Biological complexity: cell filaments come and go (Introduction)

by David Turell @, Monday, March 12, 2018, 22:51 (2448 days ago) @ David Turell

If transport filaments (microtubules) in cells are not needed they disappear:

https://phys.org/news/2018-03-railwayin-cell-body.html

"New work from the University of Warwick shows how a microscopic 'railway' system in our cells can optimise its structure to better suit bodies' needs.

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"Almost every cell in our bodies contains a 'railway' network, a system of tiny tracks called microtubules that link important destinations inside the cell. Professor Cross' team found the system of microtubule rails inside cells can adjust its own stability depending on whether it is being used or not.

"Prof Cross said: "The microtubule tracks of the cellular railway are almost unimaginably small - just 25 nanometres across (a nanometre being a millionth of a millimetre).The railway is just as crucial to a well-run cell as a full-size railway is to a well-run country. For cells and for countries the problem is very much the same - how to run a better railway?"

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"Imagine if the tracks of a real railway were able to ask themselves, 'am I useful?' To find out, they would check how often a railway engine passed along them.

"'It turns out that the microtubule railway tracks inside cells can do exactly that - they check whether or not they are in contact with tiny railway engines (called kinesins). If they are, then they remain stably in place. If they are not, they disassemble themselves. We think this allows the sections of microtubule rail to be recycled to build new and more useful rails elsewhere in the cell."

"The paper, 'Kinesin expands and stabilizes the GDP-microtubule lattice' published (12 March 2018) in Nature Nanotechnology, shows that when the kinesin railway engines contact their microtubule rails, they subtly change their structure, producing a very slight lengthening that stabilises the rail.

"Using a custom built microscope, the Warwick Open Source Microscope, the researchers who are also based at Warwick Systems Biology Centre and Mathematics Institute, University of Warwick, detected a 1.6% increase in the length of microtubules attached to kinesins, with a 200 times increase in their lifetime."

Comment: This is vivid that a designer is required


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