Severe coral loss shifts energetic dynamics on a coral reef

Morais, Renato A.; Depczynski, Martial; Fulton, Christopher J.; Marnane, Michael J.; Narvaez, Pauline; Huertas, Víctor; Brandl, Simon J.; Bellwood, David R.

doi:10.1111/1365-2435.13568

Cited by 65 publications

(70 citation statements)

References 75 publications

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“…However, the lack of difference in benthic community structure observed between regions suggests that benthic structure was at least not a primary driver of the observed patterns. Although the loss of some specialist cryptobenthic species has been reported after substantial live coral cover loss 99,105 , previous studies have not detected substantial short-term changes in either small reef fish richness and abundance or in overarching ecosystem productivity 27,29,31,56,99 .…”

Section: Discussionmentioning

confidence: 97%

“…In the wake of losing coral habitat, communities of the most prominent reef consumers, teleost fishes, also decline or shift in composition 24 – 27 , which directly affects the provision of resources to people dependent on reef fisheries 28 . Although recent evidence suggests that some fish species will be able to cope with (or even benefit from) live coral loss, at least in the short term 28 – 31 , tropical reef fishes are typically adapted to a relatively narrow suite of environmental conditions. Thus, reef fishes may also be vulnerable to the direct effects of climate change on, for instance, sea surface temperatures 13 , 32 , 33 .…”

Section: Introductionmentioning

confidence: 99%

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Extreme environmental conditions reduce coral reef fish biodiversity and productivity

et al. 2020

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Tropical ectotherms are hypothesized to be vulnerable to environmental changes, but cascading effects of organismal tolerances on the assembly and functioning of reef fish communities are largely unknown. Here, we examine differences in organismal traits, assemblage structure, and productivity of cryptobenthic reef fishes between the world's hottest, most extreme coral reefs in the southern Arabian Gulf and the nearby, but more environmentally benign, Gulf of Oman. We show that assemblages in the Arabian Gulf are half as diverse and less than 25% as abundant as in the Gulf of Oman, despite comparable benthic composition and live coral cover. This pattern appears to be driven by energetic deficiencies caused by responses to environmental extremes and distinct prey resource availability rather than absolute thermal tolerances. As a consequence, production, transfer, and replenishment of biomass through cryptobenthic fish assemblages is greatly reduced on Earth's hottest coral reefs. Extreme environmental conditions, as predicted for the end of the 21st century, could thus disrupt the community structure and productivity of a critical functional group, independent of live coral loss.

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Section: Discussionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Extreme environmental conditions reduce coral reef fish biodiversity and productivity

et al. 2020

Self Cite

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“…Nevertheless, a study in the Seychelles suggested that catch rates of some groupers in Aldabra Atoll declined across a period of climate stress (Pistorius & Taylor, 2009). The biomass and productivity of herbivorous fish has been known to increase with declines in corals, however (McClanahan, Maina, & Pet‐Soede, 2002; Morais et al, 2020). In general, the loss of coral appears to have the largest impact on small‐bodied species that do not greatly influence the metric of fishable biomass (Graham et al, 2008; Graham et al, 2011).…”

Section: Discussionmentioning

confidence: 99%

“…In some cases, human impacts override the environmental drivers by influencing reef fish habitat (Williams et al, 2015). For instance, fishing is associated with changes in the benthic cover that could potentially influence both refuge from climate disturbances and fishery production (Robinson et al, 2017; Morais et al, 2020). Thus, there are likely to be various feedback mechanisms between human impacts on habitat and fish populations, making it challenging to understand cause and effect and outcomes on ecosystem functions, such as fishery production (Williams & Graham, 2019).…”

Section: Discussionmentioning

confidence: 99%

Variability in coral reef fish baseline and benchmark biomass in the central and western Indian Ocean provinces

McClanahan

Friedlander

Graham

et al. 2020

Aquatic Conservation

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Reef fish biomass is increasingly recognized as a key indicator of fishery and biodiversity status linked to ecosystem integrity on coral reefs, and yet the evaluation of appropriate baselines for biomass, and what drives variation in potential baselines, is sparse. Variability in reef fishable biomass was assessed to test for the existence of baselines or benchmarks (B&Bs), based on field studies of 223 reef sites in remote uninhabited reefs, in high‐compliance closures of >5 km2, and among the increasing number of small and recent closures. The purpose of the study was to examine the effects of human habitation, travel time and distance to cities, habitat, depth, benthic cover, and environmental variables on fish B&Bs. There were large differences in the three categories of ‘no fishing’, with human habitation being the single best predictor of biomass. In remote areas without people (>9 hours of travel time), fish biomass had a mean of 2,450 kg ha–1 (95% confidence interval, 95% CI, 2,130–2,770 kg ha–1; median = 1,885 kg ha–1). In these remote areas, biomass was weakly associated with human travel time to the site and, to a lesser extent, wave energy. In high‐compliance closures, fish biomass peaked at 20 years and 5–10 km2, and levelled at 910 kg ha–1 (95% CI 823–989 kg ha–1) for both closure age and size. There was little evidence that human travel time and environmental factors influenced biomass greatly in these established closures. In small and recent closures (<15 years), habitat, depth and closure age were the best predictors of fish biomass. Based on the weakness of environmental factors, country or site‐specific B&Bs are not required in these two provinces. However, human habitation in the seascape as well as the size and age of closures set limits to the maximum achievable biomass. The importance of environmental factors increases as the no‐fishing areas and closure times decline. Reef wilderness is not widespread in these provinces, but provides key services and therefore needs to be included in conservation and fisheries policy and management goals.

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“…Current models based on ‘fixed’ energy metabolism of individuals imply that survival at higher temperatures requires an increase in energy intake (food) to meet thermally elevated energy demands ( Brown et al, 2004 ; Van der Meer, 2006 ; Sinclair et al, 2016 ; Huey and Kingsolver, 2019 ). Such elevated energy demands occur at the same time that performance becomes suboptimal and food availability is likely limited by reduced production and generally a reduced energy flow through the ecosystem (see Morais et al, 2020 ). However, these energetic constraints can be negated or minimized in animals with flexible or temperature independent metabolic rates that allow the lowering of resting energy demands, as occurs in many gastropods, including T. bacillum .…”

Section: Discussionmentioning

confidence: 99%

Metabolic Regulation, Oxygen Limitation and Heat Tolerance in a Subtidal Marine Gastropod Reveal the Complexity of Predicting Climate Change Vulnerability

Marshall

McQuaid

2020

Front. Physiol.

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Predictions for climate vulnerability of ectotherms have focused on performance-enhancing physiology, even though an organism’s energetic state can also be balanced by lowering resting maintenance costs. Adaptive metabolic depression (hypometabolism) enables animals to endure food scarcity, and physically extreme and variable environmental conditions. Hypometabolism is common in terrestrial and intertidal marine gastropod species, though this physiology and tolerance of environmental change are poorly understood in subtidal benthic gastropods. We investigated oxygen limitation tolerance, hypometabolism and thermal performance in the subtidal, tropical snail Turritella bacillum . Survival, cardiac activity and oxygen debt repayment were determined when oxygen uptake was limited by gill function impairment (air exposure) or exposure to hypoxic seawater. Thermal performance and tolerance were assessed from survival and cardiac performance when heated. The ability of snails to regulate metabolism during oxygen limitation was demonstrated by their tolerance of air exposure (>36 h) and hypoxia (>16 h), rhythmicity and reversibility of bradycardia, and inconsistent anaerobic compensation. Under acute heating, mean heart rate was temperature-insensitive in water and temperature-dependent in air. Converging or peaking of individual heart rates during heating suggest maximization of thermal performance at 38–39°C, whereas survival and heartbeat flatlining suggest an upper thermal limit exceeding 42°C. Snails survived 16 h in seawater at 38°C. Their metabolic regulation complies with the oxygen-limiting, sediment-burrowing lifestyle of the species. Although a tropical organism, the species’ thermal tolerance so far exceeds present habitat temperatures as to question its susceptibility to centennial climate warming. Our findings reveal the importance of knowing the metabolic regulatory capabilities and conserved physiological attributes of species used in climate vulnerability tests. Studies of ectotherm climate vulnerability that identify generalized trends based on physiologically similar animals may be misleading by missing information on physiological diversity.

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Severe coral loss shifts energetic dynamics on a coral reef

Cited by 65 publications

References 75 publications

Extreme environmental conditions reduce coral reef fish biodiversity and productivity

Extreme environmental conditions reduce coral reef fish biodiversity and productivity

Variability in coral reef fish baseline and benchmark biomass in the central and western Indian Ocean provinces

Metabolic Regulation, Oxygen Limitation and Heat Tolerance in a Subtidal Marine Gastropod Reveal the Complexity of Predicting Climate Change Vulnerability

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