Abstract
Stable isotope analysis is often used to investigate the trophic ecology of marine systems. However, a lack of standardization of the treatment of samples prior to analysis, hampers comparisons of results within and among studies. This study examined the effects of lipid extraction (LE), acidification for the removal of inorganic carbonate (RIC) and rinsing with deionized water (DIW) on δ13C and δ15N values and C:N ratios in sub-dermal tissue of whale sharks (Rhincodon typus), zooplankton (>200–1000 μm) and a wide range of micronekton (>1000 μm) taxa collected in 2013 and 2014 at Ningaloo Reef (Western Australia). For whale shark tissue, lipid extraction (LE and LE + DIW) increased values of δ13C, whereas LE, LE + DIW and DIW treatments increased values of δ5N and C:N ratios. These results confirm the need to remove lipids and 15N-depleted nitrogenous waste from elasmobranch tissues. The LE + DIW treatment was the most efficient at achieving this goal. For zooplankton and micronekton, LE and RIC treatments had consistent effects on δ13C values, however, effects on δ15N values were more unpredictable. Therefore, zooplankton and micronekton samples should be split into two portions, one subjected to LE or LE + RIC treatments to standardize δ13C values, and a second untreated portion used for analysis of δ15N values. For these taxa, the RIC + DIW treatment resulted in the greatest change in δ15N values, which may confound results. Mathematical normalization models used to predict outcomes of treatments on values of δ13C and δ15N were not found to be suitable for all the taxa in this study.
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References
Abrantes KG, Semmens JM, Lyle JM, Nichols PD (2011) Normalisation models for accounting for fat content in stable isotope measurements in salmonid muscle tissue. Mar Biol 159:57–64
Bligh EG, Dyer WJ (1959) A rapid method of total lipid extraction and purification. Can J Biochem Physiol 37:911–917
Bodin N, Le Loc’h F, Hily C (2007) Effect of lipid removal on carbon and nitrogen stable isotope ratios in crustacean tissues. J Exp Mar Biol Ecol 341:168–175
Bosley KL, Wainright SC (1999) Effects of preservatives and acidification on the stable isotope ratios (15N:14N, 13C:12C) of two species of marine animals. Can J Fish Aquat Sci 56:2181–2185
Bunn SE, Loneragan NR, Kempster MA (1995) Effects of acid washing on stable isotope ratios of C and N in penaeid shrimp and seagrass: implications for food-web studies using multiple stable isotopes. Limnol Oceanogr 40(3):622–625
Burgess KB, Bennett MB (2016) Effects of ethanol storage and lipid and urea extraction on δ15 N and δ13C isotope ratios in a benthic elasmobranch, the bluespotted maskray Neotrygon kuhlii. J Fish Biol 90:417–423
Carabel S, Godínez-Domínguez E, Verísimo P, Fernández L, Freire J (2006) An assessment of sample processing methods for stable isotope analyses of marine food webs. J Exp Mar Biol Ecol 336:254–261
Carlisle AB, Litvin SY, Madigan DJ, Lyons K, Bigman JS, Ibarra M, Bizzarro JJ (2016) Interactive effects of urea and lipid content confound stable isotope analysis in elasmobranch fishes. Can J Fish Aquat Sci dx. doi:10.1139/cjfas-2015-0584
Churchill DA, Heithaus MR, Grubbs RD (2015) Effects of lipid and urea extraction on δ15 N values of deep-sea sharks and hagfish: can mathematical correction factors be generated? Deep-Sea Res II 115:103–108
DeNiro MJ, Epstein S (1977) Mechanism of carbon isotope fractionation associated with lipid synthesis. Science 197:261–263
Deudero S, Pinnegar JK, Polunin VC (2002) Insights into the fish host-parasite trophic relationships revealed by stable isotope analysis. Dis Aquat Organ 52:77–86
Fisk AT, Tittlemier SA, Pranschke JL, Norstrom RJ (2002) Using anthropogenic contaminants and stable isotopes to assess the feeding ecology of Greenland sharks. Ecology 83(8):2162–2172
Goering J, Alexander V, Haubenstock N (1990) Seasonal variability of stable carbon and nitrogen isotope ratios of organisms in a North Pacific bay. Estuar Coast Shelf S 30:239–260
Hussey NE, Brush J, McCarthy I, Fisk AT (2010) δ13C and δ15N diet-tissue discrimination factors for large sharks under semi-controlled conditions. Comp Biochem Physiol A: Mol Integr Physiol 155:445–453
