A chromosome 19 clone from a translocation breakpoint shows close linkage and linkage disequilibrium with myotonic dystrophy

The gene for myotonic dystrophy (DM), the most common form of adult muscular dystrophy, is situated on the proximal long arm of chromosome 19. Although there exist markers that are tightly linked to the DM locus, its precise location is unknown. The identification and characterization of additional DNA probes closely linked to the DM locus continue to be priorities. In this study, we report on the linkage between a new DNA marker, designated p alpha 1.4P, and the DM locus in 50 families. The probe p alpha 1.4P was derived from a cloned breakpoint junction fragment from the chromosomal translocation t(14;19)(q32;q13.1). This translocation has been previously described in some cases of chronic lymphocytic leukemia. We have identified a BanI restriction fragment length polymorphism that is detected by p alpha 1.4P. Segregation analysis between this RFLP and DM revealed close linkage between the two loci (lod = 10.95, theta = 0). Furthermore, statistical evidence for linkage disequilibrium between p alpha 1.4P and the DM locus in a French Canadian population was found. Finally, by means of a somatic cell hybrid mapping panel, p alpha 1.4P was sublocalized to 19q12----19q13.2.     

A multipoint linkage map around the locus for myotonic dystrophy on chromosome 19

Employing 16 polymorphic DNA markers as well as the chromosome 19 centromere heteromorphism, we have performed a genetic linkage study in 26 families with myotonic dystrophy. Fourteen of these markers had been assigned previously to one of five different intervals of the 19cen-19q13.2 segment by using somatic cell hybrids. For the long arm of chromosome 19, a genetic map that encompasses 9 polymorphic markers and the DM gene has been constructed. Our studies indicate that the DM and CKMM genes map distal to the ApoC2-ApoE gene cluster and to the anonymous polymorphic markers D19S15 and D19S16, but proximal to the D19S22 marker. The orientation of DM and CKMM remains to be determined.     

Further mapping of markers around the centromere of human chromosome 19

The gene for myotonic dystrophy (DM) is located on the proximal long arm of chromosome 19 along with at least 10 cloned genes and anonymous DNA segments. In order to refine the map of this region of the chromosome, we have constructed somatic cell hybrid lines from fibroblasts carrying a balanced translocation t(1, 19) with a breakpoint at 19q12. We have established that D19S7 is the most proximal of the available long-arm markers and confirmed that PEPD localizes to 19q, along with PVS, MSK19, and MSK37. We have also examined the segregation of markers from the proximal long-arm region of chromosome 19 in hybrids containing fragments of this chromosome.     

Radiation-reduced hybrids for the myotonic dystrophy locus.

The myotonic dystrophy (DM) gene maps to the long arm of human chromosome 19 and is flanked by markers ERCC1 and D19S51. Also mapping to this region is the polio virus receptor gene (PVS). To produce more markers for this interval, we have constructed radiation-reduced hybrids by selecting for the retention of ERCC1 and for the loss of PVS. One of the cell lines produced has been characterized extensively and contains about 2 Mb of human DNA derived exclusively from chromosome 19, and includes ERCC1 and D19S51. Phage libraries constructed from DNA of this cell line have been screened and several new markers identified, including two for which cDNAs have been isolated. These represent candidate genes for DM. The new markers have also been used to extend the long-range restriction map of this region.     

Three-point linkage analysis employing C3 and 19cen markers assigns the myotonic dystrophy gene to 19q

Summary In seven large families with myotonic dystrophy (DM) comprising 102 individuals, linkage studies were perfermed employing restriction fragment length polymorphisms in the complement component 3 gene and the 19cen C banding heteromorphism as genetic markers. Three-point linkage analysis excludes DM from the 19cen-C3 segment and strongly supports its assignment to the proximal long arm of chromosome 19.     

