Culprit for infertility in older women discovered

Scientists have taken a major step towards understanding why older women are more likely to produce abnormal eggs, increasing the risk of infertility, miscarriage and birth defects such as Down's Syndrome, it was announced yesterday.

While researchers have long known that women having babies in their late 30s and 40s posed an increased risk of disability owing to eggs containing the wrong number of chromosomes, the underlying cause has not been known.

Research by Newcastle University, published in the journal Current Biology, has shed new light on why this happens.

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The key is declining levels of proteins called Cohesins, which hold chromosomes together by entrapping them in a ring. This is essential for chromosomes to split evenly when cells divide.

All the cells in the body, except for sperm and eggs, contain two copies of each chromosome. Sperm and eggs must lose exactly one copy in preparation for fertilisation.

This halving of chromosome number requires a complex form of cell division. In eggs the problem is compounded by the fact that the physical attachments that hold chromosomes together are established before birth and must be maintained by Cohesins until the egg divides just before ovulation. In humans this can take decades.

In a study led my Dr Mary Herbert, and funded primarily by Newlife Foundation for Disabled Children, Infertility Research Trust, and the MRC, researchers at Newcastle University and Newcastle Fertility Centre, used eggs from young and old mice to show that Cohesin levels decline gradually as females get older.

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This results in weakened cohesion between chromosomes and failure to divide equally during the halving of chromosome number in eggs of older females.

By tracking chromosomes during division in the egg, the Newcastle team found that the reduced Cohesin in eggs from older females resulted in some chromosomes becoming trapped and being unable to divide properly.

Eggs that are defective in this way may fail to develop, resulting in infertility, or they may give rise to a pregnancy with a high risk of miscarriage, or to the birth of a baby with Down's Syndrome.

Dr Herbert, a reader in reproductive biology at the Institute of Ageing and Health, said: "Reproductive fitness in women declines dramatically from the mid-30s onwards.

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"Our findings point to Cohesin being a major culprit in this.

"The aged mice we used are equivalent to a woman in her early forties.

"Cohesin levels were very much reduced in eggs from older mice and the chromosomes underwent a very messy division resulting in the wrong number of chromosomes being retained in the egg."

She said further research would be carried out to see why Cohesin was lost with age.

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"If we can understand this, we will be in a better position to know if there is any possibility of developing interventions to help reduce Cohesin loss," she said.

"Undoubtedly, the best way for women to avoid this problem is to have their children earlier."

Breast cancer breakthrough

Scientists searching for the source of aggressive and deadly breast cancers may have been looking in the wrong place, new research suggests.

The findings shed light on how the most dangerous breast cancers grow.

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Tumours arise in two types of glandular tissue in the breast, the outer "basal" cells and inner "luminal" cells.

Previously it was thought that more aggressive cancers sprung from basal stem cells. Milder forms of cancer were believed to arise from "intermediate" luminal cells.

The vast majority of inherited breast tumours with defective BRCA1 genes have basal-like characteristics.

But scientists who conducted studies on mice to confirm the origin of BRCA1 cancer tumours found that looks can be deceptive. They deleted the BRCA1 gene in both mouse basal stem cells and luminal intermediate cells.

Tumours formed in both kinds of cell, but only luminal cells had features identical to human BRCA1 cancers.

The work is reported in the journal Cell Stem Cell.