A non-alphoid repetitive DNA sequence from human chromosome 21

Summary A non-alphoid repetitive DNA from human chromosome 22, consisting of a 48-bp motif, shows homology to both G-group chromosomes in the gorilla, thus indicating the presence of additional repeat family members on further human chromosomes. Therefore, we screened a chromosome-21-specific cosmid library using this repetitive sequence from chromosome 22 (D22Z3). Some 40–50 cosmid clones were positive in tests for hybridization. One of the clones giving the strongest signals was digested with EcoRI/PstI, which we knew to cut frequently within the repeats; this resulted in fragments containing repeat units only. The fragments were subcloned into plasmid vector pTZ 19. Sequence-analysis of a 500-bp insert showed ten copies of a 48-bp repeat similar to D22Z3, with about 15% sequence deviation from the chromosome 22 consensus sequence. In situ hybridization of the newly isolated recombinant established its chromosome 21 specifity at high stringency. Physical mapping by pulsed field gel electrophoresis placed this new repeat in close vicinity to the chromosome 21 alphoid repeat. No cross-hybridization with other mammalian genomes except for those of apes was observed. The locus has been designated D21Z2 by the Genome Data Base. A gel mobility shift assay indicated that this repetitive motif has protein-binding properties.     

Stereospecific DNA anomalies in the human chromosome 21

Using our own original computer program, we analysed more than 10 millions b.p. of the complete nucleotide sequence in the human chromosome 21. A graphic catalogue of largest stereospecific anomalies of this sequence is presented. Clusters of different stereospecific anomalies, showing presumably areas of cooperative binding of different regulatory and structural proteins to DNA have been revealed. Most of the large stereospecific anomalies are situated in introns, being often accompanied by regions devoid of some specific dinucleotides.     

DNA sequences surrounding the centromere of chromosome 21.

The mapping and sequencing of two clones that surround the centromere of chromosome 21 are presented. These clones specify the most proximal known low-order repeat on 21p (p21-7D) and the most proximal known single-copy sequence on 21q (pUT-B37 at locus D21S120).     

Complete DNA sequence of yeast chromosome II.

In the framework of the EU genome-sequencing programmes, the complete DNA sequence of the yeast Saccharomyces cerevisiae chromosome II (807 188 bp) has been determined. At present, this is the largest eukaryotic chromosome entirely sequenced. A total of 410 open reading frames (ORFs) were identified, covering 72% of the sequence. Similarity searches revealed that 124 ORFs (30%) correspond to genes of known function, 51 ORFs (12.5%) appear to be homologues of genes whose functions are known, 52 others (12.5%) have homologues the functions of which are not well defined and another 33 of the novel putative genes (8%) exhibit a degree of similarity which is insufficient to confidently assign function. Of the genes on chromosome II, 37-45% are thus of unpredicted function. Among the novel putative genes, we found several that are related to genes that perform differentiated functions in multicellular organisms of are involved in malignancy. In addition to a compact arrangement of potential protein coding sequences, the analysis of this chromosome confirmed general chromosome patterns but also revealed particular novel features of chromosomal organization. Alternating regional variations in average base composition correlate with variations in local gene density along chromosome II, as observed in chromosomes XI and III. We propose that functional ARS elements are preferably located in the AT-rich regions that have a spacing of approximately 110 kb. Similarly, the 13 tRNA genes and the three Ty elements of chromosome II are found in AT-rich regions. In chromosome II, the distribution of coding sequences between the two strands is biased, with a ratio of 1.3:1. An interesting aspect regarding the evolution of the eukaryotic genome is the finding that chromosome II has a high degree of internal genetic redundancy, amounting to 16% of the coding capacity.     

The DNA sequence of medaka chromosome LG22

We report the genomic DNA sequence of a single chromosome (linkage group 22; LG22) of the small teleost fish medaka (Oryzias latipes) as a first whole chromosome sequence from a non-mammalian vertebrate. The order and orientation of 633 protein-coding genes were deduced from 18,803,338 bp of DNA sequence, providing the opportunity to analyze chromosome evolution of vertebrate genomes by direct comparison with the human genome. The average number of genes in the "conserved gene cluster" (CGC), a strict definition of "synteny" at the sequence basis, between medaka and human was 1.6. These and other data suggest that approximately 38.8% of pair-wise gene relationships would have been broken from their common ancestor in the human and medaka lineages and further imply that approx 20,000 (15,520-23,280) breaks would have occurred from the entire genome of the common ancestor. These breaks were generated mainly by intra-chromosomal shufflings at a specific era in the vertebrate lineage. These precise comparative genomics allowed us to identify the pieces of ancient chromosomes of the common vertebrate ancestor and estimate chromosomal evolution in the vertebrate lineage.     

