Register      Login
Marine and Freshwater Research Marine and Freshwater Research Society
Advances in the aquatic sciences
Shopping Cart: ( empty )
You are here: Home > Journals > MF > MF04071
RESEARCH ARTICLE
Contents Vol 55(7)

Drifting objects as habitat for pelagic juvenile fish off New South Wales, Australia

Tim Dempster A C and Michael J. Kingsford B
+ Author Affiliations
- Author Affiliations

A School of Biological Sciences, University of Sydney, NSW 2006, Australia.

B School of Marine Biology and Aquaculture, James Cook University, Townsville, Qld 4811, Australia.

C Corresponding author. Email: dempster@bio.usyd.edu.au

Marine and Freshwater Research 55(7) 675-687 https://doi.org/10.1071/MF04071
Submitted: 20 April 2004  Accepted: 27 July 2004   Published: 1 October 2004

Abstract

The importance of drifting objects to small juvenile pelagic fish was investigated off the coast of New South Wales, Australia. Distance-related and temporal patterns in the distribution of clumps of drifting algae were investigated with 5000 m2 transects at five distances from shore (0.1, 0.5, 1, 5 and 10 km), two to three times per season for 2 years. Juvenile fish associated with drift algae were collected. Clumps of algae, predominantly Sargassum spp., were most abundant in spring, which coincided with the highest abundance of alga-associated post-flexion juvenile fish. Drift algae were also most abundant close to shore, probably due to the proximity to source and the dominant onshore winds. Fish were quickly attracted to drifting artificial objects (fish aggregation device; FADs), although the magnitude of attraction varied greatly among days. The relative abundance of small fish in open waters available to colonise FADs and differing weather conditions may explain much of this variability. More fish colonised FADs with an odour source than unscented control FADs, indicating small fish may use chemical cues to locate drifting structures. We conclude that juvenile fish actively seek drifting objects as pre-settlement habitat, which may reduce predation and enhance settlement opportunities.

Extra keywords: drift algae, fish aggregation devices (FAD), juvenile fish, Phyllospora, Sargassum, Trachurus.


References

Atema, J. , Kingsford, M. J. , and Gerlach, G. (2002). Larval reef fish could use odour for detection, retention and orientation to reefs. Marine Ecology Progress Series 241, 151–160.


Benz, C. M. , Eiseman, N. J. , and Gallaher, E. E. (1979). Seasonal occurrence and variation in standing crop of a drift algal community in the Indian River, Florida. Botanica Marina 22, 413–420.


Castro, J. J. , Santiago, J. A. , and Santana-Ortega, A. T. (2001). A general theory on fish aggregation to floating objects: an alternative to the meeting point hypothesis. Reviews in Fish Biology and Fisheries 11, 255–277.
Crossref | GoogleScholarGoogle Scholar |

Dempster, T. (2003). ‘Association of Pelagic Fish with Floating Structures: Patterns, Processes and Ecological Consequences.’ PhD Thesis. (University of Sydney: Sydney, Australia.)

Dooley, J. K. (1972). Fishes associated with the pelagic Sargassum complex, with a discussion of the Sargassum community. Contributions in Marine Science 16, 1–32.


Druce, B. , and Kingsford, M. J. (1995). An experimental investigation on the fishes associated with drifting objects in coastal waters of temperate Australia. Bulletin of Marine Science 57, 378–392.


Elliott, J. K. , Elliott, J. M. , and Marsical, R. N. (1995). Host selection, location, and association behaviors of anemone fishes in field settlement experiments. Marine Biology 122, 377–389.


Gooding, R. M. , and Magnusson, J. J. (1967). Ecological significance of a drifting object to pelagic fishes. Pacific Science 21, 486–497.


Gray, C. A. , Otway, N. M. , Laurenson, F. A. , Miskiewicz, A. G. , and Pethebridge, R. L. (1992). Distribution and abundance of marine fish larvae in relation to effluent plumes from sewage outfalls and depth of water. Marine Biology 113, 549–559.


Howarth, G. J. (2002). ‘The Influence of Oceanography and Drifting Objects on the Distribution and Abundance of Early Life History Stage Fishes on the Great Barrier Reef.’ Honours Thesis. (James Cook University: Townsville, Australia.)

Hunter, J. R. , and Mitchell, C. T. (1968). Field experiments on the attraction of pelagic fish to floating objects. Journal du Conseil Permanent International pour l'Exploration de lar Mer 31, 427–434.


Hutchins, B., and  Swainston, R. (1986). ‘Sea Fishes of Southeastern Australia.’ (Swainston Publishing: Perth, Australia.)

Ida, H. , Hiyama, Y. , and Kusaka, T. (1967). Study on fishes gathering around floating seaweed – I. Abundance and species composition. Bulletin of the Japanese Society of Scientific Fisheries 33, 923–929.


