University of Bristol: discovery on how cells rebuild after division could have major implications for understanding cancer and degeneration

Illustration for nuclear F-actin working to reshape the nucleus and organise the genome. Image credit: Claudia Stocker VividBiology.

Abderrahmane Kaidi, MRC New Investigator and Senior Lecturer; Alice Sherrard, PhD student.

BRISTOL, 07-Dec-2017 — /EuropaWire/ — University of Bristol research has revealed how cells rebuild their nucleus and organise their genome when they divide – a discovery which could have major implications for understanding cancer and degeneration.

When cells divide, they need to rebuild their nucleus and organise their genome. New collaborative research from the University of Bristol demonstrates how cells achieve this through the unexpected deployment of filamentous actin (F-actin) to the nucleus.

The research, published online in Nature Cell Biology, provides the first evidence that actin polymerisation in the nucleus helps in reshaping the nucleus and reorganising the genome after cell division (mitosis).

In mammals, including humans, the cell nucleus packages and protects the genome.  When human cells divide, the nucleus is dissembled to allow segregation of the chromosomes. Once chromosome segregation is complete, new cells need to re-build their nucleus and organise their genome. This process, although essential for life, was poorly understood.

Alice Sherrard co-first author of this study and a PhD student with Dr Abderrahmane Kaidi, developed and implemented complementary and interdisciplinary methods to visualise nuclear structure and genome organisation after cells division. In so doing, Alice revealed that disruption of the formation of F-actin results in cells failing to expand their nuclear volume as well as their inability to de-compact their genome. Because of these defects, cells become inefficient in retrieving genetic information encoded in their DNA; thus, they divide slower.

Principal investigator Dr Abderrahmane Kaidi, a specialist in cancer biology at the University of Bristol’s School of Cellular and Molecular Medicine, says this discovery advances our fundamental knowledge of genome regulation in space and time, and could have major implications in understanding cancer and degeneration.

“This research highlights the importance of the spatiotemporal control of genome organisation for normal cells function, and we continue to define the principals that regulate these processes and their impact on cancer and degeneration,” said Dr Kaidi.

Further information

This collaborative study is funded by Human Frontiers Science Program, Medical Research Council and Wellcome Trust; and benefited greatly from the Bristol Wolfson Bioimaging(Biomedical Sciences), and the Bristol Electron Microscopy Unit (Chemistry).

SOURCE: University of Bristol

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