A cloned repeated DNA sequence in human chromosome heteromorphisms

A sequence derived by ECoRI restriction of human satellite DNA III has been cloned in lambda gt WES. The cloned DNA was used as a template for in vitro synthesis of cRNA, which was hybridized in situ to preparations of human metaphase chromosomes with a range of heterochromatic polymorphisms. Most of the hybridization was found on chromosome 1, and the amount of hybridization was related to the size of the C-band on this chromosome. Hybridization to other chromosomes was not related to the C-band size, although hybridization of total satellite DNA is proportional to C-band size. Total satellite DNAs contain a mixture of sequences, some of which are predominantly located on only one pair of chromosomes. Hybridization in situ is able to discriminate between such chromosome-specific sequences and the bulk of satellite DNA. Further analysis of satellite DNAs may identify sequences specific for every chromosome pair.     

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.     

Isolation of polymorphic DNA segments from human chromosome 21.

A somatic cell hybrid line containing only human chromosome 21 on a mouse background has been used as the source of DNA for construction of a recombinant phage library. Individual phages containing human inserts have been identified. Repeat-free human DNA subclones have been prepared and used to screen for restriction fragment length polymorphisms to provide genetic markers on chromosome 21. Nine independently isolated clones used as probes identified a total of 11 new RFLPs. Four of the DNA probes recovered from the library have been mapped unequivocally to chromosome 21 using a panel of somatic cell hybrid lines. A fifth probe detected an RFLP on chromosome 21 as well as sequences on other chromosomes. This set of RFLPs may now form the basis for construction of a genetic linkage map of human chromosome 21.     

Isolation of repetitive DNA sequences from human chromosome 21.

We have developed a method for the isolation of phage from the human genomic library that carry repetitive DNA sequences highly represented on specific human chromosomes. We have used this technique to select recombinants carrying inserts concentrated on chromosome 21. Five clones, representing two families of sequences, have been characterized. Members of each family show cross-homology, but the two families show no homology with each other. In all but one case, the clones do not contain members of the human Alu repeat family. Single chromosome-concentrated repetitive sequences should prove to be useful in studies of the origin, evolution, and function of repetitive DNA and in regional chromosome mapping.     

Use of comparative physical and sequence mapping to annotate mouse chromosome 16 and human chromosome 21

Distal mouse chromosome 16 (MMU16) shares conserved linkage with human chromosome 21 (HSA21), trisomy for which causes Down syndrome (DS). A 4.5-Mb physical map extending from Cbr1 to Tmprss2 on MMU16 provides a minimal tiling path of P1 artificial chromosomes (PACs) for comparative mapping and genomic sequencing. Thirty-four expressed sequences were positioned on the mouse map, including 19 that were not physically mapped previously. This region of the mouse:human comparative map shows a high degree of evolutionary conservation of gene order and content, which differs only by insertion of one gene (in mouse) and a small inversion involving two adjacent genes. "Low-pass" (2.2x) mouse sequence from a portion of the contig was ordered and oriented along 510 kb of finished HSA21 sequence. In combination with 68 kb of unique PAC end sequence, the comparison provided confirmation of genes predicted by comparative mapping, indicated gene predictions that are likely to be incorrect, and identified three candidate genes in mouse and human that were not observed in the initial HSA21 sequence annotation. This comparative map and sequence derived from it are powerful tools for identifying genes and regulatory regions, information that will in turn provide insights into the genetic mechanisms by which trisomy 21 results in DS.     

