David F. Barker

DNA duplication associated with Charcot-Marie-Tooth disease type 1A

Charcot-Marie-tooth disease type 1A (CMT1A) was localized by genetic mapping to a 3 cM interval on human chromosome 17p. DNA markers within this interval revealed a duplication that is completely linked and associated with CMT1A. The duplication was demonstrated in affected individuals by the presence of three alleles at a highly polymorphic locus, by dosage differences at RFLP alleles, and by two-color fluorescence in situ hybridization. Pulsed-field gel electrophoresis of genomic DNA from patients of different ethnic origins showed a novel SacII fragment of 500 kb associated with CMT1A. A severely affected CMT1A offspring from a mating between two affected individuals was demonstrated to have this duplication present on each chromosome 17. We have demonstrated that failure to recognize the molecular duplication can lead to misinterpretation of marker genotypes for affected individuals, identification of false recombinants, and incorrect localization of the disease locus.

A genetic linkage map of the human genome

We report the construction of a linkage map of the human genome, based on the pattern of inheritance of 403 polymorphic loci, including 393 RFLPs, in a panel of DNAs from 21 three-generation families. By a combination of mathematical linkage analysis and physical localization of selected clones, it was possible to arrange these loci into linkage groups representing 23 human chromosomes. We estimate that the linkage map is detectably linked to at least 95% of the DNA in the human genome.

Restriction sites containing CpG show a higher frequency of polymorphism in human DNA

Unique loci in the human genome were examined with restriction enzymes in order to detect restriction fragment length polymorphisms (RFLPs). Of 31 arbitrary loci, nine were detectably polymorphic, reflecting ten polymorphic restriction sites. Nine of the ten polymorphic sites were revealed with two restriction enzymes, Msp I and Taq I, whose recognition sequences have in common the dimer sequence CpG. The cytosines in the CpG sequence are known to be frequently methylated in mammals, and the occurrence of significant variation in Msp I and Taq I sites supports the view that methylated cytosine residues are hotspots for mutation in mammalian DNA.

Linkage of Charcot-Marie-Tooth neuropathy type 1a to chromosome 17

Charcot-Marie-Tooth disease Type 1 (CMT) is an inherited neuropathy with known genetic heterogeneity, with at least one autosomal dominant form (CMT Type 1b) linked to the Duffy region of chromosome 1. Autosomal dominant families not demonstrating linkage to the Duffy blood group marker have been designated CMT Type 1a. We report linkage of six CMT Type 1a families to the chromosome 17 markers EW301 (D17S58) and pA10-41 (D17S71) with maximum LOD scores of zeta = 10.49 at theta (maximum recombination fraction) = 0.05 and zeta = 7.36 at theta = 0.06, respectively.

X-Linked Syndrome of Polyendocrinopathy, Immune Dysfunction, and Diarrhea Maps to Xp11.23-Xq13.3

We describe genetic analysis of a large pedigree with an X-linked syndrome of polyendocrinopathy, immune dysfunction, and diarrhea (XPID), which frequently results in death during infancy or childhood. Linkage analysis mapped the XPID gene to a 17-cM interval defined by markers DXS8083 and DXS8107 on the X chromosome, at Xp11. 23-Xq13.3. The maximum LOD score was 3.99 (recombination fraction0) at DXS1235. Because this interval also harbors the gene for Wiskott-Aldrich syndrome (WAS), we investigated mutations in the WASP gene, as the molecular basis of XPID. Northern blot analysis detected the same relative amount and the same-sized WASP message in patients with XPID and in a control. Analysis of the WASP coding sequence, an alternate promoter, and an untranslated upstream first exon was carried out, and no mutations were found in patients with XPID. A C-->T transition within the alternate translation start site cosegregated with the XPID phenotype in this family; however, the same transition site was detected in a normal control male. We conclude that XPID maps to Xp11.23-Xq13.3 and that mutations of WASP are not associated with XPID.

