Feeding preference of the sea urchin Lytechinus variegatus (Lamarck, 1816) on seaweeds

Souza, Camilla Ferreira; Oliveira, Aline Santos de; Pereira, Renato Crespo

Abstracts

Seaweeds exhibit different strategies to minimize the damage caused by herbivores and also to influence the feeding preference of these consumers. This study evaluated the feeding preference of the sea urchin Lytechinus variegatus through multiple-choice experiments using the seaweeds Caulerpa racemosa, Dictyota menstrualis, Osmundaria obtusiloba, Plocamium brasiliense, Sargassum sp., and Ulva sp. In order to verify the importance of morphological and chemical aspects on this feeding preference, two assay-types were carried out using live and powdered macroalgae, respectively. Two different methods were employed to analyze the results obtained: comparison between biomass losses versus autogenic changes, and inclusion of autogenic values in biomass loss through herbivory. In both experiments a clear differential consumption of certain species of seaweeds by L. variegatus was observed, in the following decreasing order of preference: C. racemosa ≈ Ulva sp. > O. obtusiloba ≈ Sargassum sp. > P. brasiliense > D. menstrualis. It was also verified that both methods of analysis used yielded similar results. According to the results obtained, feeding preference of L. variegatus is probably established by the defensive chemicals produced by P. brasiliense and D. menstrualis, and by morphological aspects of C. racemosa, Ulva sp., O. obtusiloba and Sargassum sp.

Lytechinus variegatus; Feeding preference; Herbivory; Seaweeds; Chemical defenses; Morphological defenses

As macroalgas apresentam diversos tipos de estratégias para minimizar os danos gerados por herbívoros que influenciam a preferência alimentar dos consumidores. Este estudo avaliou a preferência alimentar do ouriço-do-mar Lytechinus variegatus em experimentos de múltipla escolha utilizando as macroalgas bentônicas Caulerpa racemosa, Dictyota menstrualis, Osmundaria obtusiloba, Plocamium brasiliense, Sargassum sp., e Ulva sp. Para verificar a importância dos aspectos morfológicos e químicos na preferência, os ensaios foram realizados com algas vivas e em pó, respectivamente. Foram utilizados dois métodos distintos de análise de dados: comparação entre a perda de biomassa e as mudanças por autogenia, e a incorporação dos valores de autogenia à perda de biomassa por herbivoria. Em ambos os experimentos observou-se uma clara preferência de L. variegatus por certas espécies de macroalgas em relação a outras, em ordem decrescente de preferência: C. racemosa ≈ Ulva sp. > O. obtusiloba ≈ Sargassum sp. > P. brasiliense > D. menstrualis. Além disso, constatou-se que os dois métodos de análise produziram resultados muito similares. De acordo com os resultados, a preferência alimentar de L. variegatus é provavelmente condicionada pela química defensiva produzida por P. brasiliense e D. menstrualis e aspectos morfológicos presentes em C. racemosa, Ulva sp., O. obtusiloba e Sargassum sp.

Lytechinus variegatus; Preferência alimentar; Herbivoria; Macroalgas marinhas; Defesas químicas; Defesas morfológicas

