Abstract 3649: Targeted sequencing of 409 cancer-related genes for somatic mutations and copy number variations in human cancer using the semiconductor sequencers

Abstract

Abstract Next-generation sequencing technologies have revolutionized cancer genomics research by providing a comprehensive method of detecting somatic cancer genome alterations. In this study, we describe a next-generation semiconductor sequencing protocol for rapid (2 days), standardized, and cost-effective gene analysis for human cancer specimens including FFPE samples. DNA was extracted from 19 human cancer cell lines and 61 human cancer specimens and their corresponding non-cancerous tissues, including oral squamous cell carcinomas and multiple myelomas. Using the Ion Ampliseq Comprehensive Cancer Panel, we sequenced 15992 loci from 409 tumor suppressor genes and oncogenes frequently cited and frequently mutated in human cancers (covered regions = 95.4% of total). Each sample underwent on average 8.3 million sequencing reads after quality filtering. The mean read depths were 461x, and >95% of targeted bases were represented by at least 20 reads. We also detected copy number variations in which segments of the genome can be duplicated or deleted from sequencing data. We found several genetic alterations that may have been associated with the poor prognosis and poor response to chemotherapy of cancer patients. Pathway assessment has shown that somatic aberrations within myeloma genomes are mainly involved in several important pathways, including cell cycle regulation, RTK-MAPK-PI3K and NF-kB. This study demonstrates the utility of using a semiconductor-based sequencing to efficiently identify human cancer mutations. The targeted next generation sequencing using low amounts of FFPE DNA is a valuable tool for high-throughput genetic testing in research and clinical settings. Citation Format: Yasushi Sasaki, Ryota Koyama, Takafumi Nakagaki, Miyuki Tamura, Masashi Idogawa, Takashi Tokino. Targeted sequencing of 409 cancer-related genes for somatic mutations and copy number variations in human cancer using the semiconductor sequencers. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 3649.