Your search keyword '"Ocean acidification"' showing total 4,367 results

1. Seasonal Upwelling Conditions Modulate the Calcification Response of a Tropical Scleractinian Coral

Author

Carlos Gómez, Andrés Acosta-Chaparro, Cesar Bernal, Diana Gómez-López, Raúl Navas-Camacho, and David Alonso

Subjects

carbonate chemistry, ocean acidification, coral reef, south-western Caribbean, Madracis auretenra, General Medicine

Abstract

Natural processes such as upwelling of deeper-water masses change the physical-chemical conditions of the water column creating localized ocean acidification events that can have an impact on the natural communities. This study was performed in a coral reef system of an archetypical bay within the Tayrona National Natural Park (PNNT) (Colombia), and aimed to quantify net calcification rates of a foundational coral species within a temporal context (6 months) taking into account the dynamics of seasonal upwelling that influence the study area. Net calcification rates of coral fragments were obtained in situ by the alkalinity anomaly technique in short-term incubations (~2.5 h). We found a significant effect of the upwelling on net calcification rates (Gnet) (p < 0.05) with an 42% increase in CaCO3 accretion compared to non-upwelling season. We found an increase in total alkalinity (AT) and dissolved inorganic carbon (DIC) with decreased aragonite saturation (Ωara) for the upwelling months, indicating an influence of the Subtropical Under Water mass (SAW) in the PNNT coral community. Significant negative correlations between net calcification with temperature and Ωara, which indicates a positive response of M. auretenra with the upwelling conditions, thus, acting as “enhancer” of resilience for coral calcification.

Published

2023

2. Heritage at Risk: Assessing Climate Vulnerability in San Juan, Puerto Rico

Author

Tommasini Canestrelli, Ana Paula

Subjects

communities, cultural identity, climate change, sea level rise, vulnerability, Puerto Rico, storm surge, coastal flooding, ocean acidification, cultural heritage, global warming, policy

Abstract

Climate change poses a threat not only to the environmental and physical aspects of the places where people live, but also to their identities and ways of living, as well as those of the communities around them. Conducted as part of the requirements of the Master of Advanced Studies in Marine Biodiversity and Conservation at Scripps Institution of Oceanography (SIO), this capstone project consists of a climate vulnerability assessment of the La Fortaleza and San Juan National Historic Site World Heritage Site in Puerto Rico, based on a literature review of existing scientific data. Its purpose is to inform a broader effort led by SIO’s Human Ecology Lab, which will complement this top-down approach with a bottom-up assessment of climate change threats to the area based on the perspectives of local stakeholders. This project includes two products: the full climate vulnerability assessment presented below and an online summary of its main findings with interactive maps, which can be found athttps://arcg.is/1quumK. Ultimately, this project contributes to the ongoing development of a climate vulnerability assessment tool for cultural heritage that can be used independently by stakeholders to meaningfully assess the vulnerability of their own cultural heritage to climate change through a decentralized process that can inspire local climate action, inform decision-making at different levels, and be repeated consistently as the components of vulnerability change over time. Please see the media created for this project here:https://storymaps.arcgis.com/stories/79ebff9ddfd741d788141b1b10cb0b54

Published

2023

3. Molecular response of Sargassum vulgare to acidification at volcanic <scp> CO 2 </scp> vents: Insights from proteomic and metabolite analyses

Author

Amit Kumar, Simona Nonnis, Immacolata Castellano, Hamada AbdElgawad, Gerrit T. S. Beemster, Maria Cristina Buia, Elisa Maffioli, Gabriella Tedeschi, Anna Palumbo, Kumar, Amit, Nonnis, Simona, Castellano, Immacolata, Abdelgawad, Hamada, Beemster, Gerrit T S, Buia, Maria Cristina, Maffioli, Elisa, Tedeschi, Gabriella, and Palumbo, Anna

Subjects

adaptation, CO2 seeps, macroalgae, metabolites, ocean acidification, proteins, metabolite, Sargassum, Proteomic, Carbon Dioxide, Hydrogen-Ion Concentration, Settore BIO/10 - Biochimica, CO2 seep, Genetics, Seawater, protein, Ecology, Evolution, Behavior and Systematics

Abstract

Ocean acidification is impacting marine life all over the world. Understanding how species can cope with the changes in seawater carbonate chemistry represents a challenging issue. We addressed this topic using underwater CO2 vents that naturally acidify some marine areas off the island of Ischia. In the most acidified area of the vents, having a mean pH value of 6.7, comparable to far-future predicted acidification scenarios (by 2300), the biomass is dominated by the brown alga Sargassum vulgare. The novelty of the present study is the characterization of the S. vulgare proteome together with metabolite analyses to identify the key proteins, metabolites, and pathways affected by ocean acidification. A total of 367 and 387 proteins were identified in populations grown at pH that approximates the current global average (8.1) and acidified sites, respectively. Analysis of their relative abundance revealed that 304 proteins are present in samples from both sites: 111 proteins are either higher or exclusively present under acidified conditions, whereas 120 proteins are either lower or present only under control conditions. Functionally, under acidification, a decrease in proteins related to translation and post-translational processes and an increase of proteins involved in photosynthesis, glycolysis, oxidation-reduction processes, and protein folding were observed. In addition, small-molecule metabolism was affected, leading to a decrease of some fatty acids and antioxidant compounds under acidification. Overall, the results obtained by proteins and metabolites analyses, integrated with previous transcriptomic, physiological, and biochemical studies, allowed us to delineate the molecular strategies adopted by S. vulgare to grow in future acidified environments, including an increase of proteins involved in energetic metabolism, oxidation-reduction processes, and protein folding at the expense of proteins involved in translation and post-translational processes.

