Zooplankton responses to simulated marine heatwave in the Mediterranean Sea using in situ mesocosms.
Soultana ZervoudakiMaria ProtopapaAndriana KoutsandreaAnna JanssonElla von WeissenbergGeorgios FyttisAthanasia SakavaraKostas KavakakisCharitomeni ChariatiKatja AnttilaPauline BourdinBehzad MostajirFrancesca VidussiJonna Engström-ÖstPublished in: PloS one (2024)
Globally, marine heatwave frequency, intensity, and duration are on the rise, posing a significant threat to plankton communities, the foundational elements of the marine food web. This study investigates the ecological and physiological responses of a temperate plankton community in the Thau lagoon, north-western Mediterranean, to a simulated +3°C ten-day heatwave followed by a ten-day post-heatwave period in in-situ mesocosms. Our analyses encompassed zooplankton grazing, production, community composition in water and sediment traps, as well as oxidative stress and anti-oxidant biomarkers. The results revealed increased abundances of harpacticoid copepods and polychaete larvae during the simulated heatwave and post-heatwave event. Sediment trap data indicated elevated mortality, particularly dominated by polychaete larvae during the post-heatwave period. Oxidative stress biomarker (lipid peroxidation LPX) levels in the plankton community correlated with temperature, signaling cellular damage during the heatwave. LPX increased and proteins decreased with increasing salinity during the experiment. Offspring production peaked during the post-heatwave phase. Notably, the calanoid copepod Acartia clausi exhibited a preference for ciliates as its primary prey, constituting 20% of the overall available prey. Our findings suggest a potential shift in coastal zooplankton communities during future marine heatwaves, transitioning from calanoid mesozooplankton dominance to a system featuring meroplankton and/or harpacticoid copepods. Although species preying on microzooplankton may gain advantages in such conditions, the study underscores the damaging impact of heatwaves on organismal lipids, with potential consequences for reproduction, growth, and survival within marine ecosystems.
Keyphrases
- oxidative stress
- healthcare
- mental health
- human health
- climate change
- heavy metals
- dna damage
- high intensity
- risk factors
- high fat diet
- type diabetes
- cardiovascular disease
- coronary artery disease
- risk assessment
- skeletal muscle
- south africa
- ischemia reperfusion injury
- insulin resistance
- machine learning
- genetic diversity
- free survival
- tertiary care