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Seasonal variations in diet of arrow squid (Nototodarus gouldi): stomach content and signature fatty acid analysis

Published online by Cambridge University Press:  03 August 2011

H. Pethybridge ,
P. Virtue ,
R. Casper ,
T. Yoshida ,
C.P. Green ,
G. Jackson  and
P.D. Nichols
H. Pethybridge*
Affiliation:
IMAS, University of Tasmania, Private Bag 77, Hobart, Australia
P. Virtue
Affiliation:
IMAS, University of Tasmania, Private Bag 77, Hobart, Australia
R. Casper
Affiliation:
IMAS, University of Tasmania, Private Bag 77, Hobart, Australia
T. Yoshida
Affiliation:
IMAS, University of Tasmania, Private Bag 77, Hobart, Australia
C.P. Green
Affiliation:
IMAS, University of Tasmania, Private Bag 77, Hobart, Australia
G. Jackson
Affiliation:
Weimar Center, 20601 West Paoli Lane, Weimar, CA 95736
P.D. Nichols
Affiliation:
CSIRO Marine and Atmospheric Research, Castray Esplanade, Hobart, Australia
*
Correspondence should be addressed to: H. Pethybridge, IMAS, University of Tasmania, Private Bag 77, Hobart, Australia email: Heidi.Pethybridge@csiro.au
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Abstract

This study details the feeding ecology of arrow squid, Nototodarus gouldi, collected opportunistically from trawlers in waters south-east off Australia in 2007 and 2008. Combined stomach content and fatty acid (FA) signature analyses provided clear evidence of seasonal dietary shifts in prey composition. Teleost fish remains (mainly otoliths) were found in 67% of stomachs with the two mesopelagic planktivorous fish, Lampanyctodes hectoris and Maurolicus muelleri dominating. Cephalopods and crustaceans were supplementary dietary components, with an increased representation in the diet over winter. Digestive gland lipid content was moderate (16.4 ± 8.4% wet weight) and was rich in triacylglycerol and monounsaturated fatty acids. Multivariate analysis of FA profiles grouped arrow squid with profiles of mesopelagic fish and cephalopods, thus supporting the findings of stomach content analysis. Seasonal differences in total lipid content were likely related to summer upwelling events and local changes in productivity, while intraspecific differences in lipid class and FA composition were related to seasonal differences of prey consumption. FA analyses also demonstrated dietary differences associated with gender, size and female maturation. Such relationships demonstrate that the diet of N. gouldi is closely linked to prey size, abundance and availability and possibly also, to key life-history stages.

Keywords

trophic ecologycephalopodssignature fatty acidsintraspecific dietary variation
Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 92 , Issue 1 , February 2012 , pp. 187 - 196
Copyright
Copyright © Marine Biological Association of the United Kingdom 2011

