Uniaxial orientation of β-chitin nanofibres used as an organic framework in the scales of a hot vent snail

Organisms use various forms and orientations of chitin nanofibres to make structures with a wide range of functions, from insect wings to mussel shells. Lophotrochozoan animals such as snails and annelid worms possess an ancient 'biomineralization toolkit', enabling them to flexibly and rapidly evolve unique hard parts. The scaly-foot snail is a gastropod endemic to deep-sea hydrothermal vents, unique in producing dermal sclerites used as sites of sulfur detoxification. Once considered to be strictly proteinaceous, recent data pointed to the presence of chitin in these sclerites, but direct evidence is still lacking. Here, we show that beta-chitin fibres (approx. 5% of native weight) are indeed the building framework, through a combination of solid-state nuclear magnetic resonance spectroscopy, wide-angle X-ray diffraction, and electron microscopy. The fibres are uniaxially oriented, likely forming a structural basis for column-like channels into which the scaly-foot snail is known to actively secrete sulfur waste-expanding the known function of chitinous hard parts in animals. Our results add to the existing evidence that animals are capable of modifying and co-opting chitin synthesis pathways flexibly and rapidly, in order to serve novel functions during their evolution.

Automated summary

Organisms use various forms and orientations of chitin nanofibres to build structures with a wide range of functions. Lophotrochozoan animals have the ability to evolve unique hard parts quickly and flexibly. Recent research has found evidence of chitin in the dermal sclerites of the scaly-foot snail, expanding our understanding of the functions of chitinous hard parts in animals.