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Abstract

Aneuploidy and whole genome duplication (WGD) events are common features of cancers associated with poor outcomes, but the ways they influence trajectories of clonal evolution are poorly understood. Phylogenetic methods for reconstructing clonal evolution from genomic data have proven a powerful tool for understanding how clonal evolution occurs in the process of cancer progression, but extant methods so far have limited the ability to resolve tumor evolution via ploidy changes. This limitation exists in part because single-cell DNA-sequencing (scSeq), which has been crucial to developing detailed profiles of clonal evolution, has difficulty in resolving ploidy changes and WGD. Multiplex interphase fluorescence in situ hybridization (miFISH) provides a more unambiguous signal of single-cell ploidy changes but it is limited to profiling small numbers of single markers. Here, we develop a joint clustering method to combine these two data sources with the goal of better resolving ploidy changes in tumor evolution. We develop a probabilistic framework to maximize the probability of latent variables given the pre-clustered datasets, which we optimize via Markov chain Monte Carlo sampling combined with linear regression. We validate the method by using simulated data derived from a glioblastoma (GBM) case profiled by both scSeq and miFISH. We further apply the method to two GBM cases with scSeq and miFISH data by reconstructing a phylogenetic tree from the joint clustering results, demonstrating their synergistic value in understanding how focal copy number changes and WGD events can collectively contribute to tumor progression.

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References

Bakhoum

S.F.

, Ngo

, Laughney

A.M.

, et al. 2018. Chromosomal instability drives metastasis through a cytosolic DNA response. Nature, 553, 467–472.

Beroukhim

, Getz

, Nghiemphu

, et al. 2007. Assessing the significance of chromosomal aberrations in cancer: Methodology and application to glioma. Proc. Natl Acad. Sci. U. S. A. 104, 20007–20012.

Bielski

C.M.

, Zehir

, Penson

A.V.

, et al. 2018. Genome doubling shapes the evolution and prognosis of advanced cancers. Nat. Genet. 50, 1189–1195.

Chowdhury

S.A.

, Gertz

E.M.

, Wangsa

, et al. 2015. Inferring models of multiscale copy number evolution for single-tumor phylogenetics. Bioinformatics, 31, i258–267.

Chowdhury

S.A.

, Shackney

S.E.

, Heselmeyer-Haddad

, et al. 2013. Phylogenetic analysis of multiprobe fluorescence in situ hybridization data from tumor cell populations. Bioinformatics, 29, i189–i198.

Chowdhury

S.A.

, Shackney

S.E.

, Heselmeyer-Haddad

, et al. 2014. Algorithms to model single gene, single chromosome, and whole genome copy number changes jointly in tumor phylogenetics. PLoS Comput. Biol. 10, e1003740.

Crespo

, Vital

A.L.

, Nieto

A.B.

, et al. 2011. Detailed characterization of alterations of chromosomes 7, 9, and 10 in glioblastomas as assessed by single-nucleotide polymorphism arrays. J. Mol. Diagn. 13, 634–647.

Fujisawa

, Reis

R.M.

, Nakamura

, et al. 2000. Loss of heterozygosity on chromosome 10 is more extensive in primary (de novo) than in secondary glioblastomas. Lab. Invest. 80, 65–72.

Gertz

E.M.

, Chowdhury

S.A.

, Lee

W.-J.

, et al. 2016. FISHtrees 3.0: Tumor phylogenetics using a ploidy probe. PLoS One, 11, e0158569.

10.

Heng

H.H.

, Bremer

S.W.

, Stevens

J.B.

, et al. 2013. Chromosomal instability (CIN): What it is and why it is crucial to cancer evolution. Cancer Metastasis Rev. 32, 325–340.

11.

Lei

, Lyu

, Gertz

E.M.

, et al. 2020a. Tumor copy number deconvolution integrating bulk and single-cell sequencing data. J. Comput. Biol. 27, 565–598.

12.

Lei

, Gertz

E.M.

, Schäffer

, et al. 2020b. Tumor heterogeneity assessed by sequencing and fluorescence in situ hybridization (FISH) data. bioRxiv 2020.02.29.970392.

13.

Letouzé

, Allory

, Bollet

M.A.

, et al. 2010. Analysis of the copy number profiles of several tumor samples from the same patient reveals the successive steps in tumorigenesis. Genome Biol. 11(Suppl 1), P25.