AMSLER, C. D.; IKEN, K.; MCCLINTOCK, J. B.; AMSLER, M. O.; PETERS, K. J.; HUBBARD, J. M.; FURROW, F. B.; BAKER, B. J. Comprehensive evaluation of the palatability and chemical defenses of subtidal macroalgae from the Antarctic Peninsula. Mar. Ecol. Prog. Ser, v. 294, p. 141-159, 2005.
ARGANDOÑA, V. H.; ROVIROSA, J.; SAN-MARTÍN, A.;RIQUELME, A.; DÍAZ-MARRERO, A. R.; CUETO, M.; DARIAS, J.; SANTANA, O.; GUADAÑO, A.; GONZÁLEZ-COLOMA, A. Antifeedant effects of marine halogenated monoterpenes. J. Agric. Food Chem, v. 50, p.7029-7033, 2002.
AYLING, A. L. The relation of food availability and food preferences to the field diet of an echinoid Evechinus chloroticus (Valenciennes). J. Exp. Mar. Biol. Ecol, v. 33, p. 223-235, 1978.
BARRY, J. P.; EHRET, M. J. Diet, food preference, algal availability for fishes and crabs on intertidal reef communities in southern California. Environ. Biol. Fishes, v. 37, p. 75-95, 1993.
BEDDINGFIELD, S. D.; MCCLINTOCK, J. B. Food resource utilization in the sea urchin Lytechinus variegatus in contrasting shallow-water microhabitats of Saint Joseph Bay, Florida. Gulf Mex. Sci, v. 1, p. 27-34, 1999.
BLUNT, J. W.; COOP, B. R.; MUNRO, M. H. G.; NORTHCOTE, P. T.; PRINSEP, M. R. Marine natural products. Nat. Prod. Rep, v. 22:15-61, 2005.
BLUNT, J. W.; COOP, B. R.; MUNRO, M. H. G.; NORTHCOTE, P. T. Marine natural products. Nat. Prod. Rep, v. 23, p. 26-78, 2006.
CARPENTER, R. C. Partitioning herbivory and its effects on coral reef algal communities. Ecol. Monogr, v. 56,p. 345-363, 1986.
COX, E. T.; MURRAY, N. S. Feeding preferences and the relationships between food choice and assimilation efficiency in the herbivorous marine snail Lithopoma undosum (Turbinidae). Mar. Biol, v. 148, p. 1295-1306, 2006.
COBB, J.; LAWRENCE, J. M. Diets and coexistence of the sea urchins Lytechinus variegatus and Arbacia punctulata (Echinodermata) along the central Florida Gulf coast. Mar. Ecol. Prog. Ser, v. 295, p. 171-182, 2005.
CRONIN, G. Resource allocation in seaweeds and marine invertebrates: chemical defense patterns in relation to defense theories. In: MCCLINTOCK J. B.; BAKER B. J. (Ed.). Marine chemical ecology Boca Raton: CRC Press, 2001. p. 325-353.
CRONIN, G.; HAY, M.E. Susceptibility to herbivores depends on recent history of both the plant and animal. Ecology, v. 77, p. 1531-1543, 1996.
DAWES, C. J. Marine Botany 2^nd ed. New York: John Wiley & Sons, 1998. 490 p.
DUFFY, J. E. & HAY, M. E. Seaweed adaptations to herbivory. Bioscience, v. 40, p. 368-374, 1990.
FENICAL, W. Halogenation in rhodophyta - review. J. Phycol, v. 11, p. 245-259, 1975.
GREENWAY, M. Trophic relationships of macrofauna within a Jamaican seagrass meadow and the role of the echinoid Lytechinus variegatus (Lamarck). Bull. mar. Sci, v. 56, p. 719-736, 1995.
HARROLD, C.; REED, D. C. Food availability, sea urchin grazing, and kelp forest community structure. Ecology, v. 66:116-169, 1985.
HAY, M. E. The ecology and evolution of seaweed-herbivore interactions on coral reefs. Coral Reefs, v. 16, p. 67-76, 1997.
HAY, M. E.; FENICAL, W. Marine plant-herbivore interactions: The ecology of chemical defenses. Ann. Rev. Ecol. Syst, v. 19, p. 111-145, 1988.
