[en] In Carapus homei, reef colonisation is associated with a penetration inside a sea cucumber followed by heavy transformations during which the length of the fish is reduced by 60%. By comparing vertebral axis to otolith ontogenetic changes, this study aimed (i) to specify the events linked to metamorphosis, and (ii) to establish to what extent these fish have the ability to delay it. Different larvae of C. homei were caught when settling on the reef and kept in different experimental conditions for at least 7 days and up to 21 days: darkness or natural light conditions, presence of sea cucumber or not, and food deprivation or not. Whatever the nutritional condition, a period of darkness seems sufficient to initiate metamorphosis. Twenty-one days in natural light conditions delayed metamorphosis, whereas the whole metamorphosis process is the fastest (15 days) for larvae living in sea cucumbers. Whether the metamorphosis was initiated or not, otoliths were modified with the formation of a transition zone, whose structure varied depending on the experimental conditions. At day 21, larvae maintained in darkness had an otolith transition zone with more increments (around 80), albeit wider than those (more or less 21) of individuals kept under natural lighting. These differences in otolith growth could indicate an increased incorporation rate of released metabolites by metamorphosing larvae. However, the presence of a transition zone in delayed-metamorphosis larvae suggests that these otolith changes record the endogenously-induced onset of metamorphosis, whereas body transformations seem to be modulated by the environmental conditions of settlement. (C) 2004 Wiley-Liss, Inc.
Disciplines :
Zoology
Author, co-author :
Parmentier, Eric ; Université de Liège - ULiège > Département des sciences et gestion de l'environnement > Morphologie fonctionnelle et évolutive
Lecchini, David; Université de Perpignan > Centre de Biologie et d’Ecologie Tropicale et Méditerranéenne
Lagardere, Françoise; CREMA-L’Houmeau (France)
Vandewalle, Pierre ; Université de Liège - ULiège > Département des sciences et gestion de l'environnement > Morphologie fonctionnelle et évolutive
Language :
English
Title :
Ontogenic and ecological control of metamorphosis onset in a carapid fish, Carapus homei: Experimental evidence from vertebra and otolith comparisons
Publication date :
01 August 2004
Journal title :
Journal of Experimental Zoology. Part A, Comparative Experimental Biology
ISSN :
1548-8969
eISSN :
1552-499X
Publisher :
Wiley Liss, Inc., Hoboken, United States - New Jersey
Amara R, Lagardère F. 1995. Size and age at onset of metamorphosis in sole (Solea solea L.) of the Gulf of Gascogne. ICES J Mar Sci 52:247-256.
Amara R, Poulard JC, Lagardère F, Désaunay Y. 1998. Comparison between the life cycles of two Soleidae, the common sole, Solea solea, and the thickback sole, Microchirus variegatus, in the Bay of Biscay (France). Env Biol Fish 53:193-209.
Bertram DF, Chambers RC, Leggett WC. 1993. Negative correlations between larval and juvenile growth rates in winter flounder: implications of compensatory for variation in size-at-age. Mar Ecol Prog Ser 96:209-215.
Bœuf G, Le Bail PY. 1999. Does light have an influence on fish growth? Aquaculture 177:129-152.
Campana SE. 1983a. Calcium deposition and otolith check formation during periods of stress in coho salmon, Onchorhynchus kisutch. Comp Biochem Physiol A 75:215-220.
Campana SE 1983b. Feeding periodicity and the production of daily growth increments in otoliths of steelhead trout (Salmo gairdneri) and starry flounder (Platichthys stellatus). Can J Zool 61:1591-1597.
Campana SE, Jones CM. 1992. Analysis of otolith microstrucure data. In: Stevenson DK, Campana SE, editors. Otolith microstructure examination analysis. Can Spec Pub Fish Aquatic Sci 117:73-100.
Campana SE, Neilson JD. 1985. Microstructure of fish otoliths. Can J Fish Aquatic Sci 42:1014-1031.
Cieri MD, McCleave JD. 2000. Discrepancies between otoliths of larvae and juveniles of the american eel: is something fishy happening at metamorphosis? J Fish Biol 57:1189-1198.
Chambers RC, Leggett WC. 1992. Possible causes and consequences of variation in age at size metamorphosis in flatfishes (Pleuronectiformes): an analysis at the individual, population and species level. Neth J Sea Res 29:7-24.
Dufour V, Riclet E, Lo-Yat A. 1996. Colonization of reef fishes at Moorea Island, French Polynesia: Temporal and spatial variation of the larva flux. NZJ Mar Fresh Res 47:413-422.
