A role for the elongator complex in zygotic paternal genome demethylation

Abstract
After fertilization in mammals, the maternal and paternal genomes undergo epigenetic reprogramming to prepare for the transition from germ cell to somatic cell transcription programs. One of the events involved in this process is the rapid demethylation of the paternal genome. To identify factors involved in this process, a live-cell imaging system was developed to monitor paternal DNA methylation state in zygotes. Elp3, a component of the elongator complex, is found to be important for paternal DNA demethylation. After fertilization in mammals, the maternal and paternal genomes undergo epigenetic reprogramming to prepare for the transition from germ cell to somatic cell transcription programs. One of the events that takes place is the demethylation of the paternal genome. To identify the factors involved in this process, a live cell imaging system is now used to monitor the paternal DNA methylation state in zygotes; Elp3, a component of the elongator complex, is found to have an important role. The life cycle of mammals begins when a sperm enters an egg. Immediately after fertilization, both the maternal and paternal genomes undergo dramatic reprogramming to prepare for the transition from germ cell to somatic cell transcription programs1. One of the molecular events that takes place during this transition is the demethylation of the paternal genome2,3. Despite extensive efforts, the factors responsible for paternal DNA demethylation have not been identified4. To search for such factors, we developed a live cell imaging system that allows us to monitor the paternal DNA methylation state in zygotes. Through short-interfering-RNA-mediated knockdown in mouse zygotes, we identified Elp3 (also called KAT9), a component of the elongator complex5, to be important for paternal DNA demethylation. We demonstrate that knockdown of Elp3 impairs paternal DNA demethylation as indicated by reporter binding, immunostaining and bisulphite sequencing. Similar results were also obtained when other elongator components, Elp1 and Elp4, were knocked down. Importantly, injection of messenger RNA encoding the Elp3 radical SAM domain mutant, but not the HAT domain mutant, into MII oocytes before fertilization also impaired paternal DNA demethylation, indicating that the SAM radical domain is involved in the demethylation process. Our study not only establishes a critical role for the elongator complex in zygotic paternal genome demethylation, but also indicates that the demethylation process may be mediated through a reaction that requires an intact radical SAM domain.