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Assessment of fish trophic status and relationships by stable isotope data in the coral reef lagoon of New Caledonia, southwest Pacific

Published online by Cambridge University Press:  05 April 2008

Laure Carassou
Affiliation:
Institute of Research for Development, BP A5, 98848 Nouméa Cedex, New Caledonia
Michel Kulbicki
Affiliation:
Institute of Research for Development, BP A5, 98848 Nouméa Cedex, New Caledonia
Thomas J.R. Nicola
Affiliation:
Department of Marine Sciences and Coastal Management, University of Newcastle, Newcastle upon Tyne, UK
Nicholas V.C. Polunin
Affiliation:
Department of Marine Sciences and Coastal Management, University of Newcastle, Newcastle upon Tyne, UK
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Abstract

This study examines the trophic status and relationships of coral reef fish in the lagoon of New Caledonia, southwest pacific. The feeding habits of 34 fish species collected at three contrasted sites were first described using a compilation of gut contents observations and data from the literature. The carbon and nitrogen isotope signatures of these fish and of some of their potential ultimate food sources were also determined at each site. Despite some spatial variations in the isotopic signatures of most food sources and fish trophic groups, the overall trophic structures of fish assemblages were similar at the three sites. Stable isotope data were then used to re-assign fish species to trophic groups based on the δ 15N signatures of fish and their food sources. Herbivorous fish species were clearly distinguished from the other trophic groups by their lower δ 15N signatures, consistent with an estimated trophic position of ~2 for all species examined. Scaridae were however characterized by relatively higher δ 13C and lower δ 15N, which is probably linked with the role of detritus in their diet. The estimated trophic positions of planktivorous fish species were consistent with their gut contents-based classification. Conversely, the isotopic signatures of carnivorous and piscivorous fish species largely overlapped, and their estimated trophic positions were much lower than expected. This suggests that these species feed over a broader range of trophic levels and food sources than implied by the gut contents observations, and indicates that their diet is partly omnivorous. Finally, the relationships between body mass and the isotopic signatures of four fish species were significant for at least one isotopic ratio for each species. Since ontogenetic variations and omnivorous diets are difficult to assess with gut contents data only, stable isotopes revealed essential in estimating the actual trophic status and relationships characterizing the fish species under study.

Type
Research Article
Copyright
© EDP Sciences, IFREMER, IRD, 2008

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References

Allen G.R., 1991, Damselfishes of the world. H.A., Baensch editor, Melle.
Allen G.R., Steene R., Allen M., 1998, A guide to angelfishes and butterflyfishes. Odyssey Publishing, Perth.
Bailey, T.G., Robertson, D.R., 1982, Organic and caloric levels of fish faeces relative to its consumption by coprophagous reef fishes. Mar. Biol. 69, 45-50. CrossRef
Blaber, S.J.M., Milton, D.A., Rawlinson, N.J.F., 1990, Diets of lagoon fishes in the Solomon Islands: predators of tuna baitfish and trophic effects of baitfishing on the subsistence fishery. Fish. Resour. 8, 263-286. CrossRef
Booth, J.D., 2004, Synergistic effects of conspecifics and food on growth and energy allocation of a damselfish. Ecology 85, 2881-2887. CrossRef
Bozec, Y.M., Gascuel, D., Kulbicki, M., 2004, Trophic model of lagoonal communities in a large open atoll (Uvea, Loyalty islands, New Caledonia). Aquat. Living Resour. 17, 151-162. CrossRef
Bozec, Y.M., Kulbicki, M., Chassot, E., Gascuel, D., 2005, Trophic signature of coral reef fish assemblages: towards a potential indicator of ecosystem disturbance. Aquat. Living Resour. 18, 103-109. CrossRef
Bruggemann, J.H., van Oppen, M.J.H., Breeman, A.M., 1994, Foraging by the stoplight parrotfish Sparisoma viride. I. Food selection in different socially determined habitats. Mar. Ecol. Prog. Ser. 106, 41-55.
