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Marine Biology

, Volume 156, Issue 4, pp 699–708 | Cite as

Tissue, ontogenic and sex-related differences in δ13C and δ15N values of the oceanic squid Todarodes filippovae (Cephalopoda: Ommastrephidae)

  • Yves CherelEmail author
  • Camille Fontaine
  • George D. Jackson
  • Christine H. Jackson
  • Pierre Richard
Original Paper

Abstract

Stable isotopes are increasingly used in the study of trophic interactions of many aquatic animals and most recently cephalopods. To evaluate the application of the method to squids, it is important to assess isotopic differences among and within consumer tissues that may confound the resolution of ecological relationships. Inter- and intra-tissue isotopic variation was examined in 55 individuals of the oceanic squid Todarodes filippovae that were collected at the beginning of April 2000 in the southwestern Indian Ocean (between 44°S, 76°E, and Saint Paul and Amsterdam islands, 38°S, 78°E). Delipidated soft tissues (mantle, arm, buccal mass, gill and reproductive organs) showed small δ13C and δ15N differences, which were probably tissue-specific. A lower carbon value was observed in the digestive gland as a consequence of incomplete lipid removal. Hard tissues, such as beaks and gladii, had lower 15N values than soft tissues, which can be explained by the presence of chitin, a 15N-depleted molecule. Females (n = 38) and males (n = 17) had identical δ13C values, but females showed higher δ15N values than males. The difference was size-related rather than sex-related, however, as females were generally larger than males. A comparison of similar-sized females and males produced identical nitrogen values. These data suggest dietary shifts from lower to higher trophic levels during growth, because δ15N values of large T. filippovae were much higher than that of small specimens. As expected, nitrogen values of lower beaks and gladii of large squids increased from the oldest to the most recently formed region, reflecting the progressive growth of chitinized tissues in parallel with dietary changes. Sequential sampling along the growth increments of squid beaks and gladii can likely be used to produce a chronological record of dietary information throughout an individual’s history.

Keywords

Chitin Isotopic Signature Digestive Gland Stable Isotopic Signature Mantle Length 

Notes

Acknowledgments

The authors thank G. Duhamel, P. Provost, and the crew from La Curieuse for their help in collecting cephalopods at sea, and G. Guillou for stable isotope analysis. The present work was supported financially and logistically by the Institut Polaire Français Paul Emile Victor (IPEV, Programme No. 109, H. Weimerskirch), and the Terres Australes et Antarctiques Françaises. Stable isotope analysis was supported by a Hermon Slade grant awarded to G.D. Jackson.

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Copyright information

© Springer-Verlag 2009

Authors and Affiliations

  • Yves Cherel
    • 1
    Email author
  • Camille Fontaine
    • 1
  • George D. Jackson
    • 2
  • Christine H. Jackson
    • 2
  • Pierre Richard
    • 3
  1. 1.Centre d’Etudes Biologiques de ChizéVilliers-en-BoisFrance
  2. 2.Institute of Antarctic and Southern Oceanic StudiesUniversity of TasmaniaHobartAustralia
  3. 3.Laboratoire Littoral, Environnement et Sociétés UMR 6250 du CNRS-Université de La RochelleLa RochelleFrance

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