Resolving genetic heterogeneity in cancer

Turajlic, Samra; Sottoriva, Andrea; Graham, Trevor A.; Swanton, Charles

doi:10.1038/s41576-019-0114-6

Cited by 526 publications

(417 citation statements)

References 180 publications

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“…Genomic analyses of tumors are becoming increasingly sophisticated, allowing investigation of their histories and the mutations and processes that drive their development (Jolly and Van Loo, 2018;Turajlic et al, 2019). However, these analyses place many assumptions on the data they use (Dentro et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

Correcting reference bias from the Illumina Isaac aligner enables analysis of cancer genomes

Chubb

Frangou

et al. 2019

Preprint

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Estimating the fraction of cancer cells with individual somatic mutations is central to many analyses in cancer genomics, including characterisation of clonal architecture and timing of mutational events. Estimation of these cancer cell fractions (CCFs) is contingent on unbiased assessment of the fraction of reads supporting variant alleles (VAFs). We demonstrate that VAFs computed by the Illumina Isaac pipeline, used in many large-scale sequencing projects includingThe 100,000 Genomes Project, are biased by the preferential soft clipping of reads supporting non-reference alleles (semi-aligned reads). We show that these biased VAFs can have deleterious effects on downstream analyses reliant on unbiased CCF estimates. While Isaac bias can be corrected through realignment with alternative parameters, this is computationally intensive. We therefore developed FixVAF, a tool for removing bias introduced by soft clipping of semi-aligned reads, facilitating downstream analyses without the need for realignment. FixVAF is freely available at https://github.com/danchubb/FixVAF.

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Section: Discussionmentioning

confidence: 99%

Correcting reference bias from the Illumina Isaac aligner enables analysis of cancer genomes

Chubb

Frangou

et al. 2019

Preprint

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“…kb band (when targeted with CiMKi allele). 10 Confirmed targeted ES cell clones for both CiMKi mutations were injected into C57BL/6 blastocyst, which were then transplanted into pseudo-pregnant females (standard techniques, performed under the license of the GDL Utrecht). Chimeric mice were bred with C57BL/6 mice to obtain germline transmission.…”

Section: Mice: Strains Experiments and Analysismentioning

confidence: 99%

“…Aneuploidy is the result of chromosomal instability (CIN): the occasional gain or loss of whole chromosomes during mitosis. CIN can lead to genome destabilization [6][7][8][9] , and is associated with high intra-tumoral genomic heterogeneity, immune evasion, and promotion of metastases (reviewed in 10 ). Furthermore, CIN and aneuploidy are correlated with tumor aggressiveness, therapy resistance and poor patient prognosis [11][12][13][14][15][16][17][18][19] .…”

Section: Introductionmentioning

confidence: 99%

Degree and site of chromosomal instability define its oncogenic potential

Hoevenaar

Janssen

Quirindongo

et al. 2019

Preprint

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Most human cancers are aneuploid, due to a chromosomal instability (CIN) phenotype. Despite being hallmarks of cancer, however, the roles of CIN and aneuploidy in tumor formation have not unequivocally emerged from animal studies and are thus still unclear. CIN can both promote and suppress tumorigenesis, but variances in mechanisms and timings of CIN induction in different oncogenic backgrounds and associated tissues limit interpretation of the contributions of CIN. Using a novel conditional mouse model for diverse degrees of CIN, we find that a particular range is sufficient to drive very early onset spontaneous adenoma formation in the intestine, showing that CIN can act as a much more potent oncogenic driver than was previously reported. In mice predisposed to intestinal cancer (Apc Min/+ ), moderate but not low CIN causes a remarkable increase in adenoma burden in the entire intestinal tract, especially in the distal colon, more closely modelling human disease. Strikingly, high levels of CIN promote adenoma formation in the distal colon even more than moderate CIN does, but have no effect in the small intestine. Our results thus show that CIN can be potently oncogenic, but that certain levels of CIN can have contrasting effects in distinct tissues. KEYWORDSChromosomal instability (CIN), aneuploidy, intestinal cancer, colorectal cancer (CRC), organoids, APC

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“…Circular ecDNA lacks centromeres, causing random segregation of ecDNA into daughter cells after division [5] ( Figure 1). Compared to somatic changes of chromosomal DNA, this adds additional stochasticity to the evolutionary dynamics of ecDNA [10,11,12]. Consequently, patterns of inter-and intra-patient ecDNA heterogeneity differ compared to chromosomal point mutations [13,14,15].…”

Section: Introductionmentioning

confidence: 99%

Stochastic dynamics of extra-chromosomal DNA

Pichugin

Huang

Werner

2019

Preprint

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Nuclear extra-chromosomal DNA (ecDNA) is highly prevalent in human tumours. ecDNA amplifications can promote accessible chromatin, oncogen over-expression and imply a worse clinical prognosis.Yet, little is known about the evolutionary process of ecDNA in human cancers. Here, we develop the theoretical foundation of the ecDNA somatic evolutionary process combining mathematical, computational and experimental approaches. We show that random ecDNA segregation leads to unintuitive dynamics even if ecDNA is under very strong positive selection. Patterns of inter-and intra-tumour ecDNA and chromosomal heterogeneity differ markedly and standard approaches are not directly applicable to quantify ecDNA evolution. We show that evolutionary informed modelling leads to testable predictions on how to distinguish positively selected from neutral ecDNA dynamics. Our predictions describe the dynamics of circular amplicons in GBM39 cell line experiments, suggesting a 300% fitness increase due to circular extra-chromosomal EGFRvI I I amplifications. Our work lies the basis for further studies to quantitate ecDNA somatic evolutionary processes.

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Resolving genetic heterogeneity in cancer

Cited by 526 publications

References 180 publications

Correcting reference bias from the Illumina Isaac aligner enables analysis of cancer genomes

Correcting reference bias from the Illumina Isaac aligner enables analysis of cancer genomes

Degree and site of chromosomal instability define its oncogenic potential

Stochastic dynamics of extra-chromosomal DNA

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