Localization of Charcot-Marie-Tooth disease type 1a (CMT1A) to chromosome 17p11.2

Charcot-Marie-Tooth (CMT) disease type 1a has been previously localized to chromosome 17 using the markers D17S58 and D17S71. In that report we were unable to provide unequivocal localization of the CMT1A gene on either the proximal p or the q arm. Therefore, data from one additional CMT1A family and typing of other probes spanning the pericentromeric region of chromosome 17 (D17S73, D17S58, D17S122, D17S125, D17S124) were analyzed. Multipoint analysis demonstrates convincing evidence (log likelihood difference greater than 5) that the CMT1A gene lies within 17p11.2 and most likely between the flanking markers D17S122 and D17S124.

Parental Origin-Dependent, Male Offspring-Specific Transmission-Ratio Distortion at Loci on the Human X Chromosome

We have analyzed the transmission of maternal alleles at loci spanning the length of the X chromosome in 47 normal, genetic disease-free families. We found a significant deviation from the expected Mendelian 1:1 ratio of grandpaternal:grandmaternal alleles at loci in Xp11.4-p21.1. The distortion in inheritance ratio was found only among male offspring and was manifested as a strong bias in favor of the inheritance of the alleles of the maternal grandfather. We found no evidence for significant heterogeneity among the families, which implies that the major determinant involved in the generation of the non-Mendelian ratio is epigenetic. Our analysis of recombinant chromosomes inherited by male offspring indicates that an 11.6-cM interval on the short arm of the X chromosome, bounded by DXS538 and DXS7, contains an imprinted gene that affects the survival of male embryos.

A genetic map of human chromosome 17p

A genetic linkage map was constructed with 18 loci from the short arm and pericentric region of chromosome 17 typed on the CEPH reference families. The genetic map includes three markers extracted from the CEPH public database. Nine loci could be ordered using a threshold of odds of at least 1000:1 against alternative orders during the map construction process. With a reduced tolerance of 100:1, a total of 13 loci could be placed on the map spanning a distance of approximately 60 cM in females and 46 cM in males. There were statistically significant differences between the male and the female genetic maps. The order inferred from the genetic data was consistent with the physical localizations of these probes obtained from somatic cell hybrids and tumor deletion studies. This map should be useful for genetic fine mapping of 17p loci.

Physical mapping of 60 DNA markers in the p21.1 → q21.3 region of the human X chromosome

Using a panel of human/rodent somatic cell hybrids and human lymphoblast lines segregating 18 different human X-chromosome rearrangements and deletions, we have assigned 60 DNA markers to the physical map of the X chromosome from Xp21.1 to Xq21.3. Data from Southern blot hybridization and polymerase chain reaction (PCR) amplification assign these markers to 15 primary map intervals. This provides a basis for further long-range cloning and mapping of the pericentromeric region of the X chromosome.

Efficient detection of alport syndrome COL4a5 mutations with multiplex genomic PCR-SSCP

We have performed effective mutation screening of COL4A5 with a new method of direct, multiplex genomic amplification that employs a single buffer condition and PCR profile. Application of the method to a consecutive series of 46 United States patients with diverse indications of Alport syndrome resulted in detection of mutations in 31 cases and of five previously unreported polymorphisms. With a correction for the presence of cases that are not likely to be due to changes at the COL4A5 locus, the mutation detection sensitivity is greater than 79%. The test examines 52 segments, including the COL4A6/COL4A5 intergenic promoter region, all 51 of the previously recognized exons and two newly detected exons between exons 41 and 42 that encode an alternatively spliced mRNA segment. New genomic sequence information was generated and used to design primer pairs that span substantial intron sequences on each side of all 53 exons. For SSCP screening, 16 multiplex PCR combinations (15 4-plex and 1 3-plex) were used to provide complete, partially redundant coverage of the gene. The selected combinations allow clear resolution of products from each segment using various SSCP gel formulations. One of the 29 different mutations detected initially seemed to be a missense change in exon 32 but was found to cause exon skipping. Another missense variant may mark a novel functional site located in the collagenous domain.