Published

2022

4. Resilient consumers accelerate the plant decomposition in a naturally acidified seagrass ecosystem

Author

Juhyung Lee, Maria Cristina Gambi, Kristy J. Kroeker, Marco Munari, Kabir Peay, and Fiorenza Micheli

Subjects

biodiversity, blue carbon, decomposition, detritivore, ecosystem function, global change, ocean acidification, seagrass, Global and Planetary Change, Alismatales, Ecology, Carbon Dioxide, Hydrogen-Ion Concentration, Environmental Chemistry, Seawater, Ecosystem, General Environmental Science

Abstract

Anthropogenic stressors are predicted to alter biodiversity and ecosystem functioning worldwide. However, scaling up from species to ecosystem responses poses a challenge, as species and functional groups can exhibit different capacities to adapt, acclimate, and compensate under changing environments. We used a naturally acidified seagrass ecosystem (the endemic Mediterranean Posidonia oceanica) as a model system to examine how ocean acidification (OA) modifies the community structure and functioning of plant detritivores, which play vital roles in the coastal nutrient cycling and food web dynamics. In seagrass beds associated with volcanic CO

Published

2022

5. Revisiting tolerance to ocean acidification: Insights from a new framework combining physiological and molecular tipping points of Pacific oyster

Author

Mathieu Lutier, Frédéric Gazeau, Alexis Appolis, Fabrice Pernet, Carole Di Poi, and Jérémy Le Luyer

Subjects

0106 biological sciences, Range (biology), 01 natural sciences, acidification, 03 medical and health sciences, threshold, Animals, Environmental Chemistry, Seawater, 14. Life underwater, Ecosystem, 030304 developmental biology, General Environmental Science, 0303 health sciences, Global and Planetary Change, biology, Ecology, 010604 marine biology & hydrobiology, Ocean acidification, Global change, mollusk, transcriptomic, Carbon Dioxide, Hydrogen-Ion Concentration, Pacific oyster, biology.organism_classification, reaction norm, lipidomic, 13. Climate action, Ph range, Environmental science, Identification (biology), Transcriptome

Abstract

Studies on the impact of ocean acidification on marine organisms involve exposing organisms to future acidification scenarios as projected for open ocean, which has limited relevance for coastal calcifiers. Characterization of reaction norms across a range of pH and identification of tipping points beyond which detrimental effects are observed has been limited and focus on only a few macro-physiological traits. Here we filled this knowledge gap by developing a framework to analyze the broad macro-physiological and molecular responses over a wide pH range of juvenile Pacific oyster, a model species for which the tolerance threshold to acidification remains unknown. We identify low tipping points for physiological traits at pH 7.3-6.9 that coincide with a major reshuffling in membrane lipids and transcriptome. In contrast, shell parameters exhibit effects with pH drop well before tipping points, likely impacting animal fitness. These findings were made possible by the development of an innovative methodology to synthesize and identify the main patterns of variations in large -omic datasets, fit them to pH and identify molecular tipping-points. We propose the application of our framework broadly to the assessment of effects of global change on other organisms.

Published

2022

6. Acidification of the Nordic Seas

Author

F. Fransner, F. Fröb, J. Tjiputra, N. Goris, S. K. Lauvset, I. Skjelvan, E. Jeansson, A. Omar, M. Chierici, E. Jones, A. Fransson, S. R. Ólafsdóttir, T. Johannessen, and A. Olsen

Subjects

QE1-996.5, Ecology, Life, Ocean acidification, QH501-531, VDP::Andre geofag: 469, Geology, Biogeochemistry, Havforsuring, VDP::Other geosciences: 469, QH540-549.5, Ecology, Evolution, Behavior and Systematics, Earth-Surface Processes

Abstract

Due to low calcium carbonate saturation states, and winter mixing that brings anthropogenic carbon to the deep ocean, the Nordic Seas and their cold-water corals are vulnerable to ocean acidification. Here, we present a detailed investigation of the changes in pH and aragonite saturation in the Nordic Seas from preindustrial times to 2100, by using in situ observations, gridded climatological data, and projections for three different future scenarios with the Norwegian Earth System Model (NorESM1-ME). During the period of regular ocean biogeochemistry observations from 1981–2019, the pH decreased with rates of 2–3 × 10−3 yr−1 in the upper 200 m of the Nordic Seas. In some regions, the pH decrease can be detected down to 2000 m depth. This resulted in a decrease in the aragonite saturation state, which is now close to undersaturation in the depth layer of 1000–2000 m. The model simulations suggest that the pH of the Nordic Seas will decrease at an overall faster rate than the global ocean from the preindustrial era to 2100, bringing the Nordic Seas' pH closer to the global average. In the esmRCP8.5 scenario, the whole water column is projected to be undersaturated with respect to aragonite at the end of the 21st century, thereby endangering all cold-water corals of the Nordic Seas. In the esmRCP4.5 scenario, the deepest cold-water coral reefs are projected to be exposed to undersaturation. Exposure of all cold-water corals to corrosive waters can only be avoided with marginal under the esmRCP2.6 scenario. Over all timescales, the main driver of the pH drop is the increase in dissolved inorganic carbon (CT) caused by the raising anthropogenic CO2, followed by the temperature increase. Thermodynamic salinity effects are of secondary importance. We find substantial changes in total alkalinity (AT) and CT as a result of the salinification, or decreased freshwater content, of the Atlantic water during all time periods, and as a result of an increased freshwater export in polar waters in past and future scenarios. However, the net impact of this decrease (increase) in freshwater content on pH is negligible, as the effects of a concentration (dilution) of CT and AT are canceling.

Published

2022

7. Calcification responses of subtropical corals to ocean acidification: a case study from Sesoko Island, Okinawa, Japan

Author

Tomoko Bell, Kazuhiko Sakai, Akira Iguchi, Atsushi Suzuki, Naoki H. Kumagai, and Cristiana Manullang

Subjects

Oceanography, medicine, Environmental science, Ocean acidification, Subtropics, medicine.disease, Calcification

Published

2022

8. Ocean acidification reduces the growth of two Southern Ocean phytoplankton

Author

SM Andrew, Michael J. Ellwood, O Branson, and Robert F. Strzepek

Subjects

Oceanography, Ecology, Phytoplankton, Environmental science, Ocean acidification, Aquatic Science, Ecology, Evolution, Behavior and Systematics

Abstract

Model projections for the Southern Ocean indicate that light, iron (Fe) availability, temperature and carbon dioxide (CO2) will change concurrently in the future. We investigated the physiological responses of Southern Ocean phytoplankton to multiple variables by culturing the haptophyte Phaeocystis antarctica and the diatom Chaetoceros flexuosus under various combinations of light, Fe, temperature and CO2. Using statistical models, the influence of each environmental variable was analysed for each physiological response, ultimately predicting how ‘future’ conditions (high temperature and high CO2) would influence the 2 phytoplankton species. Under future conditions, cellular chlorophyll a and carbon to nitrogen molar ratios were modelled to increase for both species in all light and Fe treatments, but at times were inconsistent with measured values. Measured and modelled values of the photochemical efficiency of photosystem II (Fv/Fm) declined in cultures of P. antarctica due to concurrent increases in temperature and CO2, under all light and Fe treatments. The trends in Fv/Fm for C. flexuosus were less clear. Our model and observations suggest that when temperature and CO2 are concurrently increased, the growth of both species remains largely unchanged. This modelling analysis reveals that high CO2 exerts a strong negative influence on the growth of both phytoplankton, and any ‘future’ increase in growth can be attributed to the positive effect of warming rather than a CO2 fertilisation effect.

