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1. Hypoxia threatens coral and sea anemone early life stages

   https://doi.org/10.1002/lno.12798  

   Glass, Benjamin H; Barott, Katie L (March 2025, Limnology and Oceanography)

   Seawater hypoxia is increasing globally and can drive declines in organismal performance across a wide range of marine taxa. However, the effects of hypoxia on early life stages (e.g., larvae and juveniles) are largely unknown, and it is unclear how evolutionary and life histories may influence these outcomes. Here, we addressed this question by comparing hypoxia responses across early life stages of three cnidarian species representing a range of life histories: the reef‐building coralGalaxea fascicularis, a broadcast spawner with horizontal transmission of endosymbiotic algae (family Symbiodiniaceae); the reef‐building coralPorites astreoides, a brooder with vertical endosymbiont transmission; and the estuarine sea anemoneNematostella vectensis, a non‐symbiotic broadcast spawner. Transient exposure of larvae to hypoxia (dissolved oxygen < 2 mg L⁻¹for 6 h) led to decreased larval swimming and growth for all three species, which resulted in impaired settlement for the corals. Coral‐specific responses also included larval swelling, depressed respiration rates, and decreases in symbiont densities and function. These results indicate both immediate and latent negative effects of hypoxia on cnidarian physiology and coral–algal mutualisms specifically. In addition,G. fascicularisandP. astreoideswere sensitized to heat stress following hypoxia exposure, suggesting that the combinatorial nature of climate stressors will lead to declining performance for corals. However, sensitization to heat stress was not observed inN. vectensisexposed to hypoxia, suggesting that this species may be more resilient to combined stressors. Overall, these results emphasize the importance of reducing anthropogenic carbon emissions to limit further ocean deoxygenation and warming. 

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2. Sublethal changes to coral metabolism in response to deoxygenation

   https://doi.org/10.1242/jeb.249638  

   Mallon, J E; Altieri, A H; Cyronak, T; Melendez-Declet, C V; Paul, V J; Johnson, M D (February 2025, Journal of Experimental Biology)

   ABSTRACT Coastal deoxygenation poses a critical threat to tropical coral reefs. Dissolved oxygen (DO) depletion can cause hypoxia-induced stress and mortality in scleractinian corals. Coral hypoxic responses are species-specific and likely modulated by the duration and severity of low-DO conditions, although the physiological mechanisms driving hypoxia tolerance are not fully understood. In this study, the Caribbean corals Acropora cervicornis, Porites astreoides and Siderastrea siderea were exposed to either severe (1.5 mg l−1 DO) or moderate (3.5 mg l−1 DO) deoxygenation or a control treatment (6 mg l−1 DO). All corals survived 2 weeks of deoxygenation but exhibited sublethal changes to coral metabolism after 1- and 2-week exposures, compared with controls. Maximum quantum yield (Fv/Fm) was suppressed after 1 week in both deoxygenation treatments in A. cervicornis, and after 2 weeks in S. siderea and P. astreoides exposed to severe or moderate treatments, respectively. Respiration rates were lower than controls in A. cervicornis and S. siderea after 1 and 2 weeks of severe deoxygenation. The reduced respiration of P. astreoides after 1 week of moderate deoxygenation returned to control levels in week 2. Overall coral metabolic budgets, assessed by ratios of gross photosynthesis to respiration (Pg:R), were more autotrophic, or photosynthesis-dominant, after 1 week of severe deoxygenation in S. siderea and P. astreoides, whereas Pg:R was not significantly different in A. cervicornis between treatments. These results reveal that some corals shift their metabolism to tolerate low-oxygen conditions and avoid bleaching or mortality, indicating that metabolic plasticity is an important aspect of coral resistance to deoxygenation. 

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3. Hypoxia Disrupts Sex‐Specific Physiology and Gene Expression Leading to Decreased Fitness in the Estuarine Sea Anemone Nematostella vectensis

   https://doi.org/10.1111/mec.17755  

   Glass, Benjamin H; Ye, Angela C; Hemphill, Cassidy N; Jones, Katelyn G; Dworetzky, Anna G; Barott, Katie L (May 2025, Molecular Ecology)

