27 years of benthic and coral community dynamics on turbid, highly urbanised reefs off Singapore.

Coral cover on reefs is declining globally due to coastal development, overfishing and climate change. Reefs isolated from direct human influence can recover from natural acute disturbances, but little is known about long term recovery of reefs experiencing chronic human disturbances. Here we investigate responses to acute bleaching disturbances on turbid reefs off Singapore, at two depths over a period of 27 years. Coral cover declined and there were marked changes in coral and benthic community structure during the first decade of monitoring at both depths. At shallower reef crest sites (3-4 m), benthic community structure recovered towards pre-disturbance states within a decade. In contrast, there was a net decline in coral cover and continuing shifts in community structure at deeper reef slope sites (6-7 m). There was no evidence of phase shifts to macroalgal dominance but coral habitats at deeper sites were replaced by unstable substrata such as fine sediments and rubble. The persistence of coral dominance at chronically disturbed shallow sites is likely due to an abundance of coral taxa which are tolerant to environmental stress. In addition, high turbidity may interact antagonistically with other disturbances to reduce the impact of thermal stress and limit macroalgal growth rates.

Bearing the burden of boat harbours: heavy contaminant and fouling loads in a native habitat-forming alga.

Boat harbours are an increasingly common form of artificial habitat. This paper presents a comparative study of contaminants and foulers of a habitat-forming native kelp (Saccharina latissima) in four marinas and four reference locations along the south-west coast of the UK. Fouling of algal laminae was light (<2% cover) in reference locations, while epibiota cover ranged from 25% to 80% of laminae in marinas. Metals associated with antifouling paints were up to six times more concentrated in algal tissues from marinas than from the reference locations. Marinas also carried the greatest cover and diversity of non-indigenous epibiota on the kelp laminae. This indicates not only a potential stress to kelps in these environments, but also the possibility that detached laminae will act as vectors for the dispersal of non-indigenous species. The development of boat harbours creates habitats that are high risk source localities for pollution-tolerant fouling organisms.

Do modified habitats have direct or indirect effects on epifauna?

Replacing natural habitats with artificial structures such as pier-pilings, jetties, and seawalls has important consequences to abundances of biota. It is, however, not often known whether these are direct (the novel habitat alters abundances of some species) or indirect (the novel habitat directly alters some aspect of the behavior or ecology of some species, which, in turn, alter abundances of other species). Marine animals in some modified habitats in Sydney Harbour provide experimental opportunities to test hypotheses to distinguish between direct and indirect processes. Covers of bryozoans and hydroids were greater on kelp growing on pilings than on kelp growing on natural reefs. The epifauna may be affected directly by the pilings or indirectly, i.e., the structure affects characteristics of the kelp which, in turn, influence covers of epifauna. Thus, differences in covers of epifauna on kelp can be due to: (1) factors associated with the primary habitats (pilings vs. reefs), (2) differences between characteristics of the kelp found in each habitat, or (3) an interaction between these factors (habitat and/or type of kelp). Kelp were experimentally transplanted between pilings and reefs, demonstrating that properties of the habitat directly affected covers of epifauna, which were not influenced by the type of kelp that grows on pilings or rocky reefs. Manipulative experiments to unconfound multiple components of habitats influencing disturbances to biota are needed to understand human impacts on natural systems.