Elevated levels of suspended sediment (50 mg L−1, 100 mg L−1) aff

Elevated levels of suspended sediment (50 mg L−1, 100 mg L−1) affected fertilisation, larval survival, and larval settlement in Acropora digitifera ( Gilmour, 1999). While post-fertilisation embryonic development was not inhibited by suspended sediments, larval survival and larval settlement were significantly reduced. Significant declines in fertilisation success were reported for Acropora millepora at suspended-sediment levels ⩾100 mg L−1 compared with lower levels ranging from 0 to50 mg L−1 with approximately 36% fertilisation at the highest tested suspended-sediment

levels of 200 mg L−1 ( Humphrey et al., 2008). Elevated concentrations of suspended sediment (43 mg L−1, 159 mg L−1) also significantly reduced fertilisation check details success in Pectinia lactuca compared with controls ( Erftemeijer

et al., 2012). These findings imply that increased levels of suspended sediment and/or sedimentation due to dredging operations—especially when coinciding with the main spawning season of corals—may affect their reproductive success, compromise coral recruitment and thereby compromise the recovery of degraded reefs (Erftemeijer et al., 2012). The same issues are probably relevant in naturally or episodically turbid (higher stress) settings. The mucus coat that surrounds corals, which is moved off the coral by ciliary action and is replaced repeatedly, acts as their primary defence against precipitated sediment particles. A potentially problematic by-product of this abundant 5-FU concentration mucus production can be fertilisation of the nearby water potentially causing population explosions of bacteria (Mitchell and Chet, 1975, Coffroth, 1990, Ritchie and Smith, 2004, Brown and Bythell, 2005 and Klaus et al., 2007). The metabolism of these bacteria can lead to local anoxic conditions and concomitant death of coral tissue in the immediate vicinity. Furthermore, high nutrient contents of silt can lead

to microbial activity, eventually causing the underlying coral Exoribonuclease tissue to become necrotic (Weber et al., 2006 and Hodgson, 1990a). Conversely, some coral species have been observed to exploit nutrient-rich suspended particles as a food source, thereby compensating for the stress caused by sedimentation (Fabricius and Wolanski, 2000). Numerous kinds of terrestrial pollutants, including those from sewage and agricultural runoff, make their way into nearshore sediments that can be resuspended by dredging operations and subsequently cause eutrophication of coastal waters (Kenchington, 1985, Grigg and Dollar, 1990, San Diego-McGlone et al., 2008 and Todd et al., 2010). As corals generally grow in oligotrophic waters, elevated nutrient levels can lead to a range of negative effects on coral health (Hawker and Connell, 1989), reduced fertilisation success (Harrison and Ward, 2001) and settlement rates (Hunte and Wittenberg, 1992).

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