New research has shown for the first time how structures inside cells are regulated – a breakthrough that could have a major impact on cancer therapy development. A team from the School of Biosciences uncovered the mechanism whereby the physical properties of the internal structures within cells – known as actin filaments – are ‘fine-tuned’ to undertake different functions.
While some of these actin filaments appear to completely stable, providing a framework for the cell, others are more dynamic, allowing the cell to respond rapidly to changes in its environment.
The researchers – PhD students Matthew Johnson and Daniel East, who were led by Dr Daniel Mulvihill – used yeast cells to mimic those in humans. They utilised a novel biology ‘trick’ to switch the location of molecules which bind to, and stabilise, the actin polymer and modulate the movement of molecular motors. In this way, they uncovered the mechanism which determines the functional characteristics of actin filaments in all cells and orchestrates cellular activity. It is expected the breakthrough could have a major impact on the development of therapies for a variety of diseases, including cancer.
The research, titled Formins Determine the Functional Properties of Actin Filaments in Yeast, by Matthew Johnson, Daniel A. East and Daniel Mulvihill, is published in the current issue of the journal Current Biology. See here.
For more information please contact Dr Daniel Mulvihill.