Hussey NE, Olin JA, Kinney MJ, McMeans BC, Fisk AT (2012) Lipid extraction effects on stable isotope values (δ13C and δ15N values) of elasmobranch muscle tissue. J Exp Mar Biol Ecol 434–435:7–15
Hussey NE, MacNeil MA, McMeans BC, Olin JA, Dudley SFJ, Cliff G, Wintner SP, Fennessy ST, Fisk AT (2014) Rescaling the trophic structure of marine food webs. Ecol Lett 17:239–250
Ihaka R, Gentleman R (1996) A language for data analysis and graphics. J Comput Graph Stat 5:299–314
Ingram T, Matthews B, Harrod C, Stephens T, Grey J, Markel R, Mazumder A (2007) Lipid extraction has little effect on the δ15N of aquatic consumers. Limnol Oceanogr-Meth 5:338–343
Ivlev A, Knyazev YA, Logachev M (1996) Daily average carbon isotope composition of CO2 of expired air and urine in norm and some endocrine pathologies in man. Biofizika 41(2):508–516
Jacob U, Mitenbeck K, Brey T, Knust R, Beyer K (2005) Stable isotope food web studies: a case for standardized sample treatment. Mar Ecol Prog Ser 287:251–253
Jaschinski S, Hansen T, Sommer U (2008) Effects of acidification in multiple stable isotope analyses. Limnol Oceanogr: Methods 6:12–15
Kiljunen M, Grey J, Sinisalo T, Harrod C, Immonen H, Jones RI (2006) A revised model for lipid-normalizing δ13C values from aquatic organisms, with implications for isotope mixing models. J Appl Ecol 43(6):1213–1222
Kim SL, Koch PL (2012) Methods to collect, preserve, and prepare elasmobranch tissues for stable isotope analysis. Environ Biol Fish 95:53–63
King P, Kennedy H, Newton PP, Jickells TD, Brand T, Calvert S, Cauwet G, Etcheber H, Head B, Khripounoff A, Manighetti B, Miquel JC (1998) Analysis of total and organic carbon and total nitrogen in settling oceanic particles and a marine sediment: an inter-laboratory comparison. Mar Chem 60:203–216
Li Y, Zhang Y, Hussey NE, Dai X (2016) Urea and lipid extraction treatment effects on δ15N and δ13C values in pelagic sharks. Rapid Commun Mass Spectrom 30:1–8
Logan JM, Lutcavage ME (2010) Stable isotope dynamics in elasmobranch tissue. Hydrobiologia 644:231–244
Logan JM, Jardine TD, Miller TJ, Bunn SE, Cunjak RA, Lutcavage ME (2008) Lipid corrections in carbon and nitrogen stable isotope analyses: comparison of chemical extraction and modelling methods. J Anim Ecol 77:838–846
Marcus L, Virtue P, Pethybridge HR, Meekan MG, Thums M, Nichols PD (2016) Intraspecific variability in diet and implied foraging ranges of whale sharks at Ningaloo Reef, Western Australia, from signature fatty acids. Mar Ecol Prog Ser 554:115–128
Martínez del Río C, Wolf N, Carleton SA, Gannes LZ (2009) Isotopic ecology ten years after a call for more laboratory experiments. Biol Rev 84:91–111
Matich P, Heithaus MR, Layman CA (2011) Contrasting patterns of individual specialization and trophic coupling in two marine apex predators. J Anim Ecol 80:294–305
McClelland JW, Montoya JP (2002) Trophic relationships and the nitrogen isotopic composition of amino acids in plankton. Ecology 83:2173–2180
McConnaughey T, McRoy CP (1979) Food-web structure and the fractionation of carbon isotopes in the Bering Sea. Mar Biol 53:257–262
Meekan MG, Wilson S, Halford A, Retzel A (2001) A comparison of catches of fishes and invertebrates by two light traps designs, in tropical NW Australia. Mar Biol 139:373–381
Mitenbeck K, Brey T, Jacob U, Knust R, Struck U (2008) How to account for the lipid effect on carbon stable-isotope ratio (δ13C): sample treatment effects and model bias. J Fish Biol 72:815–830
Murry BA, Farrell JM, Teece MA, Smyntek PM (2006) Effect of lipid extraction on the interpretation of fish community trophic relationships determined by stable carbon and nitrogen isotopes. Can J Fish Aquat Sci 63:2167–2172
Peterson BJ, Fry B (1987) Stable isotopes in ecosystem studies. Ann Rev Ecol Syst 18:293–320
Pethybridge HR, Daley RK, Virtue P, Nichols PD (2010) Lipid composition and partitioning of deepwater chondricthyans: inferences of feeding ecology and distribution. Mar Biol 157:1367–1384
Pinnegar JK, Polunin NVC (1999) Differential fractionation of δ13C and δ15N among fish tissues: implications for the study of trophic interactions. Funct Ecol 13:225–231
