Regime shifts shorten food chains for mesopredators with potential sublethal effects

Hempson, Tessa N.; Graham, Nicholas A. J.; MacNeil, M. Aaron; Bodin, Nathalie; Wilson, Shaun K.

doi:10.1111/1365-2435.13012

Cited by 19 publications

(18 citation statements)

References 54 publications

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“…4b, c). This is quite likely due to population declines driven by erosion of their prey base following reef structural loss 32,33 , coupled with slow life histories of species which require long recovery times in intact coral habitats 34 .…”

Section: Resultsmentioning

confidence: 99%

Changing role of coral reef marine reserves in a warming climate

et al. 2020

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Coral reef ecosystems are among the first to fundamentally change in structure due to climate change, which leads to questioning of whether decades of knowledge regarding reef management is still applicable. Here we assess ecological responses to no-take marine reserves over two decades, spanning a major climate-driven coral bleaching event. Prebleaching reserve responses were consistent with a large literature, with higher coral cover, more species of fish, and greater fish biomass, particularly of upper trophic levels. However, in the 16 years following coral mortality, reserve effects were absent for the reef benthos, and greatly diminished for fish species richness. Positive fish biomass effects persisted, but the groups of fish benefiting from marine reserves profoundly changed, with low trophic level herbivores dominating the responses. These findings highlight that while marine reserves still have important roles on coral reefs in the face of climate change, the species and functional groups they benefit will be substantially altered.

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Section: Resultsmentioning

confidence: 99%

Changing role of coral reef marine reserves in a warming climate

et al. 2020

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“…Habitat complexity may also affect the hunting efficiency of reef predators, but this is largely unexplored. Several recent studies investigating the effect of reef degradation on predators have highlighted a higher abundance and diversity of reef piscivores on recovering reefs compared to degraded reefs due to the availability of higher‐quality prey (Hempson et al ., 2018a, 2018b). On degraded reefs predators feed lower down the food chain, potentially leading to lower nutrition, survival, fecundity and growth (Hempson et al ., 2017).…”

Section: Predatory Fishesmentioning

confidence: 99%

Interactions between coral restoration and fish assemblages: implications for reef management

Seraphim

Sloman

Alexander

et al. 2020

Journal of Fish Biology

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Corals create complex reef structures that provide both habitat and food for many fish species. Because of numerous natural and anthropogenic threats, many coral reefs are currently being degraded, endangering the fish assemblages they support. Coral reef restoration, an active ecological management tool, may help reverse some of the current trends in reef degradation through the transplantation of stony corals. Although restoration techniques have been extensively reviewed in relation to coral survival, our understanding of the effects of adding live coral cover and complexity on fishes is in its infancy with a lack of scientifically validated research. This study reviews the limited data on reef restoration and fish assemblages, and complements this with the more extensive understanding of complex interactions between natural reefs and fishes and how this might inform restoration efforts. It also discusses which key fish species or functional groups may promote, facilitate or inhibit restoration efforts and, in turn, how restoration efforts can be optimised to enhance coral fish assemblages. By highlighting critical knowledge gaps in relation to fishes and restoration interactions, the study aims to stimulate research into the role of reef fishes in restoration projects. A greater understanding of the functional roles of reef fishes would also help inform whether restoration projects can return fish assemblages to their natural compositions or whether alternative species compositions develop, and over what timeframe. Although alleviation of local and global reef stressors remains a priority, reef restoration is an important tool; an increased understanding of the interactions between replanted corals and the fishes they support is critical for ensuring its success for people and nature.

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“…Shifts in the composition of the reef fish community may represent a change in the prey base available to piscivorous mesopredators, requiring them to adapt their diets and alter their trophic niche (Hempson et al 2017c). Switching to a less preferred diet can be associated with potential sublethal effects, such as decreased energy reserves, condition, growth rates, survivorship, and fecundity (Kokita and Nakazono 2001, Jones and McCormick 2002, Pratchett et al 2004, Berumen et al 2005, Hempson et al 2017a.…”

Section: Table 2 Multinomial Regression Model Coefficients and 95%mentioning

confidence: 99%

Ecosystem regime shifts disrupt trophic structure

Hempson

Graham

MacNeil

et al. 2017

Ecological Applications

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Regime shifts between alternative stable ecosystem states are becoming commonplace due to the combined effects of local stressors and global climate change. Alternative states are characterised as substantially different in form and function to pre-disturbance states, disrupting the delivery of ecosystem services and functions. On coral reefs, regime shifts are typically characterised by a change Accepted ArticleThis article is protected by copyright. All rights reserved.in the benthic composition from coral-to macroalgal-dominance. Such fundamental shifts in the benthos are anticipated to impact associated fish communities that are reliant on the reef for food andshelter, yet there is limited understanding of how regime shifts propagate through the fish community over time, relative to initial or recovery conditions. This study addresses this knowledge gap using long-term data of coral reef regime shifts and recovery on Seychelles reefs following the 1998 mass bleaching event. It shows how trophic structure of the reef fish community becomes increasingly dissimilar between alternative reef ecosystem states (regime-shifted vs recovering) with time since disturbance. Regime-shifted reefs developed a concave trophic structure, with increased biomass in base trophic levels as herbivorous species benefitted from increased algal resources. Mid trophic level species, including specialists such as corallivores, declined with loss of coral habitat, while biomass was retained in upper trophic levels by large-bodied, generalist invertivores. Recovering reefs also experienced an initial decline in mid trophic level biomass, but moved towards a bottom-heavy pyramid shape, with a wide range of feeding groups (e.g. planktivores, corallivores, omnivores) represented at mid trophic levels. Given the importance of coral reef fishes in maintaining the ecological function of coral reef ecosystems and their associated fisheries, understanding the effects of regime shifts on these communities is essential to inform decisions that enhance ecological resilience and economic sustainability.

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Regime shifts shorten food chains for mesopredators with potential sublethal effects

Cited by 19 publications

References 54 publications

Changing role of coral reef marine reserves in a warming climate

Changing role of coral reef marine reserves in a warming climate

Interactions between coral restoration and fish assemblages: implications for reef management

Ecosystem regime shifts disrupt trophic structure

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