Ekström P, Meissl H. 1997. The pineal organ of teleost fishes. Rev Fish Biol Fish 7:199-284.
Gauldie RW, Neslon DGA. 1990. Otolith Growth in fishes. Comp Biochem Physiol A 97:119-135.
Gavlik S, Albino M, Specker JL. 2002. Metamorphosis in summer flounder: manipulation of thyroid status to synchronize settling behavior, growth, and development. Aquaculture 203:359-373.
Govoni JJ, Olney JE, Markle DF, Curtsinger WR. 1984. Observations on structure and evaluation of possible functions of the vexillum in larval Carapidae (Ophidiiformes). Bull Mar Sci 34:60-70.
Kacem A, Gustafsson, Meunier FJ. 2000. Demineralization of the vertebral skeleton in Atlantic salmon Salmo salar L. during spawning migration. Comp Biochem Physiol A 125:479-484.
Lagardère F, Chaumillon G, Amara R, Heineman G, Lago JM. 1995. Examination of otolith morphology and microstructure using laser scanning microscopy. In: Secor DH, Dean JM, Campana SE, editors. Recent developments in fish otolith research. Columbia: University of South Carolina. p 7-26.
Lagardère F, Troadec H. 1997. Age estimation in common sole, Solea solea (L.), larvae: validation and evaluation of a pattern recognition technique. Mar Ecol Prog Ser 155:223-237.
Lee TW, Byun JS. 1996. Microstructural growth in otolith of conger ell (Conger myriaster) leptocephali during the metamorphic stage. Mar Biol 125:259-268.
Leis JM, McCormick MI. 2002. The biology, behavior, and ecology of the pelagic, larval stage of coral reef fishes. In: Sale PF, editor. Coral reef fishes: New Insights into their Ecology. San Diego: Academic Press. p 171-209.
Manzon RG, Eales JG, Youson JH 1998. Blocking of KClO-induced metamorphosis in premetamorphic sea lampreys by exogenous thyroid hormones (TH); effects of KClO and TH on serum TH concentrations and intestinal thyroxine outer-ring deiodination. Gen Comp Endocr 112:54-62.
Markle DF, Olney JE. 1990. Systematics of the Pearlfish (Pisces: Carapidae). Bull Mar Sci 47:269-410.
Markle DF, Harris PM, Toole CL. 1992. Metamorphosis and an overview of early-life-history stages in Dover sole Microstomus pacificus. Fish Bull 90:285-301.
Mayer I. 2000. Effect of long-term pinealectomy on growth and precocious maturation in Atlantic salmon, Salmo salar parr. Aquat Liv Res 13:39-144.
McCormick MI. 1994. Variability in age and size at settlement of the tropical goatfish Upeneus tragula (Mullidae) in the northen Great Barrier Reef lagoon. Mar Ecol Prog Ser 103:1-15.
McCormick MI. 1999. Delayed metamorphosis of a tropical reef fish (Acanthurus triostegus): a field experiment. Mar Ecol Prog Ser 176:25-38.
McCormick MI, Makey LJ. 1997. Post-settlement transition in coral reef fishes: overlooked complexity in niche shifts. Mar Ecol Prog Ser 153:247-257.
Modin J, Fagerholm B, Gunnarsson B, Pihl L. 1996. Changes in otolith microstructure at metamorphosis of plaice, Pleuronectes platessa L. ICES J Mar Sci 53:745-748.
Molony BW. 1996. Episodes of starvation are recorded in the otoliths of juvenile Ambassis vachelli (Chandidae), a tropical estuarine fish. Mar Biol 125:439-446.
Morales-Nin B. 2000. Review of the growth regulation processes of otolith daily increment formation. Fish Res 46:53-67.
Mugiya Y. 1984. Diurnal rhythm in otolith formation in the rainbow trout, Salmo gairdeni: seasonal reversal of the rhythm in relation to plasma calcium concentrations. Comp Biochem Physiol 78:289-293.
Mugiya Y, Watabe N, Yamada JM, Dunkelberger GG, Shimuzu M. 1981. Diurnal rhythm in otolith formation in the goldfish, Carassius auratus. Comp Biochem Physiol A 68:659-662.
Nolf D. 1985. Otolithi piscium. In: Schultze L, editor. Handbook of Paleoichthyology, Vol 10A. NewYork: Gustav Fisher Verlag.
Olney JE, Markle DF. 1979. Description and occurrence of vexillifer larvae of Echiodon (Pisces: Carapidae) in the western North Atlantic and notes on other carapid vexillifers. Bull Mar Sci 29:365-379.