HAY, M. E.; STEINBERG, P. D. The chemical ecology of plant herbivore interactions in marine versus terrestrial communities. In: ROSENTHAL, G. A.; BERENBAUM, M. R. (Ed.). Herbivores - their interactions with secondary plant metabolites. New York: Academic Press, 1992. p.371-413.
HAY, M. E.; KAPPEL, Q. E.; FENICAL, W. Synergisms in plant defenses against herbivores: interactions of chemistry, calcification and plant quality. Ecology, v. 75, p. 1714-1726, 1994.
HENDLER, G.; MILLER, J. E.; PAWSON, D. L.; KIER, P. M. 1995. Sea stars, sea urchins, and allies Washington DC: Smithsonian Institution Press, 1995. 392 p.
HUANG, Y. M., MCCLINTOCK, J. B., AMSLER, C. D., PETERS, K. J.; BAKER, B. J. Feeding rates of common Antarctic gammarid amphipods on ecologically important sympatric macroalgae. J. Exp. Mar. Biol. Ecol, v. 329, p. 55-65, 2006.
LAWRENCE, J. M. On the relationship between marine plants and sea urchins. Oceanogr. Mar. Biol. Ann. Rev, v. 132, 135-286, 1975.
LEWIS, S. M. 1986. The role of herbivorous fishes in the organization of a Caribbean reef community. Ecol. Monogr, v. 56, p. 83-200, 1986.
LEWIS, S. M.; NORRIS, J. N.; SEARLES, R. B. The regulation of morphological plasticity in tropical reef algae by herbivory. Ecology, v. 68, p. 636-641, 1987.
LITTLER, M. M.; LITTLER, D. S. The evolution of thallus form and survival strategies in benthic marine macroalgae: field and laboratory tests of a functional form model. Am. Naturalist, v. 116, p. 25-44, 1980.
LITTLER, M. M.; LITTLER, D. S.; TAYLOR, P. R. Evolutionary strategies in a tropical barrier reef system: functional-form groups of marine macroalgae. J. Phycol., v. 19, p. 229-237, 1983.
LITTLER, D. S.; LITTLER, M. M. An identification guide to the reef plants of the Caribbean, Bahamas, Florida and Gulf of Mexico. 1^st ed. Washington,Off Shore Graphic, 2000. 542 p.
LOBBAN, C. S.; HARRISON, P. J. Seaweed ecology and physiology 1^st ed. Cambridge: Cambridge University Press., 1994. p.366.
LOCKWOOD, J. R. On the statistical analysis of multiple-choice feeding preference experiments. Oecologia, v. 116, p. 475-481, 1998.
LOWE, E. F.; LAWRENCE, J. M. Absorption efficiencies of Lytechinus variegatus (Lamarck) (Echinodermata: Echinoidea) for selected marine plants. J. Exp. Mar. Biol. Ecol, v. 21, p. 223-234, 1976.
LUMBANG, W. A.; PAUL, V. J. Chemical defenses of the tropical green seaweed Neomeris annulata Dickie: Effects of multiple compounds on feeding by herbivores. J. Exp. Mar. Biol. Ecol, v. 201, p. 185-195, 1996.
MCCONNELL, O.; HUGHES, P. A.; TARGETT, N. M.; DALEY, J. Effects of secondary metabolites from marine algae on feeding by the sea urchin, Lytechinus variegatus J. Chem. Ecol, v. 8, p. 1437-1453, 1982.
MCSHANE, P. E., GORFINE, H. K.; KNUCKEY, I. A. Factors influencing food selection in the abalone Haliotis rubra (Mollusca: Gastropoda). J. Exp. Mar. Biol. Ecol, v. 176, p. 27-37, 1995.
MEYER, K. D.; PAUL, V. J. Intraplant variation in secondary metabolite concentration in three species of Caulerpa (Chlorophyta: Caulerpales) and its effects on herbivorous fishes. Mar. Ecol. Prog. Ser, v. 82, 249257, 1992.
OGDEN, J.C. Some aspectes of herbivore-plant relationships on Caribbean reefs and seagrass beds. Aq. Bot, v. 2, . 103-116, 1976.
PAUL, VJ; FENICAL, W. Chemical defense in tropical green-algae, order Caulerpales. Mar. Ecol. Prog. Ser, v. 34, p. 157-169. 1986.
