Photo-physiological costs associated with acute sediment stress events in three near-shore turbid water corals

Many coral reef communities thriving in inshore coastal waters characterised by chronically high natural turbidity (> 5 mg l(-1)) have adapted to low light (< 200 mu mol photons m(-2) s(-1)) and high sedimentation rates (< 10 mg cm(-2) d(-1)). Yet, short (hours) acute sediment stress events driven by wind waves, dredging operations involving suction or screening, or shipping activities with vessel wake or propeller disturbance, can result in a rise in turbidity above the natural background level. Although these may not be lethal to corals given the time frame, there could be a considerable impact on photo-trophic energy production. A novel sediment delivery system was used to quantify the effects of 3 acute sediment resuspension stress events (turbidity = 100, 170, 240 mg l(-1); sedimentation rates = 4, 9, 13 mg cm(-2) h(-1)) on 3 inshore turbid water corals common in the Indo-Pacific (Merulina ampliata, Pachyseris speciosa and Platygyra sinensis). Coral photo-physiology response (respiration, net photosynthesis, and maximum quantum yield) was measured immediately after 2 h of exposure. The respiration rate increased (from 0.72-1.44 to 0.78-1.76 mu mol O-2 cm(-2) h(-1)) as the severity of the acute sediment resuspension event increased, whereas the photosynthetic rate declined (from 0.25-0.41 to -0.19-0.25 mu mol O2 cm(-2) h(-1)). Merulina was the least tolerant to acute sediment resuspension, with a photosynthesis and respiration ratio (P/R ratio) of < 1.0 when turbidity levels reached > 170 mg l(-1), while Platygyra was most tolerant (P/R > 1.0). Fluorescence yield data suggest that the rapid photo-acclimation ability of Platygyra enabled it to maintain a positive carbon budget during the experiments, illustrating species-specific responses to acute sediment stress events.