Abstract 3863: Analytical performance of a novel next generation sequencing assay for myeloid cancers

Title: Analytical performance of a novel next generation sequencing assay for myeloid cancers Nick Khazanov, Wally Zhang, Dinesh Cyanam, Scott P. Myrand, Denis Kaznadzey, Paul Williams, Vinay Mittal, Dan Mazur, Sihong Chen, Jason Wustman, Efren Ballesteros-Villagrana, Goutam Nistala, Jon Sherlock, Michael Hogan, Jim Veitch, John Bishop, Seth Sadis Introduction: Myeloid malignancies contain a diverse and heterogeneous set of genomic alterations that include recurrent somatic mutations in key driver genes as well as frequent and diagnostic chromosomal rearrangements that generate a wide array of gene fusion products. To support clinical and translational research into precision oncology strategies for myeloid cancers, a next-generation sequencing (NGS) assay was generated to detect common and relevant somatic alterations. Methods: To define gene targets that were recurrently altered in myeloid cancers and relevant for clinical and translational research, an extensive survey of investigators at hematology oncology research labs was performed. The gene targets identified by researchers were complemented by a comprehensive survey of literature and genomic databases. Clinical guidelines for myeloid diseases in the US and in Europe were reviewed to ensure representation of relevant alterations. A targeted Ion AmpliSeq panel was generated to support the detection of recurrent single-nucleotide variants, insertions/deletions, and gene fusions from blood or bone marrow samples. The panel was developed for manual or automated library preparation and sequencing on the Ion Torrent PGM or Ion S5 instruments. Results: The Oncomine™ Myeloid Research Assay gene panel included 58 genes and generated an average read depth of >2,000 reads per targeted amplicon with an average uniformity of >95%. Important GC-rich targets such as CEBPA generated sufficient balanced read depth to support variant detection. A cohort of samples positive for FLT3 alterations was analyzed and successful detection of FLT3-internal tandem repeat variants was demonstrated. Several gene fusion transcripts common to myeloid cancers were detected. Comparable results were observed on Ion Torrent PGM and Ion S5 instruments. Conclusions: A novel myeloid specific NGS assay capable of detecting relevant DNA and RNA alterations from the same sample was developed. The assay is useful for characterizing relevant alterations in a range of myeloid diseases including acute myeloid leukemia, myelodysplastic syndrome, myeloproliferative neoplasms, chronic myelogenous leukemia, chronic myelomonocytic leukemia, and juvenile myelomonocytic leukemia. A review of the analytical studies will be presented. Citation Format: Nickolay Khazanov, Wally Zhang, Dinesh Cyanam, Scott P. Myrand, Denis Kaznadzey, Paul D. Williams, Vinay Mittal, Daniel J. Mazur, Sihong Chen, Jason Wustman, Efren Ballesteros-Villagrana, Goutam Nistala, Santhoshi Bandla, Jim Veitch, Jon Sherlock, John Bishop, Seth Sadis. Analytical performance of a novel next generation sequencing assay for myeloid cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 3863.