Assignment of autosomal dominant spinocerebellar ataxia (SCA1) centromeric to the HLA region on the short arm of chromosome 6, using multilocus linkage analysis.

A 7-generation kindred with the HLA-linked form of spinocerebellar ataxia (SCA1) was studied to determine whether the SCA1 gene maps centromeric or telomeric to the HLA loci. The DNA markers flanking the HLA-(A-B) region were used for polymorphism studies and multilocus linkage analysis. These two markers are the cDNA for the beta-subunit of HLA-DP, which is centromeric to HLA-(A-B), and the cDNA for coagulation factor XIIIa (F13A), which is telomeric to HLA-(A-B). Haplotypes were constructed using multiple polymorphisms for these two DNA markers, and pairwise linkage analysis revealed a maximum lod score of 2.18 for SCA1 versus HLA-DP at a recombination fraction of .05 and a maximum lod score of 0 for SCA1 versus F13A at a recombination fraction of .50. A possible crossover between HLA-(A-B) and HLA-DP was identified, but lack of samples from key individuals hampered the analysis. To clarify the phase and improve the analysis, the two chromosomes 6 for the crossover individual were separated in somatic cell hybrids. The results strongly favored the probability that the crossover occurred between HLA-(A-B-DR) and HLA-DP with SCA1 segregating with HLA-DP, consistent with a location centromeric to HLA-(A-B). Multilocus linkage analysis was used to evaluate further the location of SCA1 relative to F13A, HLA-(A-B), and HLA-DP; the results indicated that the SCA1 gene locus is centromeric to HLA-DP with odds of 46:1 favoring this most likely location over the second most likely location, i.e., telomeric to HLA-(A-B) between the HLA complex and F13A.     

The gene for autosomal dominant spinocerebellar ataxia (SCA1) maps telomeric to the HLA complex and is closely linked to the D6S89 locus in three large kindreds

We studied three large kindreds with the HLA-linked form of spinocerebellar ataxia (SCA1) in order to localize the SCA1 locus on the short arm of chromosome 6 (6p). Two loci containing highly informative dinucleotide repeat sequences were used for linkage analysis. These two loci are D6S89, which is telomeric to the HLA region, and T complex-associated testes-expressed 1 (TCTE1), centromeric to HLA. Pairwise linkage analysis of SCA1 and D6S89 revealed a maximum lod score of 5.86 in the Houston SCA1 (HSCA1) kindred and of 8.08 in the Calabrian SCA1 (SCA1) kindreds, at recombination fractions of .050 and .022, respectively. A maximum pairwise lod score of 4.54 at a recombination frequency of .100 was obtained for SCA1 and TCTE1 in the HSCA1 kindred. No evidence for linkage was detected between TCTE1 and SCA1 in the CSCA1 kindreds. Multilocus linkage analysis of SCA1, HLA, and D6S89 in all three kindreds provided strong evidence for localization of the SCA1 locus telomeric to the HLA regions. However, multilocus linkage analysis of SCA1, HLA, and TCTE1 with HSCA1 family genotypes indicated the possibility of a location of the SCA1 locus centromeric to HLA. An analysis of HSCA1 recombinants in this region of chromosome 6 revealed relatively high recombination frequencies between HLA and each of the other two markers and relatively low frequencies between the latter and SCA1, predicting that the SCA1 locus would tend to segregate away from HLA together with D6S89 or TCTE1, as found with the three-point linkage analyses for this family.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regional mapping of the gene for autosomal dominant spinocerebellar ataxia (SCA1) by localizing the closely linked D6S89 locus to 6p24.2----p23.05.

The locus for one subtype of autosomal dominant spinocerebellar ataxias (SCA1) is closely linked (within 1-2 cM) to D6S89, which contains a highly polymorphic dinucleotide repeat sequence. D6S89 has been mapped previously to 6p24----p21.3, between the HLA and F13A1 loci. Mutant cell lines were used to correlate the absence or presence of D6S89 with cytogenetically detectable interstitial 6p deletions. The results allowed us to map D6S89 to the 6p24.2----p23.05 region. The close linkage of SCA1 to D6S89 indicates that this locus is most likely located in the 6p24----p23 segment.     