Champalbert, G., 1993, Plankton inhabiting the surface layer of the southern and southwestern lagoon of New Caledonia. Mar. Biol. 115, 223-228. CrossRef
Chen, L.S., 2002, Post-settlement diet shift of Chlorurus sordidus and Scarus schlegeli (Pisces: Scaridae). Zool. Stud. 41, 47-58.
Choat, J.H., Clements, K.D., Robbins, W.D., 2002, The trophic status of herbivorous fishes on coral reefs. I. Dietary analysis. Mar. Biol. 140, 613-623.
Choat, J.H., Robbins, W.D., Clements, K.D., 2004, The trophic status of herbivorous fishes on coral reefs. II. Food processing modes and trophodynamics. Mar. Biol. 145, 445-454.
Coleman N., 1981, Australian Sea Fishes North of 30°S. Doubleday, Lane Cove, NSW Australia.
Feuchtmayr, H., Grey, J., 2003, Effects of preparation and preservation procedures on carbon and nitrogen stable isotope determinations from zooplankton. Rapid Commun. Mass Spectrom. 17, 2605-2610. CrossRef
Fricke R., Kulbicki M., 2006, Checklist of the shore fishes of New Caledonia. In: Payri C., Richer de Forges B. (Eds.) Compendium of Marine Species from New Caledonia, Nouméa, Doc. Sci. Tech. IRD II 7, pp. 313-358.
Geesey, G.G., Alexander, G.V., Bray, R.N., Miller, A.C., 1984, Fish faecal pellets are a source of minerals for inshore reef communities. Mar. Ecol. Prog. Ser. 15, 19-25. CrossRef
Gingerich, W.H., 1986, Tissue distribution and elimination of rotenone in rainbow trout. Aquat. Toxicol. 8, 27-40. CrossRef
Graham, B.S., Grubbs, D., Holland, K., Popp, B.N., 2007, A rapid ontogenetic shift in the diet of juvenile yellowfin tuna from Hawaii. Mar. Biol. 150, 647-658. CrossRef
Grimaud J., Kulbicki M., 1998, Influence de la distance à l'océan sur les peuplements ichthyologiques des récifs frangeants de Nouvelle-Calédonie. C.R. Acad. Sci. Paris, Life Sci. 321, 923-931.
Hata H., Kato, M. 2004, Monoculture and mixed-species algal farms on a coral reef are maintained through intensive and extensive management by damselfishes. J. Exp. Biol. Ecol. 313, 285-296.
Jouon, A., Douillet, P., Ouillon, S., Fraunié, P., 2006, Calculations of hydrodynamic time parameters in a semi-opened coastal zone using a 3D hydrodynamic model. Cont. Shelf Res. 26, 1395-1415. CrossRef
Kaehler, S., Pakhomov, E.A., 2001, Effects of storage and preservation of the δ 13C and δ 15N signatures of selected marine organisms. Mar. Ecol. Prog. Ser. 219, 299-304. CrossRef
Kavanagh, K.D., Olney, J.E., 2006, Ecological correlates of population density and behaviour in the circumtropical black triggerfish Melichthys niger (Balistidae). Environ. Biol. Fish. 76, 387-398. CrossRef
Kawakami, T., Tachihara, K., 2005, Diet shift of larval and juvenile landlocked Ryukyu-ayu Plecoglossus altivelis ryukyuensis in the Fukuji Reservoir, Okinawa Island, Japan. Fish. Sci. 71, 1003-1009. CrossRef
Kulbicki M., 2006, Ecologie des poissons lagonaires de Nouvelle Calédonie (Ecology of lagoon fishes in New Caledonia), PhD dissertation, Université de Perpignan, France.
Kulbicki, M., Bozec, Y.M., Labrosse, P., Letourneur, Y., Mou-Tham, G., Wantiez, L., 2005, Diet composition of carnivorous fishes from coral reef lagoons of New Caledonia. Aquat. Living Resour. 18, 231-250. CrossRef
Lajtha K., Michener R.H., 1994, Stable isotopes in ecology and environmental sciences. Methods in Ecology, Lawton J.M., Lickens G.E. (Eds.) Blackwell Publishing, London.
