Deep sea worm fights 'poison with poison' to survive high arsenic and sulfide levels
Sadie Harley
scientific editor
Robert Egan
associate editor
A deep sea worm that inhabits hydrothermal vents survives the high levels of toxic arsenic and sulfide in its environment by combining them in its cells to form a less hazardous mineral. Chaolun Li of the Institute of Oceanology, CAS, China, and colleagues report these findings in a study published in the open-access journal PLOS Biology.
The worm, named Paralvinella hessleri, is the only animal to inhabit the hottest part of deep sea hydrothermal vents in the west Pacific, where hot, mineral-rich water spews from the seafloor. These fluids can contain high levels of sulfide, as well as arsenic, which builds up in the tissues of P. hessleri, sometimes making up more than 1% of the worm's body weight.
Li and his team investigated how P. hessleri can tolerate the high levels of arsenic and sulfide in the vent fluids. They used advanced microscopy, and DNA, protein and chemical analyses to identify a previously unknown detoxification process. The worm accumulates particles of arsenic in its skin cells, which then react with sulfide from the hydrothermal vent fluids to form small clumps of a yellow mineral called orpiment.
The study provides new insights into the novel detoxification strategy that P. hessleri uses for "fighting poison with poison," which enables it to live in an extremely toxic environment. Previous studies have found that related worms living in other parts of the world, as well as some snail species in the West Pacific, also accumulate high levels of arsenic, and may use this same strategy.
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Image of the alvinellid worm, Paralvinella hessleri. Close-up image of P. hessleri worms close to the hydrothermal venting. Credit: Wang H, et al., 2025, PLOS Biology, CC-BY 4.0 (https://creativecommons.org/licenses/by/4.0/) -
Image of the alvinellid worm, Paralvinella hessleri. A P. hessleri colonized hydrothermal vent in Iheya north hydrothermal field. The vent fauna showed apparent variation along the environmental gradients. The areas close to hydrothermal venting were covered with white mucus matt (P. hessleri colonies). The squad lobsters Shinkaia crosnieri occupied the areas surrounding the P. hessleri colonies. Bathymodiolinae mussels stayed further away. Credit: Wang H, et al., 2025, PLOS Biology, CC-BY 4.0 (https://creativecommons.org/licenses/by/4.0/) -
Microscopy analysis of the yellow granules. Longitudinal section of P. hessleri branchial apparatus stem. Credit: Wang H, et al., 2025, PLOS Biology, CC-BY 4.0 (https://creativecommons.org/licenses/by/4.0/) -
Microscopy analysis of the yellow granules. Cross section of branchial apparatus tip. Credit: Wang H, et al., 2025, PLOS Biology, CC-BY 4.0 (https://creativecommons.org/licenses/by/4.0/)
Co-author Dr. Hao Wang adds, "This was my first deep-sea expedition, and I was stunned by what I saw on the ROV monitor—the bright yellow Paralvinella hessleri worms were unlike anything I had ever seen, standing out vividly against the white biofilm and dark hydrothermal vent landscape. It was hard to believe that any animal could survive, let alone thrive, in such an extreme and toxic environment."
Dr. Wang says, "What makes this finding even more fascinating is that orpiment—the same toxic, golden mineral produced by this worm—was once prized by medieval and Renaissance painters. It's a curious convergence of biology and art history, unfolding in the depths of the ocean."
The authors note, "We were puzzled for a long time by the nature of the yellow intracellular granules, which had a vibrant color and nearly perfect spherical shape. It took us a combination of microscopy, spectroscopy, and Raman analysis to identify them as orpiment minerals—a surprising finding."
The authors conclude, "We hope that this 'fighting poison with poison' model will encourage scientists to rethink how marine invertebrates interact with and possibly harness toxic elements in their environment."
More information: Wang H, et al. A deep-sea hydrothermal vent worm detoxifies arsenic and sulfur by intracellular biomineralization of orpiment (As2S3), PLOS Biology (2025).
Journal information: PLoS Biology
Provided by Public Library of Science
