A Systematic Review of How Multiple Stressors From an Extreme Event Drove Ecosystem-Wide Loss of Resilience in an Iconic Seagrass Community

Kendrick, Gary A.; Nowicki, Rob; Olsen, Ylva S.; Strydom, Simone; Fraser, Michelle; Sinclair, Elizabeth A.; Statton, John; Hovey, Renae K.; Thomson, Jordan A.; Burkholder, Derek A.; McMahon, Kathryn; Kilminster, Kieryn; Hetzel, Yasha; Fourqurean, James W.; Heithaus, Michael R.; Orth, Robert J.

doi:10.3389/fmars.2019.00455

Cited by 99 publications

(89 citation statements)

References 88 publications

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“…This may account for its greater resilience compared to A. antarctica against extremely high temperatures as increased respiration at higher temperatures will reduce production of photosynthate required for metabolism, which may be mediated by carbohydrate reserve mobilization. However, P. australis meadows were not entirely unaffected as complete seed abortion was reported in 2011–2012 in Shark Bay (Sinclair et al, 2016) and seed production did not recover until 2016–2017 (Kendrick et al, 2019). This suggests a reliance on adult resistance over a ‘reproduce and recover’ strategy in response to MHWs for P. australis .…”

Section: Discussionmentioning

confidence: 99%

Too hot to handle: Unprecedented seagrass death driven by marine heatwave in a World Heritage Area

Strydom

Murray²,

Wilson

et al. 2020

Global Change Biology

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160

133

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The increased occurrence of extreme climate events, such as marine heatwaves (MHWs), has resulted in substantial ecological impacts worldwide. To date, metrics of thermal stress within marine systems have focussed on coral communities, and less is known about measuring stress relevant to other primary producers, such as seagrasses. An extreme MHW occurred across the Western Australian coastline in the austral summer of 2010–2011, exposing marine communities to summer seawater temperatures 2–5°C warmer than average. Using a combination of satellite imagery and in situ assessments, we provide detailed maps of seagrass coverage across the entire Shark Bay World Heritage Area (ca. 13,000 km2) before (2002 and 2010) and after the MHW (2014 and 2016). Our temporal analysis of these maps documents the single largest loss in dense seagrass extent globally (1,310 km2) following an acute disturbance. Total change in seagrass extent was spatially heterogeneous, with the most extensive declines occurring in the Western Gulf, Wooramel Bank and Faure Sill. Spatial variation in seagrass loss was best explained by a model that included an interaction between two heat stress metrics, the most substantial loss occurring when degree heating weeks (DHWm) was ≥10 and the number of days exposed to extreme sea surface temperature during the MHW (DaysOver) was ≥94. Ground truthing at 622 points indicated that change in seagrass cover was predominantly due to loss of Amphibolis antarctica rather than Posidonia australis, the other prominent seagrass at Shark Bay. As seawater temperatures continue to rise and the incidence of MHWs increase globally, this work will provide a basis for identifying areas of meadow degradation, or stability and recovery, and potential areas of resilience.

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Section: Discussionmentioning

confidence: 99%

Too hot to handle: Unprecedented seagrass death driven by marine heatwave in a World Heritage Area

Strydom

Murray²,

Wilson

et al. 2020

Global Change Biology

Self Cite

160

133

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“…The possibility of exploiting the use of such descriptors of heating events for other subtidal efforts should be investigated, in addition to MHWs metrics for the surface 15,48 . Currently, the response of other subtidal community/species to the thermal environment is being examined based on satellite-derived SST, if the systems investigated are very shallow 62 . Alternatively, studies for deeper systems have relied on in situ loggers measures where, for very specific locations, temperature data have started to be collected long before the study was really designed and where researchers could formulate the hypotheses only a posteriori [60][61][62][63][64][65] .…”

