BIOLOGY MEETS PHYSICS Tasmin Sarkany on how interdisciplinary scientific research might lead to major insights and discoveries about disease and the origin of life.
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t can often seem that biology, chemistry and physics are growing further apart, but some of the current major scientific frontiers defy this. Lying on the boundary of theoretical physics and cell biology is the fascinating study of liquid-liquid phase separation in cells. Although the name may sound obscure, this research promises amazing applications in areas ranging from the study of Alzheimer’s and Parkinson’s disease, to insights into the origin of life. It all started with the problem of how biochemical reactions in cells are spatially organised – how does a cell make sure that the chemicals needed for a reaction all congregate in the right place for it to occur? This is easy to explain when reac-
out that the explanation can be found using theoretical physics. Although scientific history is full of examples of physics being applied to biology (optical microscopes and X-ray diffraction techniques are applications well established in biological research), the research into phase separation in cells is exciting because looking at biological systems from a theoretical physics standpoint is still very new.
Research into phase separation A leading research group that is looking into this is the ‘Mesoscopic Physics of Life’ group at the Max Planck Institute for Complex Systems, run by Dr Christoph Weber. The group investigates the theo-
Looking at biological systems from a theoretical physics standpoint is still very new. tions occur in compartments (organelles) bound by membranes, which means that chemicals are confined to where they need to be. But it is more puzzling when we consider the many “non-membrane bound” organelles in cells. Here it turns
retical physics of ‘liquid-liquid phase separated droplets’ inside cells. Liquid-liquid phase separation refers to two liquids of different compositions, which are separated in space due to a repulsive interaction between their molecules. Weber and col-
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leagues use the fact that, ultimately, this relates to a very general principle in physics: systems will tend to a state in which the energy of the system is at a minimum. In thermal physics this means that two liquids can separate into a droplet and a surrounding liquid. The important point here is that there is no membrane, or solid boundary, separating these two liquids. In 2009, Clifford Brangwynne (Princeton) showed that structures called ‘P granules’ in the nematode Caenorhabditis elegans actually displayed liquid behaviours. This meant that the physics of liquid-liquid phase separation could be applied to these ‘granules’ and other similar structures observed in cells. There are many important outcomes that arise as a result of these droplets being liquid-liquid phase separated: since the droplet is liquid, there is fast diffusion within, meaning that chemicals in the droplet will be well mixed. Thus chemical reactions can occur in these droplets, and it may even be favourable to do so if the droplet has a chemical composition with a higher concentration of reactants (or proteins) than the surrounding liquid.
Applications to Alzheimer’s disease? A thorough understanding of this has the
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