A new DNA marker (D4S90) is located terminally on the short arm of chromosome 4, close to the Huntington disease gene

Genetic linkage studies have mapped Huntington's disease (HD) to the distal portion of the short arm of chromosome 4 (4p16.3), 4 cM distal to D4S10 (G8). To date, no definite flanking marker has been identified. A new DNA marker, D4S90 (D5); which maps to the distal region of 4p16.3, is described. The marker was used in a genetic linkage study in the CEPH reference families with seven other markers at 4p16. The study, together with knowledge of the physical map of the region, places D4S90 as the most distal marker, 6 cM from D4S10. A provisional linkage study with HD gave a maximum lod score of 2.14 at a theta of 0.00 and no evidence of linkage disequilibrium. As D4S90 appears to be located terminally, it should play an important role in the accurate mapping and cloning of the HD gene.     

The gene for coagulation factor XIII a subunit (F13A) is distal to HLA on chromosome 6

Summary The locus coding for the A subunit of coagulation factor XIII (F13A) is strongly linked with the major histocompatibility complex on chromosome 6. The maximum lod score was obtained at recombination fractions of 0.12 in males and 0.40 in females. The data suggest that the F13A locus is distal to HLA, probably within the 6p22 region.     

Analysis for linkage between F13A and three chromosome 6 marker loci: evidence for 6pter: F13A:HLA:GL01:cen gene order

Summary The results of the present study provide independent support for F13A:HLA linkage and refine the F13A: HLA and F13A: GLO1 linkage relationships. Analysis of the corresponding recombination fractions for the total paternal F13A:HLA and F13A:GLO1 peak lod scores() indicates a locus order of 6pter: F13A:HLA:GLO1:cen. Lod scores between F13A and PLG, a locus recently assigned to chromosome 6, exclude close linkage between these loci.     

A gene for cleidocranial dysplasia maps to the short arm of chromosome 6.

Cleidocranial dysplasia (CCD) is an autosomal dominant generalized bone dysplasia characterized by mild-to-moderate short stature, clavicular aplasia or hypoplasia, supernumerary and ectopic teeth, delayed eruption of secondary teeth, a characteristic craniofacial appearance, and a variety of other skeletal anomalies. We have performed linkage studies in five families with CCD, with 24 affected and 20 unaffected individuals, using microsatellite markers spanning two candidate regions on chromosomes 8q and 6. The strongest support for linkage was with chromosome 6p microsatellite marker D6S282 with a two-point lod score of 4.84 (theta = .03). Furthermore, the multipoint lod score was 5.70 in the interval between D6S282 and D6S291. These data show that the gene for autosomal dominant CCD is located within a 19-cM interval on the short arm of chromosome 6, between D6S282 and D6S291.     

The anonymous RFLP locus D1S2 is close to PGM1 on chromosome 1

D1S2 was one of the first restriction fragment length polymorphisms (RFLPs) assigned to chromosome 1, but its regional location was unknown. In this paper we present data that place this RFLP into both the genetic map and the physical-cytogenetic map. Linkage data maps D1S2 7 cM from PGM1, which is localized to the middle of the short arm at 1p22.1. Southern blot analysis of DNA samples from somatic cell hybrids containing parts of chromosome 1 maps D1S2 proximal to 1p32 and distal to PGM1.     

Genetic recombination events which position the friedreich ataxia locus proximal to the D9S15/D9S5 linkage group on chromosome 9q

The absence of recombination between the mutation causing Friedreich ataxia and the two loci which originally assigned the disease locus to chromosome 9 has slowed attempts to isolate and characterize the genetic defect underlying this neurodegenerative disorder. A proximity of less than 1 cM to the linkage group has been proved by the generation of high maximal lod score (Z) to each of the two tightly linked markers D9S15 (Z = 96.69; recombination fraction [θ] = .01) and D9S5 (Z = 98.22; θ = .01). We report here recombination events which indicate that the FRDA locus is located centromeric to the D9S15/D9S5 linkage group, with the most probable order being cen–FRDA–D9S5–D9S15–qter. However, orientation of the markers with respect to the centromere, critical to the positional cloning strategy, remains to be resolved definitively.     

The Friedreich ataxia gene is assigned to chromosome 9q13-q21 by mapping of tightly linked markers and shows linkage disequilibrium with D9S15.

