Posts Tagged 'laboratory'

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Temperature and CO2 alter trophic structure of Arctic plankton assemblages

Published 27 August 2025 Science Closed
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Driven by increasing anthropogenic CO2, the impact of ongoing climate change on the marine plankton ecosystem ultimately extends to higher trophic levels and the biogeochemical cycling of carbon and nutrients. However, the impacts of multiple environmental changes on trophic interactions between predator and prey have still not been fully explored. Here we conducted incubation experiments to determine the temperature and CO2 sensitivities of marine phytoplankton growth and microzooplankton grazing in the western Arctic Ocean, where rapid climate change is taking place. The temperature sensitivity of the growth of larger phytoplankton decreased owing to the increase in CO2 levels, whereas that of the growth of smaller phytoplankton increased under higher CO2 levels. Notably, the temperature sensitivity of Arctic phytoplankton is at least two times higher than the canonical estimates irrespective of size classes, highlighting the uniqueness of the Arctic ecosystem’s response to warming. Microzooplankton grazing was closely coupled with, but did not exceed, the growth rates of their prey, suggesting that microzooplankton behavior is mainly regulated by prey availability rather than the ambient environment. The higher competitiveness of smaller phytoplankton under higher temperatures and CO2 conditions might lead to a less productive Arctic Ocean ecosystem for higher trophic-level organisms in the future.

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Within and cross-generational effects of elevated seawater pCO2 on larval bay scallops Argopecten irradians (L)

Published 27 August 2025 Science Closed
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Bivalve larvae are highly susceptible to ocean acidification (OA), but there is little knowledge of the capacity of bivalve species to acclimate or adapt to changing ocean conditions. It is challenging to compare results among studies of OA reported in the literature, as there is little consistency among studies in water chemistry across OA treatments used or how OA conditions were determined. In addition, it is difficult to predict from short-term experiments how populations might respond across generations. The bay scallop, Argopecten irradians, is a good model species for such experiments because of its short generation time and importance commercially and ecologically. Bay scallops were exposed to OA conditions from embryos to metamorphosis across two generations. Ocean acidification treatment levels included historical or preindustrial “low” (pCO2 ∼450 µatm), current average “moderate” (∼800 µatm), and future “high” (∼1,350 µatm). In the first generation, high OA had negative effects on larval performance, with no survival to metamorphosis, preventing its inclusion in the second generation. Moderate OA reduced performance (survivorship and growth) relative to the low OA. In the second generation, however, there was no difference in survival between the moderate and low OA treatments, but the difference in size at metamorphosis remained. These results suggest that over two generations, bay scallops either acclimated or adapted to moderate OA. Further work is needed to determine the extent to which long-term, generational adaptation to OA is possible in the bay scallop.

Continue reading ‘Within and cross-generational effects of elevated seawater pCO2 on larval bay scallops Argopecten irradians (L)’

Assessing the physiological and oxidative stress status of Etroplus suratensis under elevated temperature and ocean acidification

Published 27 August 2025 Science Closed
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Highlights

  • Current study delves into the impacts of ocean warming (OW) and acidification (OA) on E. suratensis.
  • Combined stressor-induced metabolic depression which indicated energy conservation strategy.
  • Lower Scope for Growth advocates impaired energy allocation under stress.
  • Oxidative stress biomarkers and apoptosis augmented due to combined stress.
  • Anticipated OA and OW could threaten future fish populations and marine ecosystem balance.

Abstract

The incessant release of anthropogenic CO2 in the atmosphere has accentuated ocean warming (OW) and elevated the partial pressure of dissolved CO₂, culminating in a foreseeable decline in oceanic pH. Thus, the present study endeavors to elucidate the concomitant impacts of OW and ocean acidification (OA) on the eco-physiological responses of Etroplus suratensis over a 30-day mesocosm experiment. Physiological parametres, encompassing ingestion, absorption, respiration, and excretion rates, were measured to gauge the scope for growth (SfG). Additionally, a comprehensive evaluation of biomarkers, comprising antioxidant defenses, detoxification pathways, lipid peroxidation, and apoptotic markers, was assessed at various biological levels. Results revealed that combined stressors curtailed the feeding activity, as substantiated by a significant reduction in ingestion and absorption rate. Metabolic depression, illustrated by reduced respiration and excretion rates, insinuated an energy conservation strategy amidst dual stressors. Despite these adaptations, SfG remained depressed, accentuating the detrimental effects of the combined stressors on the energy allocation strategy of this fish. Furthermore, oxidative stress biomarkers, including superoxide dismutase (SOD), catalase (CAT), and glutathione-S-transferase (GST), exhibited heightened activities, albeit these defenses were insufficient to counteract persistent environmental stressors, resulting in increased lipid peroxidation (LPO) and apoptosis. Notably, cleaved caspase-3 expression was significantly upregulated, which suggested that apoptosis was a key cellular response against combined stressors. Overall, anticipated OA and OW significantly impacted the energy budget, oxidative stress biomarkers, and key cellular responses of E. suratensis, compromising growth, survival, and reproductive fitness. These potentially jeopardize population structure and disrupt trophic interactions which may impair functional integrity of estuarine ecosystem.

