The team used the state-of-the-art 3D-OrbiSIMS instrument at the University of Nottingham to reveal that the surface chemistry of both worm species change over time and they are made up of predominantly lipids, which account for approximately 70-80% of the molecular composition.
The University of Nottingham was one of the first institutions in the world to obtain a 3D-OrbiSIMS instrument. This instrument enables an unprecedented level of mass spectral molecular analysis across a range of materials, including hard and soft matter as well as biological cells and tissues. When the surface sensitivity, high mass resolution, and spatial resolution, are combined with a depth profiling sputtering beam, the instrument becomes an extremely powerful tool for chemical analysis as demonstrated in this recent work.
Dr. Chauhan continues: “Discovering that these worms have predominantly oily, or lipid-based, surface is a significant step in understanding their biology. These lipid surfaces help maintain hydration and provide a barrier against bacteria, which are essential for their survival. What is also very interesting is that these lipids also appear to serve as chemical cues that influence interspecies interactions, such as predation. For example, the predatory behavior of Pristionchus pacificus is guided by physical contact with the surface lipids of its prey, Caenorhabditis elegans, and alterations in these lipids can increase the susceptibility of the prey to predation.”
Gaining this level of understanding of the surface chemistries of these worms and how they influence interaction and survival opens up new areas of scientific discovery and could ultimately help in developing strategies to fight parasitic worms and the diseases that they cause.”
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