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The production and trophic ecology of shallow-water fish assemblages in southern Australia. 3. General relationships between sediments, seagrasses, invertebrates and fishes
Fishes and benthic invertebrates were sampled in seagrass and unvegetated habitats at 14 localities across southern Australia in order to determine any consistent relationships between animal production, fish consumption and environmental parameters over a large spatial scale. Most of the features identified in a related study at Western Port were confirmed over the extended geographic range; however, an exception was that the production of fishes in the smallest size-classes (i.e. <1 g wet weight) was not consistently greater in seagrass habitat than unvegetated habitat. The more important characteristics of seagrass and unvegetated habitat types identified in the extended study were (1) more fish species were associated with seagrass habitat than unvegetated habitat, (2) the majority of small-fish species in both habitat types fed on crustaceans, with relatively few species capable of utilising algae and virtually no species utilising seagrass, (3) the few species that did ingest algae often occurred in high abundance, (4) the size of prey eaten by fishes increased consistently with fish size, with prey length averaging ≈6% of fish length, (5) abundant large fish species generally consumed smaller prey than rarer large fish species at the same body size, (6) greater benthic invertebrate and demersal fish production occurred in seagrass habitat than in unvegetated habitat, (7) most of the production of crustaceans >1-mm sieve size was ingested by fish predators while only a small proportion of non-crustacean benthic production was consumed. Fish production was highly correlated with crustacean production and seagrass biomass, and was negatively correlated with wave exposure (measured as fetch) across the range of sites. The estimated production of crustaceans was highly correlated with the biomass of seagrass material and also with the proportion of particles <63 μm in the sediments. The overall relationships between macrofaunal production (M; mg · m-2 · day-1), macrocrustacean production (C; mg · m-2 · day-1), demersal fish production (D; mg · m-2 · day-1), fetch (F; km), seagrass biomass (L; g · m-2), proportion of particles <63 μm (S;%) and temperature (T; °C) were: ln M = 1.41 + 0.088 ln (L + 1) + 0.38 ln S + 0.89 ln T, ln C = -0.93 + 0.27 ln (L + 1) + 0.22 ln S + 0.89 ln T, ln D = -1.23 - 0.62 ln F + 0.36 ln (L + 1) + 1.04 ln T. These regression equations can be used as models to predict the production of macrofauna, crustaceans and small fishes at unexamined sites. When predictions were compared with estimates of annual production at the eight sites previously examined in Western Port, most predictions lay between 50 and 200% of measured values. Additional work in Australia and overseas should allow these models to be refined. © 1995.
History
Publication title
Journal of Experimental Marine Biology and EcologyVolume
194Pagination
107-131ISSN
0022-0981Department/School
School of Natural SciencesPublisher
Elsevier Science BvPlace of publication
Amsterdam, NetherlandsRepository Status
- Restricted
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