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7863653 
Journal Article 
Effects of phosphate on growth and skeletal density in the scleractinian coral Acropora muricata: A controlled experimental approach 
Dunn, JG; Sammarco, PW; Lafleur, G, Jr 
2012 
Yes 
Journal of Experimental Marine Biology and Ecology
ISSN: 0022-0981 
411 
34-44 
English 
WOS:000299755200005 
Phosphate contamination can negatively affect corals, modifying growth rates, skeletal density, reproduction, mortality, and zooxanthellae. We determined the effects of elevated phosphate on coral growth and density. Genetically distinct colonies of Acropora muricata were sub-divided and distributed among three 110-L aquaria, and exposed to phosphate levels of 0.09, 0.20, and 0.50mgL -1 for four months. Total skeletal length, living tissue length, weight, branch production, and polyp extension were measured. Linear extension and tissue growth increased under all conditions. Growth rates were highest at a phosphate concentration of 0.50mgL -1. Weight increased through time, graded from low to high with phosphate concentration. Density decreased through time, and was significantly lowest in the high phosphate treatment. Phosphate concentration produced no visible effects of stress on the corals, as indicated by polyp extension and lack of mortality. It is suggested that the phosphate enhanced growth was due to increased zooxanthellar populations and photosynthetic production within the coral. Skeletal density reduction may be due to phosphate binding at the calcifying surface and the creation of a porous and structurally weaker calcium carbonate/calcium phosphate skeleton. Increased phosphate concentrations, often characteristic of eutrophic conditions, caused increased coral growth but also a more brittle skeleton. The latter is likely more susceptible to breakage and damage from other destructive forces (e.g., bioerosion) and makes increased coral growth a poor indicator of reef health. © 2011. 
Acropora muricata; Coral; Density; Growth; Phosphate