University of Leicester
Browse

Accurate, high-throughput typing of copy number variation using paralogue ratios from dispersed repeats

Download (767.3 kB)
journal contribution
posted on 2007-11-19, 15:38 authored by John A. L. Armour, R. Palla, P. L. Zeeuwen, M. den Heijer, J. Schalkwijk, Edward J. Hollox
Recent work has demonstrated an unexpected prevalence of copy number variation in the human genome, and has highlighted the part this variation may play in predisposition to common phenotypes. Some important genes vary in number over a high range (e.g. DEFB4, which commonly varies between two and seven copies), and have posed formidable technical challenges for accurate copy number typing, so that there are no simple, cheap, high-throughput approaches suitable for large-scale screening. We have developed a simple comparative PCR method based on dispersed repeat sequences, using a single pair of precisely designed primers to amplify products simultaneously from both test and reference loci, which are subsequently distinguished and quantified via internal sequence differences. We have validated the method for the measurement of copy number at DEFB4 by comparison of results from >800 DNA samples with copy number measurements by MAPH/REDVR, MLPA and array-CGH. The new Paralogue Ratio Test (PRT) method can require as little as 10 ng genomic DNA, appears to be comparable in accuracy to the other methods, and for the first time provides a rapid, simple and inexpensive method for copy number analysis, suitable for application to typing thousands of samples in large case-control association studies.

History

Citation

Nucleic Acids Research, 2007, 35 (3), p.e19.

Published in

Nucleic Acids Research

issn

0305-1048

Available date

2007-11-19

Publisher version

http://nar.oxfordjournals.org/content/35/3/e19

Language

en

Usage metrics

    University of Leicester Publications

    Categories

    No categories selected

    Keywords

    Exports

    RefWorks
    BibTeX
    Ref. manager
    Endnote
    DataCite
    NLM
    DC