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Positive buoyancy in eel leptocephali: an adaptation for life in the ocean surface layer
Tsukamoto, K.; Yamada, Y.; Okamura, A.; Kaneko, T.; Tanaka, H.; Miller, M.J.; Horie, N.; Mikawa, N.; Utoh, T.; Tanaka, S. (2009). Positive buoyancy in eel leptocephali: an adaptation for life in the ocean surface layer. Mar. Biol. (Berl.) 156(5): 835-846. hdl.handle.net/10.1007/s00227-008-1123-8
In: Marine Biology. Springer: Heidelberg; Berlin. ISSN 0025-3162, more
Peer reviewed article  

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Keyword
    Marine

Authors  Top 
  • Tsukamoto, K.
  • Yamada, Y.
  • Okamura, A.
  • Kaneko, T.
  • Tanaka, H.
  • Miller, M.J.
  • Horie, N.
  • Mikawa, N.
  • Utoh, T.
  • Tanaka, S.

Abstract
    Many planktonic organisms have adaptations such as floats or lighter substances to obtain buoyancy to help them remain in the surface layer of the ocean where photosynthetic primary production occurs and food is most abundant. The almost totally transparent eel larvae, called leptocephali, are a unique member of the planktonic community of the surface layer, but their ecology and physiology are poorly understood. We conducted a comparative study on the specific gravity of planktonic animals including 25 taxa of 7 phyla of marine invertebrates and 6 taxa of leptocephali (vertebrate) to gain a broad perspective on the buoyancy of the eggs and larval stages of the Japanese eel. The specific gravity values of the various freshly caught marine invertebrate taxa varied widely from 1.020 to 1.425, but leptocephali had some of the lowest values (1.028–1.043). Artificially cultured live leptocephali had even greater buoyancies with specific gravities of 1.019–1.025 that were close to or lower than seawater, and their buoyancy showed ontogenetic changes among the different early life history stages. Leptocephali appear to have a unique mechanism of buoyancy control by chloride cells all over body surface through osmoregulation of body fluid contained in the extracellular matrix of transparent gelatinous glycosaminoglycans filling their bodies. This adaptation is likely a key factor for their survival by helping them to remain in the surface layer where food particles are the most abundant, while being transparent for predator avoidance. The ontogenetic change in buoyancy of eel eggs, leptocephali and glass eels likely enhances their larval survival, transport, and recruitment to terrestrial freshwater habitats.

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