Localisation of the myotonic dystrophy locus to 19q13.2–19q13.3 and its relationship to twelve polymorphic loci on 19q

Summary The order of fourteen polymorphic markers localised to the long arm of human chromosome 19 has been established by multipoint mapping in a set of 40 CEPH (Centre d'Étude de Polymorphisme Humain, Paris) reference families. We report here the linkage relationship of the myotonic dystrophy (DM) locus to twelve of these markers as studied in 45 families with DM. The resulting genetic map is supported by the localisation of the DNA markers in a panel of somatic cell hybrids. Ten of the twelve markers have been shown to be proximal to the DM gene and two, PRKCG and D19S22, distal but at distances of approximately 25 cM and 15 cM, respectively. The closest proximal markers are APOC2 (apolipoprotein C-II) and CKM (creatine kinase, muscle) approximately 3 cM and 2 cM from the DM gene respectively, in the order APOC2-CKM-DM. The distance between APOC2, CKM and DM (of the order of 2 million base pairs) and their known orientation should permit directional chromosome walking and jumping. The data presented here should enable us to determine whether or not new markers are distal to APOC2/CKM and thus potentially flank the DM gene.     

Physical and genetic mapping of a novel chromosome 19 ERCC1 marker showing close linkage with myotonic dystrophy.

Recent genetic linkage analyses have mapped the myotonic dystrophy locus to the region of 19q13.2-13.3 lying distal to the gene for creatine kinase subunit M (CKM). The human excision repair gene ERCC1 has also been mapped to this region of chromosome 19. A novel polymorphic DNA marker, pEO.8, has been isolated from a chromosome 19 ERCC1-containing cosmid that maps to a 300-kb NotI fragment encompassing both CKM and ERCC1. Genetic linkage analysis reveals close linkage between pEO.8 and myotonic dystrophy (DM) (zmax = 19.3, theta max = 0.01). Analysis of two key recombinant events suggests a mapping of DM distal to pEO.8 and CKM.     

Linkage relationships of the insulin receptor gene with the complement component 3, LDL receptor,apolipoprotein C2 and myotonic dystrophy loci on chromosome 19

Summary Myotonic dystrophy is associated with disturbances in the insulin response, possibly due to an abnormality of the insulin receptor. Both the myotonic dystrophy (DM) and insulin receptor (INSR) genes are on chromosome 19. Using a cloned gene probe for INSR, we have studied its linkage relationships with the DM locus and other chromosome 19 markers. The results show that INSR is not closely linked to DM, but is located very close to C3, in the region 19pter-19p13.2. This implies that the basic genetic defect which causes DM is not directly responsible for the disturbed insulin response in these patients.     

Assessment of a creatine kinase isoform M defect as a cause of myotonic dystrophy and the characterization of two novel CKMM polymorphisms

Summary Recent studies have shown the gene encoding creatine kinase isoform M (CKMM) to be very closely linked to the myotonic dystrophy (DM) locus on the long arm of chromosome 19. Given this close linkage to DM and the postulated role of CKMM in skeletal muscle contraction, the possibility of a defect in CKMM causing DM was investigated. CKMM cDNA was isolated from the skeletal muscle of an individual with DM. Sequencing of the CKMM cDNA from the DM chromosome 19 revealed two novel polymorphisms but no translationally significant mutation. This work rules out a defect in the coding segment of CKMM as a cause of DM in this family and, in light of genetic homogeneity shown to date for DM, probably in all cases of DM.     

The human ryanodine receptor gene: Its mapping to 19q13.1, placement in a chromosome 19 linkage group, and exclusion as the gene causing myotonic dystrophy

The recent cloning of cDNA encoding the Ca++ release channel (ryanodine receptor) of human sarcoplasmic reticulum has enabled us to use somatic cell hybrids to localize the ryanodine receptor gene (RYR) to the proximal long arm of human chromosome 19. Studies with additional hybrids containing deletions or translocations in chromosome 19 enabled us to localize RYR to 19q13.1 in a region distal to GPI/MAG and proximal to D19S18/DNF11. On the basis that the myotonic dystrophy (DM) locus maps near this region and that myotonia could result from a defect in the ryanodine receptor, we examined the linkage between the DM locus and RYR. Our results, showing several DM-RYR recombinants, rule out an RYR defect as the cause of DM. However, localization of RYR to a region of human chromosome 19 which is syntenic to an area of pig chromosome 6 containing the HAL gene responsible for porcine malignant hyperthermia supports the candidacy of RYR for this disorder.     

Physical mapping and cloning of the proximal segment of the myotonic dystrophy gene region.

