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The peracarid epifauna associated with the ascidian Pyura chilensis (Molina, 1782) (Ascidiacea: Pyuridae)

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SEPÚLVEDA, R., CANCINO, J. M., THIEL, M. (2003): The peracarid epifauna associated with the ascidian Pyura chilensis (Molina, 1782) (Ascidiacea: Pyuridae). Journal of Natural History 37 (13): 1555-1569, DOI: 10.1080/00222930110099615, URL: https://www.tandfonline.com/doi/full/10.1080/00222930110099615

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urn:lsid:plazi.org:pub:8808FFF9BB4BE73AFFEAFFFF14613E2F

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Figure: 10.5281/zenodo.4675229 (DOI)
Figure: 10.5281/zenodo.4675231 (DOI)
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References

  • ARRONTES, J., 1999, On the evolution of interactions between marine mesoherbivores and algae, Botanica Marina, 42, 137-155.
  • BADEN, S. P. and BOSTROM, C., 2001, The leaf canopy of seagrass beds: faunal community structure and function in a salinity gradient along the Swedish coast, in K. Reise (ed.) Ecological Comparisons of Sedimentary Shores (Berlin: Springer Verlag), pp. 213-236.
  • BIERNBAUM, C. K., 1981, Seasonal changes in the amphipod fauna of Microciona prolifera (Ellis and Solander) (Porifera: Demospongia) and associated sponges in a shallow saltmarsh creek, Estuaries, 4, 85-96.
  • BOSTROM, C. and MATTILA, J., 1999, The relative importance of food and shelter for seagrassassociated invertebrates: a latitudinal comparison of habitat choice by isopod grazers, Oecologia, 120, 162-170.
  • BUSCHMANN, A. H., 1990, Intertidal macroalgae as refuge and food for Amphipoda in Central Chile, Aquatic Botany, 36, 237-245.
  • CEA, G., 1973, Biologia del piure (Pyura chilensis Molina, 1782. Chordata, Tunicata, Ascidiacea), Gayana, 28, 1-51.
  • CLARKE, M., ORTIZ, V. and CASTILLA, J. C., 1999, Does early development of the Chilean tunicate Pyura praeputialis (Heller, 1878) explain the restricted distribution of the species?, Bulletin of Marine Science, 65, 745-754.
  • COHEN, B. F., CURRIE, D. R. and MCARTHUR, M. A., 2000, Epibenthic community structure in Port Phillip Bay, Victoria, Australia, Marine and Freshwater Research, 51, 689-702.
  • COLLETT, L. C., HUTCHINGS, P. A., GIBBS, P. J. and COLLINS, A. J., 1984, A comparative study of the macro-benthic fauna of Posidonia australis seagrass meadows in New South Wales, Aquatic Botany, 18, 111-134.
  • CONRADI, M., LOPEZ-GONZALEZ , P. J. and GARCIA-GOMEZ, C., 1997, The amphipod community as a bioindicator in Algeciras Bay (Southern Iberian Peninsula) based on a spatio-temporal distribution, Marine Ecology, 18, 97-111.
  • COSTELLO, M. J. and MYERS, A. A., 1987, Amphipod fauna of the sponges Halichondria panicea and Hymeniacidon perleve in Lough Hyne, Ireland, Marine Ecology Progress Series, 41, 115-121.
  • COVI, M. P. and KNEIB, R. T., 1995, Intertidal distribution, population dynamics and production of the amphipod Uhlorchestia spartinophila in a Georgia, USA, salt marsh, Marine Biology, 121, 447-455.
  • CURRAS, A. and MORA, J., 1992, Variacion temporal de la fauna bentonica en un fondo de Zostera noltii situado en la ria del Eo (NO de Espana), Boletin del Instituto Espanol de Oceanografia, 8, 299-309.
  • DUFFY, J. E., 1990, Amphipods on seaweeds: partners or pests?, Oecologia, 83, 267-276.
  • DUFFY, J. E. and HAY, M. E., 1991, Food and shelter as determinants of food choice by an herbivorous amphipod, Ecology, 72, 1286-1298.