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Influence of intensified upwelling on two different Corallina officinalis Linneo 1758 populations by exploring direct and indirect effects

Published 26 August 2025 Science Closed
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In the perspective of a future ocean, climate change can alter upwelling systems globally. Along the Chilean coast, upwelling becomes intensified, leading to cool temperatures and low pH, which can affect common and widespread calcifying seaweed species such as Corallina officinalis. We measured physiological, biomineralogical, and palatability responses in two distinct populations originating from contrasting upwelling regimes, one from an upwelling area and the other from an upwelling shadow, by exposing them to current and future upwelling conditions. After 20 days of experimentation, photosynthetic responses such as maximum quantum yield (Fv/Fm) remained high (> 0.5) across populations. In contrast, maximal photosynthetic efficiency (rETRmax), light saturation point (Ek) and pigment content were higher in individuals exposed to future conditions, while alpha (electron transport efficiency) decreased over time. The carbonate content was higher in individuals exposed to future conditions, while the organic matter content differed between populations, with lower contents in the population originating from the site with higher environmental variability (-1.1%). Individuals exposed to future upwelling conditions presented higher soluble protein contents (2-3 mg/g wet weight) and were also more consumed by sea urchins (+162.7%). Our results indicate that the two C. officinalis populations possess strategies that confer tolerance to projected increases in upwelling, demonstrating their capacity to adapt to changing environmental conditions. However, rising herbivory pressure associated with intensified upwelling may exert a stronger influence on ecosystem dynamics, potentially altering future community composition.

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Metabolomics analysis provides new insights into the impacts of long-term ocean acidification and warming on the sensory qualities of sea urchin (Strongylocentrotus intermedius) gonads

Published 26 August 2025 Science Closed
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Highlights

  • Ocean acidification and warming (OAW) alter the color of sea urchin gonads.
  • OAW reduce the size and weight of sea urchin gonads.
  • OAW alter contents of flavor and odor-related compounds in sea urchin gonads.
  • OAW affect the quality of female gonads more seriously than that of males.

Abstract

Sea urchin gonads are popular raw, ready-to-eat seafood known for their fresh, sweet taste and high nutritional value. To investigate the impacts of ocean acidification and warming (OAW) on the sensory qualities of sea urchin gonads, farmed Strongylocentrotus intermedius were incubated separately and jointly in acidic (ΔpHNBS = −0.5 units) and thermal (ΔT = +3.0 °C) seawater for 90 days under lab-controlled conditions based on the ocean pH and temperature for 2100 projected by the Intergovernmental Panel on Climate Change (IPCC). Sensory properties (gonad size, color, and flavor-related metabolites) were subsequently determined and compared between groups. The results showed that: 1) The gonad size and gonad index (GI) decreased sharply (−49 % in female; −46 % in male) under OAW conditions in both sexes of adult S. intermedius. There were significant negative additive effects of acidification and high temperature on the GI. 2) OAW had no significant interaction effects on five gonadal color-related parameters; however, the redness (a*) of male gonads was significantly less than that of female gonads in both the separate and joint OAW groups. 3) Significant alterations to metabolome profiles, exhibiting sex-specific variations, were observed in adult S. intermedius incubated under separate/joint OAW conditions. Twenty-two significantly differentially expressed metabolites (SDMs) related to color, odor, and flavor were identified, primarily enriched in metabolic pathways associated with the biosynthesis and accumulation of odor and flavor compounds. To sum up, the data from this study indicate that OAW affect sensory qualities of sea urchin gonads negatively especially the gonads of females.

