Characterization of physical gap sizes at human telomeres.

Abstract

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.