Genome-wide hydroxymethylcytosine pattern changes in response to oxidative stress

Benjamin Delatte; Jana Jeschke; Matthieu Defrance; Martin Bachman; Catherine Creppe; Emilie Calonne; Martin Bizet; Rachel Deplus; Laura Marroquí; Myriam Libin; Mirunalini Ravichandran; Françoise Mascart; Décio L. Eizirik; Adele Murrell; Tomasz P. Jurkowski; François Fuks

doi:10.1038/srep12714

Genome-wide hydroxymethylcytosine pattern changes in response to oxidative stress

Benjamin Delatte(Epigenomics (Germany)), Jana Jeschke(Epigenomics (Germany)), Matthieu Defrance(Epigenomics (Germany)), Martin Bachman(University of Cambridge), Catherine Creppe(Epigenomics (Germany)), Emilie Calonne(Epigenomics (Germany)), Martin Bizet(Epigenomics (Germany)), Rachel Deplus(Epigenomics (Germany)), Laura Marroquí(Boston University Brussels), Myriam Libin(Total (Belgium)), Mirunalini Ravichandran(University of Stuttgart), Françoise Mascart(Total (Belgium)), Décio L. Eizirik(Boston University Brussels), Adele Murrell(University of Cambridge), Tomasz P. Jurkowski(University of Stuttgart), François Fuks(Epigenomics (Germany))

Scientific Reports

August 4, 2015

10.1038/srep12714

Cited by 58Open Access

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Abstract

The TET enzymes convert methylcytosine to the newly discovered base hydroxymethylcytosine. While recent reports suggest that TETs may play a role in response to oxidative stress, this role remains uncertain, and results lack in vivo models. Here we show a global decrease of hydroxymethylcytosine in cells treated with buthionine sulfoximine, and in mice depleted for the major antioxidant enzymes GPx1 and 2. Furthermore, genome-wide profiling revealed differentially hydroxymethylated regions in coding genes, and intriguingly in microRNA genes, both involved in response to oxidative stress. These results thus suggest a profound effect of in vivo oxidative stress on the global hydroxymethylome.

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