Continue reading ‘Metabolomics analysis provides new insights into the impacts of long-term ocean acidification and warming on the sensory qualities of sea urchin (Strongylocentrotus intermedius) gonads’

Synergistic effects of ocean acidification and copper on gamete health and fertilization potential of the Pacific oyster Magallana (Crassostrea) gigas

Published 26 August 2025 Science Closed
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Highlights

  • Ocean acidification exacerbates copper toxicity in Pacific oyster gametes.
  • Sperm show higher sensitivity to combined stressors than oocytes.
  • Fertilization success decreases at low pH and high copper concentrations.

Abstract

Ocean acidification (OA) and metal pollution pose significant threats to marine ecosystems, particularly in coastal areas. This study investigated the synergistic effects of OA and copper toxicity on Pacific oyster (Magallana gigas) gametes. Spermatozoa and oocytes were exposed to varying pCO2 levels and copper concentrations for 2 h. Flow cytometry was used to assess cell mortality, reactive oxygen species (ROS) production, and fertilization success. Results showed increased mortality in both sperm and oocytes with rising copper and pCO2 levels, with sperm exhibiting higher sensitivity. ROS production in gametes displayed complex patterns, suggesting adaptive responses at lower copper concentrations and potential cell death at higher levels. Fertilization success decreased significantly at lower pH combined with higher copper concentrations (> 10 μg Cu/L). These findings demonstrate that OA exacerbates copper toxicity in M. gigas gametes through interactive effects, highlighting the need to consider multiple stressors when assessing pollutant impacts on coastal ecosystems.

Continue reading ‘Synergistic effects of ocean acidification and copper on gamete health and fertilization potential of the Pacific oyster Magallana (Crassostrea) gigas’

The development and plasticity of acid excretion mechanisms in early life stage red drum, Sciaenops ocellatus

Published 21 August 2025 Science Closed
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Highlights

  • Components of acid-base pathways are present and stable in very early development.
  • NHE3 is localized to the apical pit of epithelial ionocytes.
  • Epithelial proton excretion is responsive to elevated CO2 and governed by NHEs.
  • nhe2/3 transcript abundance is elevated following development in high CO2.
  • Low level CO2 causes reductions in survival.

Abstract

Ocean acidification (OA) has been shown to affect early life stage fishes in a variety of ways, including reduced survival and growth, and increased tissue damage. Yet, there is also substantial interspecies variability in the sensitivity of early life stage fishes to high CO2, and it has been theorized that this may relate to the ontogeny of systemic acid-base regulatory pathways; an area that has been surprisingly understudied in obligate marine species. Here, we used an integrative set of approaches to describe the development and plasticity of acid excretion pathways in developing red drum (Sciaenops ocellatus), a marine fish native to the Gulf of Mexico. We observed mRNA expression of relevant transporters and ionocytes immediately post-hatch (36 h post-fertilization, hpf) with relatively stable abundance throughout the pre-metamorphic stages. Consistent with work in adults and seawater acclimated euryhaline larvae, we demonstrate strong co-localization of acid excretion proteins within a single epithelial ionocyte cell-type. Measurements of epithelial Δ[H]+, an indicator of proton efflux, showed that by 72 hpf larvae had CO2-responsive EIPA-sensitive acid excretion, confirming the presence of sodium proton exchanger (NHE)-mediated acid excretion. Elevated mRNA expression of nhe2 and nhe3 was induced following exposure to 5500 and 12,000 μatm CO2, which coincided with the absence of further survival effects relative to lower dose CO2. Overall, these data confirm that red drum have fully functional epithelial acid excretion pathways in early life, and that plasticity in these pathways may offer survival benefits.

