A protein coat helps chromosomes keep their distance

Billions of your cells divide every day. Cell division fuels growth and also replaces short-lived cells in some organs, like your skin, blood, and gut. Dividing cells cycle through different stages. During most of this cycle, cells are at work expressing genes. At this stage chromosomes are spread out as a network of long threads that fill the entire volume of the cell nucleus.

As the cell prepares to divide, the chromosomes replicate and undergo a dramatic metamorphosis. They compact into iconic X-shaped bodies which can move around independently to transport one copy of the genome to each of the daughter cells. But what enables this “individualization” of chromosomes in dividing cells has been a mystery.

A team led by Daniel Gerlich at IMBA discovered that the protein Ki-67 prevents chromosomes from sticking together in dividing cells. Ki-67 is a well-known marker of proliferating cells and is used in cancer diagnostics to measure erratic cell division. But the function of Ki-67 in the cell was unclear. Their findings, published in the current issue of Nature, show that the chromosomes can still compact without Ki-67, but they merge into a single mass and are essentially immobile. As a consequence, cells lacking Ki-67 divide more slowly.

The team set out to determine how Ki-67 disperses chromosomes in dividing cells. Sara Cuylen, first author of the study, explains: “one end of the Ki-67 protein is attracted to chromosomes, whereas the other end extends away from them. As a result, Ki-67 forms elongated brush-like structures at the chromosome surface — essentially a barrier that keeps them apart.” These properties of Ki-67 are reminiscent of surface-active agents (surfactants) like soap — which we use daily to break up dirt and grease. That proteins can function as surfactants inside the cell was completely unexpected.

Daniel Gerlich points out that a surfactant mechanism might also control the spatial arrangement of other cell organelles: “The cell contains many other compartments that are not confined by membranes and it was previously unknown how these compartments maintain spatial separation. It will be exciting to search for other proteins with surfactant-like properties, and to study their potential role in cellular organization.”

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The above post is reprinted from materials provided by Institute of Molecular Biotechnology. Note: Materials may be edited for content and length.