   Coastal seawater hypoxia is increasing in temperate estuaries under global climate change, yet it is unknown how low oxygen conditions affect most estuarine species. We found that hypoxia has increased since the 1990s in an estuary hosting the sea anemoneNematostella vectensis(Jacques Cousteau National Estuarine Research Reserve, New Jersey, USA). AdultN. vectensisbred from anemones collected in this estuary exposed to three consecutive nights of hypoxia (dissolved oxygen = 0.5–1.5 mg L⁻¹for ~12 h night⁻¹) during gametogenesis displayed decreased aerobic respiration rates and biomass, indicating metabolic disruption. Physiological declines were correlated with changes in the expression of genes related to oxygen‐dependent metabolic processes, many of which are targets of hypoxia‐inducible factor 1α (HIF1α), demonstrating the activity of this transcription factor for the first time in this early‐diverging metazoan. The upregulation of genes involved in the unfolded protein response and endoplasmic reticulum and Golgi apparatus homeostasis suggested that misfolded proteins contributed to disrupted physiology. Notably, these responses were more pronounced in females, demonstrating sex‐specific sensitivity that was also observed in reproductive outcomes, with declines in female but not male fecundity following hypoxia exposure. However, sperm from exposed males had higher mitochondrial membrane potential, indicating altered spermatogenesis. Further, crosses performed with gametes from hypoxia‐exposed adults yielded strikingly low developmental success (~2%), yet larvae that did develop displayed similar respiration rates and accelerated settlement compared to controls. Overall, hypoxia depressed fitness inN. vectensisby over 95%, suggesting that even stress‐tolerant estuarine species may be threatened by coastal deoxygenation. 

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4. Metabolomic Responses of Green Alga Chlamydomonas reinhardtii Exposed to Sublethal Concentrations of Inorganic and Methylmercury.

   https://doi.org/10.1021/ acs.est.0c08416  

   Slaveykova, Vera I.; Majumdar, Sanghamitra; Regier, Nicole; Li, Weiwei; Keller, Arturo A. (February 2021, Environmental science and technology)

   Metabolomics characterizes low-molecular-weight molecules involved in different biochemical reactions and provides an integrated assessment of the physiological state of an organism. By using liquid chromatography–mass spectrometry targeted metabolomics, we examined the response of green alga Chlamydomonas reinhardtii to sublethal concentrations of inorganic mercury (IHg) and monomethylmercury (MeHg). We quantified the changes in the levels of 93 metabolites preselected based on the disturbed metabolic pathways obtained in a previous transcriptomics study. Metabolites are downstream products of the gene transcription; hence, metabolite quantification provided information about the biochemical status of the algal cells exposed to Hg compounds. The results showed that the alga adjusts its metabolism during 2 h exposure to 5 × 10–9 and 5 × 10–8 mol L–1 IHg and MeHg by increasing the level of various metabolites involved in amino acid and nucleotide metabolism, photorespiration, and tricarboxylic acid (TCA) cycle, as well as the metabolism of fatty acids, carbohydrates, and antioxidants. Most of the metabolic perturbations in the alga were common for IHg and MeHg treatments. However, the exposure to IHg resulted in more pronounced perturbations in the fatty acid and TCA metabolism as compared with the exposure to MeHg. The observed metabolic perturbations were generally consistent with our previously published transcriptomics results for C. reinhardtii exposed to the comparable level of IHg and MeHg. The results highlight the potential of metabolomics for toxicity evaluation, especially to detect effects at an early stage of exposure prior to their physiological appearance. 

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5. Heat stress increases immune cell function in Hexacorallia

   https://doi.org/10.3389/fimmu.2022.1016097  

   Eliachar, Shir; Snyder, Grace Ann; Barkan, Shany Klara; Talice, Shani; Otolenghi, Aner; Jaimes-Becerra, Adrian; Sharoni, Ton; Sultan, Eliya; Hadad, Uzi; Levy, Oren; et al (December 2022, Frontiers in Immunology)

   Climate change induced heat stress has increased coral bleaching events worldwide. Differentially regulated immune genes are one of the primary responses to heat stress suggesting that immune activation is critical. However, the cellular immune mechanisms of coral bleaching is currently unknown, and it is still not known if the immune response documented during heat stress is a consequence of bleaching or is directly caused by the heat stress itself. To address this question, we have used two model system sea anemones (Order: Actiniaria): Exaiptasia diaphana and Nematostella vectensis . E. diaphana is an established sea anemone model for algal symbiont interaction, while N. vectensis is an established sea anemone model that lacks the algal symbiont. Here, we examined the effect of increased temperature on phagocytic activity, as an indication of immune function. Our data shows that immune cell activity increases during heat stress, while small molecule pinocytosis remains unaffected. We observed an increase in cellular production of reactive oxygen species with increasing temperatures. We also found that the cellular immune activity was not affected by the presence of the Symbiodiniaceae. Our results suggest that the immune activity observed in heat-stress induced bleaching in corals is a fundamental and basic response independent of the bleaching effect. These results establish a foundation for improving our understanding of hexacorallian immune cell biology, and its potential role in coral bleaching. 

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