A genetic linkage map of 27 markers on human chromosome 21.

We have constructed a genetic linkage map of the long arm of human chromosome 21 comprising 27 DNA markers. This map is an updated version of that reported earlier by group (1989, Genomics 4: 579-591), which contained 17 DNA markers. The current markers consist of 10 genes and 17 anonymous sequences. Traditional methods (restriction fragment length polymorphisms) were used to map 25 of these markers, whereas 2 markers were studied by polymerase chain reaction amplification of (GT)n dinucleotide repeats. Linkage analysis was performed on 40 CEPH families using the computer program packages LINKAGE, CRI-MAP, and MAPMAKER. Recombination rates were significantly different between the sexes, with the male map being 132 cM and the female map being 161 cM, assuming Kosambi interference and a variable ratio of sex difference in recombination. Approximately one-half of the crossovers in either sex occur distally, in terminal band 21q22.3, which also contains 16 of the markers studied. The average distance between adjacent markers was 6 cM.     

Sequence-tagged sites (STSs) for a set of mapped markers on chromosome 21.

Sequence tagged sites (STSs) have been proposed as a "common language" for comparing physical and genetic maps of the human genome produced by a variety of techniques. We have produced 44 STSs from 38 mapped loci on human chromosome 21. The STSs represent most of the loci designated as genetic reference or ordered physical framework markers, along with a number of others chosen to span all regions of 21q. Of the STSs, 12 are from gene segments, including 4 from exons of the APP gene encoding the amyloid beta protein precursor, and 32 mark anonymous DNA loci. These STSs make each of the corresponding loci readily accessible to the research community without the need for exchange of clones. These sites also represent multiple start points for the isolation of YAC clones that should permit overlapping the entire chromosome 21 long arm as cloned DNA.     

Isolation and analysis of DNA markers specific to human chromosome 15.

Chromosome-specific DNA markers provide a powerful approach for studying complex problems in human genetics and offer an opportunity to begin understanding the human genome at the molecular level. The approach described here for isolating and characterizing DNA markers specific to human chromosome 15 involved construction of a partial chromosome-15 phage library from a human/Chinese hamster cell hybrid with a single human chromosome 15. Restriction fragments that identified unique- and low-copy loci on chromosome 15 were isolated from the phage inserts. These fragments were regionally mapped to the chromosome by three methods, including Southern analysis with a mapping panel of cell hybrids, in situ hybridization to metaphase chromosomes, and quantitative hybridization or dosage analysis. A total of 42 restriction fragments of unique- and low-copy sequences were identified in 14 phage. The majority of the fragments that have been characterized so far exhibited the hybridization pattern of a unique locus on chromosome 15. Regional mapping assigned these markers to specific locations on chromosome 15, including q24-25, q21-23, q13-14, q11-12, and q11. RFLP analysis revealed that several markers displayed polymorphisms at frequencies useful for genetic linkage analysis. The markers mapped to the proximal long arm of chromosome 15 are particularly valuable for the molecular analysis of Prader-Willi syndrome, which maps to this region. Polymorphic markers in this region may also be useful for definitively establishing linkage with one form of dyslexia. DNA probes in this chromosomal region should facilitate molecular structural analysis for elucidation of the nature of instability in this region, which is frequently associated with chromosomal aberrations.     

A genetic linkage map of 17 markers on human chromosome 21

We have constructed a genetic linkage map of 17 markers on the long arm of human chromosome 21, including six genes and two anonymous loci with a variable number of tandem repeats. The estimated length of the map is 103 cM in males and 140 cM in females, assuming Kosambi interference. Recombination in females was approximately twice that in males between proximal markers. However, over half of the recombination events in either sex occur distally, in 21q22.3, although this region accounts for only about 15% of the physical length of chromosome 21.     

cDNA surveying of specific tissue expression of human chromosome 19 sequences.

cDNA surveying is a straightforward approach for identifying sequences in genomic clones expressed in specific tissues. It has been applied to a subchromosomal region of human chromosome 19 (19q13.2-q13.4), a region that contains several known expressed sequences including the locus for myotonic dystrophy (DM). Genomic clones were selected from this region by probing a human placental cosmid library with a chromosome 19q-specific minisatellite sequence, or human genomic clones were isolated from a cosmid library constructed from a human chromosome 19q13.2-q13.3 hamster hybrid cell line using human repetitive DNA as probe. Pooled cDNAs synthesized from RNA of specific tissues characteristically affected in DM were depleted in repetitive sequences and used as hybridization probes against gridded cosmid arrays. DNA from the cDNA-positive cosmid clones was transferred to nylon filters and reprobed with cDNAs to identify restriction fragments that were expressed in these tissues. Hybridizing restriction fragments were subcloned, sequenced, and demonstrated to be nonrepetitive. Primer pairs complementary to subcloned sequences were constructed and used for PCR amplification of cDNA synthesized from RNA of tissues affected in myotonic dystrophy. PCR products were sequenced to verify the identity of expressed genomic DNA and its corresponding cDNA.     

Gene-dosage mapping of 30 DNA markers on chromosome 21.

Using a slot-blot method for the dosage of single-copy sequences, the copy numbers of 30 chromosome 21 markers were assessed in the blood DNA of 11 patients with partial trisomy or monosomy 21 and in the DNA of a patient-derived human-hamster hybrid cell line carrying a microduplication of chromosome 21. The physical order of these markers on chromosome 21 was thereby determined.     