La Mesa, G., La Mesa, M., Tanasetti, P., 2007, Feeding habits of the Madeira rockfish Scorpaena maderensis from central Mediterranean Sea. Mar. Biol. 150, 1313-1320. CrossRef
Montgomery, W.L., Gerking, S.D., 1980, Marine macroalgae as foods for fishes: an evaluation of potential food quality. Environ. Biol. Fish. 5, 143-153. CrossRef
Myers, R.F., 1991, Micronesian reef fishes. 2nd edition Coral Graphics, Barrigada, Guam. Nakamura Y., Horinouchi M., Nakai T., Sano M., 2003, Food habits of fishes in a seagrass bed on a fringing coral reef at Iriomote Island, southern Japan. Ichthyol. Res. 50, 15-22.
Nelson, S.G., Wilkins, S.D., 1988, Sediment processing by the surgeonfish Ctenochaetus striatus at Moorea, French Polynesia. J. Fish Biol. 32, 817-824. CrossRef
Ochavillo, D.G., Dixon, P.I., Aliño, P.M., 1992, The daily food ration of parrotfishes in the fringing reefs of Bolinao, Pangasinan, Northwestern Philippines. Proc. 7th Int. Coral Reef Symp. 2, 927-933.
Olive, P.J.W., Pinnegar, J.K., Polunin, N.V.C., Richards, G., Welch, R., 2003, Isotope trophic-step fractionation: a dynamic equilibrium model. J. Anim. Ecol. 72, 608-617. CrossRef
Ouillon, S., Douillet, P., Fichez, R., Panché, J.Y., 2005, Enhancement of regional variations in salinity and temperature in a coral reef lagoon, New Caledonia. C. R. Geosciences 337, 1509-1517. CrossRef
Owens, N.J.P., 1987, Natural variations in 15N in the marine environment. Adv. Mar. Biol. 24, 389-451. CrossRef
Peterson, J., 1999, Stable isotopes as tracers of organic matter input and transfer in benthic food webs: a review. Acta Oecol. 20, 479-487. CrossRef
Phillips, D.L., Gregg, J.W., 2003, Source partitioning using stable isotopes: coping with too many sources. Oecologia 136, 261-269. CrossRef
Pinazo, C., Bujan, S., Douillet, P., Fichez, R., Grenz, C., Maurin, A., 2004, Impact of wind and freshwater inputs on phytoplankton biomass in the coral reef lagoon of New Caledonia during the summer cyclonic period: a coupled three-dimensional biogeochemical modelling approach. Coral Reefs 23, 281-296. CrossRef
Pinnegar, J.K., Polunin, N.V.C., 1999, Differencial fractionation of δ 13C and δ 15N among fish tissues: implications for the study of trophic interactions. Funct. Ecol. 13, 225-231. CrossRef
Pinnegar, J.K., Polunin, N.V.C., 2000, Contributions of stable-isotope data to elucidation of food webs of Mediterranean rocky littoral fishes. Oecologia 122, 399-409. CrossRef
Polunin, N.V.C., Harmelin-Vivien, M., Galzin, R., 1995, Contrasts in algal food processing among five herbivorous coral-reef fishes. J. Fish Biol. 47, 455-465. CrossRef
Post, D.M., 2002, Using stable isotopes to estimate trophic position: models, methods, and assumptions. Ecology 83, 703-718. CrossRef
Pratchett, M.S., Gust, N., Goby, G., Klanten, S.O., 2001, Consumption of coral propagules represents a significant trophic link between corals and reef fish. Coral Reefs 20, 13-17. CrossRef
Purcell, S.W., Bellwood, D.R., 1993, A functional analysis of food procurement in two surgeonfish species, Acanthurus nigrofuscus and Ctenochaetus striatus (Acanthuridae). Environ. Biol. Fishes 37, 139-159. CrossRef
Rothans, T.C., Miller, A.C., 1991, A link between biologically imported particulate organic nutrients and the detritus food web in reef communities. Mar. Biol. 110, 145-150. CrossRef
Russ, G.R., St John, J., 1988, Diets, growth rates and secondary production of herbivorous coral reef fishes. Proc. 6th Int. Coral Reef Symp. 2, 37-42.