PAUL, V. J.; HAY, M. E. Seaweed susceptibility to herbivory - chemical and morphological correlates. Mar. Ecol. Prog. Ser, v. 33, p. 255-264, 1986.
PAUL, V. J.; CRUZ-RIVERA, E.; THACKER, R. W. Chemical mediation of macroalgal-herbivore interactions: ecological and evolutionary perspectives. In: MCCLINTOCK, J. B.; BAKER, B. J. (Ed.). Marine chemical ecology Boca Raton: CRC Press, 2001. p. 227-265.
PEREIRA, R. C.; CAVALCANTI, D. N.; TEIXEIRA, V. L. Effects of secondary metabolites from the tropical Brazilian brown alga Dictyota menstrualis on the amphipod Parhyale hawaiensis Mar. Ecol. Prog. Ser, v. 205, p. 95-100, 2000.
PEREIRA, R. C.; PINHEIRO, M. D., TEIXEIRA, V. L.; GAMA, B. A. P. Feeding preferences of the endemic gastropod Astraea latispina in relation to chemical defenses of Brazilian tropical seaweeds. Braz. J. Biol, v. 62, p. 33-40, 2002.
PETERSON, C. H.; RENAUD, P. E. Analysis of feeding preference experiments. Oecologia,v. 80, p. 82-86, 1989.
POOR, G. H.; HILL, N. A. Sources of variation in herbivore preference: among-individual and past diet effects on amphipod host choice. Mar. Biol, v. 149, p. 1403-1410, 2006.
PRINCE, J. S.; LEBLANC, W. G.; MACIÁ, S. Design and analysis of multiple choice feeding preference data. Oecologia, v. 138, p. 1-4, 2004.
RAFFA, K. F.; HAVILL, N. P.; NORDHEIM, E. V. How many choices can your test animal compare effectively? Evaluating a critical assumption of behavioral preference tests. Oecologia, v. 133, p. 422-429, 2002.
ROA, R. Design and analysis of multiple-choice feeding-preference experiments. Oecologia, v. 89, p. 509-515, 1992.
STEINBERG, P. D. Feeding preferences of Tegula funebralis and chemical defenses of marine brown algae. Ecol. Monogr, v. 55, p. 333-349, 1985.
VADAS, R. L. Preferential feeding: An optimization strategy in sea urchins. Ecol. Monogr, v. 47, p. 337-371, 1977.
VADAS, R. L.; FENCHEL, T.; OGDEN, J. C. Ecological studies on the sea urchin, Lytechinus variegatus, and the algal-seagrass communities of the Miskito Cays, Nicaragua. Aq. Bot, v. 14, p. 109-125, 1982.
VAITILINGON, D., MORGAN, R., GROSJEAN, PH., GOSSELIN, P.; JANGOUX, M. Effects of delayed metamorphosis and food rations on the perimetamorphic events in the echinoid Paracentrotus lividus (Lamarck, 1816) (Echinodermata). J. Exp. Mar. Biol. Ecol, v. 262, n. 1, p. 41-60, 2003.
VAN ALSTYNE, K. L.; HOUSER, L. T. 2003. Dimethylsulfide release during macroinvertebrate grazing and its role as an activated chemical defense. Mar. Ecol. Prog. Ser, v. 250, p. 175-181, 2003.
WATANABE, J. M. Food preference, food quality and diets of three herbivorous gastropods (Trochidae: Tegula) in a temperate kelp forest habitat. Oecologia, v. 62, p. 47-52, 1984.
WESSELS, H.; HAGEN, W.; MOLIS, M.; WIENCKE, C.; KARSTEN, U. Intra- and interspecific differences in palatability of Arctic macroalgae from Kongsfjorden (Spitsbergen) for two benthic sympatric invertebrates. J. Exp. Mar. Biol. Ecol, v. 329, p. 20-33, 2006.
WYLIE, C. R.; PAUL V. J. Feeding preferences of the surgeonfish Zebrasoma flavescens in relation to chemical defenses of tropical algae. Mar. Ecol. Prog. Ser., v. 45:23-32, 1988.
ZAR, J. H. Biostatistical analysis 3^rd ed.. Upper Saddle River, N.J.: Prentice Hall, 1996. 920 p.

