Researchers focused on two species of sharks -- the swell shark and the chain catshark. They noticed that the sharks' skin had two tones light and dark and extracted chemicals from the two skin types. What they found was a type of fluorescent molecule that was only present in the light skin.
"The exciting part of this study is the description of an entirely new form of marine biofluorescence from sharks one that is based on brominated tryptophan-kynurenine small-molecule metabolites," Gruber said in the study published in the journal of iScience.
These types of small-molecule metabolites are known to be fluorescent and activate pathways similar to those that, in other vertebrates, play a role in the central nervous system and immune system.
But in the sharks, the novel small-molecule fluorescent variants account for the biophysical and spectral properties of their lighter skin. This mechanism is different from animals in the upper ocean, such as jellyfish and corals, that commonly use green fluorescent proteins as mechanisms to transform blue light into other colors.
"It's a completely different system for them to see each other that other animals cannot necessarily tap into. They have a completely different view of the world that they're in because of these biofluorescent properties that their skin exhibits and that their eyes can detect. Imagine if I were bright green, but only you could see me as being bright green, but others could not," said, one of the researchers of the study, Jason Crawford.
The molecules also serve multiple other purposes, including helping the sharks identify each other in the ocean and potentially provide protection against microbial infections.
"It is also interesting that these biofluorescent molecules display antimicrobial properties. These catsharks live on the ocean bottom, yet we don't see any biofouling or growth, so this could help explain yet another amazing feature of shark skin. This study opens new questions related to the potential function of biofluorescence in central nervous system signaling, resilience to microbial infections, and photoprotection," Gruber said.
While the study focused on two biofluorescent shark species, Gruber and Crawford hope to more broadly explore the bioluminescent and biofluorescent properties of marine animals, which can ultimately lead to the development of new imaging techniques.