Tet3 and DNA Replication Mediate Demethylation of Both the Maternal and Paternal Genomes in Mouse Zygotes

Abstract

With the exception of imprinted genes and certain repeats, DNA methylation is globally erased during preimplantation development. Recent studies have suggested that Tet3-mediated oxidation of 5-methylcytosine (5mC) and DNA replication-dependent dilution both contribute to global paternal DNA demethylation, but demethylation of the maternal genome occurs via replication. Here we present genome-scale DNA methylation maps for both the paternal and maternal genomes of Tet3-depleted and/or DNA replication-inhibited zygotes. In both genomes, we found that inhibition of DNA replication blocks DNA demethylation independently from Tet3 function and that Tet3 facilitates DNA demethylation largely by coupling with DNA replication. For both genomes, our data indicate that replication-dependent dilution is the major contributor to demethylation, but Tet3 plays an important role, particularly at certain loci. Our study thus defines the respective functions of Tet3 and DNA replication in paternal DNA demethylation and reveals an unexpected contribution of Tet3 to demethylation of the maternal genome. •Tet3 only partially mediates paternal DNA demethylation•DNA replication is the major contributor to paternal DNA demethylation•Tet3-dependent DNA demethylation also occurs on the maternal genome•Zygotic gene activation is independent of Tet3 activity Using genome-scale DNA methylation analyses of manually isolated paternal and maternal pronuclei, Zhang and colleagues show that zygotic demethylation of both genomes is mediated by Tet3 and DNA replication, with the latter as the major contributor.