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

Miura, Sayaka; Vu, Tracy; Deng, Jiamin; Buturla, Tiffany; Oladeinde, Olumide; Choi, Joongdae; Kumar, Sudhir

doi:10.1038/s41598-020-59006-2

Cited by 21 publications

(18 citation statements)

References 74 publications

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“…This is also the case when n = 1000 and m = 300 when false negative rate is 0.05, however PhISCS fails to report solutions for some instances when false negative rate is 0.2. When m = 1000 the performance of SCITE (with a 24-hour time limit) under both measures falls substantially 4 Examples include the number of ancestor-descendant and different-lineage relationships shared across the trees compared, as well as more sophisticated measures such as the Multi-Labeled Tree Edit Distance and others [24,39,40,41,42]. 5 which is important especially since many methods build trees based on mutations shared by at least two cells or pre-cluster cells based on their mutational profiles 6 Another parameter used in our simulations is the missing value rate γ, which determines the fraction of entries in the genotype matrix which are unknown.…”

Section: Benchmarking Of Methods For Reconstructing Mutation Trees Of Tumor Progression On Simulated Datamentioning

confidence: 99%

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Profiles of expressed mutations in single cells reveal subclonal expansion patterns and therapeutic impact of intratumor heterogeneity

Mehrabadi

Marie

Pérez-Guijarro

et al. 2021

Preprint

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Advances in single cell RNA sequencing (scRNAseq) technologies uncovered an unexpected complexity in solid tumors, underlining the relevance of intratumor heterogeneity for cancer progression and therapeutic resistance. Heterogeneity in the mutational composition of cancer cells is well captured by tumor phylogenies, which demonstrate how distinct cell populations evolve, and, e.g. develop metastatic potential or resistance to specific treatments. Unfortunately, because of their low read coverage per cell, mutation calls that can be made from scRNAseq data are very sparse and noisy. Additionally, available tumor phylogeny reconstruction methods cannot computationally handle a large number of cells and mutations present in typical scRNAseq datasets. Finally, there are no principled methods to assess distinct subclones observed in inferred tumor phylogenies and the genomic alterations that seed them. Here we present Trisicell, a computational toolkit for scalable tumor phylogeny reconstruction and evaluation from scRNAseq as well as single cell genome or exome sequencing data. Trisicell allows the identification of reliable subtrees of a tumor phylogeny, offering the ability to focus on the most important subclones and the genomic alterations that are associated with subclonal proliferation. We comprehensively assessed Trisicell on a melanoma model by comparing the phylogeny it builds using scRNAseq data, to those using matching bulk whole exome (bWES) and transcriptome (bWTS) sequencing data from clonal sublines derived from single cells. Our results demonstrate that tumor phylogenies based on mutation calls from scRNAseq data can be robustly inferred and evaluated by Trisicell. We also applied Trisicell to reconstruct and evaluate the phylogeny it builds using scRNAseq data from melanomas of the same mouse model after treatment with immune checkpoint blockade (ICB). After integratively analyzing our cell-specific mutation calls with their expression profiles, we observed that each subclone with a distinct set of novel somatic mutations is strongly associated with a distinct developmental status. Moreover, each subclone had developed a specific ICB-resistance mechanism. These results demonstrate that Trisicell can robustly utilize scRNAseq data to delineate intratumoral heterogeneity and tumor evolution.

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Section: Benchmarking Of Methods For Reconstructing Mutation Trees Of Tumor Progression On Simulated Datamentioning

confidence: 99%

“… 3 Examples include the number of ancestor-descendant and different-lineage relationships shared across the trees compared, as well as more sophisticated measures such as the Multi-Labeled Tree Edit Distance and others [23, 37, 38, 39, 40]. …”

mentioning

confidence: 99%

Profiles of expressed mutations in single cells reveal subclonal expansion patterns and therapeutic impact of intratumor heterogeneity

Mehrabadi

Marie

Pérez-Guijarro

et al. 2021

Preprint

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“…The evolution of a tumor is typically described by a phylogenetic tree, or phylogeny, whose leaves represent the cells observed at the present time and whose internal nodes represent ancestral cells. Tumor phylogenies are challenging to reconstruct using DNA sequencing data from bulk tumor samples, since this data contains mixtures of mutations from thousandsmillions of heterogeneous cells in the sample [3][4][5][6][7][8][9][10][11][12][13][14][15] . Recently, single-cell DNA sequencing (scDNA-seq) of tumors has become more common, and new technologies such as those from 10X Genomics 16…”