Mapping of five human chromosome 19 DNA markers to owl monkey chromosomes.

Hybridization of DNA from three panels of karyotypically distinct owl monkey x rodent somatic cell hybrids with human DNA probes resulted in the syntenic assignments of INSR-LDLR-TGFB1-APOE-D19S8 to owl monkey chromosome 25 of karyotype VI (2n = 49/50), INSR-LDLR-TGFB1-D19S8 to chromosome 2 of karyotype II (2n = 54), and INSR-APOE to chromosome 2 of karyotype V (2n = 46). The APOE and D19S8 loci are on adjacent regions proximal to the centromere of chromosomes 25q (K-VI) and 2p (K-II), as determined by in situ chromosomal hybridization analysis. These findings support our previous proposals on (1) the homology of these chromosomes of three owl monkey karyotypes, (2) the evolutionary derivation of chromosome 2 of karyotypes II and V as the result of two separate centric fusion events, and (3) the likelihood that owl monkey chromosome 25 (K-VI) (and its homologs) is a conserved genetic homoeolog of human chromosome 19.     

Evolutionary breakpoints on human chromosome 21.

Segments of the long arm of human chromosome 21 are conserved, centromere to telomere, in mouse chromosomes 16, 17, and 10. There have been 28 genes identified in human chromosome 21 between TMPRSS2, whose orthologue is the most distal gene mapped to mouse chromosome 16, and PDXK, whose orthologue is the most proximal gene mapped to mouse chromosome 10. Only 6 of these 28 genes have been mapped in mouse, and all are located on chromosome 17. To better define the chromosome 17 segment and the 16 to 17 transition, we used a combination of mouse radiation hybrid panel mapping and physical mapping by mouse: human genomic sequence comparison. We have determined the mouse chromosomal location of an additional 12 genes, predicted the location of 7 more,and defined the endpoints of the mouse chromosome 17 region. The mouse chromosome 16/chromosome 17 evolutionary breakpoint is between human genes ZNF295 and UMODL1, showing there are seven genes in the chromosome 16 segment distal to Tmprss2. The chromosome 17/chromosome 10 breakpoint seems to have involved a duplication of the gene PDXK, which on chromosome 21 lies immediately distal to the KIAA0179 gene. These data suggest that there may be as few as 21 functional genes in the mouse chromosome 17 segment. This information is important for defining existing and constructing more complete mouse models of Down syndrome.     

Alphoid DNA polymorphisms for chromosome 21 can be distinguished from those of chromosome 13 using probes homologous to both.

Although alphoid DNA sequences shared among acrocentric chromosomes have been identified, no human chromosome 21-specific sequence has been isolated from the centromeric region. To identify alphoid DNA restriction fragment length polymorphisms (RFLPs) specific for chromosome 21, we hybridized human genomic DNA with alphoid DNA probes [L1.26; aRI(680),21-208] shared by chromosomes 13 and 21. We detected RFLPs with restriction enzymes ECoRI, HaeIII, MboI,StuI, and TaqI. The segregation of these RFLPs was analyzed in the 40 CEPH families. Linkage analysis between these RFLPs and loci previously mapped to either chromosome 13 or 21 revealed RFLPs that appear to be specific to chromosome 21. These polymorphisms may be useful as genetic markers of the centromeric region of chromosome 21. Different alphoid loci within the centromeric region of chromosome 13 were identified.     

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.     

Dinucleotide repeat (GT)n markers on chromosome 21.

To further develop the linkage map of human chromosome 21 (HC21), we have concentrated on identifying highly polymorphic markers based on dinucleotide repeat sequences such as (GT)n, as these are often highly polymorphic, are widespread throughout the human genome, and can be rapidly analyzed by the polymerase chain reaction. We report here nine (GT)n polymorphic markers from HC21.     

A primary map of ten DNA markers and two serological markers for human chromosome 19

We have constructed a primary map of 10 DNA and 2 protein markers for chromosome 19. Three of the markers define loci with a variable number of tandem repeats (VNTRs); 3 define genes--insulin receptor, low-density lipoprotein (LDL) receptor, and apolipoprotein CII; and 2 are classical markers for blood group antigens (Lewis and Secretor). The estimated genetic distance covered by the map is 137 cM in males and 189 cM in females. In some regions of the chromosome we found significant differences in recombination frequencies according to sex. This set of markers will be efficient for linkage studies in families segregating genetic defects and will provide anchor points for a high-resolution map of chromosome 19.     

Generation and characterization of cells that can be conditionally depleted of mitochondrial SOD2

Manganese-dependent superoxide dismutase (SOD2) serves as the primary defense against mitochondrial superoxide, and decreased SOD2 activity results in a range of pathologies. To investigate the events occurring soon after depletion of SOD2, we generated SOD2 gene knockout chicken DT40 cells complemented with a human SOD2 (hSOD2) cDNA, whose expression can be switched off by doxycycline (Dox). When SOD2 was depleted by the addition of Dox, the cells grew slightly slower and formed fewer colonies than cells expressing hSOD2. In addition, these cells showed a high sensitivity to paraquat, which produces superoxide, and died through apoptosis. In contrast to results obtained with mouse and DrosophilaSod2 mutants, we found no indication of an increase in DNA lesions due to depletion of SOD2.