University of Leeds Press Release
Under embargo until 10:00 BST, 28 September
With graphics and images
How fish survive the extreme pressures of life in the oceans
Scientists have discovered how a chemical in the cells of marine organisms enables them to survive the high pressures found in the deep oceans.
The deeper sea creatures live, the more inhospitable and extreme the environment they must cope with. In one of the deepest points in the Pacific - the Mariana Trench, 11 kilometers below the sea surface - the pressure is 1.1 kbar or eight tons per square inch. That is a 1,100-fold increase of the pressure experienced at the Earth’s surface.
Under normal or atmospheric pressure, water molecules form a tetrahedron-like network.
Network of water molecules changes shape
At high pressure, though, the network of water molecules begins to distort and change shape. When this happens to the water inside living cells, it prevents vital bio-chemical processes from taking place - and kills the organism.
In reporting their findings, the researchers in Leeds have for the first time been able to provide an explanation of how a molecule found in the cells of marine organisms counteracts the effect of external pressure on the water molecules.
Professor Lorna Dougan, from the School of Physics and Astronomy at Leeds, said: “Life has adapted to survive and thrive in environmental extremes. In the depths of the oceans, organisms live under extreme high pressures that would destroy human life.
“These high pressures distort the liquid water that resides in all life, resulting in detrimental impacts to the biomolecules that underpin all biological processes.
“We need to understand what happens to water under pressure and how pressure-adapted organisms combat these effects. If we can understand how these organisms survive at extreme pressure, we can apply these findings to the wider study of biomolecular stability.”
Trimethylamine N-oxide or TMAO
The molecule found in cells that produces the protective effect against high external pressure is called TMAO - trimethylamine N-oxide. Studies have shown that the amount of TMAO in ocean-dwelling organisms increases in line with the depth of their habitat.
Led by Dr Harrison Laurent, also from the School of Physics and Astronomy, the study used one of the most advanced analytical facilities in the world to investigate how intense pressure alters the hydrogen bonds between neighbouring water molecules.
Neutron scattering
Called the ISIS Neutron and Muon Source, the analytical facility at the STFC Rutherford Appleton Laboratory in Oxfordshire was used to fire a beam of neutrons - which are sub-atomic particles - at samples of water with and without TMAO. The analysis was done at low pressure, 25 bar, and at high pressure, 4 kbar.
The test revealed details of the atomic structure of the water molecules.
At high pressure, the hydrogen bonds in the pure water sample became distorted and less stable and the overall network of water molecules became compacted.
The presence of TMAO, however, strengthened and stabilised the hydrogen bonding and maintained the network structure of the water molecules.
Dr Laurent said: “The TMAO provides a structural anchor which results in the water being able to resist the extreme pressure it is under. The findings are important because they help scientists understand the processes by which organisms have adapted to survive the extreme conditions found in the oceans.”
From the study, the research team have also been able to develop what is called an “osmolyte protection ratio”, which predicts the level of TMAO needed in the cells of marine organisms so they can survive at a specific depth in the oceans.
Professor Dougan added: “Professor Dougan added: “Our study provides a bridge between water under pressure at the molecular level and the wonderful ability of organisms which thrive under high pressure in depths of the oceans.
“Recently published research has revealed new species living at the bottom of the deep seas. We are now understanding the remarkable adaptations that have allowed life to exploit these habitats.”
The scientific paper - The ability of trimethylamine N-oxide to resist pressure induced perturbations to water structure - is published in the scientific journal Communications Chemistry .
END
Note to editors
For further details about the project or to talk to one of the researchers, please contact the press office at the University of Leeds – pressoffice@leeds.ac.uk
Graphics and images
There are graphics that help explain the story that you can use. Please credit: Dr Harrison Laurent, University of Leeds. To download, please click on the link.
Graphic 1 – Shows a selection of fish and how deep in the ocean they live .
Graphic 2 - Graphic shows how the structural network of water is distorted under high pressure .
Video 1 – Media can use a short video that describes how the external pressure on water molecules inside cells. Please credit University of Leeds. You can down the video from this WeTransfer link .
Funding
Funding and support for the project came from the Engineering and Physical Sciences Research Council, ISIS Facility Developoment Studentship and the University of Leeds. The research team also acknowledge beamtime at the ISIS neutron and muon facility and support from the ISIS Disordered Materials group and facility pressure and furnace team.
Communications Chemistry
Observational study
Cells
The ability of trimethylamine N-oxide to resist pressure induced perturbations to water structure
28-Sep-2022