Published

2022

9. Ocean acidification modifies the impact of warming on sediment nitrogen recycling and assimilation by enhancing the benthic microbial loop

Author

MN Simone, Joanne M. Oakes, Kai G. Schulz, and Bradley D. Eyre

Subjects

Oceanography, Ecology, chemistry, Benthic zone, chemistry.chemical_element, Sediment, Environmental science, Assimilation (biology), Ocean acidification, Aquatic Science, Microbial loop, Nitrogen, Ecology, Evolution, Behavior and Systematics

Abstract

Nitrogen that has been recycled in the benthos supports high rates of primary and secondary production in estuaries. However, little is known about the effect of future climate on benthic nitrogen recycling and assimilation. An ex situ core incubation was used to assess the impact of combinations of warming (8°C range) and ocean acidification (OA) (i.e. increased pCO2 and decreased pH) on ammonium (NH4+) and nitrate/nitrite (NOx) fluxes and 15N-nitrate assimilation in shallow unvegetated estuarine sediments. Dissolved inorganic nitrogen (DIN = NH4+ + NOx) fluxes were significantly affected by the interaction of warming and OA, highlighting the importance of considering combined stressor treatments when investigating ecosystem responses to future climates. Warming alone increased DIN efflux from the sediments. At current mean ambient temperatures (23°C) and below (Δ-3°C), OA significantly increased DIN effluxes, but there was little to no effect of OA on DIN fluxes at warmer temperatures (Δ+3°C and Δ+5°C). OA reduced the 15N assimilation/retention of the sediments across all temperatures, suggesting that nitrogen retention in bacterial biomass was reduced, despite OA also increasing primary productivity. As such, under the projected future climate of ~3°C warming and doubling of pCO2 (~1000 µatm), unvegetated estuarine sediments are likely to have a more rapid turnover of DIN driven by greater microphytobenthos production and recycling.

Published

2022

10. CAGE15-7 Cruise Report: GEO8144/3144 – Marine Geology and Geophysics Cruise, Greenhouse Gases in the Ocean

Author

Tine L. Rasmussen, Tove Nielsen, Antoon Kuijpers, Kamila Sztybor, Mohamed Ezat, Simon P. Jessen, and Noortje Dijkstra

Subjects

Vestnesa, gas hydrate sampling, water sampling, paleoceanography, stratigraphy, planktic foraminifera, ocean acidification, Fram Strait, methane seep sites, Storfjorden, coring, CTD, Storfjord Trough

Abstract

From the late afternoon of July 23rd to the morning of August 3rd, 2015, the Department of Geology Uit, the Arctic University of Norway, arranged a AMGG-Research School scientific teaching cruise aimed atinvestigating the western and northern Svalbard margin and the Barents Sea, the Fram Strait to east Greenland, methane seep sites at Vestnesa, Prins Karls Forland and Storfjorden Trough and on R/V “Helmer Hanssen”. Investigated areas were (in order of visiting sites on the cruise): west of Prins Karls Forland, Vestnesa Ridge, Molloy Deep, Fram Strait, East Greenland margin, Smeerenburgfjorden, Hinlopen, Storfjorden, Storfjorden Trough, and Leirdjupet south of Spitsbergenbanken. The scientific sampling was done within the framework of several ongoing projects at the Department of Geology, University of Tromsø: “CAGE – Centre for Arctic Gashydrate, Environment and Climate”, in which the sub-projects “Paleo-CIRCUS”, “OA-Ocean Acidification” is included. The responsible for this year’s course in GEO8144/GEO3144 is Prof. T.L. Rasmussen. A total of 26 gravity cores, 5 piston cores, 12 plankton net casts and 27 CTD (conductivity-temperature-depth) casts were performed at the planned stations. A total of 86.3 km (46 nm) of airgun surveys were run. 108.97 m mud was obtained in total. Chirp profiles and multibeam lines were acquired during transits and during surveys in Storfjorden, Storfjorden Trough and Leirdjupet. In addition, CTD’s and a small chirp and multibeam survey was performed Storfjorden and in Leirdjupet and airgun lines were run in Storfjorden Trough. The recording of echo-sounding started from c. 78 °N on the shelf outside Isfjorden and ended at c. 72 °N, with pauses when passing through protected areas of Svalbard (Smeerenburgfjorden and Hinlopen and respecting the 12 nm zone in Storfjorden). The cruise may be known as: CAGE15_7_AMGG

Published

2023

11. Investigation of the molecular mechanisms which contribute to the survival of the polychaete Platynereis spp. under ocean acidification conditions in the CO2 vent system of Ischia Island (Italy)

Author

Signorini, S. G., Munari, M., Cannavacciuolo, A., Nannini, M., Dolfini, D., Chiarore, A., Fare, F., Fontana, M., Caruso, D., Gambi, M. C., and Della Torre, C.

Subjects

CO2 vents, Global and Planetary Change, histone modifications, polychaetes, Mediterranean Sea, ocean acidification, Ocean Engineering, adaptation, metabolomics, Aquatic Science, Oceanography, Water Science and Technology

Abstract

The continuous increase of CO2 emissions in the atmosphere due to anthropogenic activities is one of the most important factors that contribute to Climate Change and generates the phenomenon known as Ocean Acidification (OA). Research conducted at the CO2 vents of Castello Aragonese (Ischia, Italy), which represents a natural laboratory for the study of OA, demonstrated that some organisms, such as polychaetes, thrive under acidified conditions through different adaptation mechanisms. Some functional and ecological traits promoting tolerance to acidification in these organisms have been identified, while the molecular and physiological mechanisms underlying acclimatisation or genetic adaptation are still largely unknown. Therefore, in this study we investigated epigenetic traits, as histone acetylation and methylation, in Platynereis spp. individuals coming from the Castello vent, and from a nearby control site, in two different periods of the year (November-June). Untargeted metabolomics analysis was also carried out in specimens from the two sites. We found a different profile of acetylation of H2B histone in the control site compared to the vent as a function of the sampling period. Metabolomic analysis showed clear separation in the pattern of metabolites in polychaetes from the control site with respect to those from the Castello vent. Specifically, a significant reduction of lipid/sterols and nucleosides was measured in polychaetes from the vent. Overall results contribute to better understand the potential metabolic pathways involved in the tolerance to OA.