  • DUFFY, J. E. and HAY, M. E., 1994, Herbivore resistance to seaweed chemical defense: the roles of mobility and predation risk, Ecology, 75, 1304-1319.
  • EDGAR, G. J., 1983, The ecology of south-east Tasmanian phytal animal communities. I. Spatial organization on a local scale, Journal of Experimental Marine Biology and Ecology, 70, 129-157.
  • EDGAR, G. J. and AOKI, M., 1993, Resource limitation and fish predation: their importance to mobile epifauna associated with Japanese Sargassum, Oecologia, 95, 122-133.
  • FAIRWEATHER, P. G., 1991, A conceptual framework for ecological studies of coastal resources: an example of a tunicate collected for bait on Australian seashores, Ocean Shoreline Management, 15, 125-142.
  • FENWICK, G. D., 1976, The effect of wave exposure on the amphipod fauna of the alga Caulerpa brownii, Journal of Experimental Marine Biology and Ecology, 25, 1-18.
  • FIELDING, P. J., WEERTS, K. A. and FORBES, A. T., 1994, Macroinvertebrate communities associated with intertidal and subtidal beds of Pyura stolonifera (Heller) (Tunicata: Ascidiacea) on the Natal coast, South African Journal of Zoology, 29, 46-51.
  • FRITH, D. W., 1976, Animals associated with sponges at North Hayling Hampshire, Zoological Journal of the Linnean Society, 58, 353-362.
  • FRITH, D. W., 1977, A preliminary analysis of the association of amphipods Microdeutopus damnoniensis (Bate), M. anomalus ( Rathke) and Corophium sextoni Crawford with sponges Halichondria panicea (Pallas) and Hymeniacidon perleve (Montagu), Crustaceana, 58, 353-362.
  • GAMBI, M. C., LORENTI, M., RUSSO, G. F., SCIPIONE, M. B. and ZUPO, V., 1992, Depths and seasonal distribution of some groups of the vagile fauna of the Posidonia oceanica leaf stratum: structural and trophic analyses, Marine Ecology, 13, 17-39.
  • GUILER, E. R., 1959, Intertidal belt-forming species on the rocky coast of Northern Chile, Proceedings of the Royal Society of Tasmania, 93, 33-98.
  • GUNNILL, F. C., 1982, Effects of plant size and distribution on the numbers of invertebrate species and individuals inhabiting the brown alga Pelvetia fastigiata, Marine Biology, 69, 263-280.
  • HOLMLUND, M. B., PETERSON, C. H. and HAY, M. E., 1990, Does algal morphology affect amphipod susceptibility to fish predation?, Journal of Experimental Marine Biology and Ecology, 139, 65-83.
  • KRAPP-SCHICKEL, G., 1993, Do algal-dwelling amphipods react to the 'critical zones' of a coastal slope?, Journal of Natural History, 27, 883-900.
  • KRAUFVELIN, P., 1999, Baltic hard bottom mesocosms unplugged: replicability, repeatability and ecological realism examined by non-parametric multivariate techniques, Journal of Experimental Marine Biology and Ecology, 240, 229-258.
  • KUNZMANN, K., 1996, Die mit ausgewahlten Schwammen (Hexactinellida und Demospongiae) aus dem Weddellmeer, Antarktis, vergesellschaftete Fauna, Berichte zur Polarforschung, 210, 1-93.
  • LANCELLOTTI, D. A. and VASQUEZ, J. A., 2000, Zoogeografia de macroinvertebrados bentonicos de la costa de Chile: contribucion para la conservacion marina, Revista Chilena de Historia Natural, 73, 99-129.
  • LEWIS, F. G., III, 1987, Crustacean epifauna of seagrass and macroalgae in Apalachee Bay, Florida, USA, Marine Biology, 94, 219-229.
  • LEWIS, J. B., 1992, Abundance, distribution and behavior of a commensal amphipod Stenothoe valida Dana on the hydrocoral Millepora complanata Lamarck., Bulletin of Marine Science, 51, 245-249.
