Otolith radiocarbon signatures provide distinct migration history of walleye pollock around Hokkaido, Japan in the North-Western Pacific.

Trace elements and stable isotope ratios in otoliths have been used as proxies for the migration history of teleosts; however, their application in oceanic fishes remains limited. This study reports the first use of radiocarbons in otoliths to evaluate the horizontal migration histories of an oceani...

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Bibliographic Details
Published in:Ecology and Evolution
Main Authors: Ando, Kozue, Yokoyama, Yusuke, Miyairi, Yosuke, Sakai, Osamu, Hamatsu, Tomonori, Yamashita, Yuuho, Chimura, Masayuki, Nagata, Toshi
Format: Article in Journal/Newspaper
Language:English
Published: PubMed Central 2024
Subjects:
oceanodromous migration
otolith
radiocarbon
radioisotope
walleye pollock
Okhotsk
Pacific
okhotsk sea
Online Access:https://doi.org/10.1002/ece3.11288
https://pubmed.ncbi.nlm.nih.gov/38952647
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11214435/
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Summary:Trace elements and stable isotope ratios in otoliths have been used as proxies for the migration history of teleosts; however, their application in oceanic fishes remains limited. This study reports the first use of radiocarbons in otoliths to evaluate the horizontal migration histories of an oceanic fish species, the walleye pollock Gadus chalcogrammus. We conducted radiocarbon analyses of three stocks sourced from Hokkaido, Japan. The radiocarbon concentrations from the outermost portion of the otoliths from the Japanese Pacific, Northern Japan Sea (JS), and Southern Okhotsk Sea (OS) stocks were in general agreement with the seawater radiocarbon concentration of the sampling region, suggesting that pollock of all three stocks generally inhabited the within the sea region where each pollocks were sampled throughout their life cycle. However, the radiocarbon signals also provided some indications that some JS and OS stocks may be migrating between different sea regions. The proposed novel approach of reconstructing the individual migration history of marine fish using radiocarbon in otoliths may help examine fish migration with a higher temporal and spatial resolution that could not be achieved by trace elements and stable isotope ratios.

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