Mapping of the spinal muscular atrophy (SMA) gene to a 750-kb interval flanked by two new microsatellites.

The gene for autosomal recessive proximal spinal muscular atrophy (SMA) has recently been mapped between D5S629 and D5S557. We report here a new single-locus microsatellite A31 (D5S823) and two multicopy microsatellites 97T-CA and 95/23-CA. The marker A31 maps to the region of overlap between YACs y116, y55 and y122, distal to D5S629; 97T-CA originates from a cosmid corresponding to the STS 97T, localized distally to A31, while 95/23-CA derives from a cosmid corresponding to the STS 97U, localized proximally to D5S557. We tested all our key recombinant families with these markers. In one type I/II SMA family, a recombinant was found that placed the SMA locus distal to D5S823. Homozygosity mapping in a consanguineous type I SMA family indicates that the SMA gene lies proximal to 95/23-CA. Thus, the two new markers, A31 and 95/23-CA further refine the SMA gene to an approximately 750-kb interval.

Efficiency of various strategies and materials to generate new markers: saturating the region 5q11.2-q13.3 with 30 new randomly distributed clones.

Several different strategies and materials were used for saturating the region 5q11.2-q13.3 with new, randomly distributed markers: isolation of human clones from three chromosome-5-specific libraries (a BssHII endclone phage library from the somatic cell hybrid H64 and two total genomic phage libraries from radiation hybrids IH12 and IH132), as well as Alu-PCR from chromosome-5-specific radiation hybrids with overlapping fragments in the region around the spinal muscular atrophy locus, followed either by direct isolation of Alu-PCR products or hybridization of Alu-PCR products to chromosome-5-gridded cosmid libraries. 253 human phage and cosmid clones were mapped to various parts of chromosome 5 by deletion mapping to somatic cell hybrid panels. 30 of these clones were mapped into the region 5q11.2-q13.3, 9 of which are flanking rate cutting BssHII-sites, known to be, often, starting points for genes. They represent excellent starting material for the development of new polymorphic markers and sequence-tagged sites, for YAC screening and building of contigs, as well as for direct isolation of genes.