Kawamura, G. , Matsushita, T. , Nishitai, M. , and Matsuoka, T. (1996). Blue and green fish aggregation devices are more attractive to fish. Fisheries Research 28, 99–108.
Crossref | GoogleScholarGoogle Scholar |

Kingsford, M. J. (1992). Drift algae and small fish in the coastal waters of northeastern New Zealand. Marine Ecology Progress Series 80, 41–55.


Kingsford, M. J. (1993). Biotic and abiotic structure in the pelagic environment: importance to small fishes. Bulletin of Marine Science 53, 393–415.


Kingsford, M. J. (1995). Drift algae: a contribution to near-shore habitat complexity in the pelagic environment and an attractant for fish. Marine Ecology Progress Series 116, 297–301.


Kingsford, M. J. , and Choat, J. H. (1985). The fauna associated with drift algae captured with a plankton-mesh purse seine net. Limnology and Oceanography 30, 618–630.


Kingsford, M. J. , and Choat, J. H. (1986). Influence of surface slicks on the distribution and onshore movements of small fish. Marine Biology 91, 161–171.


Kingsford, M. , Leis, J. , Shanks, A. , Lindeman, K. , Morgan, S. , and Pineda, J. (2002). Sensory environments, larval abilities and local self-recruitment. Bulletin of Marine Science 70, 341–375.


Kingsford, M. J. , and Suthers, I. M. (1994). Dynamic estuarine plumes and fronts: importance to small fish and plankton in coastal waters of NSW, Australia. Continental Shelf Research 14, 655–672.
Crossref | GoogleScholarGoogle Scholar |

Kobayashi, H. , and Fujiwara, K. (1987). Olfactory response in the yellowtail Seriola quinqueradiata. Nippon Suisan Gakkai Shi 53, 1717–1725.


Leis, J. M. , Carson-Ewart, B. M. , and Cato, D. H. (2002). Sound detection in situ by the larvae of a coral-reef damselfish (Pomacentridae). Marine Ecology Progress Series 232, 259–268.


Lenanton, R. C. J. , Robertson, A. I. , and Hansen, J. A. (1982). Nearshore accumulation of detached macrophytes as nursery areas for fish. Marine Ecology Progress Series 9, 51–57.


Masuda, R. , and Tsukamoto, K. (1999). School formation and concurrent developmental changes in carangid fish with reference to dietary conditions. Environmental Biology of Fish 56, 243–252.
Crossref | GoogleScholarGoogle Scholar |

Mitchell, C. T. , and Hunter, J. R. (1970). Fishes associated with drifting kelp, Macrocystis pyrifera, off the coast of southern California and northern Baja California. California Fish and Game 56, 288–297.


Morgan, V. T. (1995). Statistical distributions of wind parameters at Sydney, Australia. Renewable Energy 6, 39–47.
Crossref | GoogleScholarGoogle Scholar |

Okiyama, M. (1988). ‘An Atlas of the Early Stage Fishes in Japan.’ (Tokai University Press: Tokyo, Japan.)

Rissik, D. , and Suthers, I. M. (1996). Feeding in a larval fish assemblage: the nutritional significance of an estuarine plume front. Marine Biology 125, 233–240.


Rountree, R. A. (1989). Association of fishes with fish aggregation devices: effects of structure size on fish abundance. Bulletin of Marine Science 44, 960–972.


Safran, P. , and Omori, M. (1990). Some ecological observations of fishes associated with drifting seaweed off Tohoku coast, Japan. Marine Biology 105, 395–402.


Schiel, D. R. (1994). Kelp communities. In ‘Marine Biology’. (Eds. L. S. Hammond and R. N. Synnot)  pp. 345–361. (Longman Cheshire: Melbourne, Australia.)

Shanks, A. L. (1983). Surface slicks associated with tidally forced internal waves may transport pelagic larvae of benthic invertebrates and fishes shorewards. Marine Ecology Progress Series 24, 289–295.


Short, A. D. , and Trenaman, N. L. (1992). Wave climate of the Sydney region, an energetic and highly variable ocean wave regime. Australian Journal of Marine and Freshwater Research 43, 765–791.


Trnski, T. (1998). Carangidae: Trevallys, jacks. In ‘Larvae of Temperate Australian Fishes: Laboratory Guide for Larval Fish Identification’. (Eds. F. J. Neira, A. Miskiewicz and T. Trnski)  pp. 192–203. (University of Western Australia Press: Perth, Australia.)

Underwood, A. J. (1997). ‘Experiments in Ecology: Their Logical Design and Interpretation Using Analysis of Variance.’ (Cambridge University Press: Cambridge, UK.)

Watson, W. and  Miskiewicz, A. G. (1998). Blenniidae: Blennies. In ‘Larvae of Temperate Australian Fishes: Laboratory Guide for Larval Fish Identification’. (Eds. F. J. Neira, A. Miskiewicz and T. Trnski)  pp. 368–381. (University of Western Australia Press: Perth, Australia.)

Williams, J. D. , Holland, K. N. , Jameson, D. M. , and Bruening, R. C. (1992). Amino acid profiles and liposomes: their role as chemosensory information carriers in the marine environment. Journal of Chemical Ecology 18, 2107–2115.