Impacts of marine heatwaves in coastal ecosystems depend on local environmental conditions

Starko, Samuel; van der Mheen, Mirjam; Pessarrodona, Albert; Wood, Georgina V.; Filbee‐Dexter, Karen; Neufeld, Christopher J.; Montie, Shinae; Coleman, Melinda A.; Wernberg, Thomas

doi:10.1111/gcb.17469

Global Change Biology

2024

DOI: 10.1111/gcb.17469

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Impacts of marine heatwaves in coastal ecosystems depend on local environmental conditions

Samuel Starko,

Mirjam van der Mheen,

Albert Pessarrodona

et al.

Abstract: Marine heatwaves (MHWs), increasing in duration and intensity because of climate change, are now a major threat to marine life and can have lasting effects on the structure and function of ecosystems. However, the responses of marine taxa and ecosystems to MHWs can be highly variable, making predicting and interpreting biological outcomes a challenge. Here, we review how biological responses to MHWs, from individuals to ecosystems, are mediated by fine‐scale spatial variability in the coastal marine environmen… Show more

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2024

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Cited by 2 publications

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Long‐Term Stability of Marine Forests Facing Moderate Gradual Warming in a Remote Biodiversity Hotspot

Pessarrodona,

Wood,

Grimaldi

et al. 2024

Diversity and Distributions

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AimOcean warming and marine heatwaves are rapidly reconfiguring the composition of seaweed forests—the world's largest coastal vegetated biome. Seaweed forest responses to climate change in remote locations, which constitute the majority of the forest biome, remain however poorly quantified. Here, we examine the temporal stability of the seaweed forests across a global seaweed biodiversity hotspot where several species are predicted to undergo severe range contractions in this century.LocationWestern south coast of Australia.MethodsSeaweed forest canopies were censused at 18 shallow (< 10 m) sheltered reefs between 1997 and 2006 and again between 2021 and 2024 (six sites per location). We also surveyed 24 sites to examine whether temporal changes differed over gradients of wave exposure and depth.ResultsSeaweed forest canopies across all locations showed surprisingly little change in biomass, cover, stand density and species composition over two decades, with strong spatial structuring across depth and exposure gradients persisting over time. The average thermal affinity of forest canopies (i.e., the community temperature index, CTI) did not track warming, suggesting that factors other than temperature (e.g., wave exposure and depth) are more important drivers of forest stand structure and/or that key thermal thresholds have not yet been crossed. Forests in the location with the most pronounced warming exhibited increased thermal bias over time (total bias of 0.8°C–2.2°C), indicating they were dominated by species with cooler affinities than their local temperatures.Main ConclusionsThe greater thermal bias in forests at the warmer edge of southern Australia suggests these will be more susceptible to future warming‐related compositional changes than forests in cooler locations. The relative stability we found contrasts with a current context of rapidly changing seaweed forests nationally and globally, highlighting the need to deepen our ecological understanding of the region so that future changes to its unique biodiversity and ecosystem services can be predicted and mitigated.

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Long‐Term Stability of Marine Forests Facing Moderate Gradual Warming in a Remote Biodiversity Hotspot

Pessarrodona,

Wood,

Grimaldi

et al. 2024

Diversity and Distributions

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Low light exacerbates effects of marine heatwaves on seaweeds

Wernberg,

Straub

2024

Mar. Ecol. Prog. Ser.

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Marine heatwaves (MHWs) are becoming more frequent and intense. At the same time, diverse human activities are causing coastal darkening: increased turbidity and reduced light at the seafloor. Since both temperature and light are critical to the physiological and ecological performance of seaweeds—important habitat-formers and primary producers—these co-occurring stressors could have knock-on effects in coastal ecosystems. We tested the effects of MHWs under different irradiance levels on 3 brown seaweeds: the kelp Ecklonia radiata and 2 common understorey species, Zonaria turneriana and Lobophora variegata. The seaweeds were subjected to 15 d MHWs of different maximum intensities (25° and 28°C) at 2 reduced light levels (~40 and ~10 µmol m-2 s-1). Effects on cover of bleached tissue, biomass, maximum quantum yield and pigment concentrations were assessed. Temperature was the main cause of observed changes in seaweed condition, with strong negative effects of the most intense MHW (28°C) especially for tissue bleaching and maximum quantum yield. Low light had a minor effect at 19°C (background temperature) and in the moderate MHW treatment (25°C). However, at extreme temperatures (28°C), low light enhanced the negative effects on virtually all seaweed condition metrics. For all species, the negative effects of the most severe MHW persisted during the recovery period, during which temperatures were returned to background conditions. The compounding effect of high temperature and reduced light highlights the need to assess the interactive nature of multiple stressors with respect to the emerging threat of MHWs to reef ecosystems.

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Impacts of marine heatwaves in coastal ecosystems depend on local environmental conditions

Cited by 2 publications

References 153 publications

Long‐Term Stability of Marine Forests Facing Moderate Gradual Warming in a Remote Biodiversity Hotspot

Long‐Term Stability of Marine Forests Facing Moderate Gradual Warming in a Remote Biodiversity Hotspot

Low light exacerbates effects of marine heatwaves on seaweeds

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