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References

REFERENCES

Abollo, E., Gestal, C., López, A., González, A.F., Guerra, A. and Pascual, S. (1998) Squid as trophic bridges for parasite flow within marine ecosystems: the case of Anisakis simplex (Nematoda: Anisakidae), or when the wrong way can be right. South African Journal of Marine Science 20, 223232.CrossRefGoogle Scholar
Abolmasova, G.I., Shul'man, G.Y., Shchepkina, A.M. and Dzhiganshin, G.F. (1990) Content of dry matter in the liver of the squid Sthenoteuthis pteropus in the Eastern Atlantic Ocean as an index of trophicity. Oceanology 30, 359362.Google Scholar
Arkhipkin, A.I. and Middleton, D. (2002) Sexual segregation in ontogenetic migrations by the squid Loligo gahi around the Falkland Islands. Bulletin of Marine Science 71, 109127.Google Scholar
Battaglia, P., Mlara, D., Rorneo, T. and Andaloro, F. (2010) Relationships between otolith size and fish size in some mesopelagic and bathypelagic species from the Mediterranean Sea (Strait of Messina, Italy). Scientia Marina 74, 605612.CrossRefGoogle Scholar
Blanchier, B. and Boucaud-Camou, E. (1984) Lipids in the digestive gland and the gonad of immature and mature Sepia officinalis (Mollusca: Cephalopoda). Marine Biology 80, 3943.CrossRefGoogle Scholar
Bligh, E.G. and Dyer, W.G. (1959) A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology B 37, 911917.CrossRefGoogle ScholarPubMed
Bradshaw, C.J, Hindell, M.A., Best, N.J., Phillips, K.L., Wilson, D. and Nichols, P.D. (2003) You are what you eat: describing the foraging ecology of southern elephant seals (Mirounga leonina) using blubber fatty acids. Proceedings of the Royal Society of London B 270, 12831292.CrossRefGoogle ScholarPubMed
Braley, M., Goldsworthy, S., Page, B., Steer, M. and Austin, J.J. (2010) Assessing morphological and DNA-based diet analysis techniques in a generalist predator, the arrow squid Nototodarus gouldi. Molecular Ecology Resources 10, 466474.CrossRefGoogle Scholar
Castellanos, Z.A. (1960) Una nueva especie de calamar argentino Ommastrephes argentinus sp. nov. (Mollusca, Cephalopoda). Neotropica 6, 5558.Google Scholar
Clark, T.A. (1982) Distribution, growth and reproduction of the lightfish Maurolicus muelleri (Sternoptychidae) off South-East Australia. CSIRO Marine Laboratory Reports, No. 145, 10 pp.Google Scholar
Collins, M.A. and Pierce, G.J. (1996) Size selectivity in the diet of Loligo forbesi (Cephalopoda: Loliginidae). Journal of the Marine Biological Association of the United Kingdom 76, 10811090.CrossRefGoogle Scholar
Dalsgaard, J., St John, M., Kattner, G., Müler-Navarra, D. and Hagen, W. (2003) Fatty acid trophic markers in the pelagic marine environment: a review. Advances in Marine Biology 46, 225340.CrossRefGoogle Scholar
Dawe, E.G., Dalley, E.L. and Lindster, W.W. (1997) Fish prey spectrum of short-finned squid (Illex illecebrosus) at Newfoundland. Canadian Journal of Fisheries and Aquatic Science 54, 200208.Google Scholar
Dunning, M.C. (1998) Zoogeography of arrow squids (Cephalopoda: Ommastrephidae) in the Coral and Tasman Seas, south-west Pacific. In Voss, N.A., Vecchione, M., Toll, R.B. and Sweeney, M.J. (eds) Systematics and biogeography of cephalopods. Smithsonian Contributions to Zoology, Volume 586. Washington, DC: Smithsonian Institution Press, pp. 435453.Google Scholar
Furlani, D., Gales, R. and Pemberton, D. (2007) Otoliths of common Australian temperate fish. Victoria, NSW: CSIRO Publishing.CrossRefGoogle Scholar
Gales, R., Pemberton, D., Lu, C.C. and Clarke, M.R. (1993) Cephalopod diet of the Australian fur seal—variation due to location, season, and sample type. Australian Journal of Marine and Freshwater Research 44, 657671.CrossRefGoogle Scholar
González, A.F., Pascual, S., Gestal, C., Abollo, E. and Guerra, A. (2003) What makes a cephalopod a suitable host for parasite? The case of Galician waters. Fisheries Research 60, 177183.CrossRefGoogle Scholar