Published

2023

12. CAGE13-2 Cruise Report: CAGE, OAFS and Paleo-CIRCUS cruise to Northwest Norway, Jan Mayen and East Greenland

Author

Tine L. Rasmussen, Tove Nielsen, Katarzyna Zamelczyk, and Antoon Kuijpers

Subjects

Norway-East, long cores, surface samples, paleoceanography, CTD and water sampling, ocean acidification, Norway-East Greenland sampling transect

Abstract

From the morning of June 23rd to the morning of July 7th 2013, the Department of Geology of the University of Tromsø, Norway, arranged a scientific cruise aimed at investigating the western Northern Norwegian margin and the central Nordic seas and east Greenland margin| on R/V “Helmer Hanssen”. Investigated areas were (in order of visiting sites on the cruise): the northwestern Norwegian Sea margin to north of Jan Mayen, and the western Greenland Sea north and off Scorebysund. The scientific sampling was done within the framework of ongoing projects at the Department of Geology, University of Tromsø: “CAGE (CoE): Arctic Gas Hydrate, Environment and Climate”, hereunder the projects “OAFS-Ocean Acidification Fram Strait” and “Paleo-CIRCUS”. A total of 12 gravity cores, 5 piston cores and 9 multi-cores (with a total of 27 sub-coresretrieved), 15 plankton net casts and 20 CTD (conductivity-temperature-depth) casts were performed at the western Barents Sea slope, and the Barents Sea. >44 chirp profiles and multibeam echo sounder lines were acquired during transits and during surveys of potential core sites. -4 seismic lines using GI mini airgun The cruise may be known as: CAGE13_OA_PaleoCIRCUS

Published

2023

13. Anthropogenic alterations to the global carbon cycle and climate change

Author

David E. Reichle

Subjects

chemistry.chemical_compound, Ozone, chemistry, Greenhouse gas, Effects of global warming on oceans, Carbon dioxide, Environmental science, Climate change, Ocean acidification, Atmospheric sciences, Greenhouse effect, Carbon cycle

Abstract

The Earth receives a large amount of radiant energy from the sun and about 30% of this energy is reflected. The longer wave infrared radiation does not penetrate back through the atmosphere as efficiently as did the incident radiation. The reflected heat is absorbed by water vapor and carbon dioxide thereby warming the Earth. Anthropogenic activities result in increased atmospheric levels of carbon dioxide (CO2), methane (CH4), ozone (O3), sulfur dioxide (SO2), chlorofluorocarbon (CFC) and nitrogen dioxide (NO2), collectively known as greenhouse gases, causing the Earth to grow warmer. The consequences of the greenhouse effect are evidenced in the rising records of global temperature and atmospheric CO2. Over the past 150 years, atmospheric CO2 concentrations have risen from ∼270 ppm to over 415 ppm today. Resulting changes in carbon chemistry, precipitation, and temperature will lead to largescale adjustments in the distribution of vegetation, global net primary production, agricultural productivity, ocean acidification, ocean warming, and sea level rise.

Published

2023

14. Adaptive strategies of sponges to deoxygenated oceans

Author

Rob McAllen, John R. Turner, Luke Harman, James J. Bell, Valerio Micaroni, Lisa Woods, and Francesca Strano

Subjects

Ocean deoxygenation, Polymastia, Evolution, Hypoxic events, Climate Change, Oceans and Seas, Zoology, Phenotypic plasticity, Climate change, Environmental Chemistry, Seawater, Sessile organisms, General Environmental Science, Oxygen depletion, Global and Planetary Change, Ecology, biology, Eeutrophication, Hypoxia (environmental), Ocean acidification, Eutrophication, Hydrogen-Ion Concentration, biology.organism_classification, Porifera, Dead zones, Sponge, Marine benthic hypoxia, Limiting oxygen concentration, Respiration rate, Suberites

Abstract

Ocean deoxygenation is one of the major consequences of climate change. In coastal waters, this process can be exacerbated by eutrophication, which is contributing to an alarming increase in the so-called "dead zones" globally. Despite its severity, the effect of reduced dissolved oxygen has only been studied for a very limited number of organisms, compared to other climate change impacts such as ocean acidification and warming. Here we experimentally assessed the response of sponges to moderate and severe simulated hypoxic events. We ran three laboratory experiments on four species from two different temperate oceans (NE Atlantic and SW Pacific). Sponges were exposed to a total of five hypoxic treatments, with increasing severity (3.3, 1.6, 0.5, 0.4 and 0.13 mg O2 L-1 , over 7-12-days). We found that sponges are generally very tolerant of hypoxia. All the sponges survived in the experimental conditions, except Polymastia crocea, which showed significant mortality at the lowest oxygen concentration (0.13 mg O2 L-1 , lethal median time: 286 h). In all species except Suberites carnosus, hypoxic conditions do not significantly affect respiration rate down to 0.4 mg O2 L-1 , showing that sponges can uptake oxygen at very low concentrations in the surrounding environment. Importantly, sponges displayed species-specific phenotypic modifications in response to the hypoxic treatments, including physiological, morphological, and behavioural changes. This phenotypic plasticity likely represents an adaptive strategy to live in reduced or low oxygen water. Our results also show that a single sponge species (i.e., Suberites australiensis) can display different strategies at different oxygen concentrations. Compared to other sessile organisms, sponges generally showed higher tolerance to hypoxia, suggesting that sponges could be favoured and survive in future deoxygenated oceans.

