131 DIFFERENTIAL DNA METHYLATION CHANGES OF THE REPETITIVE SEQUENCES DURING PREIMPLANTATION DEVELOPMENT IN THE MOUSE

Abstract

DNA demethylation as an epigenetic change is a unique event genome-wide, occurring at preimplantation and germ cell stages during mouse development. The paternal genome after fertilization is demethylated first, referred to active demethylation, followed by demethylation of the maternal genome during preimplantation development in the mouse. To examine methylation changes in the early mouse embryo, methylation states of various genomic regions such as intracisternal A-particle (IAP), early retrotransposon (Etn) and centromeric satellite sequences were determined by means of a bisulfite sequencing method. For methylation analysis, genomic DNA was first isolated from each developmental stage of embryo (about 300 cells in total), respectively, and exposed to 1.9 M sodium bisulfite overnight. Targeted DNA sequences were amplified from bisulfite-treated genomic DNAs by PCR, cloned into pGEM T-easy vector and sequenced. Results indicated that IAP sequences maintained high levels of methylation until the morula stage and were demethylated in blastocysts. In contrast to the IAP sequences, methylation states of Etn elements were remarkably erased after fertilization, completely demethylated at the 8-cell stage and then remethylated at the morula stage. Centromeric satellite sequences showed low methylation states throughout all preimplantation stages of embryos, indicating that the satellite sequences are substantially demethylated in both paternal and maternal genomes. The results suggest that differential epifenetic changes among the repetitive sequences may be responsible for peculiar chromatin structure of respective genomic loci and/or may regulate gene expression during preimplantation development in the mouse.