Pomerleau C, Winkler G, Sastri A, Nelson RJ, Williams WJ (2014) The effect of acidification and the combined effects of acidification/lipid extraction on carbon stable isotope ratios for sub-arctic and arctic marine zooplankton studies. Polar Biol 37:1541–1548
Post DM (2002) Using stable isotopes to estimate trophic position: models, methods and assumptions. Ecology 83(3):703–718
Post DM, Layman CA, Arrington DA, Takimoto G, Quattrochi J, Montaña CG (2007) Getting to the fat of the matter: models, methods and assumptions for dealing with lipids in stable isotope analysis. Oecologia 152:179–189
Ruiz-Cooley RI, Garcia KY, Hetherington ED (2011) Effects of lipid removal and preservatives on carbon and nitrogen stable isotope ratios of squid tissue: implications for ecological studies. J Exp Mar Biol Ecol 407(1):101–107
Sotiropoulos MA, Tonn WM, Wassenaar LI (2004) Effects of lipid extraction on stable carbon and nitrogen analyses of fish tissue: potential consequences for food web studies. Ecol Freshw Fish 13:155–160
Speed CW, Meekan MG, Field IC, McMahon CR, Abrantes K, Bradshaw CJA (2012) Trophic ecology of reef sharks determined using stable isotopes and telemetry. Coral Reefs 31:357–367
Sweeting CJ, Polunin NVC, Jennings S (2006) Effects of chemical lipid extraction and arithmetic lipid correction on stable isotope ratios of fish tissue. Rapid Commun Mass Spestrom 20:595–601
Syväranta J, Rautio M (2010) Zooplankton, lipids and stable isotopes: importance of seasonal, latitudinal and taxonomic differences. Can J Fish Aquat Sci 67:1721–1729
Wada E, Mizutani H, Mingawa M (1991) The use of stable isotopes for food web analysis. Crit Rev Food Sci Nutr 30:361–371
Wilson SG, Meekan MG, Carleton J, Stewart T, Knott B (2003) Distribution, abundance and reproductive biology of Pseudeuphausia latifrons and other euphuasiids on the southern North West Shelf, Western Australia. Mar Biol 42:369–379
Wolf N, Carleton SA, Martínez del Río C (2009) Ten years of experimental animal isotopic ecology. Funct Ecol 23:17–26
Olson KR (1999) Rectal gland and volume homeostasis. In: Hamlett WC (Eds.) Sharks, skates and rays: the biology of elasmobranchs fishes. The John Hopkins University Press Baltimore, Maryland, pp 329–352
Yurkowski DJ, Ferguson S, Choy ES, Loseto LL, Brown TM, Muir DCG, Semeniuk CAD, Fisk AT (2016) Latitudinal variation in ecological opportunity and intraspecific competition indicates differences in niche variability and diet specialization of Arctic marine predators. Ecol Evol 6(6):1666–1678
Zybailov B, Coleman MK, Florens L, Washburn MP (2005) Correlation of relative abundance ratios derived from peptide ion chromatograms and spectrum counting for quantitative proteomic analysis using stable isotope labelling. Anal Chem 77:6218–6224
Acknowledgements
This work was funded by the Save Our Seas Foundation, Winifred Violet Scott Charitable Trust, Holsworth Wildlife Research Endowment Grants and the Australian Institute of Marine Science. We also thank captain Terry Maxwell and his crew and all the people who contributed to fieldwork, with special mention to Kim Brooks, Michelle Thums, Dani Rob and the WA Department of Parks and Wildlife. We thank Peter Mansour and Diana Davies at CSIRO, James Horne at the Central Science Laboratory, University of Tasmania and Andrea Walters and Jorge Mardones at the Institute for Marine and Antarctic Science for their help during analysis. The manuscript was improved by the assistance and helpful comments from the editor Chris Harrod and two anonymous journal reviewers.
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All applicable national and institutional guidelines for the care and use of animals were followed. All work was conducted after ethical approval by the University of Tasmania Animal Ethics Committee (A13102) and under permits and exemptions from the Department of Park and Wildlife (SF009814, SF009227) and the Western Australian Department of Fisheries (2255, 2307).
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Marcus, L., Virtue, P., Nichols, P.D. et al. Effects of sample treatment on the analysis of stable isotopes of carbon and nitrogen in zooplankton, micronekton and a filter-feeding shark. Mar Biol 164, 124 (2017). https://doi.org/10.1007/s00227-017-3153-6
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DOI: https://doi.org/10.1007/s00227-017-3153-6