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Ocean acidification influences strain selection and metabolism of the benthic diatom Cocconeis neothumensis var. marina

Published 21 August 2025 Science Closed
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The uptake of carbon dioxide (CO2) by oceans is dramatically altering the chemistry of seawater, leading to a continuous decrease of pH over the last century. This phenomenon, called ocean acidification (OA), has raised concerns due to its negative effects on marine biodiversity, including plankton communities and seagrass meadows. The most relevant seagrass in the Mediterranean is Posidonia oceanica, producing complex and stable benthic ecosystems. OA markedly affects the colonization and settlement patterns of epibionts within the leaf communities of P. oceanica. Epiphytic diatoms associated with P. oceanica are influenced by complex chemical and trophic interactions and play a fundamental role in the ecological successions characterizing the leaf stratum. In this study, we isolated two strains of Cocconeis neothumensis var. marina, one of the main epiphyte diatoms associated with P. oceanica, from two sites off the Island of Ischia (Italy) characterized by different pH conditions, i.e., a naturally low pH site (pH 7.6) influenced by volcanic CO2 emissions, and an adjacent location with ambient pH conditions (pH 8.1). We further cultured both strains of C. neothumensis under both pH conditions, resulting in four treatment conditions. Four significantly different growth curves were obtained, and metabolomic studies confirmed that the physiology of the strains differed according to pH conditions. Overall, this study demonstrated that OA is likely to trigger the selection of specific diatom strains, with possible consequences for trophic and chemical relationships among the associated consumers.

Continue reading ‘Ocean acidification influences strain selection and metabolism of the benthic diatom Cocconeis neothumensis var. marina’

Ocean acidification and nitrate enrichment can mitigate negative effects of soft coral (Xenia) competition on hard coral (Stylophora pistillata) endosymbionts

Published 21 August 2025 Science Closed
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The combination of ocean acidification (OA) and eutrophication can undermine the physiological performance of reef-building corals during competition for benthic space, leading to shifts towards non-accreting organisms like soft corals. We conducted a 28-day laboratory orthogonal experiment to test if acidification (950 µatm pCO2) and moderate to high nitrate enrichment (4 and 8 µmolL−1) negatively affect the hard coral Stylophora pistillata while physically competing with the soft coral Xenia spp. We measured photosynthetic efficiency (PE) in hard corals and growth rate, Symbiodiniaceae density, and chlorophyll-a concentration in both hard and soft corals as proxies for their condition and responses to competition. Competition with the soft coral reduced PE, Symbiodiniaceae and chlorophyll-a contents of S. pistillata, while acidification alone and coupled with nitrate enrichment mitigated endosymbiont responses. The growth and chlorophyll-a concentrations of Xenia spp. were decreased by competition, but the soft coral was consistently benefited under nitrate enrichment. These results highlight that competition alone has a stronger negative impact on hard corals than on soft corals. Our study provides experimental evidence on how OA and eutrophication interact and shape coral dynamics, an overlooked but urgent topic in predicting reef futures under environmental change.

Continue reading ‘Ocean acidification and nitrate enrichment can mitigate negative effects of soft coral (Xenia) competition on hard coral (Stylophora pistillata) endosymbionts’

The influence of cross-generational warming on the juvenile development of a coral reef fish under ocean warming and acidification

Published 20 August 2025 Science Closed
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Marine ecosystems are facing escalating chronic and acute environmental stressors, yet our understanding of how multiple stressors influence individuals is limited. Here, we investigated how projected ocean warming (+1.5°C) during grandparental (F1) and parental (F2) generations of the spiny chromis damselfish (Acanthochromis polyacanthus), influences the sensitivity of F3 juveniles to ocean warming (present-day vs +1.5°C) and/or elevated CO2 (490 μatm vs 825 μatm). After 16 weeks of exposure, aerobic physiology (resting oxygen consumption, maximum oxygen consumption, and absolute aerobic scope), behaviour (boldness and activity), and growth (length and physical condition) were measured in F3 juveniles and the relationships between these performance traits was explored. We found that warming during F3 development resulted in juveniles that were shorter, bolder, and in better physical condition, while elevated CO2 resulted in shorter juveniles with a reduced resting oxygen consumption. However, across juvenile performance traits there was no interaction between ocean warming and acidification, demonstrating the additive nature of these two environmental stressors. Although we found limited signs of transgenerational plasticity, there was evidence of parental and grandparental carry-over effects which resulted in juveniles that were larger and/or in better condition when grandparents and parents experienced warming during their development regardless of the F3 juvenile developmental treatment. These finding illustrate the significant role phenotypic plasticity has on juvenile performance under projected future climate change.

