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The mutational signatures of formalin fixation on the human genome
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The mutational signatures of formalin fixation on the human genome
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The mutational signatures of formalin fixation on the human genome
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Journal Article
The mutational signatures of formalin fixation on the human genome
2022
Overview
Clinical archives of patient material near-exclusively consist of formalin-fixed and paraffin-embedded (FFPE) blocks. The ability to precisely characterise mutational signatures from FFPE-derived DNA has tremendous translational potential. However, sequencing of DNA derived from FFPE material is known to be riddled with artefacts. Here we derive genome-wide mutational signatures caused by formalin fixation. We show that the FFPE-signature is highly similar to signature 30 (the signature of Base Excision Repair deficiency due to
NTHL1
mutations), and chemical repair of DNA lesions leads to a signature highly similar to signature 1 (clock-like signature due to spontaneous deamination of methylcytosine). We demonstrate that using uncorrected mutational catalogues of FFPE samples leads to major mis-assignment of signature activities. To correct for this, we introduce FFPEsig, a computational algorithm to rectify the formalin-induced artefacts in the mutational catalogue. We demonstrate that FFPEsig enables accurate mutational signature analysis both in simulated and whole-genome sequenced FFPE cancer samples. FFPEsig thus provides an opportunity to unlock additional clinical potential of archival patient tissues.
Many archived tumour samples are stored as formalin-fixed and paraffin-embedded (FFPE) blocks, but this treatment can impact downstream genomics analyses. Here, the authors derive the mutational signatures of formalin on the cancer genome, and present FFPEsig, an algorithm that can distinguish and correct FFPE mutational signatures in archived cancer samples.