  • LOPEZ, C. and STOTZ, W., 1997, Descripcion de la fauna asociada a Corallina officinalis L. en el intermareal rocoso de la costa de 'Palo Colorado' (Los Vilos, IV Region, Chile), Revista de Biologia Marina y Oceanografia, 32, 17-35.
  • MARSH, G. A., 1973. The Zostera epifaunal community in the York River, Virginia, Chesapeake Science, 14, 87-97.
  • MATTILA, J., CHAPLIN, G., EILERS, M. R., HECK, K. L. JR, O'NEAL, J. P. and VALENTINE, J. F., 1999, Spatial and diurnal distribution of invertebrate and fish fauna of a Zostera marina bed and nearby unvegetated sediments in Damariscotta River, Maine (USA), Journal of Sea Research, 41, 321-332.
  • MONNIOT, C., 1965, Etude systematique et evolutive de la famille des Pyuridae (Ascidiacea), Memoires du Museum national d'histoire naturelle, Serie A, Zoologie, 36, 1-192.
  • MOORE, P. G., 1973, The kelp fauna of Northeast Britain. II. Multivariate classification: turbidity as an ecological factor, Journal of Experimental Marine Biology and Ecology, 13, 127-163.
  • MOORE, P. G., 1986, Seaweed-associated animal communities in the Firth of Clyde, with special reference to the population biology of the amphipod Hyale nilssoni (Rathke), Proceedings of the Royal Society of Edinburgh, 90B, 271-286.
  • MOORE, P. G. and EARLL, R., 1985, Sediment 'whips': amphipod artifacts from the rocky sublittoral in Britain, Journal of Experimental Marine Biology and Ecology, 90, 165-170.
  • MORENO, C. A., 1995, Macroalgae as a refuge from predation for recruits of the mussel Choromytilus chorus (Molina, 1782) in Southern Chile, Journal of Experimental Marine Biology and Ecology, 191, 181-193.
  • NAVARRETE, S. A. and CASTILLA, J. C., 1990, Resource partitioning between intertidal predatory crabs: interference and refuge utilization, Journal of Experimental Marine Biology and Ecology, 143, 101-129.
  • NELSON, W. G. and DEMETRIADES, L., 1992, Peracarids associated with sabellariid worm rock (Phragmatopoma lapidosa Kinberg) at Sebastian Inlet, Florida, U.S.A., Journal of Crustacean Biology, 12, 647-654.
  • NELSON, W. G., CAIRNS, K. D. and VIRNSTEIN, R. W., 1982, Seasonality and spatial patterns of seagrass-associated amphipods of the Indian River Lagoon, Florida, Bulletin of Marine Science, 32, 121-129.
  • ONG CHE, R. G. and MORTON, B., 1992, Structure and seasonal variations in abundance of the macro-invertebrate community associated with Septifer virgatus (Bivalvia: Mytilidae) at Cape d'Aguilar, Hong Kong, Asian Marine Biology, 9, 217-233.
  • PAVIA, H., CARR, H. and ABERG, P., 1999, Habitat and feeding preferences of crustacean mesoherbivores inhabiting the brown seaweed Ascophyllum nodosum (L.) Le Jol. and its epiphytic macroalgae, Journal of Experimental Marine Biology and Ecology, 236, 15-32.
  • PEATTIE, M. E. and HOARE, R., 1981, The sublittoral ecology of the Menai Strait. II. The sponge Halichondria panicea (Pallas) and its associated fauna, Estuarine Coastal Shelf Science, 13, 621-635.
  • POORE, A. G. B. and STEINBERG, P. D., 1999, Preference-performance relationships and effects of host plant choice in an herbivorous marine amphipod, Ecological Monographs, 69, 443-464.
  • POORE, A. G. B., WATSON, M. J., DE NYS, R., LOWRY, J. K. and STEINBERG, P. D., 2000, Patterns of host use among alga-and sponge-associated amphipods, Marine Ecology Progress Series, 208, 183-196.
