Scientific Reports (Nov 2022)

Encapsulated salts in velvet worm slime drive its hardening

  • Yendry Regina Corrales-Ureña,
  • Fabienne Schwab,
  • Efraín Ochoa-Martínez,
  • Miguel Benavides-Acevedo,
  • José Vega-Baudrit,
  • Reinaldo Pereira,
  • Klaus Rischka,
  • Paul-Ludwig Michael Noeske,
  • Alexander Gogos,
  • Dimitri Vanhecke,
  • Barbara Rothen-Rutishauser,
  • Alke Petri-Fink

DOI
https://doi.org/10.1038/s41598-022-23523-z
Journal volume & issue
Vol. 12, no. 1
pp. 1 – 15

Abstract

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Abstract Slime expelled by velvet worms entraps prey insects within seconds in a hardened biopolymer network that matches the mechanical strength of industrial polymers. While the mechanic stimuli-responsive nature and building blocks of the polymerization are known, it is still unclear how the velvet worms’ slime hardens so fast. Here, we investigated the slime for the first time, not only after, but also before expulsion. Further, we investigated the slime’s micro- and nanostructures in-depth. Besides the previously reported protein nanoglobules, carbohydrates, and lipids, we discovered abundant encapsulated phosphate and carbonate salts. We also detected CO2 bubbles during the hardening of the slime. These findings, along with further observations, suggest that the encapsulated salts in expelled slime rapidly dissolve and neutralize in a baking-powder-like reaction, which seems to accelerate the drying of the slime. The proteins’ conformation and aggregation are thus influenced by shear stress and the salts’ neutralization reaction, increasing the slime’s pH and ionic strength. These insights into the drying process of the velvet worm’s slime demonstrate how naturally evolved polymerizations can unwind in seconds, and could inspire new polymers that are stimuli-responsive or fast-drying under ambient conditions.