Abstract
The prey selection of larvae of three common littoral fish species (pike, Esox lucius; roach,Rutilus rutilus; and three-spined stickleback, Gasterosteus aculeatus) was studied experimentally in the laboratory by using natural zooplankton assemblages. Zooplankton prey was offered at four different concentrations to study the functional responses of the planktivores. The diets of pike and sticklebacks were formed mainly of copepod juveniles and adults, which dominated the prey communities, although sticklebacks ate also cladocerans. The diet of roach larvae consisted of rotifers, cladocerans and copepods, without prey selection, in equal proportions indicating a more omnivorous diet. All fish larvae were able to feed selectively although in sticklebacks prey selection was less pronounced. Pike and roach larvae preferred large prey to smaller prey types. Patterns of prey selection are discussed in the context of size-selection theory and apparent vs. true selection.
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References
Brooks JL, Dodson SI (1965) Predation, body size, and composition of plankton. Science 150:28–35
Browman HI, Kruse S, Oȁ9Brien WJ (1989) Foraging behavior of the predaceous cladoceran, Leptodora kindtii, and escape responses of their prey. J Plankton Res 11:1075–1088
Bry C, Bonamy J, Manelphe J, Duranthon B (1995) Early life characteristics of pike, Esox lucius, in rearing ponds: temporal survival pattern and ontogenetic diet shifts. J Fish Biol 46:99–113
Confer JL, Howick GL, Corzette MH, Kramer SL, Fitzgibbon S, Landesberg R (1978) Visual predation by planktivores. Oikos 31:27–37
Desvilettes C, Bourdier G, Breton J-C (1994) Lipid class and fatty acid composition of planktivorous larval pike Esox lucius living in a natural pond. Aquat Living Resour 7:67–77
Drenner RW, Strickler JR, Oȁ9Brien WJ (1978) Capture probability: the role of zooplankter escape in the selective feeding of planktivorous fish. J Fish Res Board Can 35:1370–1373
Eggers DM (1977) The nature of prey selection by planktivorous fish. Ecology 58:46–59
Eklöv P, Diehl S (1994) Piscivore efficiency and refuging prey: the importance of predator search mode. Oecologia 98:344–353
Engström-Öst J, Karjalainen M, Viitasalo M (in press) Feeding and refuge use by small fish in the presence of cyanobacteria. Env Biol Fish
Fuiman LA, Werner RG (eds.) (2002) Fishery Science. The unique contributions of early life stages. Blackwell Publishing, Malden
Gerritsen J (1984) Size efficiency reconsidered: a general foraging model for free-swimming aquatic animals. Am Nat 123:450–467
Gerritsen J, Strickler JR (1977) Encounter probabilities and community structure in zooplankton: a mathematical model. J Fish Res Bd Can 34:73—82
Gill AB (2003) The dynamics of prey choice in fish: the importance of prey size and satiation. J Fish Biol 63:105–116
Greene CG (1986) Patterns of prey selection: implications of predator foraging tactics. Am Nat 128:824–839
Hammer C (1985) Feeding behaviour of roach (Rutilus rutilus) larvae and the fry of perch (Perca fluviatilis) in Lake Lankau. Arch Hydrobiol 103:61–74
Hangelin C, Vuorinen I (1988) Food selection in juvenile three-spined sticklebacks studied in relation to size, abundance and biomass of prey. Hydrobiol 157:169–177
Hart PJB, Ison S (1991) The influence of prey size and abundance, and individual phenotype on prey choice by the three-spined stickleback, Gasterosteus aculeatus L. J Fish Biol 38:359—372
Hjort J (1914) Fluctuations in the great fisheries of northern Europe viewed in the light of biological research. Rapp P-V Réun, Cons Int lȁ9Exp Mer 20:1–z228
Holling CS (1959) The components of predation as revealed by a study of small-mammal predation of the European pine sawfly. Can Entomol 91:293–320
Hughes RN (1980) Optimal foraging theory in the marine context. Oceanogr Mar Biol Annu Rev 18:423–481
Jennings S, Kaiser MJ, Reynolds JD (2001) Marine fisheries ecology. Blackwell Publishing, Malden
Karjalainen M, Reinikainen M, Spoof L, Meriluoto JAO, Sivonen K, Viitasalo M (2005) Trophic transfer of cyanobacterial toxins from zooplankton to planktivores: consequenses for pike larvae and mysid shrimps. Environ Toxicol 20:354–362