Published

2021

15. The primary controls on U/Ca and minor element proxies in a cold-water coral cultured under decoupled carbonate chemistry conditions

Author

Alexander C. Gagnon and Anne M. Gothmann

Subjects

0303 health sciences, 010504 meteorology & atmospheric sciences, Isotope dilution method, Coral, chemistry.chemical_element, Ocean acidification, Calcium, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Paleothermometer, chemistry, Geochemistry and Petrology, Environmental chemistry, Carbonate, Seawater, 14. Life underwater, 030304 developmental biology, 0105 earth and related environmental sciences, Biomineralization

Abstract

Culture experiments are uniquely suited for uncovering the fundamental factors controlling skeletal geochemistry because it is possible to explore conditions beyond what is found in the modern ocean and to decouple parameters that co-vary in nature. We cultured juvenile individuals of a cold-water coral (Balanophyllia elegans) in a set of experiments that decoupled carbonate chemistry parameters over a wide range of pH, DIC, and [CO32−] values. Using a multi-element mixed spike isotope dilution method we then analyzed cultured skeletons for U/Ca, which has been proposed as a potential proxy for seawater pH and [CO32−], as well as Sr/Ca, and Mg/Ca. We find that U/Ca and Sr/Ca ratios in cultured B. elegans are most strongly correlated with solution DIC and not pH or [CO32−]. We also confirm previous observations that Metal/Calcium (Me/Ca) ratios follow the same correlated relationships between and among individuals across different experimental conditions. Interpretation of these robust Me/Ca patterns within the framework of a geochemical model of biomineralization allows us to identify two “rules” of skeletal growth for B. elegans. First, changes in seawater exchange rates can explain variability in B. elegans Me/Ca ratios, correlations between these ratios, and sensitivity of Me/Ca to changes in seawater carbonate chemistry. Second, our model best fits our data if we assume that calcifying fluid pH for B. elegans remains constant across widely varying experimental seawater compositions. Our study has implications for the recently developed Sr-U paleothermometer because it refines our understanding of the environmental parameters affecting this proxy. Our model further demonstrates that U/Ca is not a robust indicator of seawater pH or [CO32−]. Instead, U/Ca may record how calcifying fluid [CO32−] responds to changes in the environment or calcification dynamics, which may be useful in evaluating how corals respond to changes like ocean acidification. Measurements of U/Ca and additional Me/Ca ratios in other coral species, evaluated within a similar framework, may elucidate how those species respond to environmental change.

Published

2021

16. Constraints on coccolithophores under ocean acidification obtained from boron and carbon geochemical approaches

Author

Sebastian D. Rokitta, Yi-Wei Liu, Robert A. Eagle, Björn Rost, Laboratoire des Sciences de l'Environnement Marin (LEMAR) (LEMAR), Institut de Recherche pour le Développement (IRD)-Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER)-Université de Brest (UBO)-Institut Universitaire Européen de la Mer (IUEM), Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Institute of Earth Sciences, Academia Sinica, Taipei, Taiwan, Alfred Wegener Institute for Polar and Marine Research (AWI), ANR-17-EURE-0015,ISBlue,Interdisciplinary Graduate School for the Blue planet(2017), and Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

010504 meteorology & atmospheric sciences, chemistry.chemical_element, 01 natural sciences, Carbon utilization, 03 medical and health sciences, Total inorganic carbon, Geochemistry and Petrology, Dissolved organic carbon, Coccolithophores, Pleurochrysis carterae, 14. Life underwater, 030304 developmental biology, 0105 earth and related environmental sciences, Emiliania huxleyi, 0303 health sciences, biology, Chemistry, Ocean acidification, Carbon isotopes, biology.organism_classification, [SDU]Sciences of the Universe [physics], 13. Climate action, Isotopes of carbon, Environmental chemistry, [SDE]Environmental Sciences, Boron isotopes, Carbon

Abstract

International audience; Ocean acidification (OA) appears to have diverse impacts on calcareous coccolithophores, but the cellular processes underlying these responses are not well understood. Here we use stable boron and carbon isotopes, B/Ca ratios, as well as inorganic and organic carbon production rates to investigate the carbon utilization and the internal pH regulation at the site of calcification in Emiliania huxleyi, Calcidiscus leptoporus and Pleurochrysis carterae cultured over a wide pCO2 range (180–1000 μatm). Despite large variability, the geochemistry data indicate species-specific modes of pH control and differences in the utilization of inorganic carbon. Boron isotope data suggest that all three species generally upregulate the pH of the calcification fluid (pHCF) compared to surrounding seawater, which coincides with relatively constant growth rates and cellular ratios of inorganic to organic carbon. Furthermore, species exhibit different strategies in regulating their pHCF, i.e., two species maintain homeostasis (pHCF = ∼8.7), while one species shows a constant offset to the surrounding seawater (ΔpH = ∼0.6 units) over the entire tested pCO2 range. In addition to these different strategies, carbon isotope data suggests that high plasticity in the utilization of dissolved inorganic carbon might be an explanation for species-specific differences in coccolithophore responses to OA.

Published

2021

17. Ocean acidification causes fundamental changes in the cellular metabolism of the Arctic copepod Calanus glacialis as detected by metabolomic analysis

Author

Peter Thor, Fanny Vermandele, Allison Bailey, Ella Guscelli, Léa Loubet-Sartrou, Sam Dupont, and Piero Calosi

Subjects

Copepoda, Adenosine Triphosphate, Multidisciplinary, Ocean Acidification, Animals, Ketoglutaric Acids, Seawater, Hydrogen-Ion Concentration, Amino Acids

Abstract

Using a targeted metabolomic approach we investigated the effects of low seawater pH on energy metabolism in two late copepodite stages (CIV and CV) of the keystone Arctic copepod species Calanus glacialis. Exposure to decreasing seawater pH (from 8.0 to 7.0) caused increased ATP, ADP and NAD+ and decreased AMP concentrations in stage CIV, and increased ATP and phospho-L-arginine and decreased AMP concentrations in stage CV. Metabolic pathway enrichment analysis showed enrichment of the TCA cycle and a range of amino acid metabolic pathways in both stages. Concentrations of lactate, malate, fumarate and alpha-ketoglutarate (all involved in the TCA cycle) increased in stage CIV, whereas only alpha-ketoglutarate increased in stage CV. Based on the pattern of concentration changes in glucose, pyruvate, TCA cycle metabolites, and free amino acids, we hypothesise that ocean acidification will lead to a shift in energy production from carbohydrate metabolism in the glycolysis toward amino acid metabolism in the TCA cycle and oxidative phosphorylation in stage CIV. In stage CV, concentrations of most of the analysed free fatty acids increased, suggesting in particular that ocean acidification increases the metabolism of stored wax esters in this stage. Moreover, aminoacyl-tRNA biosynthesis was enriched in both stages indicating increased enzyme production to handle low pH stress.

