Systemic mutagen exposures reported by normal kidney cell genomes
Wang, Y.; Knight, W.; Ferreiro-Iglesias, A.; Abedi-Ardekani, B.; Pham, M. H.; Moody, S.; Hooks, Y.; Abascal, F.; Nunn, C.; Fitzgerald, S.; Cattiaux, T.; Gaborieau, V.; Fukagawa, A.; Jinga, V.; Rascu, S.; Sima, C.; Zaridze, D. G.; Mukeria, A. F.; Holcatova, I.; Hornakova, A.; Vasudev, N. S.; Banks, R. E.; Ognjanovic, S.; Savic, S.; Curado, M. P.; Zequi, S. d. C.; Reis, R. M.; Magnabosco, W. J.; Vianna, F.; Silva Neto, B.; Jarmalaite, S.; Zalimas, A.; Foretova, L.; Navratilova, M.; Phouthavongsy, L.; Shire, C.; Attawettayanon, W.; Sangkhathat, S.; Ding, C.; Lawson, A. R. J.; Latimer, C.; Humphre
Show abstract
Lifestyle, environmental and other exposures to exogenous mutagens generate somatic mutations in normal human cells in vivo and increase cancer risk. However, the global repertoire of exogenous mutagen exposures is uncertain. The mutational signatures of mutagens in normal tissues offer opportunities to detect such exposures and survey them at population level. Using single-molecule duplex sequencing of normal kidney (n=319) and blood (n=272) samples from 10 countries, we show that normal kidney cell genomes report an extensive repertoire of somatic mutational signatures. Microdissection of kidney structures revealed that proximal tubules exhibit higher mutation rates than other components of the nephron and most normal cell types despite low cell division rates. This is explained by marked enrichment of mutational signatures due to known exogenous carcinogenic mutagens including the plant-derived aristolochic acids, as well as several signatures of unknown causes including an unknown agent prevalent in Japan (SBS12), and signatures of uncertain origins (SBS40b and SBS40c). The results suggest the existence of multiple, common, systemically circulating mutagens affecting human populations and indicate that the genomes of kidney proximal tubule cells report such exposures with high sensitivity.
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