Chamberlain et al. have assigned the gene for Friedreich ataxia (FA), a recessive neurodegenerative disorder, to chromosome 9, and have proposed a regional localization in the proximal short arm (9p22-cen), on the basis of linkage to D9S15 and to interferon-beta (IFNB), the latter being localized in 9p22. We confirmed more recently the close linkage to D9S15 in another set of families but found much looser linkage to IFNB. We also reported another closely linked marker, D9S5. Additional families have now been studied, and our updated lod scores are z = 14.30 at theta = .00 for D9S15-FA linkage and z = 6.30 at theta = .00 for D9S5-FA linkage. Together with the recent data of Chamberlain et al., this shows that D9S15 is very likely within 1 cM of the FA locus. We have found very significant linkage disequilibrium (delta Std = .28, chi 2 = 9.71, P less than .01) between FA and the D9S15 MspI RFLP in French families, which further supports the very close proximity of these two loci. No recombination between D9S5 and D9S15 was found in the FA families or Centre d'Etude du Polymorphisme Humain families (z = 9.30 at theta = .00). Thus D9S5, D9S15, and FA define a cluster of tightly linked loci. We have mapped D9S5 by in situ hybridization to 9q13-q21, and, accordingly, we assign the D9S5, D9S15, and FA cluster to the proximal part of chromosome 9 long arm, close to the heterochromatic region.     

The gene for human carbonic anhydrase VI(CA6) is on the tip of the short arm of chromosome 1

The gene encoding the human secreted carbonic anhydrase isozyme CAVI(CA6) maps to chromosome 1 by Southern analysis of a somatic cell hybrid panel and to 1p36.22----p36.33 by in situ hybridization. CA6 is therefore not linked to the cytoplasmic carbonic anhydrase genes on chromosome 8 or to CA7 on chromosome 16.     

Localization of the hemochromatosis gene close to D6S105.

The hemochromatosis (HC) gene is known to be linked to HLA-A (6p21.3); however, its precise location has been difficult to determine because of a lack of additional highly polymorphic markers for this region. The recent identification of short tandem repeat sequences (microsatellites) has now provided this area with a number of markers with similar polymorphic index to the HLA serological polymorphisms. Using four microsatellites--D6S105, D6S109, D6S89, and F13A--together with the HLA class I loci HLA-A and HLA-B in 13 large pedigrees clearly segregating for HC, we have been able to refine the location of the HC gene. We identified no recombination between HC and HLA-A or D6S105, and two-point analyses placed the HC gene within one centimorgan (cM) of HLA-A and D6S105 (HLA-A maximum of the lod score [Zmax] of 9.90 at recombination fraction [theta] of 0.0, and D6S105 Zmax of 8.26 at theta of 0.0). The markers HLA-B, D6S109, D6S89, and F13A were separated from the HC locus by recombination, defining the centromeric and telomeric limits for the HC gene as HLA-B and D6S109, respectively. A multipoint map constructed using HLA-B, HLA-A, and D6S109 indicates that the HC gene is located in a region less than 1 cM proximal to HLA-A and less than 1 cM telomeric of HLA-A. These pedigree data indicate an association between HC and specific alleles at HLA-A and D6S105 (i.e., HLA-A3 and D6S105 allele 8).(ABSTRACT TRUNCATED AT 250 WORDS)     

The gene for the muscle-specific enolase is on the short arm of human chromosome 17

The human gene encoding the muscle-specific beta-enolase has been isolated. The beta-enolase gene was mapped to chromosome 17 by analysis of a panel of rodent-human somatic cell hybrids. The gene was further localized to the short arm and tentatively to the region 17pter-p11 by analysis of cell hybrids and transfectant cell lines carrying different portions of chromosome 17.     

The pronatriodilatin gene is located on the distal short arm of human chromosome 1 and on mouse chromosome 4.

Atrial natriuretic factors (ANF) are polypeptides having natriuretic, diuretic, and smooth muscle-relaxing activities that are synthesized from a single larger precursor: pronatriodilatin. Chromosomal assignment of the gene coding for human pronatriodilatin was accomplished by in situ hybridization of a [3H]-labeled pronatriodilatin probe to human chromosome preparations and by Southern blot analysis of somatic cell hybrid DNAs with normal and rearranged chromosomes 1. The human pronatriodilatin gene was mapped to the distal short arm of chromosome 1, in band 1p36. Southern blot analysis of mouse X Chinese hamster somatic cell hybrids was used to assign the mouse pronatriodilatin gene to chromosome 4. This assignment adds another locus to the conserved syntenic group of homologous genes located on the distal half of the short arm of human chromosome 1 and on mouse chromosome 4.     

