Epifaunal composition and fractal dimensions of marine plants in relation to emersion

J. Davenport; A. Butler; A. Cheshire

doi:10.1017/S0025315498000393

Abstract

Three macroalgae were studied: Enteromorpha sp. (Chlorophyceae), Hormosira banksii (Turner) Descaisne (Phaeophyceae), Corallina sp. (Rhodophyceae). Fractal dimensions (D) for the outlines of the three species were 1.24, 1.07 and 1.35 respectively in the step range 0.5–5.0 mm. All three species showed loss of epifauna on the falling tide; loss was greatest in Enteromorpha, least in Corallina. In Enteromorpha and Hormosira, most loss of epifauna was in the form of harpacticoid copepods; in Corallina loss was spread more evenly across the taxa. Epifaunal biomass and retention was much greater in Corallina than in the other two species, partially because of better water-retention properties. Enteromorpha and Hormosira both showed marked decreases in epifaunal diversity during emersion; Corallina did not.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Commito, J. A. and Dankers, N. M. J. A. 2001. Ecological Comparisons of Sedimentary Shores. Vol. 151, Issue. , p. 39.

Kelaher, B. P. and Lowry, J. K. 2002. A NEW SPECIES OF ELASMOPUS FROM AUSTRALIA AND ITS VARIATION IN DENSITY WITH RESPECT TO PHYSICAL ARCHITECTURE OF CORALLINE ALGAL TURF. Journal of Crustacean Biology, Vol. 22, Issue. 4, p. 861.

Kelaher, B. P. 2003. Changes in habitat complexity negatively affect diverse gastropod assemblages in coralline algal turf. Oecologia, Vol. 135, Issue. 3, p. 431.

Davenport, John 2003. Handbook of Scaling Methods in Aquatic Ecology. p. 245.

Crowe, Tasman P. Smith, Emma L. Donkin, Peter Barnaby, Deborah L. and Rowland, Steven J. 2004. Measurements of sublethal effects on individual organisms indicate community‐level impacts of pollution. Journal of Applied Ecology, Vol. 41, Issue. 1, p. 114.

McAbendroth, L. Ramsay, P. M. Foggo, A. Rundle, S. D. and Bilton, D. T. 2005. Does macrophyte fractal complexity drive invertebrate diversity, biomass and body size distributions?. Oikos, Vol. 111, Issue. 2, p. 279.

Kelaher, Brendan P. and Carlos Castilla, Juan 2005. Habitat characteristics influence macrofaunal communities in coralline turf more than mesoscale coastal upwelling on the coast of Northern Chile. Estuarine, Coastal and Shelf Science, Vol. 63, Issue. 1-2, p. 155.

Kelaher, Brendan P. Castilla, Juan Carlos Prado, Luis York, Paul Schwindt, Evangelina and Bortolus, Alejandro 2007. Spatial variation in molluscan assemblages from coralline turfs of Argentinean Patagonia. Journal of Molluscan Studies, Vol. 73, Issue. 2, p. 139.

Leite, Fosca P. P. Tanaka, Marcel O. Sudatti, Daniela B. and Gebara, Raquel S. 2007. Diel density variation of amphipods associated with Sargassum beds from two shores of Ubatuba, Southeastern, Brazil. Iheringia. Série Zoologia, Vol. 97, Issue. 4, p. 400.

THOMAZ, SIDINEI M. DIBBLE, ERIC D. EVANGELISTA, LUIZ R. HIGUTI, JANET and BINI, LUIS M. 2008. Influence of aquatic macrophyte habitat complexity on invertebrate abundance and richness in tropical lagoons. Freshwater Biology, Vol. 53, Issue. 2, p. 358.

Mieczan, Tomasz 2010. The influence of emergent and submerged macrophyte beds on ciliate communities in a shallow lake. Oceanological and Hydrobiological Studies, Vol. 39, Issue. 4, p. 107.

Irwin, Sandra and Davenport, John 2011. OXYGEN MICROENVIRONMENT OF CORALLINE ALGAL TUFTS AND THEIR ASSOCIATED EPIPHYTIC ANIMALS. Biology & Environment: Proceedings of the Royal Irish Academy, Vol. 110, Issue. 3, p. 185.

Hayakawa, Jun Kawamura, Tomohiko Kurogi, Hiroaki and Watanabe, Yoshiro 2013. Shelter effects of coralline algal turfs: protection for Turbo cornutus juveniles from predation by a predatory gastropod and wrasse. Fisheries Science, Vol. 79, Issue. 1, p. 15.

St. Pierre, Jasmine I. and Kovalenko, Katya E. 2014. Effect of habitat complexity attributes on species richness. Ecosphere, Vol. 5, Issue. 2, p. 1.

Veiga, Puri Rubal, Marcos and Sousa-Pinto, Isabel 2014. Structural complexity of macroalgae influences epifaunal assemblages associated with native and invasive species. Marine Environmental Research, Vol. 101, Issue. , p. 115.

Torres, A.C. Veiga, P. Rubal, M. and Sousa-Pinto, I. 2015. The role of annual macroalgal morphology in driving its epifaunal assemblages. Journal of Experimental Marine Biology and Ecology, Vol. 464, Issue. , p. 96.

Cúrdia, João Carvalho, Susana Pereira, Fábio Guerra-García, José Manuel Santos, Miguel N. and Cunha, Marina R. 2015. Diversity and abundance of invertebrate epifaunal assemblages associated with gorgonians are driven by colony attributes. Coral Reefs, Vol. 34, Issue. 2, p. 611.

Thomsen, Mads S. Hildebrand, Thomas South, Paul M. Foster, Travis Siciliano, Alfonso Oldach, Eliza and Schiel, David R. 2016. A sixth‐level habitat cascade increases biodiversity in an intertidal estuary. Ecology and Evolution, Vol. 6, Issue. 22, p. 8291.

Bellgrove, Alecia McKenzie, Prudence F. Cameron, Hayley and Pocklington, Jacqueline B. 2017. Restoring rocky intertidal communities: Lessons from a benthic macroalgal ecosystem engineer. Marine Pollution Bulletin, Vol. 117, Issue. 1-2, p. 17.

Saarinen, Anniina Salovius-Laurén, Sonja and Mattila, Johanna 2018. Epifaunal community composition in five macroalgal species – What are the consequences if some algal species are lost?. Estuarine, Coastal and Shelf Science, Vol. 207, Issue. , p. 402.

Download full list

Article contents

Epifaunal composition and fractal dimensions of marine plants in relation to emersion

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Epifaunal composition and fractal dimensions of marine plants in relation to emersion

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests