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Marine and Freshwater Research Marine and Freshwater Research Society
Advances in the aquatic sciences
RESEARCH ARTICLE (Open Access)

Artificial crevice habitats to assess the biodiversity of vagile macro-cryptofauna of subtidal rocky reefs

Mateus de A. Baronio A and Daniel J. Bucher A B
+ Author Affiliations
- Author Affiliations

A School of Environmental Science and Management, Southern Cross University, Lismore, NSW 2480, Australia.

B Corresponding author. Email: daniel.bucher@scu.edu.au

Marine and Freshwater Research 59(8) 661-670 https://doi.org/10.1071/MF07170
Submitted: 25 September 2007  Accepted: 22 April 2008   Published: 22 August 2008

Abstract

Reef cryptofauna (animals inhabiting cracks and crevices) represent much of a reef’s biodiversity yet are seldom studied owing to their inaccessibility. Subtidal rocky reefs off Brunswick Heads and Byron Bay in northern New South Wales, Australia support benthic communities ranging from coral-dominated offshore reefs to kelp beds of Ecklonia radiata on inshore reefs. It was hypothesised that differential exposure to river discharge and the East Australian Current, as well as proximity to other reef habitats, may produce differences in recruitment and persistence of cryptofauna between superficially similar reefs within a small geographical range. Artificial crevice habitats were deployed at similar depths on three inshore reefs supporting similar Ecklonia densities. Although the species richness of crevice fauna was similar at all reefs, the species composition differed significantly along with the assemblages recruited in different seasons and to different crevice sizes. Neither reef faunas nor that of varying crevice sizes changed consistently with the seasons, yet all crevices appeared equally accessible to colonists. These results demonstrate the potential inadequacy of classifying reef communities for management of regional biodiversity based on the visual dominance of a few species that may not be as sensitive to environmental variables as many of the less obvious taxa.

Additional keywords: crevice fauna, cryptofauna, multi-plate artificial habitats.


Acknowledgements

This work was made possible by internal research funding from Southern Cross University. Although not specifically funded by the New South Wales Marine Parks Authority, this work was able to make use of sampling opportunities associated with MPA-funded projects. We thank the four anonymous reviewers and the editor for their valuable comments that have greatly improved this manuscript and particularly thank Assoc. Prof. Steve Smith of the University of New England for his assistance with applying PERMANOVA to this study.


References

Ambrose R. F. (1986). Octopus Predation and Community Structure of Subtidal Rocky Reefs at Santa Catalina Island, California. Ph.D. Thesis, University of California, Los Angeles, CA, USA.

Anderson M. J. (2005). ‘PERMANOVA: A FORTRAN Computer Program for Permutational Multivariate Analysis of Variance.’ (University of Auckland: Auckland.)

Atilla, N. , and Fleeger, J. W. (2000). Meiofaunal colonisation of artificial substrates in an estuarine embayment. Marine Ecology 21, 69–83.
Crossref | GoogleScholarGoogle Scholar | Bickers A. (2004). Cape Byron Marine Park: habitat mapping. Report to New South Wales Marine Parks Authority. CRC Coastal Zone, Estuary and Waterway Management, Perth.

Booth, J. D. , and Tarring, S. C. (1986). Settlement of the red rock lobster Jasus edwardsii, near Gisbourne, New Zealand. New Zealand Journal of Marine and Freshwater Research 20, 291–297.
Britton L. J., and Greeson P. E. (1987). Methods for collection and analysis of aquatic biological and microbiological samples. In ‘Techniques of Water-Resources Investigations, Book 5’. Chapter A4. (US Geological Survey: Denver, CO.)

Bucher D., and Hartley S. (2004). Surveys of subtidal rocky reefs within and adjacent to Cape Byron Marine Park, New South Wales. Report to the New South Wales Marine Park Authority. Center for Coastal Management, Southern Cross University, Lismore.

Coleman, M. A. , Vytopil, E. , Goodsell, P. J. , Gillanders, B. M. , and Connell, S. D. (2007). Diversity and depth-related patterns of mobile invertebrates associated with kelp forests. Marine and Freshwater Research 58, 589–595.
Crossref | GoogleScholarGoogle Scholar | Hutchings P. (1983). Cryptofaunal communities of coral reefs. In ‘Perspectives on Coral Reefs’. (Ed. D. J. Barnes.) pp. 200–208. (Australian Institute of Marine Science: Townsville.)

Hutchings, P. A. , and Weate, P. D. (1977). Distribution and abundance of cryptofauna from Lizard Island, Great Barrier Reef. Marine Research in Indonesia 17, 99–112.
Kelleher G. (1999). Guidelines for marine protected areas. Best practice protected area guidelines. Series No.3, IUCN, Gland, Switzerland.

Kohn, A. , and Nybakken, J. (1975). Ecology of Conus on eastern Indian Ocean fringing reefs: diversity of species and resource utilization. Marine Biology (Berlin) 29, 211–234.
Crossref | GoogleScholarGoogle Scholar | Perera N. (2005). Reef fish assemblages in kelp (Ecklonia radiata) habitats off Brunswick Heads and Byron Bay, New South Wales. M.Env.Sci. Thesis, Southern Cross University, Lismore.

Peyrot-Clausade, M. (1980). Motile cryptofauna of Tulèar reef flats. Marine Biology 59, 43–47.
Crossref | GoogleScholarGoogle Scholar | Reaka-Kudla M. L. (1997). The global biodiversity of coral reefs: a comparison with rain forests. In ‘Biodiversity II: Understanding and Protecting our Natural Resources’. (Eds M. L. Reaka-Kudla, D. E. Wilson and E. O. Wilson.) pp. 83–108. (Joseph Henry/National Academy Press: Washington, DC.)

Rule, M. J. , and Smith, S. D. A. (2005). Spatial variation in the recruitment of benthic assemblages to artificial substrata. Marine Ecology Progress Series 290, 67–78.
Crossref | GoogleScholarGoogle Scholar | Schultz A. (2007). A comparison of shallow reef fish communities in Cape Byron Marine Park using a range of survey methods. B.App.Sci. (Hons) Thesis, Southern Cross University, Lismore.

Slack, K. V. , Ferreira, R. F. , Averett, R. C. , and Kennelly, S. S. (1988). Effects of spatial orientation of multiple plate artificial substrates on invertebrate colonization. Journal of the American Water Resources Association 24, 781–789.
Crossref | GoogleScholarGoogle Scholar | Uebelacker J. M. (1977). Cryptofaunal species/area relationship in the coral reef sponge, Gelliodes digitalis. In ‘Proceedings of the 3rd International Coral Reef Symposium, Fisher Island Station, Miami Beach, FL, USA’. University of Miami, Miami, FL, USA. pp. 69–73.

Vivien M. L., and Peyrot-Clausade M. (1974). A comparative study of the feeding behaviour of three coral reef fishes (Holocentridae), with special reference to the polychaetes of the reef cryptofauna as prey. In ‘Proceedings of the 2nd International Coral Reef Symposium Brisbane, Vol. 1’. Great Barrier Reef Committee. (Eds A. M. Cameron, B. M. Cambell, A. B. Cribb, R. Endean, J. S. Jell, O. A. Jones, P. Mather and F. H. Talbot.) pp. 179–192.