Refined physical map of the spinal muscular atrophy gene (SMA) region at 5q13 based on YAC and cosmid contiguous arrays

The gene for the autosomal recessive neurodegenerative disorder spinal muscular atrophy has been mapped to a region of 5q13 flanked proximally by CMS-1 and distally by D5S557. We present a 2-Mb yeast artificial chromosome (YAC) contig constructed from three libraries encompassing the D5S435/D5S629/CMS-1—SMA—D5S557/D5S112 interval. The D5S629/CMS-1—SMA—D5S557 interval is unusual insofar as chromosome 5-specific repetitive sequences are present and many of the simple tandem repeats (STR) are located at multiple loci that are unstable in our YAC clones. A long-range restriction map that demonstrates the SMA-containing interval to be 550 kb is presented. Moreover, a 210-kb cosmid array from both a YAC-specific and a chromosome 5-specific cosmid library encompassing the multilocus STRs CATT-1, CMS-1, D5F149, D5F150, and D5F153 has been assembled. We have recently reported strong linkage disequilibrium with Type I SMA for two of these STRs, indicating that the gene is located in close proximity to or within our cosmid clone array.     

Mapping of two new markers within the smallest interval harboring the spinal muscular atrophy locus by family and radiation hybrid analysis

The locus responsible for the childhood-onset proximal spinal muscular atrophies (SMA) has recently been mapped to an area of 2–3 Mb in the region q12–13.3 of chromosome 5. We have used a series of radiation hybrids (RHs) containing distinct parts of the SMA region as defined by reference markers. A cosmid library was constructed from one RH. Thirteen clones were isolated and five of these were mapped within the SMA region. Both RH mapping and fluorescence in situ hybridization analysis showed that two clones map in the region between loci D5S125 and D5S351. One of the cosmids contains expressed sequences. Polymorphic dinucleotide repeats were identified in both clones and used for segregation analysis of key recombinant SMA families. One recombination between the SMA locus and the new marker 9Ic (D5S685) indicates that 9Ic is probably the closest distal marker. The absence of recombination between the SMA locus and marker Fc (D5S684) suggests that Fc is located close to the disease gene. These new loci should refine linkage analysis in SMA family studies and may facilitate the isolation of the disease gene.     

Refined Linkage Map of Chromosome 5 in the Region of the Spinal Muscular Atrophy Gene

The genetic map in the region of human chromosome 5 that harbors the gene for autosomal recessive forms of spinal muscular atrophy (SMA) has been refined by a multilocus linkage study in 50 SMA-segregating families. Among six markers spanning 8 cM for combined sexes, four were shown to be tightly linked to the SMA locus. Multipoint linkage analysis was used to establish the best estimate of the SMA gene location. Our data suggest that the most likely location for the SMA locus is between blocks AFM114ye7 (D5S465)/EF5.15 (D5S125) and MAP-1B/JK53 (D5S112) at a sex-combined genetic distance of 2.4 and 1.7 cM, respectively. Thus the SMA gene lies in the 4-cM region between these two blocks. This information is of primary importance for designing strategies for isolating the SMA gene.     

Linkage analysis in spinal muscular atrophy, by six closely flanking markers on chromosome 5

The proximal spinal muscular atrophies (SMA) represent the second most common autosomal recessive disorder, after cystic fibrosis. The gene responsible for chronic SMA has recently been mapped to chromosome 5q by using genetic linkage studies. Among six markers mapping to this region, five were shown to be linked with the SMA locus in 39 chronic SMA families each containing at least two affected individuals. Multilocus analysis by the method of location score was used to establish the best estimate of the SMA gene location. Our data suggest that the most likely location for SMA is between loci D5S6 and D5S39. The genetic distances between these two markers are estimated to be 6.4 cM in males and 11.9 cM in females. Since meiosis were informative with D5S39 and D5S6 in 92% and 87% of SMA families, respectively, it is hoped that the present study will contribute to the calculation of genetic risk in SMA families.     

Use of Genetic and Physical Mapping to Locate the Spinal Muscular Atrophy Locus between Two New Highly Polymorphic DNA Markers

The gene for autosomal recessive forms of spinal muscular atrophy (SMA) has recently been mapped to chromosome 5ql3, within a 4-cM region between the blocks D5S465/D5S125 and MAP-1B/D5S112. We identified two new highly polymorphic microsatellite DNA markers—namely, AFM265wf5 (D5S629) and AFM281yh9 (D5S637)—which are the closest markers to the SMA locus. Multilocus analysis by the location-score method was used to establish the best estimate of the SMA gene location. Our data suggest that the most likely location for SMA is between locus D5S629 and the block D5S637/D5S351/MAP-1B/D5S112/D5S357. Genetic analysis of inbred SMA families, based on homozygosity by descent and physical mapping using mega-YACs, gave additional information for the loci order as follows: cen–D5S6–D5S125/D5S465–D5S435–D5S629–SMA–D5S637–D5S351–MAP–1B/D5S112–D5S357–D5S39–tel. These data give the direction for bidirectional walking in order to clone this interval and isolate the SMA gene.     

High-resolution genetic map around the spinal muscular atrophy (SMA) locus on chromosome 5.

Although autosomal recessive spinal muscular atrophy (SMA) has been mapped to chromosome 5q12-q13, there is for this region no genetic map based on highly informative markers. In this study we present the mapping of two previously reported microsatellite markers in 40 CEPH and 31 SMA pedigrees. We also describe the isolation of a new microsatellite marker at the D5S112 locus. The most likely order of markers (with recombination fractions given in parentheses) is 5cen-D5S6-(.02)-D5S125-(.04)-(JK53CA1/2,D5S11 2)-(.04)-D5S39-qter. The relative order of D5S6, D5S112, and D5S39 was confirmed by in situ hybridization. Multipoint linkage analysis in 31 SMA families indicates that the SMA locus lies in the 6-cM interval between D5S6 and JK53CA1/2, D5S112.     

A recombination event occurring within two complex 5q13.1 microsatellite repeat polymorphisms suggests a telomeric mapping of spinal muscular atrophy

The gene for the childhood spinal muscular atrophies (SMAs) has been mapped to 5q13.1. The interval containing the SMA gene has been defined by linkage analysis as 5qcen-D5S629-SMA-D5S557-5qter. We have identified a recombination event within this interval on a type-I SMA chromosome. The recombination maps to a region of multilocus microsatellite repeat (MSR) markers, and occurs between different subloci of two such markers, CMS-1 and 7613. While the possibility of a novel mutation caused by the recombination cannot be discounted, we believe when viewed in the context of a similar recombination in a Dutch SMA family, a centromeric boundary at the recombination site for the critical SMA interval is likely. This new proximal boundary would reduce the minimal region harboring the SMA locus from 1.1 Mb to approximately 600 kb.     

Fine-mapping of the spinal muscular atrophy locus to a region flanked by MAP1B and D5S6.

The microtubule-associated protein 1B (MAP1B) locus has been mapped in close proximity to spinal muscular atrophy (SMA) on chromosome 5q13. We have identified a second microsatellite within a MAP1B intron, which increases the heterozygosity of this locus to 94%. Two unambiguous recombination events establish MAP1B as a closely linked, distal flanking marker for the disease locus, while a third recombinant establishes D5S6 as the proximal flanking marker. The combination of key recombinants and linkage analysis place the SMA gene in an approximately 2-cM interval between loci D5S6 and MAP1B. Physical mapping and cloning locate MAP1B within 250 kb of locus D5S112. The identification and characterization of a highly polymorphic gene locus tightly linked to SMA will facilitate isolation of the disease gene, evaluation of heterogeneity, and development of a prenatal test for SMA.     

The spinal muscular atrophy gene region at 5q13.1 has a paralogous chromosomal region at 6p21.3

Paralogous regions are duplicated segments of chromosomal DNA that have been acquired during the evolution of the genome. Subsequent divergent evolution of the genes within paralogous regions can lead to the formation of gene families. Here, we report the identification of a region on Chromosome (Chr) 6 at 6p21.3 that is paralogous with the Spinal Muscular Atrophy (SMA) gene region on Chr 5 at 5q13.1. Partial characterization of this region identified nine sequences all of which are highly homologous to DNA sequences of the SMA gene region at 5q13.1. These sequences include four β-glucuronidase sequences, two retrotransposon sequences, a novel cDNA, a Sequence Tagged Site (STS), and one that is homologous to exon 9 of the Neuronal Apoptosis Inhibitor Protein (NAIP) gene. The 6p21.3 paralogous SMA region may contain genes that are related to those in the SMA region at 5q13.1; however, a direct association of this region with SMA is unlikely given that no linkage of SMA with Chr 6 has been reported. Received: 12 May 1997 / Accepted: 13 November 1997     

In situ hybridization of two markers closely flanking the spinal muscular atrophy gene to 5q12----q13.3

In order to refine the physical location of the p105-153Ra and M4 probes which closely flank the spinal muscular atrophy gene (SMA) on human chromosome 5q, in situ hybridization has been carried out on prometaphase chromosomes. Our results demonstrate that the disease gene is located between the 5q12----q13.1 and 5q13.3 bands. The present study will hopefully contribute to microdissection of the chromosomal region of the SMA gene.     

High-resolution meiotic and physical mapping of the best vitelliform macular dystrophy (VMD2) locus to pericentromeric chromosome 11.

Best vitelliform macular dystrophy (VMD2) has previously been linked to several microsatellite markers from chromosome 11. Subsequently, additional genetic studies have refined the Best disease region to a 3.7-cM interval flanked by markers at D11S903 and PYGM. To further narrow the interval containing the Best disease gene and to obtain an estimate of the physical size of the minimal candidate region, we used a combination of high-resolution PCR hybrid mapping and analysis of recombinant Best disease chromosomes. We identified six markers from within the D11S903-PYGM interval that show no recombination with the defective gene in three multigeneration Best disease pedigrees. Our hybrid panel localizes these markers on either side of the centromere on chromosome 11. The closest markers flanking the disease gene are at D11S986 in band p12-11.22 on the short arm and at D11S480 in band q13.2-13.3 on the proximal long arm. This study demonstrates that the physical size of the Best disease region is exceedingly larger than previously estimated from the genetic data, because of the proximity of the defective gene to the centromere of chromosome 11.     

Refinement of the Spinal Muscular Atrophy Locus by Genetic and Physical Mapping

We report the mapping and characterization of 12 microsatellite markers including 11 novel markers. All markers were generated from overlapping YAC clones that span the spinal muscular atrophy (SMA) locus. PCR amplification of 32 overlapping YAC clones shows that 9 of the new markers (those set in italics) map to the interval between the two previous closest flanking markers (D5S629 and D5S557): cen - D5S6 - D5S125 - D5S435 - D5S1407-D5S629-D5S1410-D5S1411/D5S1412-D5S1413-D5S1414-D5Z8-D5Z9-CATT1-D5Z10/D5Z6-D5S557-D5S1408-D5S1409-D5S637-D5S351-MAP1B-tel. Four of these new markers detect multiple loci in and out of the SMA gene region. Genetic analysis of recombinant SMA families indicates that D5S1413 is a new proximal flanking locus for the SMA gene. Interestingly, among the 40 physically mapped loci, the 14 multilocus markers map contiguously to a genomic region that overlaps, and perhaps helps define, the minimum genetic region encompassing the SMA gene(s).     

Recombinants in the H-2S/H-2D interval of mouse chromosome 17 define the map position of a gene for cleft palate susceptibility

The H-2 region of mouse chromosome 17 is known to include one or more genes that affect susceptibility to cortisone-induced cleft palate. We have now studied congenic strains that possess crossovers in the interval between H-2S and H-2D and have observed significant differences in susceptibility among recombinants that had been believed to possess the same H-2 haplotypes. Pregnant mice were injected on days 11 through 14 of gestation with 100 mg of cortisone per kg of body weight. The frequency of cleft palate in B10.A(2R) was significantly greater than in B10.A(1R), despite the fact that both have H-2a/H-2b crossovers in the interval between the S and D loci and have the same alleles at all loci that have been previously characterized. Both B10.BAR5 and B10.BAR12 were significantly more susceptible than B10.A(18R), although these strains also share the same alleles at all loci that have been previously characterized. All three of these strains have H-2b/H-2a recombinant chromosomes, with crossovers in the S/D interval. Genetic linkage between H-2 and the high-susceptibility gene of B10.BAR5 was confirmed by testing H-2 homozygotes derived by intercrossing backcross animals. These data therefore suggest that a gene coding for susceptibility, which we designate Cps-1, maps in the 350-kb interval between H-2S and H-2D, and the congenic strains that we have found to be different have different crossover points within this interval. Alleles at the Cps-1 locus have embryonic effects, but no demonstrable effects on the maternal environment.     

Two novel microsatellite markers for prenatal prediction of spinal muscular atrophy (SMA)

Autosomal recessive spinal muscular atrophy (SMA) has been mapped to a 6-cM interval on chromosome 5q12–13.3, flanked proximally by locus D5S6 and distally by locus D5S112. In this study we describe the isolation of two new microsatellite markers (EF1/2a and EF13/14) near locus D5S125, which lies 2 cM distal to D5S6. We show by linkage analysis and the study of the recombinants in 55 SMA pedigrees that the disease lies in the 4-cM interval between EF1/2a and D5S112. Fluorescence in situ analysis of cosmids from D5S6, EF1/2a and D5S112 confirms the genetic order and relative distance of markers. The microsatellites EF1/2a and EF13/14 are the first highly polymorphic PCR based proximal markers in SMA to be described, and will be of value in prental prediction of the disorder.     

The gene for cherubism maps to chromosome 4p16.3.

Cherubism is a rare familial disease of childhood characterized by proliferative lesions within the mandible and maxilla that lead to prominence of the lower face and an appearance reminiscent of the cherubs portrayed in Renaissance art. Resolution of these bony abnormalities is often observed after puberty. Many cases are inherited in an autosomal dominant fashion, although several cases without a family history have been reported. Using two families with clinically, radiologically, and/or histologically proved cherubism, we have performed a genomewide linkage search and have localized the gene to chromosome 4p16.3, with a maximum multipoint LOD score of 5. 64. Both families showed evidence of linkage to this locus. Critical meiotic recombinants place the gene in a 3-cM interval between D4S127 and 4p-telomere. Within this region a strong candidate is the gene for fibroblast growth factor receptor 3 (FGFR3); mutations in this gene have been implicated in a diverse set of disorders of bone development.