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One protein, two channels: Scientists
explain mechanism in aquaporins
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[OCT. 19, 2006]
CHAMPAIGN -- Using computer simulations and
experimental results, researchers at the University of Illinois at
Urbana-Champaign and the University of Arizona have identified a key
component of the gating mechanism in aquaporins that controls both
the passage of water and the conduction of ions.
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Aquaporins are a class of proteins that form membrane channels in
cell walls and allow for water movement between a cell and its
surroundings. A number of aquaporins, including aquaporin-1, have
been found to function also as ion channels. "Understanding the
molecular mechanism behind gating in membrane channels could lead to
more effective protein engineering," said Emad Tajkhorshid, a
professor of
biochemistry at Illinois and a researcher at the
Beckman Institute for
Advanced Science and Technology.
In work funded by the National Institutes of Health, Tajkhorshid
and co-workers show that the same protein can be used as a water
channel or an ion channel, depending on the signaling pathway
activated in the cell. The scientists reported their findings in the
September issue of the journal Structure.
Taking advantage of the known crystal structure of aquaporin-1
and the power of molecular dynamics simulations, the researchers
explored the central pore as a candidate pathway for conducting
ions. Gating of the central pore is controlled by cyclic guanosine
monophosphate, a signaling nucleotide inside the cell, which induces
a conformational change in one of the aquaporin loops, loop D.
"This loop is very flexible, has four positively charged arginine
residues in a row and extends into the central pore," Tajkhorshid
said. "We believe the cGMP interacts with loop D, facilitating its
outward motion, which triggers the opening of the gate."
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 The work highlights a close interaction between simulation and
experiment. Based on their simulation results, the researchers
designed a mutant in which two arginines in loop D were replaced by
two alanines. In laboratory experiments performed at Arizona, the
substitution caused an almost complete removal of ion conduction but
had no appreciable effect on water passage.
"Knowing the mechanism gives us a new handle to control the
opening or closing of the central pore," Tajkhorshid said. "By
modifying the pore-lining residue, or altering the length of loop D
that gates the pore, we can shut down the ion conductivity
completely, or engineer new aquaporins that can be opened more
easily or have a higher ion conduction rate once open."
With Tajkhorshid, co-authors of the paper are Illinois graduate
student and lead author Jin Yu, University of Arizona
experimentalist Andrea J. Yool, and Illinois physicist Klaus
Schulten.
[University
of Illinois news release] |