Haimovici, M., Bruetti, N.E., Rodhouse, P.G., Csirke, J. and Leta, R.H. (1998) Illex argentinus. In Rodhouse, P.G., Dawe, E.G. and O'Gor, R.K. (eds) Squid recruitment dynamics. FAO Fisheries Technical Paper 376, pp. 2758.Google Scholar
Hedd, A. and Gales, R. (2001) The diet of shy albatrosses (Thalassarche cauta) at Albatross Island, Tasmania. Journal of Zoology 253, 6990.CrossRefGoogle Scholar
Hully, P.A. and Lutjeharms, J.R.E. (1989) Lanternfish of the southern Benguela region. Part 3. The pseudoceanic–oceanic interface. Annals of the South African Museum 98, 409435.Google Scholar
Ibáñez, C.M.Arancibia, H. and Cubillos, L.A. (2008) Biases in determining the diet of jumbo squid Dosidicus gigas (D'Orbigny 1835) (Cephalopoda: Ommastrephidae) off southern-central Chile (34°S–40°S). Helgoland Marine Research 62, 331338.CrossRefGoogle Scholar
Iverson, S.J., Frost, K.J. and Lowry, L.F. (1997) Fatty acid signatures reveal fine scale structure of foraging distribution of harbour seals and their prey in Prince William Sound, Alaska. Marine Ecology Progress Series 151, 255271.CrossRefGoogle Scholar
Iverson, S.J., Frost, K.J. and Lang, S.L.C. (2002) Fat content and fatty acid composition of forage fish and invertebrates in Prince William Sound, Alaska: factors contributing to among and within species variability. Marine Ecology Progress Series 241, 161181.CrossRefGoogle Scholar
Jackson, G.D., McKinnon, J.F., Lalas, C., Ardem, R. and Buxton, N.G. (1998) Food spectrum of the deepwater squid Moroteuthis ingens (Cephalopoda: Onychoteuthidae) in New Zealand waters. Polar Biology 20, 5665.CrossRefGoogle Scholar
Jackson, G.D., McGrath Steer, B., Wotherspoon, S. and Hobday, A. (2003) Variation in age, growth and maturity in the Australian arrow squid Nototodarus gouldi over time and space; what is the pattern? Marine Ecology Progress Series 264, 5771.CrossRefGoogle Scholar
Jackson, G.D. and McGrath Steer, B. (1999) Arrow squid in southern Australian waters—supplying management needs through biological investigations. Australia Research and Development Institute, FRDC Final Report. Project No 1999/112.Google Scholar
Lansdell, M. and Young, J. (2007) Pelagic cephalopods from eastern Australia: species composition, horizontal and vertical distribution determined from the diets of pelagic fishes. Reviews in Fish Biology and Fisheries 17, 125138.CrossRefGoogle Scholar
Lea, M., Nichols, P.D. and Wilson, G. (2002) Fatty acid composition of lipid rich myctophids and mackerel icefish (Champsocephalus gunnari)—Southern Ocean food-web implications. Polar Biology 25, 843845.CrossRefGoogle Scholar
Lipinski, M.R. (1979) Universal maturity scale for the commercially important squid (Cephalopoda: Teuthoidea). The results of maturity classifications of the Illex illecebrosus (LeSueur, 1821) populations for the years 1973–1977. International Commission for the Northwest Atlantic Fisheries Research Documents, no.79/II/38, 40 pp.Google Scholar
Nowara, G.B. and Walker, T.I. (1998) Effects of time of solar day, jigging method and jigging depth on catch rates and size of Gould's squid, Nototodarus gouldi (McCoy), in south-eastern Australian waters. Fisheries Research 34, 279288.CrossRefGoogle Scholar
Middleton, J.F. (2000) Wind-forced upwelling: the role of the surface mixed layer. Journal of Physical Oceanography 30, 745763.2.0.CO;2>CrossRefGoogle Scholar
Nichols, P.D., Nichols, D.S. and Bakes, M.J. (1994) Recent developments in marine oil products in Australia. INFORM 5, 254261.Google Scholar
O' Sullivan, D. and Cullen, J.M. (1983) Food of the squid Nototodarus gouldi in Bass Strait. Journal of Marine and Freshwater Research 30, 261285.CrossRefGoogle Scholar
O'Dor, R.K. and Webber, D.M. (1986) Properties of Illex illecebrosus egg masses potentially influencing larval oceanographic distribution. Northwest Atlantic Fisheries Organization Scientific Council Studies 9, 6976.Google Scholar