Published

2022

18. Supplementary information for: Extreme original data yield extreme decline effects

Author

Clements, Jeff

Subjects

meta-analysis, decline effect, animal behaviour, fish behaviour, behavioural ecology, ocean acidification

Published

2022

19. Crustose coralline algae display sensitivity to near future global ocean change scenarios

Author

Damon Britton, Christina M. McGraw, Craig Mundy, Fanny Noisette, and Catriona L. Hurd

Subjects

Species complex, Ecology, biology, Effects of global warming on oceans, fungi, Coralline algae, Ocean acidification, Aquatic Science, Oceanography, biology.organism_classification, Algae, parasitic diseases, Environmental science, Crustose, Keystone species, Ecology, Evolution, Behavior and Systematics, Invertebrate

Abstract

Most research investigating how ocean warming and acidification will impact marine species has focused on visually dominant species, such as kelps and corals, while ignoring visually cryptic species such as crustose coralline algae (CCA). CCA are important keystone species that provide settlement cues for invertebrate larvae and can be highly sensitive to global ocean change. However, few studies have assessed how CCA respond to low emission scenarios or conditions. In a laboratory experiment, we examined the responses of temperate CCA assemblages to combined warming and acidification projected under low, medium, and high emissions. Net calcification and net photosynthesis significantly declined in all emissions scenarios, while significant reductions in relative growth rates and increases in percentage bleaching were observed in the highest emission scenario. The negative responses of CCA to both low and medium emissions suggest that they may be adversely impacted by combined warming and acidification by 2030 if current emissions are sustained. This will have far reaching consequences for commercially important invertebrates that rely on them to induce settlement of larvae. These findings highlight the need to take rapid action to preserve these critical keystone species and the valuable services they provide.

Published

2021

20. Experimentally decomposing phytoplankton community change into ecological and evolutionary contributions

Author

Luisa Listmann, Lynn Govaert, Birte Matthiessen, Giannina S. I. Hattich, Thorsten B. H. Reusch, and Christian Pansch

Subjects

SELECTION, DYNAMICS, 0106 biological sciences, 010504 meteorology & atmospheric sciences, Environmental change, DIVERSITY, Community change, Environmental Sciences & Ecology, Biology, 010603 evolutionary biology, 01 natural sciences, RAPID EVOLUTION, Phytoplankton, skin and connective tissue diseases, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Science & Technology, relative contribution, Ecology, partitioning metrics, OCEAN ACIDIFICATION, Ocean acidification, eco-evolutionary shifts, environmental change, 15. Life on land, community change, interspecific diversity, MARINE-PHYTOPLANKTON, 13. Climate action, intraspecific diversity, CO2, BIODIVERSITY, sense organs, Life Sciences & Biomedicine, RESPONSES

Abstract

Shifts in microbial communities and their functioning in response to environmental change result from contemporary interspecific and intraspecific diversity changes. Interspecific changes are driven by ecological shifts in species composition, while intraspecific changes are here assumed to be dominated by evolutionary shifts in genotype frequency. Quantifying the relative contributions of interspecific and intraspecific diversity shifts to community change thus addresses the essential, yet understudied question as to how important ecological and evolutionary contributions are to total community changes. This debate is to date practically constrained by (a) a lack of studies integrating across organizational levels and (b) a mismatch between data requirements of existing partitioning metrics and the feasibility to collect such data, especially in microscopic organisms like phytoplankton. We experimentally assessed the relative ecological and evolutionary contributions to total phytoplankton community changes using a new design and validated its functionality by comparisons to established partitioning metrics. We used a community of coexisting Emiliania huxleyi and Chaetoceros affinis with initially nine genotypes each. First, we exposed the community to elevated CO2 concentration for 80 days (~50 generations) to induce interspecific and intraspecific diversity changes and a total abundance change. Second, we independently manipulated the induced interspecific and intraspecific diversity changes in an assay to quantify the corresponding ecological and evolutionary contributions to the total change. Third, we applied existing partitioning metrics to our experimental data and compared the outcomes. Total phytoplankton abundance declined to one-fifth in the high CO2 exposed community compared to ambient conditions. Consistently across all applied partitioning metrics, the abundance decline could predominantly be explained by ecological shifts and to a low extent by evolutionary changes. We discuss potential consequences of the observed community changes on ecosystem functioning. Furthermore, we explain that the low evolutionary contributions likely resulted of intraspecific diversity changes that occurred irrespectively of CO2. We discuss how the assay could be upscaled to more realistic settings, including more species and drivers. Overall, the presented calculations of eco-evolutionary contributions to phytoplankton community changes constitute another important step towards understanding future phytoplankton shifts, and eco-evolutionary dynamics in general.

Published

2021

21. Fluctuaciones del pH, alcalinidad, oxígeno disuelto y nutriente en Cayos Miskitos, municipio de Puerto Cabezas, Región Autónoma del Atlántico Norte (RAAN)

Author

Yader Santiago Caballero Arbizú

Subjects

Alkalinity, Climate change, Ocean acidification, General Medicine, Normal values, chemistry.chemical_compound, Nutrient, chemistry, 2409 Análisis fisicoquímico, Environmental chemistry, Carbon dioxide, Environmental science, Seawater, Calcareous, 3107 Características fisicoquímicas del agua

Abstract

La acidificación de océanos es el descenso del pH causado por la absorción del dióxido de carbono antropogénico producido por la combustión de combustibles fósiles, entre otras actividades humanas, aumentando la acidez del agua y disminuyendo la disponibilidad de los carbonatos, lo que amenaza la supervivencia de especies marinas calcáreas: corales, ostras, cangrejos y langostas, entre otros. Estos efectos constituyen una amenaza en el Caribe de Nicaragua, por lo que se realizó un monitoreo de parámetros físico-químicos del agua en Cayos Miskitos (Puerto Cabezas, Región Autónoma del Atlántico Norte, RAAN) en julio, septiembre y noviembre del 2018; febrero y marzo del 2019. Los muestreos se realizaron con la colaboración de técnicos de IREMADES-URACCAN. Los parámetros físicos – químicos medidos fueron: pH, alcalinidad total, oxígeno disuelto y nutrientes; se analizaron por métodos estándares. El pH presentó valores normales para el agua de mar (8,05 y 8,19 unidades de pH), mientras la alcalinidad mostró valores ligeramente por encima de los valores típicos del agua del mar (118 a 124 mg/l-1 como CaCO3). Las concentraciones del NTD en todos los sitios muestreados representaron aproximadamente el 50% de las concentraciones del NT, mientras la presencia del FT, FTD y FRD se debe al fenómeno del afloramiento a la superficie de aguas más profundas. Estos resultados destacan la importancia de estudiar el pH y la alcalinidad para conocer su impacto en la evolución de la acidificación del océano y sus efectos para apoyar políticas tendientes a mitigar los fenómenos de calentamiento y adaptación al cambio climático.