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Quantifying evolutionary changes to temperature-CO2 growth response surfaces in Skeletonema marinoi after adaptation to extreme conditions 

Published 19 August 2025 Science Closed
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Global warming and ocean acidification are having an unprecedented impact on marine ecosystems, yet we do not yet know how phytoplankton will respond to simultaneous changes in multiple drivers. To better comprehend the combined impact of oceanic warming and acidification, we experimentally estimated how evolution shifted the temperature-CO2 growth response surfaces of two strains of Skeletonema marinoi that were each previously adapted to four different temperature × CO2 combinations. These adapted strains were then grown under a factorial combination of five temperatures and five CO2 concentrations to capture the temperature-CO2 response surfaces for their unacclimated growth rates. The development of the first complete temperature-CO2 response surfaces showed the optimal CO2 concentration for growth to be substantially higher than expected future CO2 levels (~6000 ppm). There was minimal variation in the optimal CO2 concentration across the tested temperatures, suggesting that temperature will have a greater influence on growth rates compared to enhanced CO2. Optimal temperature did not show a unimodal response to CO2, either due to the lack of acclimation or the highly efficient CO2 concentrating mechanisms, which diatoms (e.g. Skeletonema) can up-/downregulate depending on the CO2 conditions. We also found that both strains showed evidence of evolutionary shifts as a result of adaptation to temperature and CO2. The evolutionary response differed between strains, underscoring how genetic differences (perhaps related to historical regimes) can impact phytoplankton performance. Understanding how a dominant algal species responds to multiple drivers provides insight into real-world scenarios and helps construct theoretical predictions of environmental change.

Continue reading ‘Quantifying evolutionary changes to temperature-CO2 growth response surfaces in Skeletonema marinoi after adaptation to extreme conditions ‘

Molecular markers of stress in the sea urchin embryo test: analysing the effect of climate change and pollutant mixtures on Paracentrotus lividus larvae

Published 15 August 2025 Science Closed
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Highlights

  • Combined effects of ocean stressors on sea urchin larvae were analysed.
  • RNA-seq revealed key transcriptional changes under stressor combinations.
  • Larval growth and deformities worsened with acidification and warming.
  • Biomarkers for early detection of stress in marine larvae were identified.
  • Insights contribute to predicting organismal responses to climate change.

Abstract

Climate change and pollution represent critical stressors for marine ecosystems, particularly for calcifying organisms such as the sea urchin Paracentrotus lividus. This study examines the combined effects of ocean acidification (OA), ocean warming (OW), and microplastics (MP) loaded with chlorpyrifos (CPF), a broad-spectrum organophosphate insecticide, on sea urchin larvae, evaluating growth and molecular endpoints. Experimental treatments simulated future ocean conditions predicted for 2100, exposing larvae to varying temperature and pH levels, alongside CPF-contaminated MP. RNA sequencing (RNA-seq) was utilized to assess gene expression changes, revealing significant transcriptional shifts in metabolic, cellular, and developmental pathways. Morphological responses showed reduced larval growth, exacerbated under OA and OW conditions. Molecular analyses identified key upregulated pathways associated with stress response, including nitrogen metabolism and extracellular matrix remodelling, while downregulated genes involved DNA stability, cell cycle regulation, and enzymatic activities. These findings suggest a dual compensatory and deleterious response to combined stressors. Notably, temperature acted as a modulator of stressor effects, amplifying oxidative stress and metabolic costs at higher temperatures. Potential biomarkers, such as genes involved in actin regulation and embryonic development, were identified, offering possible tools for early detection of environmental stress. This study highlights the compounded impacts of anthropogenic and climate-induced stressors on marine invertebrates, emphasizing the need for integrative molecular approaches in ecotoxicology. Our findings contribute to the understanding of organismal adaptation and vulnerability in the face of global climate change and pollution, informing conservation strategies for marine ecosystems.

Continue reading ‘Molecular markers of stress in the sea urchin embryo test: analysing the effect of climate change and pollutant mixtures on Paracentrotus lividus larvae’

Tubastraea coccinea (Lesson, 1830), a coral species with high invasive potential, can benefit from the synergistic effects of ocean warming and acidification

Published 14 August 2025 Science Closed
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Temperature rise and pH decrease, coupled with increasing maritime traffic, are inducing modifications in the distribution of many exotic species, such as Tubastraea coccinea, a species with high invasive potential recently recorded in the Canary Islands. This study assessed the effect of the expected end-of-century temperature and pH (26°C and pH 7.50) on this coral species through manipulative laboratory experiments conducted over different time periods (30 days vs. 80 days). The impact of acidification, warming, and time on variables such as weight, buoyant weight, number of new polyps, area, respiration, calcification and reproduction rates were analysed. Results revealed a negative effect of acidification on growth and respiration rates of T. coccinea, with significant differences between experimental treatments in weight, buoyant weight, number of polyps, area, and respired carbon. However, in future, T. coccinea may not be adversely affected by low pH values, as the negative effect is mitigated when colonies are exposed to 26°C. Using different experimental periods showed how this species’ response is liable to change over time under future climate change conditions.