A new DNA marker (D4S90) is located terminally on the short arm of chromosome 4, close to the Huntington disease gene

Genetic linkage studies have mapped Huntington's disease (HD) to the distal portion of the short arm of chromosome 4 (4p16.3), 4 cM distal to D4S10 (G8). To date, no definite flanking marker has been identified. A new DNA marker, D4S90 (D5), which maps to the distal region of 4p16.3, is described. The marker was used in a genetic linkage study in the CEPH reference families with seven other markers at 4p16. The study, together with knowledge of the physical map of the region, places D4S90 as the most distal marker, 6 cM from D4S10. A provisional linkage study with HD gave a maximum lod score of 2.14 at a θ of 0.00 and no evidence of linkage disequilibrium. As D4S90 appears to be located terminally, it should play an important role in the accurate mapping and cloning of the HD gene.     

The gene for autosomal dominant spinocerebellar ataxia (SCA1) maps centromeric to D6S89 and shows no recombination, in nine large kindreds, with a dinucleotide repeat at the AM10 locus

Spinocerebellar ataxia type 1 (SCA1) is an autosomal dominant disorder which is genetically linked to the short arm of chromosome 6, telomeric to the human major histocompatibility complex (HLA) and very close to D6S89. Previous multipoint linkage analysis using HLA, D6S89, and SCA1 suggested that SCA1 maps centromeric to D6S89. Data from this study using nine large kindreds indicate a maximum lod score between SCA1 and D6S89 of 67.58 at a maximum recombination fraction of .004. To localize SCA1 more precisely, we identified five dinucleotide polymorphisms near D6S89. Genotypic analyses at these polymorphic loci were carried out in nine multigeneration SCA1 kindreds and in the Centre d'Étude du Polymorphisme Humain reference families. A new marker, AM10GA, demonstrates no recombination with SCA1. The maximum lod score for AM10GA linkage to SCA1 is 42.14 at a recombination fraction of 0. Linkage analysis and analysis of recombination events confirm that SCA1 maps centromeric to D6S89 and establish the following order: CEN-D6S109–AM10GA/SCA1–D6S89–LR40–D6S202–TEL.     

The gene for human transforming growth factor alpha is on the short arm of chromosome 2

Transforming growth factor alpha is a polypeptide growth factor that participates in the reversible transformation of cells in vitro and is secreted by many transformed cell lines. It also shares sequence and functional homologies with epidermal growth factor. Working with a cloned cDNA probe (lambda hTGF1-10) and derivatives, we have mapped this gene (TGFA) to 2p13 with the use of somatic cell hybrids and in situ hybridization. This is the same region involved in the 2;8 translocations of Burkitt lymphoma. Such a rearrangement could orient c-myc (8q24) adjacent to TGFA, resulting in activation of one or both of these genes.     

Localization of a gene which complements branched-chain amino acid transaminase deficiency to the short arm of human chromosome 12

Summary A humanxChinese hamster somatic cell hybrid (J1) containing only one human chromosome (number 11) does not express branched-chain amino acid transaminase and, therefore, cannot grow if the branched--keto acids are substituted for the branched-chain amino acids in the growth medium. J1 cells, which are glycine auxotrophs (Gly A), were fused with normal human lymphocytes and the resulting hybrids selectively isolated in glycine-free medium. A total of 16 primary and 46 secondary clones were analyzed for isozymic and nutritional markers. Cytogenetic analysis with chromosome banding was also performed on selected hybrid clones. The results provide evidence that branched-chain amino acid transaminase is syntenic with lactic dehydrogenase B and is located on the short arm of human chromosome 12.     

Localisation of the Becker muscular dystrophy gene on the short arm of the X chromosome by linkage to cloned DNA sequences

Summary A linkage study in 30 Becker muscular dystrophy (BMD) kindreds using three cloned DNA sequences from the X chromosome which demonstrate restriction fragment length polymorphisms (RFLPs), suggests that the BMD gene is located on the short arm of the X chromosome, in the p21 region. The genes for Becker and Duchenne dystrophies must therefore be closely linked, if not allelic, and any future DNA probes found to be of practical use in one disorder should be equally applicable to the other. The linkage analysis also provides data on the frequency of recombination along the short arm of the X chromosome, and across the centromeric region.