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Elimination of False Positives Generated Through PCR Re-amplification of Differential Display cDNA

    G. Miele

    Roslin Institute, Roslin

    BBSRC/MRC Neuropathogenesis Unit, Edinburgh, Scotland, UK

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    ,
    L. MacRae

    Roslin Institute, Roslin

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    ,
    D. McBride

    Roslin Institute, Roslin

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    ,
    J. Manson

    BBSRC/MRC Neuropathogenesis Unit, Edinburgh, Scotland, UK

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    &
    M. Clinton

    *Address correspondence to: Dr. Michael Clinton, Division of Development & Reproduction, Roslin Institute, Roslin, Midlothian, Scotland, EH25 9PS. Internet:

    E-mail Address: michael.clinton@bbsrc.ac.uk

    Roslin Institute, Roslin

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    Published Online:15 Aug 2018https://doi.org/10.2144/98251rr02

    Abstract

    Differential display (DD) is a powerful molecular tool that allows the identification and subsequent isolation of transcripts differentially expressed between biological samples, for example, between undifferentiated and differentiated cells, between different tissues or in one tissue at different stages of development.

    However, significantly high rates of apparent false positives have been reported using this technique. We suggest that the vast majority of false positives do not represent the originally selected transcript, but instead result from the re-amplification of cDNA species that co-migrate with the cDNA of interest in DD gels.

    Here we describe the use of a procedure to resolve co-migrating cDNAs and to purify the candidate of interest before cloning. The use of this modified technique resolves downstream problems encountered during DD experiments.