Continue reading ‘Tubastraea coccinea (Lesson, 1830), a coral species with high invasive potential, can benefit from the synergistic effects of ocean warming and acidification’

Factorial field manipulation reveals CO2 and temperature effects on a critical habitat-forming shellfish

Published 14 August 2025 Science Closed
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Ocean acidification and warming could have substantial negative impacts on marine organisms, particularly shell-building species. These environmental drivers may operate independently or interactively, amplifying or mitigating their impacts. Previous results have primarily come from lab studies, yet these climate drivers co-occur within naturally dynamic systems with high abiotic and biotic variability. Within intertidal habitats, the impacts of these drivers in situ remain poorly understood. We conducted a 6-month field manipulation to determine the effects of ocean acidification and warming on a habitat-forming shellfish, the Pacific blue mussel (Mytilus trossulus), in a dynamic intertidal system. Fourteen tide pools containing mussels were manipulated, including ambient (unmanipulated control), CO2 added, warmed, and combined CO2 added and warmed treatments. We measured mussel shell thickness, strength, and corrosion at 0, 3, and 6 months of exposure to treatment conditions. CO2 addition led to decreases in shell thickness and strength and increases in shell corrosion. However, we also detected increases in shell strength compared to controls for mussels exposed to both CO2 addition and warming. These findings indicate that ocean acidification negatively impacted shellfish overall, and the effects of acidification on shell strength might be mitigated under concurrent exposure to moderate warming, leading to an interactive effect of acidification and warming on this critical habitat-forming shellfish.

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Microplastic–tebuconazole interactions under ocean acidification: role of material type and salinity

Published 14 August 2025 Science Closed
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The escalating global plastic pollution has led to the widespread presence of microplastics in marine environments, posing a significant risk by adsorbing organic pollutants such as tebuconazole (TEB). Ocean acidification, a consequence of increased carbon dioxide (CO2) emissions, is also altering the marine environment. This study investigates the adsorption behavior of TEB on various microplastic materials under conditions of seawater acidification, a critical environmental stressor. It was found that the adsorption capacity of TEB varies among different microplastics, with degradable microplastics Poly(butylene adipate-co-terephthalate) (PBAT) and Poly(butylene succinate) (PBS) exhibiting higher adsorption capacity due to the presence of oxygen-containing functional groups. The sorption capacity followed the order of PBAT ≈ PBS > Polyamide (PA) > Polyvinyl Chloride (PVC) > Polystyrene (PS) > Polyethylene (PE). The influence of salinity on adsorption was pronounced, with increased salt concentrations enhancing adsorption on certain microplastics (PA, PBAT, and PBS), likely due to the salting-out effect and charge neutralization. Acidification significantly affected the adsorption on nondegradable microplastics by altering the degree of TEB dissociation and microplastic surface potential, showing up to 15–30% higher capacity when exposed to CO2– or HCl-acidified environments, while degradable microplastics and PA showed minimal pH sensitivity, suggesting hydrogen bonding as the conduct adsorption mechanism, which makes them less affected by changes in pH. These findings provide insights into how microplastic properties and environmental changes affect the distribution and behavior of organic pollutants in marine settings, emphasizing the ecological risks linked to microplastic pollution and ocean acidification.

