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Population sequencing data reveal a compendium of mutational processes in the human germ line.

Vladimir B SeplyarskiyRuslan A SoldatovEvan M KochRyan J McGintyJakob M GoldmannRyan D HernandezKathleen BarnesAdolfo CorreaEsteban González BurchardPatrick T EllinorStephen T McGarveyBraxton D MitchellRamachandran S VasanSusan RedlineEdwin K SilvermanScott T WeissDonna K ArnettJohn BlangeroEric BoerwinkleJiang HeCourtney G MontgomeryD C RaoJerome I RotterKent D TaylorJennifer A BrodyYii-Der Ida ChenLisa de Las FuentesChii-Min HwaStephen S RichAni W ManichaikulJosyf C MychaleckyiNicholette D D AllredJennifer A SmithSharon L R KardiaPatricia A PeyserLawrence F BielakTimothy D O'ConnorLeslie S Emerynull nullnull nullChristian GilissenWendy S W WongPeter V KharchenkoShamil R Sunyaev
Published in: Science (New York, N.Y.) (2021)
Biological mechanisms underlying human germline mutations remain largely unknown. We statistically decompose variation in the rate and spectra of mutations along the genome using volume-regularized nonnegative matrix factorization. The analysis of a sequencing dataset (TOPMed) reveals nine processes that explain the variation in mutation properties between loci. We provide a biological interpretation for seven of these processes. We associate one process with bulky DNA lesions that are resolved asymmetrically with respect to transcription and replication. Two processes track direction of replication fork and replication timing, respectively. We identify a mutagenic effect of active demethylation primarily acting in regulatory regions and a mutagenic effect of long interspersed nuclear elements. We localize a mutagenic process specific to oocytes from population sequencing data. This process appears transcriptionally asymmetric.
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