Section: Introductionmentioning

confidence: 99%

Single-cell tumor phylogeny inference with copy-number constrained mutation losses

Satas

Zaccaria

Mon

et al. 2019

Preprint

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Motivation: Single-cell DNA sequencing enables the measurement of somatic mutations in individual tumor cells, and provides data to reconstruct the evolutionary history of the tumor. Nearly all existing methods to construct phylogenetic trees from single-cell sequencing data use single-nucleotide variants (SNVs) as markers. However, most solid tumors contain copy-number aberrations (CNAs) which can overlap loci containing SNVs. Particularly problematic are CNAs that delete an SNV, thus returning the SNV locus to the unmutated state. Such mutation losses are allowed in some models of SNV evolution, but these models are generally too permissive, allowing mutation losses without evidence of a CNA overlapping the locus. Results:We introduce a novel loss-supported evolutionary model, a generalization of the infinite sites and Dollo models, that constrains mutation losses to loci with evidence of a decrease in copy number.We design a new algorithm, Single-Cell Algorithm for Reconstructing the Loss-supported Evolution of Tumors (SCARLET), that infers phylogenies from single-cell tumor sequencing data using the losssupported model and a probabilistic model of sequencing errors and allele dropout. On simulated data, we show that SCARLET outperforms current single-cell phylogeny methods, recovering more accurate trees and correcting errors in SNV data. On single-cell sequencing data from a metastatic colorectal cancer patient, SCARLET constructs a phylogeny that is both more consistent with the observed copynumber data and also reveals a simpler monooclonal seeding of the metastasis, contrasting with published reports of polyclonal seeding in this patient. SCARLET substantially improves single-cell phylogeny inference in tumors with CNAs, yielding new insights into the analysis of tumor evolution.Availability: Software is available at

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“…By the way, in the above, we assumed that the clone phylogeny is known. In empirical data analysis, one needs to generate it using available computational tools for bulk and single-cell sequencing methods; see reviews in the accuracy of methods (Miura et al, 2018a; Miura et al, 2018b; Miura et al, 2020). The errors in the collection of variants for each branch will lead to false-negative detection of signatures due to diluted signals caused by incorrect variants and correct variants that are not assigned to a branch.…”

Section: Methodsmentioning

confidence: 99%

“…Tumor cells accumulate somatic mutations during cancer progression, in which cells exhibit dynamic demography, including emergence, expansion, and extinction (Bailey et al, 2018; Martincorena & Campbell, 2015). Through the analysis of genomic variation, researchers now routinely reconstruct mutational histories and phylogenies of clones (Brown et al, 2017; El-Kebir et al, 2018; Miura et al, 2020; Turajlic et al, 2018; Zhao et al, 2016). In a clone phylogeny, variants can be localized to individual branches and relative frequencies of different variant types compared across lineages to detect shifts in cellular mutational processes over time.…”

Section: Introductionmentioning

confidence: 99%

Phylomedicine of mutational processes in somatic cancer cell populations

Miura

Choi

et al. 2021

Preprint

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Mutational processes in somatic cancer cell populations are constantly changing, leaving their signatures in the accumulated genomic variation in tumors. The inference of mutational signatures from the observed genetic variation enables spatiotemporal tracking of tumor mutational processes that evolve due to cellular environmental changes, mutations, and treatment regimes. Ultimately, mutational patterns illuminate the mechanistic understanding of their evolution in cancer progression. We show that the integration of cancer cell phylogeny with mutational signature deconvolution enables higher-resolution detection of gain and loss of mutational processes within the phylogeny. This approach to analyzing somatic genomic variations in 61 lung cancer patients revealed a high turn-over of mutational processes over time and closely related clonal lineages. Some mutational signatures (e.g., smoking-related) showed a higher propensity to be lost, whereas others (e.g., AID/APOBEC) were gained during lung tumors evolution. These observations shed light on the evolution of mutational processes in somatic cell evolution.

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

Cited by 21 publications

References 74 publications

Profiles of expressed mutations in single cells reveal subclonal expansion patterns and therapeutic impact of intratumor heterogeneity

Profiles of expressed mutations in single cells reveal subclonal expansion patterns and therapeutic impact of intratumor heterogeneity

Single-cell tumor phylogeny inference with copy-number constrained mutation losses

Phylomedicine of mutational processes in somatic cancer cell populations

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