DXS98 (4D-8) and DXS52 (St14) are presented from 22 kindreds segregating with the fragile X. Two-point linkage analysis was carried out taking into account cytogenetic results and penetrance classes defined by mental impairment status of mothers. Recombination frequencies (theta) corresponding to the maximum z scores (z) were obtained between F9 (z = 3.48, theta = 0.18), DXS105 (z = 5.06, theta = 0.07), DXS98 (z = 4.79, theta = 0.01) and DXS52 (z = 6.44, theta = 0.09) and the fragile X. Recombination frequencies between marker loci in fragile X families are also presented. These recombination frequencies need to be combined with those from other studies in order to determine the best estimates of map distances for use in genetic counselling, until markers closer to the fragile X, or at the fragile X, can be used. Most potential fra(X) heterozygotes were informative for flanking markers using the above 4 probes. Carrier risks were determined by 3-point analysis using informative flanking markers, taking into account cytogenetic results. Low level fra(X) expression occurred in 2 probable non-carriers; emphasising the need for extreme caution in the interpretation of low rates of expression.     

Mapping of a new RFLP marker RN1 (DXS369) close to the fragile site FRAXA on Xq27-q28.

A new polymorphic DNA marker RN1, defining locus DXS369, was recently isolated. Using different somatic cell hybrids, RN1 was mapped between markers 4D-8 and U6.2. We have narrowed the localization of RN1 to the region between 4D-8 and FRAXA by genetic mapping in fragile X [fra(X)] families. Combined with information from other reports, the following order of loci on Xq27-q28 is suggested: cen-F9-(DXS105-DXS152)-DXS98-DXS369-FRAXA- DXS304-(DXS52-DXS15-F8)-tel. The locus DXS369 is closely linked to FRAXA, with a peak lodscore of 18.5 at a recombination fraction of 0.05. Therefore, RN1 is a useful probe for carrier detection and prenatal diagnosis in fra(X) families.     

Linkage relationships between DXS105, DXS98, and other polymorphic DNA markers flanking the fragile X locus.

We report on linkage data between DXS105, DXS98, the locus for the fragile X syndrome (FRAXA), and 3 other polymorphic loci that flank the FRAXA locus. An analysis was undertaken to determine the relative positions of DXS105 and DXS98 and to test the assignment of DXS105 to a location proximal and closely linked to FRAXA. In this study of fragile X fra(X) syndrome families, the DXS105 locus was calculated to be proximal to FRAXA with a maximum lod score of 10.36 at theta = 0.08. DXS105 was also shown to be closely linked to the gene for factor IX (F9)(Z = 11.84 at theta = 0.08) and to DXS98 (Z = 4.91 at theta = 0.04). The order of the loci proximal to FRAXA is most likely centromere-factor IX-DXS105-DXS98-FRAXA-telomere. The use of DXS105 and DXS98 in clinical investigations should significantly increase the accuracy of risk assessment in informative fragile X families.     

Genetic linkage analysis identifies new proximal and distal flanking markers for the X-linked agammaglobulinemia gene locus, refining its localization in Xq22

Genetic linkage analysis has been instrumental in mapping thegene for X-linked agammaglobulinemia (XLA) to the proximal longarm of the human X chromosome, to Xq22. Due to the relativerarity of this disease the localization of the gene within Xq22has remained imprecise. We have investigated twenty-nine familiesaffected by XLA and have found no recombinants with the DXS178locus in over 30 informative meioses. DXS178 is now the mostreliable and informative locus for use in pre-natal diagnosisand carrier detection of XLA. In addition, we have identifiednew closely linked proximal and distal flanking markers forXLA, DXS442 and DXS101, respectively. These loci are separatedby 2cM, considerably reducing the extent of DNA within whichthe XLA locus can be contained. This will open up the way formore directed positional cloning efforts for the isolation ofthe XLA gene.     

A new restriction fragment length polymorphism at the DXS101 locus allows carrier detection in a family with X linked agammaglobulinaemia.

The gene responsible for X linked agammaglobulinaemia (XLA) lies in Xq22 and has recently been identified as atk. DXS101 is a polymorphic locus which is closely linked to the disease locus. In this report we describe the identification, by pulsed field gel electrophoresis, of a new polymorphism at the DXS101 locus with a predicted heterozygosity of 4.9%. Despite this low value, we show how this polymorphism has been important in carrier status determination in a family with XLA where assessment was not possible by other means.     

The DXS423E gene in Xp11.21 escapes X chromosome inactivation

The DXS423E gene has been localized to Xp11.21 and is expressedin somatic cell hybrids retaining either the human active orinactive X chromosome, demonstrating that DXS423E escapes Xchromosome inactivation. The XE169 (DXS1272E or SMCX) gene thatescapes X chromosome Inactivation is also located in Xp11.21–11.22and maps within the same YAC as DXS423E. Thus the DXS423E andXE169 genes define a new region in the proximal short arm ofthe X chromosome that is not subject to X chromosome inactivation,supporting a regional basis for escape from inactivation.