  • RAGNARSSON, S. A. and RAFFAELLI, D., 1999, Effects of the mussel Mytilus edulis L. on the invertebrate fauna of sediments, Journal of Experimental Marine Biology and Ecology, 241, 31-43.
  • SCHAFFELKE, B., EVERS, D. and WALHORN, A., 1995, Selective grazing of the isopod Idotea baltica between Fucus evanescens and F. vesiculosus from Kiel Fjord (western Baltic), Marine Biology, 124, 215-218.
  • SEREJO, C. S., 1998, Gammaridean and caprellidean fauna (Crustacea) associated with the sponge Dysidea fragilis Johnston at Arraial Do Cabo, Rio de Janeiro, Brazil, Bulletin of Marine Science, 63, 363-385.
  • SHILLAKER, R. O. and MOORE, P. G., 1978, Tube building by the amphipods Lembos websteri Bate and Corophium bonnellii Milne Edwards, Journal of Experimental Marine Biology and Ecology, 33, 169-185.
  • SOKAL, R. and ROHLF, F., 1995, The Principles and Practice of Statistics in Biological Research, 3rd edn (New York: W. H. Freeman and Co.), 887 pp.
  • STONER, A., 1983, Distributional ecology of amphipods and tanaidaceans associated with three sea grass species, Journal of Crustacean Biology, 3, 505-518.
  • SVANE, I. and LUNDALV, T., 1982, Population dynamics and reproductive patterns of Boltenia echinata (Ascidiacea) on the Swedish West Coast, Netherlands Journal of Sea Research, 16, 105-118.
  • SVANE, I. and SETYOBUDIANDI, I., 1996, Diversity of associated fauna in beds of the blue mussel Mytilus edulis L.: effects of location, patch size, and position within the patch, Ophelia, 45, 39-54.
  • TAYLOR, R. B., 1998, Seasonal variation in assemblages of mobile epifauna inhabiting three subtidal brown seaweeds in northeastern New Zealand, Hydrobiologia, 361, 25-35.
  • TAYLOR, R. B. and COLE, R. G., 1994, Mobile epifauna on subtidal brown seaweeds in northeastern New Zealand, Marine Ecology Progress Series, 115, 271-282.
  • THIEL, M. and ULLRICH, N., 2002, Hard rock versus soft bottom: The fauna associated with hard bottom mussel beds along the coast of Chile-and a comparison with fauna found in soft bottom mussel beds, Helgoland Marine Research, 56, 21-30.
  • THIEL, M. and VASQUEZ, J., 2000, Are kelp holdfasts islands on the ocean floor? Indication for temporarily closed aggregations of peracarid crustaceans, Hydrobiologia, 440, 45-54.
  • TSUCHIYA, M. and BELLAN-SANTINI, D., 1989, Vertical distribution of shallow rocky shore organisms and community structure of mussel beds (Mytilus galloprovincialis) along the coast of Marseille, France, Mesogee, 49, 91-110.
  • TSUCHIYA, M. and NISHIHIRA, M., 1986, Islands of Mytilus edulis as a habitat for small intertidal animals: effect of Mytilus age structure on the species composition of the associated fauna and community organization, Marine Ecology Progress Series, 31, 171-178.
  • VADER, W., 1984a, Notes on Norwegian marine Amphipoda. 7. Amphipod associates of Geodia sponges in western Norway, Fauna norvegica Serie A, 5, 14-16.
  • VADER, W., 1984b, Notes on Norwegian marine Amphipoda. 8. Amphipods found in association with sponges and tunicates, Fauna norvegica Serie A, 5, 16-21.
  • VOULTSIADOU-KOUKOURA, M. E., KOUKOURAS, A. and ELEFTHERIOU, A., 1987, Macrofauna associated with the sponge Verongia aerophoba in the North Aegean Sea, Estuarine Coastal Shelf Science, 24, 265-278.
  • WORTHINGTON, D. and FAIRWEATHER, P., 1989, Shelter and food: interactions between Turbo undulatum (Archaeogastropoda: Turbinidae) and coralline algae on rocky seashores in New South Wales, Journal of Experimental Marine Biology and Ecology, 129, 61-79.