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The influence of maternal size/age effects on the physiological responses of adult female gopher rockfish (Sebastes carnatus) to ocean acidification and hypoxia

Published 13 August 2025 Science Closed
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Climate change is rapidly reshaping the chemistry of the ocean. Fishes living in California coastal waters are experiencing increased ocean acidification and hypoxia (OAH) due to more frequent and intense upwelling. Nearshore rockfish may be particularly threatened by these conditions due to their long generational times. However, it is unknown how OAH may impact maternal physiology and reproduction in these viviparous fish. To understand the physiological effects of OAH during gestation, adult female gopher rockfish, Sebastes carnatus, were exposed to a variety of combined OAH stress treatments during different gestational stages. Routine metabolic rate (RMR), maximum metabolic rate (MMR), blood hematocrit (Hct), hemoglobin (tHb), pCO2, HCO3, Na+, K+, Cl, and metabolites, were measured to assess physiological responses to OAH stress. Ovarian oxygen was measured to examine the ability to buffer embryos against low oxygen. Fish exposed to higher OAH stress displayed elevated blood Hct, tHb, pCO2 and HCO3, and decreased MMR, indicating attempted compensation for low pH and hypoxia (with varying levels of success), at increased physiological costs. Fish showed signs of buffering their ovaries against hypoxia. Lastly, pregnancy altered Hct and RMR under OAH exposure and size/age did not have a consistent effect on maternal physiology. By evaluating responses of maternal physiology to OAH stress, we can better understand how climate change affects fecundity, larval condition, and survival, influencing nearshore fisheries in an ever-changing climate.

Continue reading ‘The influence of maternal size/age effects on the physiological responses of adult female gopher rockfish (Sebastes carnatus) to ocean acidification and hypoxia’

When time reveals the cost: effects of long-term exposure to low pH on a predatory gastropod

Published 13 August 2025 Science Closed
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Ocean acidification, a direct consequence of anthropogenic carbon dioxide emissions, is among the major challenges for marine organisms. While an increased body of evidence is documenting the negative effects of ocean acidification, most of these studies are still based on short-term exposure. Long-term experiments, studying multiple traits simultaneously, and accounting for short-term local pH variability in the species’ habitat are needed. This study investigated the impact of a 310-day exposure to low pH on the banded-dye murex, Hexaplex trunculus (Linnaeus, 1758), a predatory Mediterranean gastropod. Temperature strongly influences the behavior and activity of the banded-dye murex, so we allowed it to vary naturally in this experiment. Our results showed that the net calcification rate was negatively affected by low pH throughout the duration of the experiment. While the banded-dye murexes were able to maintain their total body weight at the beginning of the experiment, it decreased under chronic exposure to low pH. Soft tissue body weight remained unaffected for more than 200days, followed by a pronounced decrease when exposed to lower pH. No sex-specific differences in response to low pH were observed, but females generally exhibited higher rates of calcification and growth during the winter period, likely due to energy allocation strategies associated with the reproductive cycle. These results suggest that while the banded-dye murex can temporarily reallocate energy to maintain essential physiological functions under low pH, this capacity diminishes over time, revealing physiological limits to long-term stress tolerance. This finding highlights the importance of incorporating long-term, multi-trait experiments in ocean acidification research to better predict species vulnerability, ecosystem-level impacts, and the resilience of coastal marine communities under future climate change scenarios.

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Identification, characterization, and expression analysis reveal regulatory roles of MCM genes in Patinopecten yessoensis under low-pH stress

Published 12 August 2025 Science Closed
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Highlights

  • Nine MCM genes are systematically identified from Patinopecten yessoensis genome.
  • PyMCMs are widely expressed during development and adult tissues, especially PyMCM6.
  • PyMCM5 is particularly sensitive to low pH stress, whereas PyMCM8 and PyMCM9 are not.
  • Scallops reduce DNA replication but maintain DNA repair in response to low-pH stress.

