npj Biodiversity (May 2024)

Utilizing environmental DNA and imaging to study the deep-sea fish community of Takuyo-Daigo Seamount

  • Akira Iguchi,
  • Miyuki Nishijima,
  • Eri Ikeuchi,
  • Hiroyuki Yokooka,
  • Hideki Sugishima,
  • Kazumasa Ikeda,
  • Ryuichi Miwa,
  • Yoshiro Sekido,
  • Nozomu Iwasaki,
  • Masahiro Suzumura,
  • Ayumi Tsukasaki,
  • Yuichiro Tanaka,
  • Shogo Kato,
  • Jumpei Minatoya,
  • Nobuyuki Okamoto,
  • Taiga Kunishima,
  • Yuji Ise,
  • Atsushi Suzuki

DOI
https://doi.org/10.1038/s44185-024-00042-w
Journal volume & issue
Vol. 3, no. 1
pp. 1 – 11

Abstract

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Abstract The increase in interest of mining at seamounts means there is a critical need to establish baseline inventories through environmental survey, with the aim of promoting the conservation and stewardship of these remote habitats. To efficiently evaluate fish biodiversity around a seamount, we compared environmental DNA (eDNA) methods using seawater and sponge samples against methods using imagery obtained with a remotely operated vehicle (ROV) and a free-fall deep-sea camera lander called the Edokko Mark I on the Takuyo-Daigo Seamount (153.0°E, 23.5°N) in the northwestern Pacific Ocean. We detected a total of 18 fish families by these methods. The fish fauna detected on the seamount included many families commonly found in deep-sea areas and were similar to the fish fauna of other seamounts located at similar latitudes in the northwestern Pacific. Significant differences in the patterns of detection of fish families between the eDNA and imaging methods is attributed to the differing powers of detection of some fish groups between methods (related to primer compatibility and fish size). For deep-sea fish, the difference in fish composition at the family level between seawater and sponge eDNA methods was not significant, but the difference between Edokko Mark I and ROV methods was significant; the latter difference is likely due to whether or not bait is used to attract fish. Although the eDNA workflow implemented here requires improvements, the use of eDNA and imaging methods in combination provided better insight into the biodiversity of deep-sea fishes in the deep-sea around a seamount, where our knowledge of the fish fauna has been extremely limited. Our recovery of eDNA from seawater and sponge samples around the seamount demonstrates the potential of these methods for facilitating environmental baseline surveys and impact assessments of mining activities to obtain results not previously possible with the use of visual methods only.