Combined effect of marine heatwaves and light intensity on the cellular stress response and photophysiology of the leather coral Sarcophyton cf. glaucum

Combined effect of marine heatwaves and light intensity on the cellular stress response and photophysiology of the leather coral Sarcophyton cf. glaucum

Marine heatwaves (MHW) are threatening tropical coral reef ecosystems, leading to mass bleaching events worldwide. The combination of heat stress with high irradiance is known to shape the health and redox status of corals, but research is biased toward scleractinian corals, while much less is known...

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Bibliographic Details
Published in:The Science of the total environment Vol. 861; p. 160460
Main Authors: Travesso, Margarida, Missionário, Madalena, Cruz, Sónia, Calado, Ricardo, Madeira, Diana
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 25-02-2023
Subjects:
Animals
Anthozoa - physiology
Antioxidants
Biomarkers
Chlorophyll A
Coral holobiont
Coral Reefs
Ecosystem
Light
Oxidative stress
Photoacclimation
Photosynthetic activity
Symbiosis - physiology
Temperature
Biomarkers
Oxidative stress
Temperature
Photosynthetic activity
Photoacclimation
Coral holobiont
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Summary:Marine heatwaves (MHW) are threatening tropical coral reef ecosystems, leading to mass bleaching events worldwide. The combination of heat stress with high irradiance is known to shape the health and redox status of corals, but research is biased toward scleractinian corals, while much less is known on tropical symbiotic soft corals. Here, we evaluated the cellular stress response and the photophysiological performance of the soft coral Sarcophyton cf. glaucum, popularly termed as leather coral, under different global change scenarios. Corals were exposed to different light intensities (high light, low light, ∼662 and 253 μmol photons m−2 s−1) for 30 days (time-point 1) and a subsequent MHW simulation was carried out for 10 days (control 26 vs 32 °C) (time-point 2). Subsequently, corals were returned to control temperature and allowed to recover for 30 days (time-point 3). Photophysiological performance (maximum quantum yield of photosystem II (Fv/Fm), a measure of photosynthetic activity; dark-level fluorescence (F0), as a proxy of chlorophyll a content (Chl a); and zooxanthellae density) and stress biomarkers (total protein, antioxidants, lipid peroxidation, ubiquitin, and heat shock protein 70) were assessed in corals at these three time-points. Corals were especially sensitive to the combination of heat and high light stress, experiencing a decrease in their photosynthetic efficiency under these conditions. Heat stress resulted in bleaching via zooxanthellae loss while high light stress led to pigment (Chl a) loss. This species' antioxidant defenses, and protein degradation were particularly enhanced under heat stress. A recovery was clear for molecular parameters after 30 days of recovery, whereby photophysiological performance required more time to return to basal levels. We conclude that soft corals distributed along intertidal areas, where the light intensity is high, could be especially vulnerable to marine heatwave events, highlighting the need to direct conservation efforts toward these organisms. [Display omitted] •The impacts of marine heatwaves under different light intensities were tested on Sarcophyton cf. glaucum.•Photosynthetic efficiency was particularly reduced under heat and high light stress.•Temperature was the factor that led to a stronger increase in antioxidant defenses.•After recovery, molecular markers returned to basal levels, unlike photophysiological ones.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2022.160460