Lappalainen A, Rask M, Koponen H, Vesala S (2001) Relative abundance, diet and growth of perch (Perca fluviatilis) and roach (Rutilus rutilus) at Tvärminne, northern Baltic Sea, in 1975 and 1997: responses to eutrophication. Boreal Env Res 6:107–118
Lehtiniemi M (2005) Swim or hide – predator cues cause species specific reactions in young fish larvae. J Fish Biol 66:1285–1299
Lonsdale DJ, Heinle DR, Siegfried C (1979) Carnivorous feeding behavior of the adult calanoid copepod Acartia tonsa dana. J Exp Mar Biol Ecol 36:235–248
Maksimenkov VV, Tokranov AM (1995) Feeding habits of three-spined stickleback, Gasterosteus aculeatus (Gasterosteidae), in the Bolȁ9shaya river estuary (West Kamchatka). J Ichthyol 35:88–99
Mamcarz A, Kucharczyk D, Kujawa R, Skrzypczak A, Furgala-Selezniow G (1998) Ontogeny of feeding habits in northern pike, Esox lucius(Esocidae), larvae reared in illuminated cages. Ital J Zool 65:251–253
Mann RHK, Bass JAB, Leach D, Pinder AC (1997) Temporal and spatial variations in the diet of 0 group roach (Rutilus rutilus) larvae and juveniles in the river Great Ouse in relation to prey availability. Regulated Rivers: Research & Management 13:287–294
Mehner T, Heerkloss R (1994) Direct estimation of food consumption of juvenile fish in a shallow inlet of the southern Baltic. Int Revue Ges Hydrobiol 79:295–304
Pastorok RA (1981) Prey vulnerability and size selection by Chaoborus larvae. Ecology 62:1311–1324
Pearre S (1982) Estimating prey preference by predators: uses of various indices, and a proposal of another based on χ2. Can J Fish Aquat Sci 39:914–923
Peterson I, Wroblenski JS (1984) Mortality rate of fishes in the pelagic ecosystem. Can J Fish Aquat Sci 41:1117–1120
Solomon ME (1949) The natural control of animal populations. J Anim Ecol 18:1–35
Thiel R (1996) The impact of fish predation on the zooplankton community in a southern Baltic bay. Limnologica 26:123–137
Urho L (2002) The importance of larvae and nursery areas for fish production. Ph.D. thesis, University of Helsinki and Finnish Game and Fisheries Institute. Vammalan Kirjapaino, Vammala
Wanzenböck J (1995) Changing handling times during feeding and consequences for prey size selection of 0 + zooplanktivorous fish. Oecologia 104:372–378
Wanzenböck J, Schiemer F (1989) Prey detection in cyprinids during early development. Can J Fish Aquat Sci 46:995–1001
Viherluoto M, Viitasalo M (2001) Temporal variability in functional responses and prey selectivity of the pelagic mysid, Mysis mixta, in natural prey assemblages. Mar Biol 138:575–583
Viitasalo M, Vuorinen I, Saesmaa S (1995) Mesozooplankton dynamics in the northern Baltic Sea: implications of variations in hydrography and climate. J␣Plankton Res 17:1857—1878
Viitasalo M, Kiørboe T, Flinkman J, Pedersen LW, Visser AW (1998) Predation vulnerability of planktonic copepods: consequences of predator foraging strategies and prey sensory abilities. Mar Ecol Prog Ser 175:129–142
Viitasalo M, Flinkman J, Viherluoto M (2001) Zooplanktivory in the Baltic Sea: a comparison of prey selectivity by Clupea harengus and Mysis mixta, with reference to prey escape reactions. Mar Ecol Prog Ser 216:191—200
Wootton RJ (1990) Ecology of teleost fishes. Chapman & Hall, London
Acknowledgements
The Tvärminne Zoological Station, University of Helsinki provided good laboratory facilities for the experiments and boats for sampling. H. Strandberg (Trollböle fish hatchery) is acknowledged for providing the pike larvae, T. Meriläinen for help in the field, L. Urho for identification of roach larvae, J.-P. Pääkkönen for help with the equations and E. Lindén, J.-P. Pääkkönen, L. Urho and three anonymous referees for comments on the manuscript. The study was financed by the Academy of Finland (project no. 202437 and 203799) and by the Walter and Andrée de Nottbeck Foundation. The experiments comply with the current laws of Finland.
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Lehtiniemi, M., Hakala, T., Saesmaa, . et al. Prey selection by the larvae of three species of littoral fishes on natural zooplankton assemblages. Aquat Ecol 41, 85–94 (2007). https://doi.org/10.1007/s10452-006-9042-6
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DOI: https://doi.org/10.1007/s10452-006-9042-6