The repertoire of mutational signatures in human cancer

Alexandrov, Ludmil B.; Kim, Jaegil; Haradhvala, Nicholas J.; Mi, Huang; Ng, Alvin Wei Tian; Wu, Yang; Boot, Arnoud; Covington, Kyle R.; Gordenin, Dmitry A.; Bergstrom, Erik N.; Islam, S. M. Ashiqul; López‐Bigas, Núria; Klimczak, Leszek J.; McPherson, John R.; Morganella, Sandro; Sabarinathan, Radhakrishnan; Wheeler, David A.; Mustonen, Ville; Getz, Gad; Rozen, Steven G.; Stratton, Michael R.

doi:10.1038/s41586-020-1943-3

Cited by 2,210 publications

(2,722 citation statements)

References 63 publications

(66 reference statements)

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“…In the third and fourth papers, Alexandrov et al 3 Notably, Li and colleagues are among the first to uncover reproducible signatures involving structural variants (SVs) -re arrangements of large portions of the genome. The process was much more intricate than that for identifying mutational signatures because of the diversity and complexity of SVs.…”

Section: Marcin Cieslik and Arul M Chinnaiyanmentioning

confidence: 99%

“…Since then, advances in sequencing technology and analytical tools have allowed this research field to flourish. In six papers [1][2][3][4][5][6] in this issue of Nature, the Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium presents the most comprehensive and ambitious meta-analysis of cancer genomes so far. Unlike previous efforts that focused largely on protein-coding regions of the cancer genome, PCAWG analyses whole genomes.…”

mentioning

confidence: 99%

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Global genomics project unravels cancer’s complexity at unprecedented scale

Cieślik

Chinnaiyan

2020

Nature

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Section: Marcin Cieslik and Arul M Chinnaiyanmentioning

confidence: 99%

mentioning

confidence: 99%

Global genomics project unravels cancer’s complexity at unprecedented scale

Cieślik

Chinnaiyan

2020

Nature

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“…Signature 1 (called SBS1 in (Alexandrov et al, 2020) and Sig.B in (Blokzijl et al, 2016)) represents mainly the C to T transitions in CpG contexts resulting from spontaneous deamination of methylated cytosine into thymine (Alexandrov et al, 2013;Blokzijl et al, 2016). This mutational process plays a major role in small intestinal and colon ASCs ( Fig EV1B).…”

Section: Transcription Factor Binding Regions Encompass Up To a Thirdmentioning

confidence: 99%

“…Somatic mutations are caused by a combination of DNA damage and DNA repair failures (Volkova et al, 2020). The interplay of these processes can produce mutation sets in different preferred genomic contexts, the so-called mutation signatures (Alexandrov et al, 2020(Alexandrov et al, , 2013, with varying impact on creation or disruption of transcription factor binding motifs (Yiu Chan et al, 2019). In cancer, the overall patterns of mutational processes in transcription factor binding sites are very complex, due to the interference of numerous incidental circumstances, both local, such as the extended context of mutation signatures (Fredriksson et al, 2017), and global, such as the pressure of clonal selection (Vorontsov et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Enhanced C/EBPs binding to C>T mismatches facilitates fixation of CpG mutations

Ershova

Eliseeva

Nikonov

et al. 2020

Preprint

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Knowledge of mechanisms responsible for mutagenesis of adult stem cells is crucial to track genomic alterations that may affect cell renovation and provoke malignant cell transformation. Mutations in regulatory regions are widely studied nowadays, though mostly in cancer. In this study, we decomposed the mutation signature of adult stem cells, mapped the corresponding mutations into transcription factor binding regions, and assessed mutation frequency in sequence motif occurrences. We found binding sites of C/EBP transcription factors strongly enriched with [C>T]G mutations within the core CG dinucleotide related to deamination of the methylated cytosine. This effect was also exhibited in related cancer samples. Structural modeling predicted enhanced CEBPB binding to the consensus sequence with the [C>T]G mismatch, which was then confirmed in the direct experiment. We propose that it is the enhanced binding of C/EBPs that shields C>T transitions from DNA repair and leads to selective accumulation of the [C>T]G mutations within binding sites.

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“…Single nucleotide variants (SNV) were called by Mutect2 10 . Resulting somatic SNVs were converted to 96-classes of trinucleotide context profiles by the PCAWG signature preparation tool 11 . Trinucleotide context profiles were used as input for sigProfiler 11 to perform a mutational signature analysis and to retrieve the signature exposures of 45 SNV signatures from COSMIC single base substitution (SBS) signatures V3.…”

Section: Quantification Of Single Base Substitution (Sbs) Signaturesmentioning

confidence: 99%

A versatile system to introduce clusters of genomic double-strand breaks in large cell populations

Kolb

Khalid

Simović

et al. 2020

Preprint

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In vitro assays for clustered DNA lesions will facilitate the analysis of the mechanisms underlying complex genome rearrangements such as chromothripsis, including the recruitment of repair factors to sites of DNA double-strand breaks. We present a novel method generating localized DNA double-strand breaks using UV-irradiation with photomasks. The size of the damage foci and the spacing between lesions are fully adjustable, making the assay suitable for different cell types and targeted areas. We validated this set-up with genomically stable epithelial cells, normal fibroblasts, pluripotent stem cells and patient-derived primary cultures. Our method does not require a specialized device such as a laser, making it accessible to a broad range of users. Sensitization by BrdU incorporation is not required, which enables analyzing the DNA damage response in post-mitotic cells. Irradiated cells can be cultivated further, followed by time-lapse imaging or used for downstream biochemical analyses, thanks to the high-throughput of the system. Importantly, we showed genome rearrangements in the irradiated cells, providing a proof of principle for the induction of structural variants by localized DNA lesions. * *** 0 J 1 0 0 J 2 0 0 J 3 0 0 J 0 1000 2000 3000 Energy applied γH2AX foci (mean intensity)

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The repertoire of mutational signatures in human cancer

Cited by 2,210 publications

References 63 publications

Global genomics project unravels cancer’s complexity at unprecedented scale

Global genomics project unravels cancer’s complexity at unprecedented scale

Enhanced C/EBPs binding to C>T mismatches facilitates fixation of CpG mutations

A versatile system to introduce clusters of genomic double-strand breaks in large cell populations

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