Closing in on telomeric closure

Molecular cytogenetic analysis of telomere rearrangements

Genomic imbalances involving the telomeric regions of human chromosomes, which contain the highest gene concentration in the genome, are proposed to have severe phenotypic consequences. For this reason, it is important to identify telomere rearrangements and assess their contribution to human pathology. This unit describes the structure and function of human telomeres and outlines several methodologies that can be employed to study these unique regions of human chromosomes. It is a revision of the original version of the unit published in 2000, now including an introductory section describing advances in the discipline that have taken place since the original publication.

Molecular cytogenetic analysis of telomere rearrangements

Genomic imbalances involving the telomeric regions of human chromosomes, which contain the highest gene concentration in the genome, are proposed to have severe phenotypic consequences. For this reason, it is important to identify telomere rearrangements and assess their contribution to human pathology. This unit describes the structure and function of human telomeres and outlines several FISH-based methodologies that can be employed to study these unique regions of human chromosomes.

Toward closing rice telomere gaps: mapping and sequence characterization of rice subtelomere regions

Despite the collective efforts of the international community to sequence the complete rice genome, telomeric regions of most chromosome arms remain uncharacterized. In this report we present sequence data from subtelomere regions obtained by analyzing telomeric clones from two 8.8 x genome equivalent 10-kb libraries derived from partial restriction digestion with HaeIII or Sau3AI (OSJNPb HaeIII and OSJNPc Sau3AI). Seven telomere clones were identified and contain 25-100 copies of the telomere repeat (CCCTAAA)(n) on one end and unique sequences on the opposite end. Polymorphic sequence-tagged site markers from five clones and one additional PCR product were genetically mapped on the ends of chromosome arms 2S, 5L, 10S, 10L, 7L, and 7S. We found distinct chromosome-specific telomere-associated tandem repeats (TATR) on chromosome 7 (TATR7) and on the short arm of chromosome 10 (TATR10s) that showed no significant homology to any International Rice Genome Sequencing Project (IRGSP) genomic sequence. The TATR7, a degenerate tandem repeat which is interrupted by transposable elements, appeared on both ends of chromosome 7. The TATR10s was found to contain an inverted array of three tandem repeats displaying an interesting secondary folding pattern that resembles a telomere loop (t-loop) and which may be involved in a protective function against chromosomal end degradation.

Genetic, physical, and comparative map of the subtelomeric region of mouse Chromosome 4

The subtelomeric region of mouse chromosome (Chr) 4 harbors loci with effects on behavior, development, and disease susceptibility. Regions near the telomeres are more difficult to map and characterize than other areas because of the unique features of subtelomeric DNA. As a result of these problems, the available mapping information for this part of mouse Chr 4 was insufficient to pursue candidate gene evaluation. Therefore, we sought to characterize the area in greater detail by creating a comprehensive genetic, physical, and comparative map. We constructed a genetic map that contained 30 markers and covered 13.3 cM; then we created a 1.2-Mb sequence-ready BAC contig, representing a 5.1-cM area, and sequenced a 246-kb mouse BAC from this contig. The resulting sequence, as well as approximately 40 kb of previously deposited genomic sequence, yielded a total of 284 kb of sequence, which contained over 20 putative genes. These putative genes were confirmed by matching ESTs or cDNA in the public databases to the genomic sequence and/or by direct sequencing of cDNA. Comparative genome sequence analysis demonstrated conserved synteny between the mouse and the human genomes (1p36.3). DNA from two strains of mice (C57BL/6ByJ and 129P3/J) was sequenced to detect single nucleotide polymorphisms (SNPs). The frequency of SNPs in this region was more than threefold higher than the genome-wide average for comparable mouse strains (129/Sv and C57BL/6J). The resulting SNP map, in conjunction with the sequence annotation and with physical and genetic maps, provides a detailed description of this gene-rich region. These data will facilitate genetic and comparative mapping studies and identification of a large number of novel candidate genes for the trait loci mapped to this region.