Abstract

The Yesso scallop (Patinopecten yessoensis), an ecomically important bivalve species, exhibits high susceptibility to ocean acidification. The growth retardation induced by low-pH stress poses a significant challenge for Yesso scallop aquaculture. However, the molecular mechanisms underlying this phenomenon are not well understood. Considering the pivotal role of cell proliferation in organism growth, we investigated the minichromosome maintenance (MCM) family in P. yessoensis, which are key regulators of DNA replication initiation and cell cycle regulation. In this study, we identified nine MCM genes (PyMCM2–10) in the P. yessoensis genome. These PyMCMs exhibit highly conserved sequence characteristics and typical MCM domains. Phylogenetic analysis showed that PyMCMs cluster into nine distinct clades, underscoring their strong evolutionary conservation across species homologs. Spatiotemporal expression profiling demonstrated widespread expressions of PyMCMs throughout all developmental stages and adult tissues, with particularly high levels in vigorous cell proliferation (e.g., up to 318 TPM in multicell stage and up to 202 TPM in gonad tissue). Notably, PyMCM6 exhibited consistently high expression across development and across tissues (> 44 TPM), suggesting a key regulatory role in both development and tissue maintenance. Under low-pH stress, the expressions of PyMCMs were downregulated to varying degrees, with PyMCM5 showing the most significant reduction (|log2FC| up to 3.5), while PyMCM8 and PyMCM9 remained relatively stable. This pattern suggests a strategic response that scallops reduce DNA replication capacity (mediated by PyMCM2–7) but potentially maintain DNA repair functions (associated with PyMCM8/9 stability) to mitigate damage induced by low-pH, potentially explaining the intrinsic inhibition of cell proliferation. Quantitative real-time PCR and in situ hybridization further confirmed that low-pH stress inhibits PyMCMs expressions (p < 0.05), with the effect amplified as pH decreases. Collectively, these findings enhance our understanding of PyMCMs in regulating bivalve growth retardation under low-pH stress and provide valuable insights into the mechanisms of environmental adaptation in bivalves.

Continue reading ‘Identification, characterization, and expression analysis reveal regulatory roles of MCM genes in Patinopecten yessoensis under low-pH stress’

Adaptive phenotypic evolution of Skeletonema costatum to ocean acidification and warming with trade-offs from a multi-year outdoor experiment

Published 11 August 2025 Science Closed
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Human-induced climate change is increasing variability in marine environments, significantly affecting marine organisms and ecosystems. While marine diatoms can adapt to ocean acidification and warming in stable laboratory settings, their responses to long-term environmental changes under natural variability remain unclear. To investigate this, we cultivated Skeletonema costatum in outdoor semi-continuous cultures for over 3 years, exposing them to fluctuating natural light and temperature that tracked the in situ sea surface temperatures. We simulated current and future ocean conditions through four treatments: ambient CO2 and temperature (LTLC), elevated CO2 (LTHC), elevated temperature (+4°C, HTLC) and combined increases (HTHC). After 1396 days, we assessed populations in two assay environments (20°C, 400 ppm CO2 and 24°C, 1000 ppm CO2) for adaptations in growth rate, pigment composition and photosynthesis. The HTLC-selected group showed the highest growth rates in the HTHC assay environment, while the LTLC-selected group grew fastest in the LTLC assay environment, indicating adaptive evolution. Furthermore, populations selected under elevated conditions exhibited lower fitness in LTLC environments, highlighting a trade-off and underscoring the complexity of evolutionary adaptation in marine diatoms. Understanding these mechanisms is crucial for predicting phytoplankton dynamics and their role in marine ecosystems, especially in response to climate change.

Continue reading ‘Adaptive phenotypic evolution of Skeletonema costatum to ocean acidification and warming with trade-offs from a multi-year outdoor experiment’

Copper dynamics in the aquatic environment under ocean acidification and contamination by microplastics

Published 7 August 2025 Science Closed
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Microplastics can act as vectors of copper (Cu) ions, potentially altering their dynamics and availability in the marine environment through adsorption processes, which are influenced by several factors, including water pH. Given that ocean acidification is a current process that causes a reduction in pH and can be further aggravated through an increase in anthropogenic CO2 emissions, the aim of this study was to evaluate the behaviour of Cu in an acidified environment that was contaminated with photodegraded microplastics (polyethylene terephthalate (PET)) and to verify chemical changes in the carbonate system and Cu speciation under a reduced pH scenario. At the current pH (7.88), the concentration of dissolved Cu decreased after 48 h, primarily due to inorganic complexation and adsorption onto natural particles rather than adsorption onto microplastics, which exhibited a limited capacity to adsorb Cu2+ under the experimental conditions. Conversely, in the acidified pH scenario (7.59), the concentration of dissolved Cu increased, likely due to the release of previously complexed Cu and the reduced adsorption capacity of the microplastics, as Cu2+ competes with the increased H+ concentrations for the sorption sites on the surfaces of microplastics. These results indicate that under future acidification scenarios, the capacity of microplastics to act as vectors of Cu could be insufficient, potentially increasing the concentration of free ionic-Cu and increasing its availability and consequent toxicity to marine biota.

Continue reading ‘Copper dynamics in the aquatic environment under ocean acidification and contamination by microplastics’

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