Showing papers by "Jean Weissenbach published in 1993"

A linkage map of human chromosome 15 with an average resolution of 2 cM and containing 55 polymorphic microsatellites

Abstract: We have constructed a 2.0 centiMorgan (cM) resolution genetic linkage map for chromosome 15q that contains 55 polymorphic satellites and 3 RFLPs that have placed on the map with odds for order of at least 1,000:1. Genotypes from 67 polymorphic loci (64 polymorphic microsatellites) were used to construct the map. Nine genes are included in the 1,000:1 map and 37 markers have heterozygosities of at least 70%. The sex-equal map length is 128 cM and the largest genetic interval is 11 cM (15.5 cM on the female map). The female and male map lengths are 150 cM and 106 cM, respectively. The map was constructed with 'MultiMap' and is based on the CEPH reference pedigrees and includes over 12,000 new genotypes. A sub-set of 12 markers spanning the length of the linkage map were genotyped in a somatic cell hybrid panel with breakpoints that divided 15q into five segments. Cytogenetic placement agreed with the linkage positions for each of the microsatellites tested with the exception of one (ACTC) which failed to give consistent results. Ten spontaneous new mutations were identified from a subset of 42 polymorphic microsatellites (out of a total of 20,420 transmissions), giving an apparent observed spontaneous mutation rate of 5 x 10(-4) per locus. An integrated map of chromosome 15q was also constructed with the microsatellite markers described here and previously genotyped RFLP-based markers. The sex average map spans 144.7 cM with an average distance between unique map locations of 3.5 cM and a maximum intermarker distance of 11.5 cM. These genetic linkage maps can be considered baseline maps for 15q which will be useful for physical mapping and the localization of disease genes and other genes of interest.

A 4.5-megabase yeast artificial chromosome contig from human chromosome 13q14.3 ordering 9 polymorphic microsatellites (22 sequence-tagged sites) tightly linked to the Wilson disease locus

Abstract: We have previously performed a genetic analysis of multiply affected families to map a locus responsible for Wilson disease (WND) to a 0.3-centimorgan (cM) region within chromosome 13q14.3, between D13S31 and D13S59. Here we describe the construction of a contig of approximately 4.5 Mb, which spans this region and extends from D13S25 to D13S59. This contig consists of 28 genomic yeast artificial chromosome (YAC) clones. Five critical crossover events have been defined in this interval in two unaffected (Centre d'Etudes du Polymorphisme Humain) and three WND families. The combination of sequence tagged site content mapping of YACs with both polymorphic and nonpolymorphic markers and recombination breakpoint mapping resulted in the following order of polymorphic markers: centromere-RB1-D13S25-AFM205vh2-D13S31-D13S22 7-D13S228-AFM238vc3-D13S133- AFM084xc5-D13S137-D13S169, D13S155-D13S59-telomere. The recombination/physical distance ratio varies from approximately 3000 kb per cM in the region between D13S31 and D13S25 to 6000 kb per cM in the region between D13S31 and D13S59. Three WND families exhibiting recombination between the disease locus and D13S31 or D13S59 were genotyped for additional markers in this region and further refined the location of the WND gene to between D13S155 and D13S133. Nine of the markers in this region of < 1 cM are polymorphic microsatellites (seven have observed heterozygosities of 70% or above) that will be extremely useful in prenatal and preclinical diagnosis of this disease. This physical map is an essential step in the isolation of the WND gene and is a framework for the identification of candidate genes.