H. Kozman

Refinement of the background genetic map of Xq26‐q27 and gene localisation for Börjeson‐Forssman‐Lehmann syndrome

A detailed map of genetic markers was constructed around the gene for the X-linked mental retardation syndrome of Börjeson-Forssman-Lehmann (BFLS). A multipoint linkage map of framework markers across Xq26-27, based on CEPH families, was integrated with the physical map, based on a YAC contig, to confirm marker order. The remaining genetic markers, which could not be ordered by linkage, were added to create the comprehensive genetic back-ground map, in the order determined by physical mapping, to determine genetic distances between adjacent markers. This background genetic map is applicable to the refinement of the regional localisation for any disease gene mapping to this region. The BFLS gene was localised using this background map in an extended version of the family described by Turner et al. [1989]. The regional localisation for BFLS extends between recombination events at DXS425 and DXS105, an interval of 24.6 cM on the background genetic map. The phenotypic findings commonly seen in the feet of affected males and obligate carrier females may represent a useful clinical indicator of carrier status in potential female carriers in the family. Recombination between DXS425 and DXS105 in a female with such characteristic feet suggests that the distal limit of the regional localisation for the BFLS gene might reasonably be reduced to DXS294 for the purpose of selecting candidate genes, reducing the interval for the BFLS gene to 15.5 cM. Positional candidate genes from the interval between DXS425 and DXS105 include the SOX3 gene, mapped between DXS51(52A) and DXS98(4D-8). SOX3 may have a role in regulating the development of the nervous system. The HMG-box region of this single exon gene was examined by PCR for a deletion and then sequenced. No deviation from normal was observed, excluding mutations in the conserved HMG-box region as the cause of BFLS in this family.

A microsatellite marker within the duplicated D16S79 locus has a null allele: significance for linkage mapping

The dinucleotide repeat 16AC66f3 was characterised from D16S79A within a duplicated section of 16p13.11, which is duplicated on all normal chromosome 16s. This marker has a common null allele caused by polymorphism within one of the primer sites. A redesigned primer overcame this problem; however, this allowed amplification of two dinucleotide repeats, at D16S79A and D16S79B, with an overlapping and uninterpretable distribution of alleles. Thus, the 16AC66F3 marker with a null allele is potentially useful for linkage mapping, as it avoids the ambiguity associated with the genotyping of homologous AC repeats at this duplicated locus. The distribution of additional D16S79 RFLPs flanking FRA16A is clarified.

Integration of the cytogenetic and genetic linkage maps of human chromosome 16 using 50 physical intervals and 50 polymorphic loci

A comprehensive genetic linkage map constructed from 50 loci represented by 68 markers was anchored to 50 cytogenetically defined intervals on human chromosome 16. The linear order of the loci on the cytogenetic map was compatible with the independently derived linear order on the genetic map. The sex-averaged genetic length is 164.5 cM, with an average distance between loci of 3.3 cM. Sex-specific distances are 132.8 cM in males and 201.8 cM in females. This is the first detailed synthesis of genetic and cytogenetic maps for any human chromosome and is the first step in correlating the genetic and physical maps of this chromosome. The combined map, containing 15 loci with a minimum heterozygosity of 60% and 6 PCR-formatted microsatellite markers, will be useful for assignment and regional localization of disease genes to this chromosome.

A (CA)n repeat polymorphism for the human skeletal muscle α-actinin gene ACTN2 and its localization on the linkage map of chromosome 1

A CA dinucleotide repeat polymorphism has been identified for the skeletal muscle alpha-actinin gene ACTN2. The observed heterozygosity is 44% (predicted heterozygosity 50%, PIC 0.47). This polymorphic marker has been localized between D1S74 and D1S103 on the multipoint linkage map of chromosome 1 at a position 44.4 cM from the most distal marker D1S68 at 1 qter.

Addition of MT, D16S10, D16S4, and D16S91 to the linkage map within 16q12.1-q22.1

A 10-point genetic linkage map of the region 16q12.1 to 16q22.1 has been constructed using the CEPH reference families. Four loci, MT, D16S10, D16S91, and D16S4, not previously localized on a multipoint linkage map, were incorporated on the map presented here. The order of loci was cen-D16S39-MT, D16S65-D16S10-FRA16B-D16S38, D16S4, D16S91, D16S46-D16S47-HP-qter. The interval between D16S10 and 4D16S38 is 3.1 cM in males and 2.3 cM in females, and contains FRA16B. The cloning strategy for FRA16B will now be based on YAC walking from D16S10 and D16S38. The location of FRA16B between D16S10 and D16S38 provides a physical reference point for the multipoint linkage map on the short arm of chromosome 16.