DNA methyltransferase loading, but not de novo methylation, is an oocyte-autonomous process stimulated by SCF signalling

Epigenetic reprogramming occurs during oocyte growth in mice, a stage where a number of important events are occurring, including transcription of maternal mRNAs for storage in the mature egg, global transcriptional silencing and the acquisition of meiotic competence. Oocyte growth occurs in conjunction with follicular development over a period of many days. The signals involved in initiating different stages in oocyte and follicular development and the concurrent epigenetic changes are poorly understood. Here we examine the role of stem cell factor (SCF or Kit ligand) on the early- to mid-stages of oocyte growth and on DNA methyltransferase expression and function using a one-step in vitro culture system. Our results show that SCF promotes early oocyte growth and development to the multilaminar follicle stage. Oocyte growth is sufficient to trigger transcription of Dnmt1 and Dnmt3L from dedicated oocyte promoters, and we show that eggs undergoing growth in the absence of follicle development in Foxo3 mutants show elevated levels of Dnmt1. The methyltransferase proteins undergo sequential relocalisation in the oocyte, with DNMT1 being exported from the nucleus at the bilaminar follicle stage, while DNMT3A is transported into the nucleus at the multilaminar stage, indicating an important role for trafficking in controlling imprinting. SCF is thought to signal partly through the phophostidylinositol 3 (PI3) kinase pathway: inhibiting this path was previously shown to prevent FOXO3 nuclear export and we could show here that it also prevented DNMT1 export. Some oocytes reached full size (70 μM) in this in vitro system, but no secondary follicles were formed, most likely due to failure of the thecal layer to form properly. De novo methylation of imprinted genes was seen in some oocyte cultures, with methylation levels being highest for Snrpn and Igf2r which are methylated early in vivo, while Peg1, which is methylated late, showed little or no methylation. SCF treatment did not increase the number of cultures showing methylation. We saw no evidence for de novo methylation of IAP repeats in our cultures. These results suggest that while methyltransferase loading is triggered by oocyte growth, in which SCF plays an important role, complete methylation probably requires progression to the secondary follicle stage and is unlikely to be affected by SCF.