Human gamma X satellite DNA: an X chromosome specific centromeric DNA sequence

The cosmid clone, CX16-2D12, was previously localized to the centromeric region of the human X chromosome and shown to lack human X-specific satellite DNA. A 1.2 kb EcoRI fragment was subcloned from the CX16-2D12 cosmid and was named 2D12/E2. DNA sequencing revealed that this 1,205 bp fragment consisted of approximately five tandemly repeated DNA monomers of 220 bp. DNA sequence homology between the monomers of 2D12/E2 ranged from 72.8% to 78.6%. Interestingly, DNA sequence analysis of the 2D12/E2 clone displayed a change in monomer unit orientation between nucleotide positions 585–586 from a tail-to-head arrangement to a head-to-tail configuration. This may reflect the existence of at least one inversion within this repetitive DNA array in the centromeric region of the human X chromosome. The DNA consensus sequence derived from a compilation of these 220 bp monomers had approximately 62% DNA sequence similarity to the previously determined 8 satellite DNA consensus sequence. Comparison of the 2D12/E2 and 8 consensus sequences revealed a 20 bp DNA sequence that was well conserved in both DNA consensus sequences. Slot-blot analysis revealed that this repetitive DNA sequence comprises approximately 0.015% of the human genome, similar to that found with 8 satellite DNA. These observations suggest that this satellite DNA clone is derived from a subfamily of satellite DNA and is thus designated X satellite DNA. When genomic DNA from six unrelated males and two unrelated females was cut with SstI or HpaI and separated by pulsed-field gel electrophoresis, no restriction fragment length polymorphisms were observed for either X (2D12/E2) or 8 (50E4) probes. Fluorescence in situ hybridization localized the 2D12/E2 clone to the lateral sides of the primary constriction specifically on the human X chromosome.     

Tertiary structures of the Escherichia coli and human chromosome 21 molecules of DNA

Using the NDB database, we calculated geometrical parameters that were needed to reproduce crystal structures of short DNA fragments in a phosphorus atom representation. The geometrical parameters were included in a software generating tertiary structures of, for example, the Escherichia coli and human chromosome 21 molecules of DNA whose complete nucleotide sequences are deposited in the EMBL and related databases. Both molecules were found to be heavily folded and composed of domains. A more elaborate version of the present approach will make analysis and comparison possible of tertiary structures of genomic DNA molecules of various chromosomes to identify the chromosome evolutionary and functional relationships.     

Criteria for gene identification and features of genome organization: analysis of 6.5 Mb of DNA sequence from human chromosome 21

To establish criteria for and the limitations of novel gene identification, to identify novel genes of potential relevance to Down Syndrome and to investigate features of genome organization, 6. 550kb. In total, 41 novel gene models were predicted, and for a subset of these, RT-PCR experiments helped to verify and refine the models, and were used to assess expression in early development and in adult brain regions of potential relevance to Down syndrome. Results suggest generally low and/or restricted patterns of expression, and also reveal examples of complex alternative processing, especially in brain, that may have important implications for regulation of protein function. Analysis of complete gene structures of the known genes identified a number of very large introns, a number of very short intergenic distances, and at least one potentially bi-directional promoter. At least 3/4 of known genes and 1/2 of predicted genes are associated with CpG islands. For novel genes, three cases of overlapping genes are predicted. Results of these analyses illustrate some of the complexities inherent in mammalian genome organization and some of the limitations of current sequence analysis technologies. They also doubled the number of potential genes within the region.     

Use of short sequence repeat DNA polymorphisms after PCR amplification to detect the parental origin of the additional chromosome 21 in Down syndrome.

The origin of nondisjunction in trisomy 21 has so far been studied using cytogenetic heteromorphisms and DNA polymorphisms using Southern blot analysis. Short sequence repeats have recently been described as an abundant class of DNA polymorphisms in the human genome, which can be typed using the polymerase chain reaction (PCR) amplification. We describe the usage of such markers on chromosome 21 in the study of parental origin of the additional chromosome 21 in 87 cases of Down syndrome. The polymorphisms studied were (a) two (GT)n repeats and a poly(A) tract of an Alu sequence within the HMG14 gene and (b) a (GT)n repeat of locus D21S156. The parental origin was determined in 68 cases by studying the segregation of polymorphic alleles in the nuclear families (either by scoring three different alleles in the proband or by dosage comparison of two different alleles in the proband). Our results demonstrate the usefulness of highly informative PCR markers for the study of nondisjunction in Down syndrome.