24 EFFECTS OF HISTONE METHYLATION RELATED GENES ON EPIGENETIC REPROGRAMMING AND ZYGOTIC GENE ACTIVATION IN OVINE SOMATIC CELL NUCLEAR TRANSFER (SCNT) EMBRYOS

Abstract

After fertilization, early embryo development is dependent upon maternally inherited proteins and protein synthesised from maternal mRNA until zygotic gene activation (ZGA) occurs. The transition of transcriptional activity from maternal to embryonic control occurs with the activation of rRNA genes and the formation of the nucleolus at the 8- to 16-cell stage that coincides with a prolonged fourth cell cycle in bovine and ovine embryos. However, previous studies have reported a shift in the longest cell cycle (fifth cell cycle) in bovine somatic cell nuclear transfer (SCNT) embryos, suggesting that the major genome activation is delayed, possibly due to incomplete changes in chromatin structure such as hypermethylation and hypoacetylation of histone (Memili and First 2000 Zygote 8, 87–96; Holm et al. 2003 Cloning Stem Cells 5, 133–142). Although global gene expression profile studies have been carried out in somatic cell nuclear transfer embryos, little is known about the expression of genes which can alter chromatin structure in early embryo development and possibly effect ZGA. To determine whether epigenetic reprogramming of donor nuclei affected ZGA and expression profiles in SCNT embryos, ZBTB33 (zinc finger and BTB domain containing 33, also known as kaiso, a methy-CpG specific repressor), BRG1(brahma-related gene 1, SWI/SNF family of the ATP-dependent chromatin remodeling complexes), JMJD1A (jumonji domain containing 1A, H3K9me2/1-specific demethylase), JMJD1C (putative H3K9-specific demethylase), and JMJD2C (H3K9me3-specific demethylase) were examined by RT-PCR at different developmental stages [germinal vesicle (GV), metaphase II (MII), 8- to 16-cell, 16- to 32-cell, and blastocyst in both parthenogenetic and SCNT embryos]. All genes were detected in parthenogenetic and SCNT blastocyts, and ZBTB33 was also expressed in all embryos at all stages tested. However, the onset of expression of JMJD1C, containing POU5F1 binding site at 5′-promoter region and BRG1 required for ZGA are delayed in SCNT embryos as compared to parthenotes (16- v. 8-cell, and blastoocyst v. 16-cell stage). Furthermore, JMJD2C containing NANOG binding sites at the 3′-flanking region was expressed in GV and MII oocytes and parthenogenetic blastocysts, whereas in SCNT embryos, JMJD2C was only observed from the 16-cell stage onwards. Interestingly, JMJD1A, which is positively regulated by POU5F1, was not detected in GV and MII oocytes but was present in blastocyst stage embryos of both groups. Taken together, these results suggest that incomplete epigenetic modifications of genomic DNA and histones lead to a delayed onset of ZGA which may affect further development and establishment of totipotency. Subsequently, aberrant expression patterns reported previously in SCNT embryos may be attributed to improper expression of histone H3K9 and H3K4 demethylase genes during early embryo development.