The myotonic dystrophy (DM) region has been recently shown to be bracketed by two key recombinant events. One recombinant occurs in a Dutch DM family, which maps the DM locus distal to the ERCC1 gene and D19S115 (pE0.8). The other recombinant event is in a French Canadian DM family, which maps DM proximal to D19S51 (p134c). To further resolve this region, we initiated a chromosome walk in a telomeric direction from pE0.8, a proximal marker tightly linked to DM, toward the genetic locus. An Alu-PCR approach to chromosome walking in a cosmid library from flow-sorted chromosome 19 was used to isolate DM region cosmids. This effort has resulted in the cloning of a 350-kb genomic contig of human chromosome 19q13.3. New genetic and physical mapping information has been generated using the newly cloned markers from this study. As a result of this new mapping information, the minimal area that is to contain the DM gene has been redefined. Approximately 200 kb of sequence between pE0.8 and the closest proximal marker to DM, pKEX0.8, that would have otherwise been screened for DM candidate genes, has been eliminated as containing the DM gene.     

Establishment of the mouse chromosome 7 region with homology to the myotonic dystrophy region of human chromosome 19q

A number of genetic markers, including ATP1A3, TGFB, CKMM, and PRKCG, define the genetic region on human chromosome 19 containing the myotonic dystrophy locus. These and a number of other DNA probes have been mapped to mouse chromosome 7 utilizing a mouse Mus domesticus/Mus spretus interspecific backcross segregating for the genetic markers pink-eye dilution (p) and chinchilla (cch). The establishment of a highly syntenic group conserved between mouse chromosome 7 and human chromosome 19q indicates the likely position of the homologous gene locus to the human myotonic dystrophy gene on proximal mouse chromosome 7. In addition, we have mapped the muscle ryanodine receptor gene (Ryr) to mouse chromosome 7 and demonstrated its close linkage to the Atpa-2, Tgfb-1, and Ckmm cluster of genes. In humans, the malignant hyperthermia susceptibility locus (MHS) also maps close to this gene cluster. The comparative mapping data support Ryr as a candidate gene for MHS.     

Detection of linkage disequilibrium between the myotonic dystrophy locus and a new polymorphic DNA marker.

We have examined the linkage of two new polymorphic DNA markers (D19S62 and D19S63) and a previously unreported polymorphism with an existing DNA marker (ERCC1) to the myotonic dystrophy (DM) locus. In addition, we have used pulsed-field gel electrophoresis to obtain a fine-structure map of this region. The detection of linkage disequilibrium between DM and one of these markers (D19S63) is the first demonstration of this phenomenon in a heterogeneous DM population. The results suggest that at least 58% of DM patients in the British population, as well as those in a French-Canadian subpopulation, are descended from the same ancestral DM mutation. We discuss the implications of this finding in terms of strategies for cloning the DM gene, for a possible role in modification of risk for prenatal and presymptomatic testing, and we speculate on the origin and number of existing mutations which may result in a DM phenotype.     

Localization of DNA sequences in region Xp21 of the human X chromosome: Search for molecular markers close to the duchenne muscular dystrophy locus

Panels of somatic cell hybrid lines carrying various structural rearrangements of the human X chromosome short arm were analyzed with 21 X-chromosome-specific cloned DNA fragments. We mapped these molecular markers to five different regions of the short arm of the X chromosome. The results were confirmed by gene-dosage studies of human lymphoblasts with structurally abnormal X chromosomes. The ornithine transcarbamylase gene and four anonymous DNA sequences map within band Xp21, flanking the presumed locus for Duchenne muscular dystrophy.     

Flanking markers bracket the neurofibromatosis type 2 (NF2) gene on chromosome 22.

Neurofibromatosis 2 or bilateral acoustic neurofibromatosis (NF2) is a severe autosomal dominant disorder characterized by the development of multiple tumors of the nervous system, including meningiomas, gliomas, neurofibromas, ependymomas, and particularly acoustic neuromas. Polymorphic DNA markers have revealed frequent loss of one copy of chromosome 22 in the tumor types associated with NF2. Family studies have demonstrated that the primary defect in NF2 is linked to DNA markers on chromosome 22, suggesting that it involves inactivation of a tumor suppressor gene. We have employed a combination of multipoint linkage analysis and examination of deletions in primary tumor specimens to precisely map the NF2 locus between flanking polymorphic DNA markers on chromosome 22. The 13-cM region bracketed by these markers corresponds to 13% of the genetic length of the long arm of chromosome 22 and is expected to contain less than 5 x 10(6) bp of DNA. The delineation of flanking markers for NF2 should permit accurate presymptomatic and prenatal diagnosis for the disorder and greatly facilitate efforts to isolate the defective gene on the basis of its location.     