Panfili J, Meunier FJ, Mosegaard H, Troadec H, Wright PJ, Geffen AJ. 2002. Glossary. In: Panfili J, Pontual H (de), Troadec H, Wright PJ, editors. Manual of fish sclerochronology. Brest, France: Ifremer-IRD coedition. p 373-383.
Pannella G. 1980. Growth pattern of fish sagittae. In: Rhoad DC, Lutz RA, editors. Skeletal growth of aquatic organisms: Biological records of environmental change. Vol.1, Topics in geobiology. New York: Plenum Press. p 519-560.
Parmentier E, Castillo G, Chardon M, Vandewalle P. 2000. Phylogenetic analysis of the pearlfish tribe Carapini (Pisces: Carapidae). Acta Zool 81:293-306.
Parmentier E, Vandewalle P, Lagardère F. 2001. Morpho-anatomy of the otic region in carapid fishes: eco-morphological study of their otoliths. J Fish Biol 58:1046-1061.
Parmentier E, Lagardère F, Vandewalle P. 2002a. Relationships between inner ear and sagitta growth during ontogenesis of three Carapini species and consequences of life-history events on the otolith microstructure. Mar Biol 141:491-501.
Parmentier E, Lo-Yat A, Vandewalle P. 2002b. Identification of four French Polynesia tenuis Carapini (Carapidae: Teleostei). Mar Biol 140:633-638.
Parmentier E, Lecchini D, Vandewalle P. 2004. Remodelling of the vertebral axis during metamorphic shrinkage in the pearlfish. J Fish Biol 64:159-169.
Payan P, Edeyer A, de Pontual H, Borelli G, Bœuf G, Mayer-Gostan N. 1999. Chemical composition of saccular endolymph and otolith in fish based on the chemistry of the endolymph. Am J Physiol 277:123-131.
Payan P, Borelli G, Priouzeau F, De Pontual H, Bœuf G, Mayer-Gostan N. 2002. Otolith growth in trout Onchorynchus mykiss: supply of Ca2+ and Sr2+ to the saccular endolymph. J Exp Biol 205:2687-2695.
Pfeiler E. 1986. Towards an explanation of the developmental strategy in leptocephalous larvae of marine teleost fishes. Env Biol Fish 15:3-13.
Pfeiler E. 1997. Effects on Ca2+ on survival and development of metamorphosis bonefish (Albula sp.) leptocephali. Mar Biol 127:571-578.
Pfeiler E. 1999. Developmental physiology of elopomorph leptocephali. Comp Biochem Phys A 123:113-128.
Smith CL, Tyler JC, Feinberg MN. 1981. Population ecology and biology of the pearlfish (Carapus bermudenis) in the lagoon at Bimini, Bahamas. Bull Mar Sci 3:876-902.
Sogard SM. 1991. Interpretation of otolith microstrucutre in juvenile winter flounder (Pseudopleuronectes americanus): ontogenetic development, daily increment validation, and somatic growth relationships. Can J Fish Aquat Sci 48:1862-1871.
Taylor WR, Van Dyke GC. 1985. Revised procedure for staining and clearing small fishes and other vertebrates for bone and cartilage study. Cybium 2:107-119.
Toshe H, Mugiya Y. 2002. Diel variation in carbonate incorporation into otoliths in goldfish. J Fish Biol 61:199-206.
Victor BC. 1986. Delayed metamorphosis with reduced larval growth in a coral reef fish (Thalassoma bifasciatum). Can J Fish Aquat Sci 43:1208-1213.
Wang CH, Tzeng WN. 2000. The timing of metamorphosis and growth rates of American and European eel leptocephali: a mechanism of larval segregative migration. Fish Res 46:191-205.
Wellington GM, Victor BC. 1992. Regional differences in duration of the planktonic larva stage of reef fishes in the eastern Pacific Ocean. Mar Biol 101:557-567.
Wilson DT, McCornick MI. 1997. Spatial and temporal validation of settlement-marks in the otoliths of tropical reef fishes. Mar Ecol Prog Ser 153:491-498.
Wilson DT, McCornick MI. 1999. Microstructure of settlement-marks in the otoliths of tropical reef fishes. Mar Biol 134:29-41.
Wright PJ. 1993. Otolith microstructure on the lesser sandeel, Ammodytes marinus. J Mar Biol Ass UK 73:245-248.
Youson JH. 1988. First metamorphosis. In: Hoar WS, Randall DJ, editors. Fish Physiology, vol 11B. New York: Academic Press. p 135-196.