Russell B.C., 1990, Nemipterid fishes of the world (Threadfin breams, whiptail breams, monocle breams, dwarf monocle breams, and coral breams). Family Nemipteridae. An annotated and illustrated catalogue of nemipterid species known to date. FAO Fish Synopsis 12, N°125, pp.1-149.
Sano M., Shimizu M., Nose Y., 1984, Food habits of the teleostean reef fishes in Okinawa Island, southern Japan. Univ. Tokyo Bull. 25.
Scherrer, B., 1984, Biostatistique. G. Morin ed., Boucherville, Québec. Shibuno T., Shigeta T., Abe O., Fujita H., Hashimato H., Gushima K., 1996, Feeding habits of pinguiped and synodontid fishes at Kuchierabu-Jima. J. Fac. Appl. Biol. Sci. Hiroshima Univ. 35, 105-111.
Shirai S., 1986, Ecological encyclopedie of the marine animals of the Indo-Pacific. Vol. 1 Vertebrata (Mammals, Reptiles, Fishes). Shin Nippon Kyoiku Tosho, Tokyo.
Silvano, R.A.M., Guth, A.Z., 2002, Diet and feeding behaviour of Kyphosus spp. (Kyphosidae) in a Brazilian subtropical reef. Braz. Arch. Biol. Technol. 49, 623-629. CrossRef
Sweeting, C.J., Barry, J., Barnes, C., Polunin, N.V.C., Jennings, S., 2007, Effects of body size and environment on diet-tissue δ 15N fractionation in fishes. J. Exp. Mar. Biol. Ecol. 340, 1-10. CrossRef
Tenório, M.M.B., Le Borgne, R., Rodier, M., Neveux, J., 2005, The impact of terrigeneous inputs on the Bay of Ouinné (New Caledonia) phytoplankton communities: a spectrofluorometric and microscopic approach. Estuar. Coast. Shelf Sci. 64, 531-545. CrossRef
Ter Kuile, C., 1989, The forage base of some reef fishes in the Flores sea with notes on sampling and fishery. Neth. J. Sea Res. 23, 171-179. CrossRef
Tibbetts, I.R., Carseldine, L., 2005, Trophic shifts in three subtropical Australian halfbeaks (Teleostei: Hemiramphidae). Mar. Freshw. Res. 56, 925-932. CrossRef
Vander Zanden, M.J., Rasmussen, J.B., 2001, Variation in δ 15N and δ 13C trophic fractionation: implications for aquatic food webs studies. Limnol. Oceanogr. 46, 2061-2066. CrossRef
Van Rooij, J.M., Bruggemann, J.H., Videler, J.J., Breeman, A.M., 1995, Plastic growth of the herbivorous reef fish Sparisoma viride: field evidence for a trade-off between growth and reproduction. Mar. Ecol. Prog. Ser. 122, 93-105. CrossRef
Westneat M.W., 2001, Labridae. Wrasses, hogfishes, razorfishes, corises, tuskfishes. In: Carpenter, K.E., Niem, V. (Eds.), 2001. FAO species identification guide for fishery purposes. The living marine resources of the Central West Pacific. Vol. 6. Bony fishes part 4 (Labridae to Latimeriidae), estuarine crocodiles. FAO, Rome, pp. 3381-3467.
Woodland D., 1997, Siganidae. Spinefoots. Rabbitfishes. In: Carpenter K.E., Niem V. (Eds.), FAO Identification Guide for Fishery Purposes. The Western Central Pacific, pp. 3627-3650.