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New insights into temperature-induced white muscle growth plasticity during Dicentrarchus labrax early life: a developmental and allometric study

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Abstract

Dicentrarchus labrax is a major finfish of interest in Mediterranean aquaculture. As the development of its hatchery production had gone with an increase of its larval rearing temperature, we studied the effect of a constant high (20°C) and two lower (13 and 15°C) temperatures on its early white muscle growth, with developmental and allometric approaches. D. labrax, sampled at hatching and at three developmental stages corresponding to main events in fish early life (first exogenous feeding, notochord flexion and completion of fin ray counts), were histologically processed in order to follow changes in the white myotomal muscle size, cellularity and localisation of proliferative nuclei. Morphometric analyses showed that, for 13, 15 and 20°C incubated/reared D. labrax, the total cross-sectional area of white muscle increased slowly in eleutheroembryos shorter than 5.2 mm, and four times faster in longer fish (free-swimming larvae). White muscle growth occurred both by hypertrophy (increase in muscle fibre size) and hyperplasia (increase in total number of muscle fibres) in all sampled fish, but both processes were higher in free-swimming larvae than in eleutheroembryos. The morphometric establishment of a higher hyperplastic growth of white muscle in free-swimming larvae was confirmed at immunological level by a high occurrence of proliferative nuclei. Early thermal environment was demonstrated to affect the growth process of white muscle on a different way in eleutheroembryos and free-swimming larvae: in the former, white muscle hypertrophy was stimulated at 20°C and hyperplasia at lower temperature, whereas in the latter, both white muscle hypertrophy and hyperplasia were more stimulated at 20°C than at lower temperatures. This was verified at once when the fish length and the white muscle total cross-sectional area were used as explicative variables.

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Acknowledgements

This work was financed by the European Commission, FAIR Program No. PL96-1941 “Muscle Ontogeny in Sea bass and Trout”. We thank Mrs L. Anesaki and Dr G. Koumoudouros for taking care of the fish and for providing us with larvae, Dr S.J. Kaushik for his comments on the manuscript and Mr D. Bazin for his help in photographic plates realisation.

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Authors and Affiliations

  1. Nutrition Aquaculture and Genomic Research Unit, National Institute for Agronomic Research, Pôle d’Hydrobiologie, 64310, Saint Pée-sur-Nivelle, France

    Hélène Alami-Durante & Michèle Rouel

  2. Department of Biology, University of Crete, 71409, Heraklio, Crete, Greece

    Maroudio Kentouri

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  1. Hélène Alami-Durante
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  2. Michèle Rouel
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  3. Maroudio Kentouri
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Correspondence to Hélène Alami-Durante.

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Communicated by S.A. Poulet, Roscoff

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Alami-Durante, H., Rouel, M. & Kentouri, M. New insights into temperature-induced white muscle growth plasticity during Dicentrarchus labrax early life: a developmental and allometric study. Mar Biol 149, 1551–1565 (2006). https://doi.org/10.1007/s00227-006-0304-6

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  • DOI: https://doi.org/10.1007/s00227-006-0304-6

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