CLEMENT: genomic decomposition and reconstruction of non-tumor subclones

Abstract Genome-level clonal decomposition of a single specimen has been widely studied; however, it is mostly limited to cancer research. In this study, we developed a new algorithm CLEMENT, which conducts accurate decomposition and reconstruction of multiple subclones in genome sequencing of non-t...

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Published in:Nucleic acids research 2024-06, Vol.52 (14), p.e62-e62
Main Authors: Chung, Young-soo, Kang, Seungseok, Kim, Jisu, Lee, Sangbo, Kim, Sangwoo
Format: Article
Language:English
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Summary:Abstract Genome-level clonal decomposition of a single specimen has been widely studied; however, it is mostly limited to cancer research. In this study, we developed a new algorithm CLEMENT, which conducts accurate decomposition and reconstruction of multiple subclones in genome sequencing of non-tumor (normal) samples. CLEMENT employs the Expectation-Maximization (EM) algorithm with optimization strategies specific to non-tumor subclones, including false variant call identification, non-disparate clone fuzzy clustering, and clonal allele fraction confinement. In the simulation and in vitro cell line mixture data, CLEMENT outperformed current cancer decomposition algorithms in estimating the number of clones (root-mean-square-error = 0.58–0.78 versus 1.43–3.34) and in the variant-clone membership agreement (∼85.5% versus 70.1–76.7%). Additional testing on human multi-clonal normal tissue sequencing confirmed the accurate identification of subclones that originated from different cell types. Clone-level analysis, including mutational burden and signatures, provided a new understanding of normal-tissue composition. We expect that CLEMENT will serve as a crucial tool in the currently emerging field of non-tumor genome analysis. Graphical Abstract Graphical Abstract
ISSN:0305-1048
1362-4962
1362-4962
DOI:10.1093/nar/gkae527