Abstract
The reef flat is one of the largest and most distinctive habitats on coral reefs, yet its role in reef trophodynamics is poorly understood. Evolutionary evidence suggests that reef flat colonization by grazing fishes was a major innovation that permitted the exploitation of new space and trophic resources. However, the reef flat is hydrodynamically challenging, subject to high predation risks and covered with sediments that inhibit feeding by grazers. To explore these opposing influences, we examine the Great Barrier Reef (GBR) as a model system. We focus on grazing herbivores that directly access algal primary productivity in the epilithic algal matrix (EAM). By assessing abundance, biomass, and potential fish productivity, we explore the potential of the reef flat to support key ecosystem processes and its ability to maintain fisheries yields. On the GBR, the reef flat is, by far, the most important habitat for turf‐grazing fishes, supporting an estimated 79% of individuals and 58% of the total biomass of grazing surgeonfishes, parrotfishes, and rabbitfishes. Approximately 59% of all (reef‐wide) turf algal productivity is removed by reef flat grazers. The flat also supports approximately 75% of all grazer biomass growth. Our results highlight the evolutionary and ecological benefits of occupying shallow‐water habitats (permitting a ninefold population increase). The acquisition of key locomotor and feeding traits has enabled fishes to access the trophic benefits of the reef flat, outweighing the costs imposed by water movement, predation, and sediments. Benthic assemblages on reefs in the future may increasingly resemble those seen on reef flats today, with low coral cover, limited topographic complexity, and extensive EAM. Reef flat grazing fishes may therefore play an increasingly important role in key ecosystem processes and in sustaining future fisheries yields.
Highlights
By excluding species that feed on other benthic resources, we focus on the direct link between algal (EAM) primary productivity and fish biomass
The generalized linear mixed-effects models (GLMMs) indicated that the reef flat has significantly higher (1) consumption of algal productivity by grazing fishes and (2) biomass growth of grazers, compared to all other habitats (GLMM; p < .001 in all cases: Table S4)
The wave-swept reef flat and/or crest supports the highest m2 densities of grazing herbivorous fishes. These findings are in broad agreement with previous studies that reported relatively high abundances of nominally herbivorous fishes in the shallowest areas of the reef, usually the crest, on both Great Barrier Reef (GBR) (Russ, 1984; Wismer et al, 2009) and Caribbean reefs (Hay, 1981; Steneck, 1983, 1988)
Summary
Most Indo-Pacific coral reefs have four distinct reef zones: the reef slope, crest, flat, and back. The crest has the highest diversity of fishes (Russ, 1984; Wismer et al, 2009), extensive territoriality (with fishes protecting preferred feeding locations) (Choat & Bellwood, 1985), the highest rates of primary productivity (Klumpp & McKinnon, 1989; Russ, 2003; Steneck, 1997), and the highest detrital quality (Crossman, Choat, Clements, Hardy, & McConochie, 2001; Purcell & Bellwood, 2001) In contrast to these beneficial characteristics of the reef crest, the conditions on the reef flat appear to limit the locomotion, feeding, and survival of fishes, with evidence of intolerably high- sediment loads, strong water currents, and high predation risks. By focusing on grazing reef fishes, we examine the reef flat’s role in reef trophodynamics within the context of the previously posited challenging environmental characteristics
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