Publication Dates

Publication in this collection
25 Sept 2008
Date of issue
Sept 2008

History

Accepted
12 Nov 2007
Reviewed
27 Sept 2007
Received
31 Aug 2007

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] AMSLER, C. D.; IKEN, K.; MCCLINTOCK, J. B.; AMSLER, M. O.; PETERS, K. J.; HUBBARD, J. M.; FURROW, F. B.; BAKER, B. J. Comprehensive evaluation of the palatability and chemical defenses of subtidal macroalgae from the Antarctic Peninsula. Mar. Ecol. Prog. Ser, v. 294, p. 141-159, 2005.

[2] ARGANDOÑA, V. H.; ROVIROSA, J.; SAN-MARTÍN, A.;RIQUELME, A.; DÍAZ-MARRERO, A. R.; CUETO, M.; DARIAS, J.; SANTANA, O.; GUADAÑO, A.; GONZÁLEZ-COLOMA, A. Antifeedant effects of marine halogenated monoterpenes. J. Agric. Food Chem, v. 50, p.7029-7033, 2002.

[3] AYLING, A. L. The relation of food availability and food preferences to the field diet of an echinoid Evechinus chloroticus (Valenciennes). J. Exp. Mar. Biol. Ecol, v. 33, p. 223-235, 1978.

[4] BARRY, J. P.; EHRET, M. J. Diet, food preference, algal availability for fishes and crabs on intertidal reef communities in southern California. Environ. Biol. Fishes, v. 37, p. 75-95, 1993.

[5] BEDDINGFIELD, S. D.; MCCLINTOCK, J. B. Food resource utilization in the sea urchin Lytechinus variegatus in contrasting shallow-water microhabitats of Saint Joseph Bay, Florida. Gulf Mex. Sci, v. 1, p. 27-34, 1999.

[6] BLUNT, J. W.; COOP, B. R.; MUNRO, M. H. G.; NORTHCOTE, P. T.; PRINSEP, M. R. Marine natural products. Nat. Prod. Rep, v. 22:15-61, 2005.

[7] BLUNT, J. W.; COOP, B. R.; MUNRO, M. H. G.; NORTHCOTE, P. T. Marine natural products. Nat. Prod. Rep, v. 23, p. 26-78, 2006.

[8] CARPENTER, R. C. Partitioning herbivory and its effects on coral reef algal communities. Ecol. Monogr, v. 56,p. 345-363, 1986.

[9] COX, E. T.; MURRAY, N. S. Feeding preferences and the relationships between food choice and assimilation efficiency in the herbivorous marine snail Lithopoma undosum (Turbinidae). Mar. Biol, v. 148, p. 1295-1306, 2006.

[10] COBB, J.; LAWRENCE, J. M. Diets and coexistence of the sea urchins Lytechinus variegatus and Arbacia punctulata (Echinodermata) along the central Florida Gulf coast. Mar. Ecol. Prog. Ser, v. 295, p. 171-182, 2005.

[11] CRONIN, G. Resource allocation in seaweeds and marine invertebrates: chemical defense patterns in relation to defense theories. In: MCCLINTOCK J. B.; BAKER B. J. (Ed.). Marine chemical ecology Boca Raton: CRC Press, 2001. p. 325-353.

[12] CRONIN, G.; HAY, M.E. Susceptibility to herbivores depends on recent history of both the plant and animal. Ecology, v. 77, p. 1531-1543, 1996.

[13] DAWES, C. J. Marine Botany 2^nd ed. New York: John Wiley & Sons, 1998. 490 p.

[14] DUFFY, J. E. & HAY, M. E. Seaweed adaptations to herbivory. Bioscience, v. 40, p. 368-374, 1990.

[15] FENICAL, W. Halogenation in rhodophyta - review. J. Phycol, v. 11, p. 245-259, 1975.

[16] GREENWAY, M. Trophic relationships of macrofauna within a Jamaican seagrass meadow and the role of the echinoid Lytechinus variegatus (Lamarck). Bull. mar. Sci, v. 56, p. 719-736, 1995.

[17] HARROLD, C.; REED, D. C. Food availability, sea urchin grazing, and kelp forest community structure. Ecology, v. 66:116-169, 1985.

[18] HAY, M. E. The ecology and evolution of seaweed-herbivore interactions on coral reefs. Coral Reefs, v. 16, p. 67-76, 1997.

[19] HAY, M. E.; FENICAL, W. Marine plant-herbivore interactions: The ecology of chemical defenses. Ann. Rev. Ecol. Syst, v. 19, p. 111-145, 1988.

[20] HAY, M. E.; STEINBERG, P. D. The chemical ecology of plant herbivore interactions in marine versus terrestrial communities. In: ROSENTHAL, G. A.; BERENBAUM, M. R. (Ed.). Herbivores - their interactions with secondary plant metabolites. New York: Academic Press, 1992. p.371-413.

[21] HAY, M. E.; KAPPEL, Q. E.; FENICAL, W. Synergisms in plant defenses against herbivores: interactions of chemistry, calcification and plant quality. Ecology, v. 75, p. 1714-1726, 1994.