Nephrogenic diabetes insipidus: close linkage with markers from the distal long arm of the human X chromosome

Summary Ten families with nephrogenic diabetes insipidus (NDI) have been analysed for restriction fragment length polymorphisms (RFLPs). A search for linkage was performed using various chromosome-specific single-copy DNA probes of known regional assignment to the human X chromosome. Close linkage was found between the disease locus and the markers DXS52, DXS15, DXS134 and the F8 gene. This result assigns the NDI gene to the subtelomeric region of the long arm of the X chromosome. The regional localization of the gene by the identification of closely linked markers should have repercussions for genetic counselling and prevention in NDI families.     

Characterization of a YAC and cosmid contig containing markers tightly linked to the myotonic dystrophy locus on chromosome 19.

Myotonic dystrophy (DM) is caused by a defect in an unknown gene that maps to 19q13.3, flanked by the tightly linked markers ERCC1 on the proximal side and D19S51 on the distal side. We report the isolation and characterization of overlapping YAC and cosmid clones around D19S51 for the construction of a physical map around this locus. The resulting contig contains the markers D19S51 and D19S62 (another new marker tightly linked to the DM locus) and the distal breakpoint of a radiation hybrid cell line used in the physical mapping of the DM region. We have compared the restriction maps of the YACs and cosmids with that of the genome to investigate the fidelity of these clones.     

Confirmation of the SCA-2 locus as an alternative locus for dominantly inherited spinocerebellar ataxias and refinement of the candidate region.

The autosomal dominant spinocerebellar ataxias (SCAs) are a clinically heterogeneous group of neurodegenerative diseases. To date, two SCA loci have been identified-one locus (SCA-1) on the short arm of chromosome 6 and the second locus (SCA-2) on the long arm of chromosome 12. We have studied two large kindreds from different ethnic backgrounds, segregating an autosomal dominant form of SCA. A total of 207 living individuals, including 50 affected, were examined, and blood was collected. We performed linkage analysis using anonymous DNA markers which flank the two previously described loci. Our results demonstrate that the two kindreds, one Austrian-Canadian and one French-Canadian, are linked to SCA-2 (chromosome 12q). Multipoint linkage analysis places the SCA-2 locus within a region of approximately 16 cM between the microsatellites D12S58 and D12S84/D12S105 (odds ratio 2,371:1 in favor of this position). We show that the SCA-2 locus is not a private gene and represents an alternative SCA locus.     

Identification of variable simple sequence motifs in 19q13.2-qter: markers for the myotonic dystrophy locus.

Variable simple sequence motifs (VSSMs), or microsatellites, were used for the genetic delimitation of the myotonic dystrophy (DM) region at 19q. Three simple sequence motifs were identified in and around the ERCC1 DNA-repair gene at 19q13.2-13.3 and one in the vicinity of the RRAS gene at 19q13.3-qter. A (TG)n repeat, situated within the ninth intron of the ERCC1 gene, was converted into a highly informative multiallelic marker using PCR-mediated DNA amplification and high-resolution gel analysis. The structurally similar sequence motif in the RRAS gene yielded a marker system with only two alleles. Use of these VSSMs for linkage analysis and haplotyping in a selected set of DM families revealed that the DM gene is distal but close to the ERCC1 locus and can be excluded from the CKM-ERCC1 interval at 19q13.2. The order for RRAS and other distally located markers was established as DM-D19S50-[RRAS,KLK]-D19S22-ter.     

Choroideremia-locus maps between DXS3 and DXS11 on Xq

Summary Choroideremia is a progressive tapetochoroidal dystrophy with X-linked transmission leading frequently to blindness in affected males. The choroideremia-locus (TCD) has recently been assigned to the long arm of the X chromosome by linkage to polymorphic DNA markers. In order to further define the location of the gene defect, two families segregating for choroideremia were examined for DNA restriction fragment length polymorphisms. A search was undertaken for linkage with cloned DNA probes from the proximal short and long arm as well as from the mid-portion of the long arm of the X chromosome. Our data suggest that the most plausible gene order on the Xq is: Xcen-DXYS1-DXS3-TCD-DXS11-Xqter.