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Scientists identify 'checkpoint' to prevent birth defects and spontaneous miscarriage

University of Southampton

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IMAGE: The Southampton research team (l-r): Josie Collins (Ph.D. student); Professor Keith Jones; Dr. Simon Lane (postdoctoral fellow); and Dr. Julie Merriman (postdoctoral fellow). view more

Credit: University of Southampton.

Researchers from the University of Southampton have established that eggs have a protective 'checkpoint' that helps to prevent DNA damaged eggs being fertilised.

Damage to an egg's DNA can result in infertility, birth defects and miscarriages. This damage can occur as a result of the natural ageing process and also as a result of women taking certain types of medication following chemotherapy, or radiotherapy.

The researchers found that damage to DNA during meiosis, the process that results in the formation of sperm cells and egg cells, activates the spindle assembly checkpoint (SAC) in the maturing egg, known as an oocyte, which prevents it from fully developing and stops it from being fertilised.

While the SAC is known to exist in most cells in our body, where it helps to make sure chromosomes are shared equally when a cell divides into two, uniquely in oocytes this checkpoint appears to respond to DNA damage in the chromosomes.

Lead author of the study Professor Keith Jones, Head of Biological Sciences at the University of Southampton, said: "The discovery of such a checkpoint is an important breakthrough that allows further investigation into what could affect the strength of the checkpoint.

"My group aims to go on to understand how the initial DNA damage trigger actually manages to switch-on this checkpoint, because the connection is far from clear. However, we already know that a woman's age is an important factor affecting her fertility, and as such it would be important to determine if this checkpoint is reduced by the ageing process. It would also be an interesting idea to try to switch on this checkpoint in cancer cells because it would augment the actions of chemotherapeutic drugs that work by inducing DNA damage and so preventing their ability to divide."

The study is published in Nature Communications and was funded by the Biotechnology and Biological Sciences Research Council (BBSRC).

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