Water in our bodies is different from ordinary water
August 7th, 2008 - 1:53 pm ICT by ANIWashington, Aug 7 (ANI): Water, as we know it, does not exist within our bodies, says a leading researcher, who added that the fluid has different physical properties from ordinary bulk water.
“Water in our bodies has different physical properties from ordinary bulk water, because of the presence of proteins and other biomolecules. Proteins change the properties of water to perform particular tasks in different parts of our cells, said Martin Gruebele, a William H. and Janet Lycan Professor of Chemistry at the University of Illinois.
Consisting of two hydrogen atoms and one oxygen atom, water molecules are by far the body’’s largest component, constituting about 75 percent of body volume.
When bound to proteins, water molecules participate in a carefully choreographed ballet that permits the proteins to fold into their functional, native states. This delicate dance is essential to life.
“While it is well known that water plays an important role in the folding process, we usually only look at the motion of the protein,” said Gruebele, who also is the director of the U. of I.’’s Center for Biophysics and Computational Biology, and a researcher at the Beckman Institute.
“This is the first time we”ve been able to look at the motion of water molecules during the folding process.”
Using a technique called terahertz absorption spectroscopy, Gruebele and his collaborator Martina Havenith at the Ruhr-University Bochum studied the motions of a protein on a picosecond time scale (a picosecond is 1 trillionth of a second).
The technique, which uses ultrashort laser pulses, also allowed the researchers to study the motions of nearby water molecules as the protein folded into its native state.
The researchers present their findings in a paper published July 23 in the online version of the chemistry journal Angewandte Chemie.
Terahertz spectroscopy provides a window on protein-water rearrangements during the folding process, such as breaking protein-water-hydrogen bonds and replacing them with protein-protein-hydrogen bonds, Gruebele said.
The remaking of hydrogen bonds helps organize the structure of a protein.
In tests on ubiquitin, a common protein in cells, the researchers found that water molecules bound to the protein changed to a native-type arrangement much faster than the protein. The water motion helped establish the correct configuration, making it much easier for the protein to fold.
“Water can be viewed as a ”designer fluid” in living cells,” Gruebele said.
“Our experiments showed that the volume of active water was about the same size as that of the protein,” Gruebele added. (ANI)
- Why don't fish in the Arctic Ocean freeze? - Aug 26, 2010
- Scientists unveil new method to heat water in 'nano bathtubs' - Jul 31, 2010
- Mimicking photosynthesis key to inexpensive solar-powered jet fuel - Feb 21, 2011
- Scientists identify molecules that help propel cancer metastasis - Apr 09, 2011
- Harnessing electromagnetic waves for medical scanning - Jan 22, 2012
- Where on Earth did life start? - Aug 07, 2010
- Coming soon: 'X-ray' cameras to look through objects - even clothes - May 22, 2010
- Study sheds light on behaviour of enzyme linked to Alzheimer's, cancer - Nov 20, 2010
- Scientists discover new hydrogen-storage method - Nov 23, 2009
- New 'nanodrug' can attack breast cancer cells from the inside out - Mar 30, 2011
- Turmeric compound shows promise in Parkinson's - Mar 21, 2012
- Breakthrough could help hydrogen replace petrol as fuel - Apr 01, 2011
- Molecular glue to impart cutting edge to chemotherapy - Jun 23, 2011
- Now, a method to predict nanoparticle interaction with human body - Aug 16, 2010
- Discovery could lead to 'next-gen' vaccines - Apr 08, 2012
Tags: absorption spectroscopy, angewandte chemie, beckman institute, biophysics, chemistry journal, collaborator, computational biology, delicate dance, hydrogen atoms, lycan, native states, nearby water molecules, oxygen atom, properties of water, ruhr university bochum, s center, terahertz spectroscopy, time scale, trillionth, water water