Dynamics of DNA methylation levels in maternal and paternal rabbit genomes after fertilization.

The reprogramming of DNA methylation in early embryos has been considered to be essential for the reprogramming of differentiated parental genomes to totipotency, the transcription of embryonic genome activation (EGA) and subsequent development. However, its degree appears to differ as a function of species and it may be altered by the in vitro environment. While the rabbit is a pertinent model for species with a delayed EGA because both in vivo and in vitro developed embryos are easily available, the status of DNA methylation levels in both parental genomes after fertilization remains controversial. In order to generate precise data on the DNA methylation status in rabbit zygotes, we first of all defined five pronuclear (PN) stages during the first cell cycle and then classified in vivo and in vitro developed rabbit zygotes according to these PN stages. Using this classification we precisely quantified both methylated DNA and the total DNA content during the one cell stage. The quantification of methylated DNA, normalized for the total DNA content, showed that both pronuclei displayed distinct patterns of DNA methylation reprogramming. In the maternal pronucleus (MP) the methylation level remained constant throughout the one cell stage, thanks to maintenance methylation during the S phase. Conversely, in the paternal pronucleus (PP) partial demethylation occurred before replication, probably as a result of active DNA demethylation, while maintenance methylation subsequently occurred during the S phase. Interestingly, we showed that PP DNA methylation reprogramming was partially altered by the in vitro environment. Taken together, our approach evidenced that rabbit is one of the species displaying partial DNA demethylation in the PP, and for the first time demonstrated maintenance methylation activity in both pronuclei during the first S phase.