Numerous studies have emphasised the importance of apex predators in determining community dynamics and broader functioning in marine ecosystems. However, less understood is the ecology of plastic foraging behaviours employed by predators, with drivers of foraging plasticity being a particular knowledge gap in marine sediments. In June/July 2015, we assessed the role of traits and abundance of prey assemblages in influencing decisions made by greater flamingos Phoenicopterus roseus to employ different foraging behaviours in intertidal sandflat ecosystems in Langebaan Lagoon, on the west coast of South Africa (33°11′27″S, 18°07′37″E and 33°03′54″S, 17°58′07″E). Greater flamingos feed by either (1) creating pits, which involves flamingos stirring up deep sediments with their feet or (2) creating channels, in which their inverted bills are swept from side to side on the sediment surface. RandomForest modelling techniques indicated that both pit- and channel-foraging strategies were linked to low macrofaunal biomass in sediment patches, indicating that smaller prey items may be preferred targets for consumption. Channel foraging was linked mainly to the abundance of surface-associated fauna, suggesting that this feeding technique was predominantly a surficial foraging strategy. The probability of pit foraging increased with increasing concentrations of benthic microalgae, suggesting that high microalgal biomass may be linked to pit foraging. Overall, this study adds to knowledge on the role of flamingos as predators in marine sediments, by highlighting biotic predictors of foraging plasticity. The study demonstrates the relevance of understanding potential drivers of foraging plasticity in developing a predictive understanding of predator impacts in heterogeneous ecosystems.
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Gihwala, K.N., Pillay, D. & Varughese, M. Predictors of foraging plasticity by greater flamingo (Phoenicopterus roseus) in intertidal soft sediments. Mar Biol 166, 50 (2019). https://doi.org/10.1007/s00227-019-3497-1