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Role of Epigenetics in Preservation of Oocytes Through Childhood

Epigenetic modifications established during gametogenesis regulate transcription and other nuclear processes in gametes, but also have influences in the zygote, embryo and postnatal life.

A new research now sheds light on the role of epigenetics in placing egg cells into stasis through childhood.

Keeping egg cells in stasis during childhood is a key part of female fertility- a fertilised egg cell is the start of every human life.

Egg cells are created inside a woman’s body even before she is born. They are then kept in stasis throughout childhood until they’re needed as an adult. If egg cells don’t go into stasis they can’t become mature eggs and they will never have the chance to form a new life. And in order to put an egg cell into stasis, biology requires many epigenetic marks throughout its DNA.

Epigenetic marks attached to DNA act as footnotes, indicating which genes are turned ‘on’ or ‘off’.

Therefore, the key is to understand where these marks come from in egg cells and how mistakes can cause disease. It is particula

rly challenging to study epigenetics in egg cells as there are so few of them.

Therefore, a study led by Dr Gavin Kelsey in the Babraham Institute and colleagues in Dresden and Munich, created new, highly sensitive ways to detect epigenetic marks in such small numbers of cells.

Using this approach, they found that, as eggs develop, a mark called H3K4me3 spreads throughout the genome. Scientists have already seen the same mark close to the start of active genes in many cells, but the team discovered that its role in egg cells is different.

Role of Epigenetics in Preservation of Oocytes Through Childhood
A type of epigenetic mark, H3K4me3, spreads through the genome during oogenesis, inducing a transcriptionally silent state. The process is facilitated by the MLL2 protein. In this image, which shows an egg cell within a mouse ovary, DNA is colored blue, epigenetic methylation is colored green, and epigenetic acetylation is colored red. [Courtney Hanna/Babraham Institute]
They demonstrated that the MLL2 protein is responsible for this unusual placement of H3K4me3 in egg cells. Without MLL2, most H3K4me3 marks in egg cells are lost and the cells die before getting the chance to form a new life.

Speaking about the results, first author Dr Courtney Hanna, said: “Our findings show that H3K4me3 is created in two ways. MLL2 can add the H3K4me3 mark without any nearby gene activity while another process, that doesn’t use MLL2, places the same mark around active genes. By studying this new mechanism we hope to expand our knowledge of epigenetics in general as well as adding to our understanding of fertility.

Lead scientist, Dr Kelsey, said: “We are only beginning to unravel the details of the connection between epigenetics and egg development, a fundamental aspect of biology that may play a part in transmitting information from mother to fetus. Discoveries like this highlight some of the unusual biological processes that take place in these highly important cells.

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