Detection of rare mutant alleles by restriction endonuclease-mediated selective-PCR: Design and optimization

Abstract

Background: Restriction endonuclease-mediated selective (REMS)-PCR, allows detection of point mutations, deletions, and insertions. Reactions require concurrent activity of a restriction endonuclease (RE) and a DNA polymerase, both of which must be sufficiently thermostable to retain activity during thermocycling. The inclusion of the RE in REMS-PCR inhibits amplification of sequences containing the RE recognition site, thus producing selective amplification of sequences that lack the RE site. Methods: Assays were used that allowed the selection of conditions that produce concurrent RE/DNA polymerase activity. The RE thermostability assay involved thermocycling a RE under various conditions and assessing residual cleavage activity at various time points. Conditions found to preserve RE activity during thermocyling were then tested for their compatibility with DNA polymerase-mediated PCR. Results: A range of conditions that preserve activity of the RE BstNI over 30 cycles of PCR was identified. A subset of these conditions was subsequently found to mediate specific amplification using Taq DNA polymerase. These conditions were used to develop a REMS-PCR protocol for the detection of mutations at codon 12 of the K-ras gene. This protocol allowed the detection of 1 mutant allele in a background of 1000 wild-type alleles. The presence of primer sets for RE and PCR control amplicons provided unambiguous assessment of mutant status. Conclusion: Implementation of the assays described may facilitate development of REMS-PCR assays targeted to other loci associated with disease. (C) 2000 American Association for Clinical Chemistry.