[22] HENDLER, G.; MILLER, J. E.; PAWSON, D. L.; KIER, P. M. 1995. Sea stars, sea urchins, and allies Washington DC: Smithsonian Institution Press, 1995. 392 p.

[23] HUANG, Y. M., MCCLINTOCK, J. B., AMSLER, C. D., PETERS, K. J.; BAKER, B. J. Feeding rates of common Antarctic gammarid amphipods on ecologically important sympatric macroalgae. J. Exp. Mar. Biol. Ecol, v. 329, p. 55-65, 2006.

[24] LAWRENCE, J. M. On the relationship between marine plants and sea urchins. Oceanogr. Mar. Biol. Ann. Rev, v. 132, 135-286, 1975.

[25] LEWIS, S. M. 1986. The role of herbivorous fishes in the organization of a Caribbean reef community. Ecol. Monogr, v. 56, p. 83-200, 1986.

[26] LEWIS, S. M.; NORRIS, J. N.; SEARLES, R. B. The regulation of morphological plasticity in tropical reef algae by herbivory. Ecology, v. 68, p. 636-641, 1987.

[27] LITTLER, M. M.; LITTLER, D. S. The evolution of thallus form and survival strategies in benthic marine macroalgae: field and laboratory tests of a functional form model. Am. Naturalist, v. 116, p. 25-44, 1980.

[28] LITTLER, M. M.; LITTLER, D. S.; TAYLOR, P. R. Evolutionary strategies in a tropical barrier reef system: functional-form groups of marine macroalgae. J. Phycol., v. 19, p. 229-237, 1983.

[29] LITTLER, D. S.; LITTLER, M. M. An identification guide to the reef plants of the Caribbean, Bahamas, Florida and Gulf of Mexico. 1^st ed. Washington,Off Shore Graphic, 2000. 542 p.

[30] LOBBAN, C. S.; HARRISON, P. J. Seaweed ecology and physiology 1^st ed. Cambridge: Cambridge University Press., 1994. p.366.

[31] LOCKWOOD, J. R. On the statistical analysis of multiple-choice feeding preference experiments. Oecologia, v. 116, p. 475-481, 1998.

[32] LOWE, E. F.; LAWRENCE, J. M. Absorption efficiencies of Lytechinus variegatus (Lamarck) (Echinodermata: Echinoidea) for selected marine plants. J. Exp. Mar. Biol. Ecol, v. 21, p. 223-234, 1976.

[33] LUMBANG, W. A.; PAUL, V. J. Chemical defenses of the tropical green seaweed Neomeris annulata Dickie: Effects of multiple compounds on feeding by herbivores. J. Exp. Mar. Biol. Ecol, v. 201, p. 185-195, 1996.

[34] MCCONNELL, O.; HUGHES, P. A.; TARGETT, N. M.; DALEY, J. Effects of secondary metabolites from marine algae on feeding by the sea urchin, Lytechinus variegatus J. Chem. Ecol, v. 8, p. 1437-1453, 1982.

[35] MCSHANE, P. E., GORFINE, H. K.; KNUCKEY, I. A. Factors influencing food selection in the abalone Haliotis rubra (Mollusca: Gastropoda). J. Exp. Mar. Biol. Ecol, v. 176, p. 27-37, 1995.

[36] MEYER, K. D.; PAUL, V. J. Intraplant variation in secondary metabolite concentration in three species of Caulerpa (Chlorophyta: Caulerpales) and its effects on herbivorous fishes. Mar. Ecol. Prog. Ser, v. 82, 249257, 1992.

[37] OGDEN, J.C. Some aspectes of herbivore-plant relationships on Caribbean reefs and seagrass beds. Aq. Bot, v. 2, . 103-116, 1976.

[38] PAUL, VJ; FENICAL, W. Chemical defense in tropical green-algae, order Caulerpales. Mar. Ecol. Prog. Ser, v. 34, p. 157-169. 1986.

[39] PAUL, V. J.; HAY, M. E. Seaweed susceptibility to herbivory - chemical and morphological correlates. Mar. Ecol. Prog. Ser, v. 33, p. 255-264, 1986.

