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| Nature 338, 774 - 776 (27 April 1989); doi:10.1038/338774a0 |
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Molecular cloning of human telomeres in yeast
William R. A. Brown
Biochemistry Department, Oxford University, South Parks Road, Oxford OX1 3QU, UK
TELOMERES are the DNA sequences found at the ends of linear chromosomes. They define the boundaries of the genetical and physical maps of such chromosomes and so are particularly important for the complete mapping of large genomes that is now being attempted. Telomeres have been intensively studied in the yeast Saccharomyces cerevisiae and in ciliated protozoa1: in these organisms the telomeric DNA consists of arrays of tandemly repeated short sequences in which one strand is guanosine-rich and oriented 5' to 3' towards the chromosome end. The conservation of these structural features is reflected in the observation that telomeric DNA from a variety of protozoa will function as telomeres on artificial linear mini-chromosomes in yeast1, 2. Tandem arrays of the sequence TTAGGG have been identified at the telomeres of humans and other mammals3 and also of trypanosomes4. This indicates that the structural features of telomeres are conserved between higher and lower eukaryotes and implies that human telomeric DNA could function in yeast. I have used this idea to develop a strategy to isolate a specific human telomere as a molecular clone in yeast and have devised a simple and effective way of cloning other human telomeres and their associated sequences.
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