Published

2021

22. Simulated ocean acidification altered community composition and growth of a coastal phytoplankton assemblage (South West coast of India, eastern Arabian Sea)

Author

Haimanti Biswas, Debasmita Bandyopadhyay, and Diksha Sharma

Subjects

Diatoms, Total organic carbon, Cyanobacteria, biology, Oceans and Seas, Health, Toxicology and Mutagenesis, fungi, Ocean acidification, General Medicine, Carbon Dioxide, Hydrogen-Ion Concentration, biology.organism_classification, Pollution, Oceanography, Algae, Navicula, Phytoplankton, Environmental Chemistry, Environmental science, Seawater, Microcosm, Trophic level

Abstract

Marine phytoplankton can be highly sensitive to ocean acidification; however, their responses are diverse and therefore, phytoplankton response study on the regional scale is of high research priority. The present study documented the community shift and growth responses of a natural phytoplankton assemblage from the South West coastal water of India (South Eastern Arabian Sea) under ambient CO2 (A-CO2 ≈ 400 µatm) and high CO2 (H-CO2 ≈ 830 µatm) levels in microcosms during the winter monsoon. A doubling of pCO2 resulted in increased cell density, particulate organic carbon and nitrogen (POC, PON) contents, and C:N ratios. The depleted values of δ13CPOC in the H-CO2-incubated cells indicated a higher diffusive CO2 influx. HPLC marker pigment analysis revealed that the community was microphytoplankton dominated (mostly diatoms); nanoplanktonic prymnesiophytic algae and picoplanktonic cyanobacteria showed insignificant response to the simulated ocean acidification. A high CO2-induced increased growth rate was noticed in 6 diatoms (Leptocylindrus danicus; Rhizosolenia setigera; Navicula sp., Asterionella glacialis, Dactyliosolen fragilissimus, and Thalassiosira sp.). The cell volumes of Thalassionema frauenfeldii, Asterionella glacialis, and Cylindrotheca closterium increased significantly, whereas Rhizosolenia setigera and Thalassiosira sp. showed decreased cell volume at the elevated CO2 levels. These changes in growth rate, cell volume, and elemental stoichiometry could be related to CO2 acquisition and the nutritional status of the cells. Some phytoplankton genera from this region are probably acclimatized to pCO2 fluctuations and are likely to benefit from the future increase in CO2 levels. Higher POC production and increased C:N ratio along with variable cell volume may impact the trophic transfer and cycling of organic carbon in this coastal water. However, a multi-stressor approach in a longer experimental exposure should be considered in future research.

Published

2021

23. Climate cascades affect coastal Antarctic seafloor ecosystem functioning

Author

Vonda J. Cummings, Simon F. Thrush, Alf Norkko, and Andrew M. Lohrer

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Climate, Antarctic Regions, 01 natural sciences, Benthos, Phytoplankton, Sea ice, Environmental Chemistry, Ice Cover, Ecosystem, 14. Life underwater, 0105 earth and related environmental sciences, General Environmental Science, Global and Planetary Change, geography, geography.geographical_feature_category, Ecology, Chlorophyll A, 010604 marine biology & hydrobiology, Ocean acidification, 15. Life on land, Seafloor spreading, Oceanography, 13. Climate action, Benthic zone, Environmental science, Antarctic oscillation

Abstract

Polar seafloor ecosystems are changing rapidly and dramatically, challenging previously held paradigms of extreme dynamical stability. Warming-related declines in polar sea ice are expected to alter fluxes of phytoplankton and under-ice algae to the seafloor. Yet, how changes in food flux cascade through to seafloor communities and functions remains unclear. We leveraged natural spatial and temporal gradients in summertime sea ice extent to better understand the trajectories and implications of climate-related change in McMurdo Sound, Antarctica. McMurdo Sound was expected to be one of the last coastal marine environments on Earth to be affected by planetary warming, but the situation may be changing. Comparing satellite observations of selected coastal sites in McMurdo Sound between 2010-2017 and 2002-2009 revealed more ice-free days per year, and shorter distances to open water during the warmest months each year, in the more recent period. Interdecadal Pacific Oscillation (IPO), Oceanic Niño Index (ONI) and Antarctic Oscillation (AAO) climate indices peaked concurrently between 2014 and 2017 when sea ice breakouts in McMurdo Sound were most spatially and temporally extensive. Increases in sediment chlorophyll a and phaeophytin content (indicating increased deposition of detrital algal food material) were recorded during 2014-2017 at three coastal study sites in McMurdo Sound following the major sea ice breakouts. Soft-sediment seafloor ecosystem metabolism (measured in benthic incubation chambers as dissolved oxygen and inorganic nutrient fluxes) was correlated with sediment algal pigment concentration. Epifaunal invertebrate density, particularly opportunistic sessile suspension feeders, and infaunal community composition also shifted with increased food supply. The ecological characteristics and functions measured at the food-poor sites shifted towards those observed at richer sites at a surprisingly fast pace. These results indicate the sensitivity of the benthos and shed light on Antarctic marine trophic cascades and trajectories of response of iconic high-latitude seafloor habitats to a warming climate.