Section: Discussionmentioning

confidence: 99%

“…Currently, the response of other subtidal community/species to the thermal environment is being examined based on satellite-derived SST, if the systems investigated are very shallow 62 . Alternatively, studies for deeper systems have relied on in situ loggers measures where, for very specific locations, temperature data have started to be collected long before the study was really designed and where researchers could formulate the hypotheses only a posteriori [60][61][62][63][64][65] . However, estimating subtidal temperature anomalies based on the subtidal climatology by long-time series of field temperature data has to be supported, although it will concern a limited number of localities: the recent promotion of research projects or temperature monitoring programs (i.e.…”

Section: Discussionmentioning

confidence: 99%

The constraint of ignoring the subtidal water climatology in evaluating the changes of coralligenous reefs due to heating events

Ceccherelli

Pinna

Pansini

et al. 2020

Sci Rep

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Predicting community-level responses to seawater warming is a pressing goal of global change ecologists. How far such predictions can be derived from a fine gradient of thermal environments needs to be explored, even if ignoring water climatology does not allow estimating subtidal marine heat waves. In this study insights about the influence of the thermal environment on the coralligenous community structure were gained by considering sites (Sardinia, Italy) at different temperature conditions. Heating events were measured (by loggers at 18 m, 23 m, 28 m, 33 m and 38 m deep) and proxies for their duration (the maximum duration of events warmer than the 90th percentile temperature), intensity (the median temperature) and variability (the number of daily ΔT larger than the mean daily ΔT, and the number of heating events larger in ΔT than the 90th percentile ΔT) were selected by GAM models. Reliable predictions of decrease in coralligenous richness of taxa/morphological groups, with relevant increment in turfs and encrusting coralline algae abundance at the expenses of bryozoans were made. Associations to the different types of heating descriptor have highlighted the aspect (intensity, duration or variability) of the heating events and the threshold for each of them responsible for the trajectories of change.

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“…Oceanic MHWs are extreme climatic disturbances that are predicted to increase in frequency and intensity owing to climate change [8]. MHWs are defined as extended periods of anomalously high sea surface temperatures [24] which have already resulted in devastating effects on coastal marine communities characterized by widespread mortalities of invertebrates [3,25], seagrasses [26], coral, (associated with coral bleaching) [27], range contractions of habitat-forming species [28], and changes to community structure and ecosystem function [3,23]. MHWs have been documented across the globe: in the Mediterranean [29]; Australia [30]; northwestern Atlantic [31] and in the northeastern Pacific [32].…”

Section: Introductionmentioning

confidence: 99%

Depth moderates loss of marine foundation species after an extreme marine heatwave: could deep temperate reefs act as a refuge?

2020

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Marine heatwaves (MHWs) have been documented around the world, causing widespread mortality of numerous benthic species on shallow reefs (less than 15 m depth). Deeper habitats are hypothesized to be a potential refuge from environmental extremes, though we have little understanding of the response of deeper benthic communities to MHWs. Here, we show how increasing depth moderates the response of seaweed- and coral-dominated benthic communities to an extreme MHW across a subtropical–temperate biogeographical transition zone. Benthic community composition and key habitat-building species were characterized across three depths (15, 25 and 40 m) before and several times after the 2011 Western Australian MHW to assess resistance during and recovery after the heatwave. We found high natural variability in benthic community composition along the biogeographic transition zone and across depths with a clear shift in the composition after the MHW in shallow (15 m) sites but a lot less in deeper communities (40 m). Most importantly, key habitat-building seaweeds such as Ecklonia radiata and Syctothalia dorycarpa which had catastrophic losses on shallow reefs, remained and were less affected in deeper communities. Evidently, deep reefs have the potential to act as a refuge during MHWs for the foundation species of shallow reefs in this region.

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A Systematic Review of How Multiple Stressors From an Extreme Event Drove Ecosystem-Wide Loss of Resilience in an Iconic Seagrass Community

Cited by 99 publications

References 88 publications

Too hot to handle: Unprecedented seagrass death driven by marine heatwave in a World Heritage Area

Too hot to handle: Unprecedented seagrass death driven by marine heatwave in a World Heritage Area

The constraint of ignoring the subtidal water climatology in evaluating the changes of coralligenous reefs due to heating events

Depth moderates loss of marine foundation species after an extreme marine heatwave: could deep temperate reefs act as a refuge?

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