Abstract
Oocyte meiotic progression and maternal-to-zygote transition are accompanied by dynamic epigenetic changes. The functional significance of these changes and the key epigenetic regulators involved are largely unknown. Here we show that Setdb1, a lysine methyltransferase, controls the global level of histone H3 lysine 9 di-methyl (H3K9me2) mark in growing oocytes. Conditional deletion of Setdb1 in developing oocytes leads to meiotic arrest at the germinal vesicle and meiosis I stages, resulting in substantially fewer mature eggs. Embryos derived from these eggs exhibit severe defects in cell cycle progression, progressive delays in preimplantation development, and degeneration before reaching the blastocyst stage. Rescue experiments by expressing wild-type or inactive Setdb1 in Setdb1-deficient oocytes suggest that the catalytic activity of Setdb1 is essential for meiotic progression and early embryogenesis. Mechanistically, up-regulation of Cdc14b, a dual-specificity phosphatase that inhibits meiotic progression, greatly contributes to the meiotic arrest phenotype. Setdb1 deficiency also leads to derepression of transposons and increased DNA damage in oocytes, which likely also contribute to meiotic defects. Thus, Setdb1 is a maternal-effect gene that controls meiotic progression and is essential for early embryogenesis. Our results uncover an important link between the epigenetic machinery and the major signaling pathway governing meiotic progression.
Highlights
Mammalian development begins with fertilization, when the haploid sperm and egg fuse to form the diploid zygote
Maternal Setdb1 Is Required for Meiosis and Embryogenesis in Mice
Overexpression of Cdc14b in 1-cell embryos has been shown to cause mitotic arrest and inhibit zygotic genome activation (ZGA) [9]. These findings suggest that proper regulation of Cdc14b expression is important for meiosis and early embryogenesis
Summary
Mammalian development begins with fertilization, when the haploid sperm and egg fuse to form the diploid zygote. Both gametes have equal genetic contributions to the offspring, the early embryo is almost entirely dependent on the egg for the supply of subcellular organelles and macromolecules for initial survival and development [1]. These maternal components are encoded by maternal-effect genes, which are transcribed in oocytes and their products (RNA or protein) are present in early embryos before expression of zygotic genes is initiated. The molecular machinery and regulatory mechanisms involved in meiotic progression and maternal-tozygotic transition are not well understood
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