A sequence-ready map of the human chromosome 1q telomere

A 260-kb half-YAC clone derived from human chromosome 1q was mapped at high resolution using cosmid subclone fingerprint analysis and was integrated with overlapping clones from the telomeric end of a separately derived 1q44 BAC contig to create a sequence-ready map extending to the molecular telomere of 1q. Analysis of 100 kb of sample sequences from across the 260-kb region encompassed by the half-YAC revealed the presence of EST sequence matches corresponding to 12 separate Unigene clusters and to 12 separate unclustered EST sequences. Low-copy subtelomeric repeats typical of many human telomere regions are present within the distal-most 30 kb of 1q. The previously isolated and radiation hybrid-mapped markers Bda84F03, 1QTEL019, and WI11861 localized at distances approximately 32, 88, and 99 kb, respectively, from the 1q terminus. This sequence-ready map permits high-resolution integration of genetic maps with the DNA sequences directly adjacent to the tip of human chromosome 1q and will enable telomeric closure of the human chromosome 1q DNA reference sequence by connecting the molecular 1q telomere to an internal BAC contig.

Characterization of physical gap sizes at human telomeres

Genome-wide physical and genetic mapping efforts have not yet fully addressed the problem of closure at the telomeric ends of human chromosomes. Targeted efforts at cloning human and mouse telomeres have succeeded in identifying unique sequences at most telomeres, but gap sizes between these telomere clones and the distal markers on integrated genetic/physical maps remain largely unknown. As telomeric regions are known to be the most gene-rich regions of the human genome, filling these gaps should have a high priority in completion of the Human Genome Project. We reported previously a first generation set of unique sequence probes for human telomeric regions. Of 41 human telomere regions, 33 were represented by unique clones with a known distance (</= 300 kb) from the end of the chromosome; clones for the remaining eight telomeric regions had not yet been identified and were represented by the most distal markers on the integrated genetic/physical map. We have identified unique telomere clones for four of the remaining telomeres, 9p, 12p, 15q, and 16p. To determine the telomeric gap size for these chromosomes and five other human telomeres, interphase FISH analysis was performed to measure the distance between each telomere clone and the corresponding most distal marker. These studies provide distance estimates ranging from <100 kb to >1 Mb, thus defining the physical mapping task for filling telomeric gaps.

A sequence-ready map of the human chromosome 17p telomere

A half-YAC clone derived from human chromosome 17p was mapped at high resolution using cosmid subclone fingerprint analysis. Colinearity of the half-YAC with the telomeric human genomic DNA fragment was ascertained by RecA-assisted restriction endonuclease cleavage mapping. Previously isolated and radiation hybrid-mapped markers TEL17P37, TEL17P49, and TEL17P80 mapped 30-60 kb from the 17p terminus. This sequence-ready map permits high-resolution integration of genetic maps with the DNA sequences directly adjacent to the tip of human chromosome 17p, and will provide the cloned DNA required for ascertaining the nucleotide sequence of this subtelomeric region.

Cloning and mapping of human chromosome 6q26-q27 deleted in B-cell non-Hodgkin lymphoma and multiple tumor types

Frequent deletions of the distal region on the long arm of chromosome 6 have been reported in multiple human tumors including B-cell non-Hodgkin lymphoma (B-NHL), suggesting the presence of one or more tumor suppressor genes (TSGs) at this locus. Previously, we identified a region of minimal molecular deletion at 6q25-q27 (RMD-1) in B-NHL cases. To facilitate positional cloning efforts to identify the RMD-1 TSG(s), a yeast artificial chromosome (YAC) contig consisting of 110 clones was constructed across 6q26-q27 by sequence-tagged site/probe content mapping. The contig integrates 79 ordered markers including restriction fragment length polymorphisms, minisatellites, microsatellites, YAC-insert termini, expressed sequence tags, and known genes. It spans 34 cM and has a minimal tiling path of approximately 12 clones, covering an estimated 9-14 Mb with nearly every marker on the map showing at least double linkage to its adjacent markers. Dual-color fluorescence in situ hybridization of selected marker pairs on normal pachytene chromosome 6 further confirmed the YAC-based mappings. Utilizing a loss of constitutional heterozygosity assay in the B-NHL tumor panel, 24 additional 6q26-q27 polymorphic markers (21 mapping to the contig) further defined RMD-1 between markers D6S186 proximally and D6S227 distally. The minimal tiling path of the B-NHL RMD-1 consists of approximately 8 YAC clones, providing a size estimate of 5-9 Mb. This interval contains, in their entirety, several smaller candidate TSG critical regions previously delimited in other tumor systems. The AF-6 gene, mapping within RMD-1, revealed no mutations in a small subset of B-NHL. The deletion and physical maps presented herein provide a framework for the identification of the gene(s) involved in B-NHL as well as other malignancies and diseases mapped to this region and provide the initial reagents for large-scale genomic sequencing.