[40] PAUL, V. J.; CRUZ-RIVERA, E.; THACKER, R. W. Chemical mediation of macroalgal-herbivore interactions: ecological and evolutionary perspectives. In: MCCLINTOCK, J. B.; BAKER, B. J. (Ed.). Marine chemical ecology Boca Raton: CRC Press, 2001. p. 227-265.

[41] PEREIRA, R. C.; CAVALCANTI, D. N.; TEIXEIRA, V. L. Effects of secondary metabolites from the tropical Brazilian brown alga Dictyota menstrualis on the amphipod Parhyale hawaiensis Mar. Ecol. Prog. Ser, v. 205, p. 95-100, 2000.

[42] PEREIRA, R. C.; PINHEIRO, M. D., TEIXEIRA, V. L.; GAMA, B. A. P. Feeding preferences of the endemic gastropod Astraea latispina in relation to chemical defenses of Brazilian tropical seaweeds. Braz. J. Biol, v. 62, p. 33-40, 2002.

[43] PETERSON, C. H.; RENAUD, P. E. Analysis of feeding preference experiments. Oecologia,v. 80, p. 82-86, 1989.

[44] POOR, G. H.; HILL, N. A. Sources of variation in herbivore preference: among-individual and past diet effects on amphipod host choice. Mar. Biol, v. 149, p. 1403-1410, 2006.

[45] PRINCE, J. S.; LEBLANC, W. G.; MACIÁ, S. Design and analysis of multiple choice feeding preference data. Oecologia, v. 138, p. 1-4, 2004.

[46] RAFFA, K. F.; HAVILL, N. P.; NORDHEIM, E. V. How many choices can your test animal compare effectively? Evaluating a critical assumption of behavioral preference tests. Oecologia, v. 133, p. 422-429, 2002.

[47] ROA, R. Design and analysis of multiple-choice feeding-preference experiments. Oecologia, v. 89, p. 509-515, 1992.

[48] STEINBERG, P. D. Feeding preferences of Tegula funebralis and chemical defenses of marine brown algae. Ecol. Monogr, v. 55, p. 333-349, 1985.

[49] VADAS, R. L. Preferential feeding: An optimization strategy in sea urchins. Ecol. Monogr, v. 47, p. 337-371, 1977.

[50] VADAS, R. L.; FENCHEL, T.; OGDEN, J. C. Ecological studies on the sea urchin, Lytechinus variegatus, and the algal-seagrass communities of the Miskito Cays, Nicaragua. Aq. Bot, v. 14, p. 109-125, 1982.

[51] VAITILINGON, D., MORGAN, R., GROSJEAN, PH., GOSSELIN, P.; JANGOUX, M. Effects of delayed metamorphosis and food rations on the perimetamorphic events in the echinoid Paracentrotus lividus (Lamarck, 1816) (Echinodermata). J. Exp. Mar. Biol. Ecol, v. 262, n. 1, p. 41-60, 2003.

[52] VAN ALSTYNE, K. L.; HOUSER, L. T. 2003. Dimethylsulfide release during macroinvertebrate grazing and its role as an activated chemical defense. Mar. Ecol. Prog. Ser, v. 250, p. 175-181, 2003.

[53] WATANABE, J. M. Food preference, food quality and diets of three herbivorous gastropods (Trochidae: Tegula) in a temperate kelp forest habitat. Oecologia, v. 62, p. 47-52, 1984.

[54] WESSELS, H.; HAGEN, W.; MOLIS, M.; WIENCKE, C.; KARSTEN, U. Intra- and interspecific differences in palatability of Arctic macroalgae from Kongsfjorden (Spitsbergen) for two benthic sympatric invertebrates. J. Exp. Mar. Biol. Ecol, v. 329, p. 20-33, 2006.

[55] WYLIE, C. R.; PAUL V. J. Feeding preferences of the surgeonfish Zebrasoma flavescens in relation to chemical defenses of tropical algae. Mar. Ecol. Prog. Ser., v. 45:23-32, 1988.

[56] ZAR, J. H. Biostatistical analysis 3^rd ed.. Upper Saddle River, N.J.: Prentice Hall, 1996. 920 p.

Brasil

Brasil

Feeding preference of the sea urchin Lytechinus variegatus (Lamarck, 1816) on seaweeds

Abstracts

Publication Dates

History