Pardo-Gandarillas, M.C., Lorhmann, K., Valdivia, A.L. and Ibáñez, C.M. (2009) First record of parasites of Dosidicus gigas (d'Orbigny 1835) (Cephalopoda: Ommastrephidae) from the Humboldt Current system off Chile. Revista de Biología Marina y Oceanografía 44, 397408.CrossRefGoogle Scholar
Pethybridge, H., Daley, R., Virtue, P., Butler, E.C.V., Cossa, D. and Nichols, P.D. (2010) Lipid and mercury profiles of 61 mid-trophic species collected off south-eastern Australia. Journal of Marine and Freshwater Research 61, 10921108.CrossRefGoogle Scholar
Phillips, K.L., Nichols, P.D. and Jackson, G.D. (2002) Lipid and fatty acid composition of the mantle and digestive gland of four Southern Ocean squid species: implications for food-web studies. Antarctic Science 14, 212220.CrossRefGoogle Scholar
Phillips, K.L., Nichols, P.D. and Jackson, G.D. (2003) Dietary variation of the squid Moroteuthis ingens at four sites in the Southern Ocean: stomach contents, lipid and fatty acid profiles. Journal of the Marine Biological Association of the United Kingdom 83, 523534.CrossRefGoogle Scholar
Rodhouse, P.G. and Nigmatullin, C.M. (1996) Role of consumers. Philosophical Transactions of the Royal Society of London, Series B 351, 10031022.Google Scholar
Rosland, R. and Ciske, J. (1997) A dynamic model for the life history of Maurolicus muelleri, a pelagic planktivorous fish. Fisheries Oceanography 6, 1934.CrossRefGoogle Scholar
Saito, H. and Murata, M. (1996) The high content of monoene fatty acids in the lipids of some midwater fishes: family Myctophidae. Lipids 31, 757763.CrossRefGoogle ScholarPubMed
Semmens, J.M. (1998) An examination of the role of the digestive gland of two loliginid squid, with respect to lipid: storage or excretion. Proceedings of the Royal Society of London B 265, 16851690.CrossRefGoogle Scholar
Smale, M.J, Watson, G. and Thomas, H. (1995) Ichthyological monographs No.1. Grahamstown, South Africa: J.L.B. Smith Institute of Ichthyology.Google Scholar
Smith, H.K. (1983) Fishery and biology of Nototodarus gouldi (McCoy, 1888) in western Bass Strait. Memoirs of the National Museum Victoria 44, 285290.CrossRefGoogle Scholar
Stowasser, G., Pierce, G.J., Moffat, C.F., Collins, M.A. and Forsythe, J.W. (2006) Experimental study on the effect of diet on fatty acid and stable isotope profiles of the squid Lolliguncula brevis. Journal of Experimental Marine Biology and Ecology 333, 97114.CrossRefGoogle Scholar
Uozumi, Y. (1998) Fishery biology of arrow squids, Nototodarus gouldi and N. sloanii in New Zealand waters. Bulletin of the National Research Institute of Far Seas Fisheries 35, 1111.Google Scholar
Vlieg, P. (1984) Proximate composition of New Zealand squid species. New Zealand Journal of Science 27, 145150.Google Scholar
Ward, T.M., Goldsworthy, S.D., Rogers, P.J., Page, B., McLeavy, L.J., Dimmlich, W.F., Einoder, L., Wiebkin, A., Roberts, M., Daly, K., Caines, R. and Huveneers, C. (2008) Ecological importance of small pelagic fishes in the Flinders Current System. Report to the Department of the Environment and Water Resources. SARDI Research Report Series no. 276. Adelaide: South Australian Research and Development Institute.Google Scholar
Williams, R. and McEldowney, A. (1990) ANARE Research notes 75. Kingston, Tasmania: Australian Antarctic Division.Google Scholar
Williams, A. and Koslow, J.A. (1997) Species composition, biomass and vertical distribution of micronekton over the mid-slope region off southern Tasmania, Australia. Marine Biology 130, 269276.CrossRefGoogle Scholar
Young, J.W. (1998) The ecology of midwater fish and zooplankton from coastal and oceanic waters of eastern Tasmania, Australia. PhD thesis. University of Tasmania, 145 pp.Google Scholar
Young, J.W., Lamb, T.D., Le, D., Bradford, R.W. and Whitelaw, A.W. (1997) Feeding ecology and interannual variations in diet of southern bluefin tuna, Thunnus maccoyi, in relation to coastal and oceanic waters off eastern Tasmania, Australia. Environmental Biology of Fishes 50, 275291.CrossRefGoogle Scholar