Abstract
Abstract The purpose of this study is to develop a universally applicable Duplex Sequencing (DS) assay for extremely sensitive detection of minimal residual disease (MRD) in acute myeloid leukemia (AML). The presence of MRD plays a critical role in AML recurrence and mortality, and is an important prognostic marker to guide clinical care and clinical trial risk stratification. Unfortunately, current MRD detection methods, including light microscopy, cytogenetics, qPCR, and flow cytometry have shortcomings in terms of sensitivity, general applicability, and/or inter-laboratory reproducibility. Duplex Sequencing eliminates technical artefacts observed with other sequencing technologies and delivers an unprecedented level of accuracy and sensitivity, on widely available NGS platforms. Here, we report validation of our DS MRD mutation detection assay, with a background mutation level more than 100-fold below single-stranded tag-based error correction (SSCS). Our complete DS MRD probe panel targets mutation hotspots or full coding sequences in 29 genes recurrently mutated in AML, representing mutations found in approximately 90% of patients. Supplementing with a targeted RNA-seq panel for recurrent gene fusions would approach 100%. To simulate low frequency mutations in MRD, we generated 2 DNA dilution series: either AML patient DNA or cell line DNA with known AML mutations that were serially diluted into normal human DNA. Replicate libraries were prepared with custom targeted probe panels and sequenced to over 50,000x or over 1,000,000x total Duplex depth (original Duplex DNA molecules sequenced per site), respectively. Expected mutations were detected down to MAFs of 1.9x10-5 and 6.0x10-6. Background mutation levels of 5.7x10-7 and 5.8x10-7, were respectively seen in each series, and likely reflect the true age-associated biological background, rather than technical noise. SSCS artefacts in these samples were approximately 100x higher than the frequency of DS mutations, and obscured expected mutations in the lower dilutions. We are further validating our method in both retrospective and prospective studies. In retrospective samples from a completed clinical trial, we are comparing the sensitivity and accuracy of DS vs. multicolor flow cytometry for MRD with known clinical outcomes. The relative prognostic value of DNA from blood vs. bone marrow will be quantified with DS as well. We will also perform DS on prospective samples to examine the prognostic value of specific genes and MAFs to eliminate uninformative variants, which will also allow accurate quantification of low level mutations in non-leukemic clones that accumulate with aging and can confound detection of MRD. Elimination of sequencing artefacts is critical for the application of NGS assays to MRD detection, especially when expected mutations are unknown, and DS is an important new tool in high sensitivity cancer diagnostics. Citation Format: Jacob E. Higgins, Lindsey N. Williams, Christopher S. Hourigan, Jerald P. Radich, Jesse J. Salk. Duplex sequencing for MRD detection in acute myeloid leukemia [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 422.
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