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Posted: Aug 03, 2012
How the cell swallows (w/video)
(Nanowerk News) Scientists at the European Molecular Biology Laboratory (EMBL) in Heidelberg, Germany, have combined the power of two kinds of microscope to produce a 3-dimensional movie of how cells ‘swallow’ nutrients and other molecules by engulfing them. The study, published today in Cell ("Plasma Membrane Reshaping during Endocytosis Is Revealed by Time-Resolved Electron Tomography"), is the first to follow changes in the shape of the cell’s membrane and track proteins thought to influence those changes. It also provides ample data to investigate this essential process further.
This ‘swallowing’, called endocytosis, is involved in a variety of crucial tasks. It is used by brain cells relaying information to each other, for instance, and is also hijacked by many viruses, which use it to invade their host’s cells. When a cell is about to swallow some molecules, a dent appears in the cell’s membrane, and gradually expands inwards, pinching off to form a little pouch, or vesicle, that transports molecules into the cell.
Different microscopy techniques combined to uncover how cells swallow molecules.
To investigate how the cell’s machinery pulls in the membrane and forms the vesicle, researchers led by Marko Kaksonen and John Briggs employed a method they developed two years ago to faithfully follow the exact same molecules first under a light microscope and then with the higher resolution of an electron microscope. This enabled them to combine two sets of data that so far could only be obtained in isolation: the timing and sequence with which different components of the cell’s machinery arrive at the vesicle-to-be, and the 3D changes to membrane shape that ultimately form that vesicle. They discovered, for instance, that the first proteins to arrive on the inside of the cell’s membrane are not able to start bending it inwards until a network of the cell’s scaffolding protein, actin, forms and starts pulling on the membrane.
The data used to make the video is freely available to the scientific community and will, Kaksonen and Briggs believe, provide valuable information to others trying to develop physical models of how this process works. The EMBL scientists themselves are probing the roles of individual proteins in this process, by perturbing them, and would like to extend the current work in yeast to human cells.