Abstract
Whole exome sequencing (WES) is used to identify mutations in a patient’s tumor DNA that are predictive of tumor behavior, including the likelihood of response or resistance to cancer therapy. WES has a mutation limit of detection (LoD) at variant allele frequencies (VAF) of 5%. Putative mutations called at ≤ 5% VAF are frequently due to sequencing errors, therefore reporting these subclonal mutations incurs risk of significant false positives. Here we performed ~ 1000 × WES on fresh-frozen and formalin-fixed paraffin-embedded (FFPE) tissue biopsy samples from a non-small cell lung cancer patient, and identified 226 putative mutations at between 0.5 and 5% VAF. Each variant was then tested using NuProbe NGSure, to confirm the original WES calls. NGSure utilizes Blocker Displacement Amplification to first enrich the allelic fraction of the mutation and then uses Sanger sequencing to determine mutation identity. Results showed that 52% of the 226 (117) putative variants were disconfirmed, among which 2% (5) putative variants were found to be misidentified in WES. In the 66 cancer-related variants, the disconfirmed rate was 82% (54/66). This data demonstrates Blocker Displacement Amplification allelic enrichment coupled with Sanger sequencing can be used to confirm putative mutations ≤ 5% VAF. By implementing this method, next-generation sequencing can reliably report low-level variants at a high sensitivity, without the cost of high sequencing depth.
Highlights
Whole exome sequencing (WES) is used to identify mutations in a patient’s tumor DNA that are predictive of tumor behavior, including the likelihood of response or resistance to cancer therapy
In this article we describe a study with 226 WES detected variants of variant allele frequencies (VAF) < 5% analyzed by Blocker Displacement Amplification technology (BDA) qPCR/Sanger method. 52% (117/226) of the variants were disconfirmed
For low quality DNA samples like the formalin-fixed paraffin-embedded (FFPE) sample used in this study, we recommend confirmation for variants with higher threshold (e.g. VAF < 20%)
Summary
Whole exome sequencing (WES) is used to identify mutations in a patient’s tumor DNA that are predictive of tumor behavior, including the likelihood of response or resistance to cancer therapy. In the 66 cancer-related variants, the disconfirmed rate was 82% (54/66) This data demonstrates Blocker Displacement Amplification allelic enrichment coupled with Sanger sequencing can be used to confirm putative mutations ≤ 5% VAF. By implementing this method, next-generation sequencing can reliably report low-level variants at a high sensitivity, without the cost of high sequencing depth. Higher mutation sensitivity is required to identify subclonal drug resistance mutations from tumor tissue or perform non-invasive tumor profiling with cell-free DNA from peripheral blood samples (“liquid biopsy”)[6,7] For these applications, high clinical sensitivity can only be achieved when the NGS panel’s mutation sensitivity reaches 0.1% to 0.5% VAF. Mu et al reported an extensive Sanger confirmation of 7845 variants called in a 14-gene NGS panel; most disconfirmed variants were
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