14.

McInnes

, Healy

, and Melville

2018. UMAP: Uniform Manifold Approximation and Projection for Dimension Reduction. arXiv preprint; arXiv.1802.03426.

15.

Navin

, Kendall

, Troge

, et al. 2011. Tumour evolution inferred by single-cell sequencing. Nature, 472, 90–94.

16.

Nowell

1976. The clonal evolution of tumor cell populations. Science, 194, 23–28.

17.

Oltmann

, Heselmeyer-Haddad

, Hernandez

L.S.

, et al. 2018. Aneuploidy, tp53 mutation, and amplification of myc correlate with increased intratumor heterogeneity and poor prognosis of breast cancer patients. Genes Chromosomes Cancer. 57, 165–175.

18.

Pennington

, Smith

C.A.

, Shackney

, et al. 2007. Reconstructing tumor phylogenies from heterogeneous single-cell data. J. Bioinform. Comput. Biol. 5, 407–427.

19.

Petkovic

, Watkins

T.B.

, Colliver

E.C.

, et al. 2021. Whole-genome doubling-aware copy number phylogenies for cancer evolution with MEDICC2. bioRxiv 2021.02.28.433227.

20.

Sainudiin

, and Veber

2015. A beta-splitting model for evolutionary trees. R. Soc. Open Sci. 3, 160016.

21.

Satas

, Zaccaria

, Mon

, et al. 2020. SCARLET: Single-cell tumor phylogeny inference with copy-number constrained mutation losses. Cell Syst. 10, 323–332.

22.

Schwartz

, and Schäffer

A.A.

2017. The evolution of tumour phylogenetics: Principles and practice. Nat. Rev. Genet. 18, 213–229.

23.

Schwarz

R.F.

, Trinh

, Sipos

, et al. 2014a. Phylogenetic quantification of intra-tumour heterogeneity. PLoS Comput. Biol. 10, 1003535.

24.

Schwarz

R.F.

, Trinh

, Sipos

, et al. 2014b. Phylogenetic quantification of intra-tumour heterogeneity. PLoS Comput. Biol. 10, e1003535.

25.

Shackney

S.E.

, Singh

S.G.

, Yakulis

, et al. 1995. Aneuploidy in breast cancer: A fluorescence in situ hybridization study. Cytometry, 22, 282–291.

26.

Storchova

, and Pellman

2004. From polyploidy to aneuploidy, genome instability and cancer. Nat. Rev. Mol. Cell Biol. 5, 45–54.

27.

Van de Peer

, Mizrachi

, and Marchal

2017. The evolutionary significance of polyploidy. Nat Rev Genet. 18, 411–424.

28.

Verhaak

R.G.

, Hoadley

K.A.

, Purdom

, et al. 2010. Integrated genomic analysis identifies clinically relevant subtypes of glioblastoma characterized by abnormalities in PDGFRA, IDH1, EGFR, and NF1. Cancer Cell, 17, 98–110.

29.

, Wan

, Hou

, et al. 2016. Diverse evolutionary dynamics in glioblastoma inference by multi-region and single-cell sequencing. J Clin Oncol. 34, 11580.

30.

Zaccaria

, and Raphael

B.J.

2020. Characterizing allele- and haplotype-specific copy numbers in single cells with CHISEL. Nat. Biotechnol. 39, 1–8.

31.

Zack

T.I.

, Schumacher

S.E.

, Carter

S.L.

, et al. 2013. Pan-cancer patterns of somatic copy number alteration. Nat. Genet. 45, 1134–1140.

32.

Zafar

, Navin

, Chen

, et al. 2019. SiCloneFit: Bayesian inference of population structure, genotype, and phylogeny of tumor clones from single-cell genome sequencing data. Genome Res. 29, 1847–1859.

33.

Zeira

, and Raphael

B.J.

2020. Copy number evolution with weighted aberrations in cancer. Bioinformatics, 36, i344–i352.

34.

Zeira

, Zehavi

, and Shamir

2017. A linear-time algorithm for the copy number transformation problem. J. Comput. Biol. 24, 1179–1194.

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Joint Clustering of Single-Cell Sequencing and Fluorescence In Situ Hybridization Data for Reconstructing Clonal Heterogeneity in Cancers

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