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Power and pitfalls of computational methods for inferring clone phylogenies and mutation orders from bulk sequencing data.


ABSTRACT: Tumors harbor extensive genetic heterogeneity in the form of distinct clone genotypes that arise over time and across different tissues and regions in cancer. Many computational methods produce clone phylogenies from population bulk sequencing data collected from multiple tumor samples from a patient. These clone phylogenies are used to infer mutation order and clone origins during tumor progression, rendering the selection of the appropriate clonal deconvolution method critical. Surprisingly, absolute and relative accuracies of these methods in correctly inferring clone phylogenies are yet to consistently assessed. Therefore, we evaluated the performance of seven computational methods. The accuracy of the reconstructed mutation order and inferred clone groupings varied extensively among methods. All the tested methods showed limited ability to identify ancestral clone sequences present in tumor samples correctly. The presence of copy number alterations, the occurrence of multiple seeding events among tumor sites during metastatic tumor evolution, and extensive intermixture of cancer cells among tumors hindered the detection of clones and the inference of clone phylogenies for all methods tested. Overall, CloneFinder, MACHINA, and LICHeE showed the highest overall accuracy, but none of the methods performed well for all simulated datasets. So, we present guidelines for selecting methods for data analysis.

SUBMITTER: Miura S 

PROVIDER: S-EPMC7044161 | biostudies-literature | 2020 Feb

REPOSITORIES: biostudies-literature

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Power and pitfalls of computational methods for inferring clone phylogenies and mutation orders from bulk sequencing data.

Miura Sayaka S   Vu Tracy T   Deng Jiamin J   Buturla Tiffany T   Oladeinde Olumide O   Choi Jiyeong J   Kumar Sudhir S  

Scientific reports 20200226 1


Tumors harbor extensive genetic heterogeneity in the form of distinct clone genotypes that arise over time and across different tissues and regions in cancer. Many computational methods produce clone phylogenies from population bulk sequencing data collected from multiple tumor samples from a patient. These clone phylogenies are used to infer mutation order and clone origins during tumor progression, rendering the selection of the appropriate clonal deconvolution method critical. Surprisingly, a  ...[more]

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