Coral and Fish Biocoenosis: Ecological Cells Gradually Maturing in Complexity, Species Composition and Energy Turnover

Long-term observations on coral units and their coral fishes, as well as observations on the growth of colonies of marked corals in the Gulf of Aqaba (Red Sea), have revealed the relationship between coral dimension and complexity and the ecomorphology and sociobiology of the inhabiting fishes. In this study, coral fishes are identified as species that, following the planktonic interval, settle and remain in a selected coral or its immediate vicinity. Parallel with growth of the refuge, the number of fishes in such a coral–fish association (=ecological cell) increases to a certain asymptote, forming a stable symbiotic entity of fish species, specific in composition and biomass. The initial cell begins with 4–5-year-old branching corals that harbors 3–4 cryptic species of gobies (Paragobiodon and Gobiodon species). This is followed by several stages of coral growth and increase in fish species and biomass, especially of pomacentrids, anthiases, pseudochromids and blennies. The water column or functional space from which the fishes harvest plankton, their main food source, starts at around a 0.2m³ column in the young colonies, and ends with a water column of around 500m³ in the mature ecological cells of large coral knolls. At the mature stage, large cells harbor up to 100 diurnal and nocturnal species of fish, permanently using this refuge and forming an integrated collective. The territorial limits of the piscivorous groupers (Cephalopholis species) generally establish the dimensions of these ecological cells. Preliminary data on standard energy metabolism of the fishes for mature ecological cells reveal that 800kg food is required each year to maintain this biomass. The biological composition and stability of fish populations of such ecological cells will depend on the biological and physical stability of the host coral population.