Published

2021

24. The regulatory role of GABAA receptor in Actinia equina nervous system and the possible effect of global ocean acidification

Author

S. M. Snigirov and Sergiy Sylantyev

Subjects

Agonist, 0303 health sciences, Startle response, medicine.diagnostic_test, biology, Physiology, Chemistry, medicine.drug_class, GABAA receptor, Clinical Biochemistry, Allosteric regulation, Context (language use), Ocean acidification, biology.organism_classification, 03 medical and health sciences, 0302 clinical medicine, Physiology (medical), Anthozoa, medicine, 14. Life underwater, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology, Actinia

Abstract

Global warming and connected acidification of the world ocean attract a substantial amount of research efforts, in particular in a context of their impact on behaviour and metabolism of marine organisms, such as Cnidaria. Nevertheless, mechanisms underlying Cnidarians’ neural signalling and behaviour and their (possible) alterations due to the world ocean acidification remain poorly understood. Here we researched for the first time modulation of GABAA receptors (GABAARs) in Actinia equina (Cnidaria: Anthozoa) by pH fluctuations within a range predicted by the world ocean acidification scenarios for the next 80–100 years and by selective pharmacological activation. We found that in line with earlier studies on vertebrates, both changes of pH and activation of GABAARs with a selective allosteric agonist (diazepam) modulate electrical charge transfer through GABAAR and the whole-cell excitability. On top of that, diazepam modifies the animal behavioural reaction on startle response. However, despite behavioural reactions displayed by living animals are controlled by GABAARs, changes of pH do not alter them significantly. Possible mechanisms underlying the species resistance to acidification impact are discussed.

Published

2021

25. Nitrous oxide and methane in a changing Arctic Ocean

Author

Andrew P. Rees, Carol Turley, Ian Brown, Glen A. Tarran, Damian L. Arevalo-Martinez, Yuri Artioli, Vassilis Kitidis, Hanna I. Campen, Gennadi Lessin, Dawn M. Ashby, Hermann W. Bange, and Darren R. Clark

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Environmental change, Oceans and Seas, Earth science, Geography, Planning and Development, 01 natural sciences, Methane, Atmosphere, chemistry.chemical_compound, Arctic Ocean, Sea ice, Ice retreat, Humans, Environmental Chemistry, Seawater, 0105 earth and related environmental sciences, geography, Nitrous oxide, geography.geographical_feature_category, Ecology, Arctic Regions, Ocean acidification, 010604 marine biology & hydrobiology, General Medicine, Hydrogen-Ion Concentration, Trace gas, chemistry, Arctic, 13. Climate action, Environmental science, Changing Arctic Ocean, Warming

Abstract

Human activities are changing the Arctic environment at an unprecedented rate resulting in rapid warming, freshening, sea ice retreat and ocean acidification of the Arctic Ocean. Trace gases such as nitrous oxide (N2O) and methane (CH4) play important roles in both the atmospheric reactivity and radiative budget of the Arctic and thus have a high potential to influence the region’s climate. However, little is known about how these rapid physical and chemical changes will impact the emissions of major climate-relevant trace gases from the Arctic Ocean. The combined consequences of these stressors present a complex combination of environmental changes which might impact on trace gas production and their subsequent release to the Arctic atmosphere. Here we present our current understanding of nitrous oxide and methane cycling in the Arctic Ocean and its relevance for regional and global atmosphere and climate and offer our thoughts on how this might change over coming decades. Supplementary Information The online version contains supplementary material available at 10.1007/s13280-021-01633-8.

Published

2021

26. Abundances and morphotypes of the coccolithophore Emiliania huxleyi in southern Patagonia compared to neighbouring oceans and Northern Hemisphere fjords

Author

F. Díaz-Rosas, C. Alves-de-Souza, E. Alarcón, E. Menschel, H. E. González, R. Torres, and P. von Dassow

Subjects

Ecological niche, QE1-996.5, geography, geography.geographical_feature_category, Ecology, biology, Coccolithophore, Range (biology), Geology, Fjord, Ocean acidification, biology.organism_classification, Oceanography, Diatom, Life, QH501-531, Realized niche width, QH540-549.5, Ecology, Evolution, Behavior and Systematics, Earth-Surface Processes, Emiliania huxleyi

Abstract

Coccolithophores are potentially affected by ongoing ocean acidification, where rising CO2 lowers seawater pH and calcite saturation state (Ωcal). Southern Patagonian fjords and channels provide natural laboratories for studying these issues due to high variability in physical and chemical conditions. We surveyed coccolithophore assemblages in Patagonian fjords during late spring 2015 and early spring 2017. Surface Ωcal exhibited large variations driven mostly by freshwater inputs. High-Ωcal conditions (max. 3.6) occurred in the Archipelago Madre de Dios. Ωcal ranged from 2.0–2.6 in the western Strait of Magellan and 1.5–2.2 in the inner channel and was subsaturating (0.5) in Skyring Sound. Emiliania huxleyi was the only coccolithophore widely distributed in Patagonian fjords (> 96 % of total coccolithophores), only disappearing in the Skyring Sound, a semi-closed mesohaline system. Correspondence analysis associated higher E. huxleyi biomasses with lower diatom biomasses. The highest E. huxleyi abundances in Patagonia were in the lower range of those reported in Norwegian fjords. Predominant morphotypes were distinct from those previously documented in nearby oceans but similar to those of Norwegian fjords. Moderately calcified forms of E. huxleyi A morphotype were uniformly distributed throughout Patagonia fjords. The exceptional R/hyper-calcified coccoliths, associated with low Ωcal values in Chilean and Peruvian coastal upwellings, were a minor component associated with high Ωcal levels in Patagonia. Outlying mean index (OMI) niche analysis suggested that pH and Ωcal conditions explained most variation in the realized niches of E. huxleyi morphotypes. The moderately calcified A morphotype exhibited the widest niche breadth (generalist), while the R/hyper-calcified morphotype exhibited a more restricted realized niche (specialist). Nevertheless, when considering an expanded sampling domain, including nearby southeast Pacific coastal and offshore waters, even the R/hyper-calcified morphotype exhibited a higher niche breadth than other closely phylogenetically related coccolithophore species. The occurrence of E. huxleyi in naturally low pH–Ωcal environments indicates that its ecological response is plastic and capable of adaptation.

Published

2021

27. Effects of thermal history on the responses to thermal stress of a large benthic foraminifera, Calcarina gaudichaudii

Author

Tung-Yung Fan, Vianney Denis, Gaby E. Carpenter, and Steve S. Doo

Subjects

geography, geography.geographical_feature_category, Ecology, Effects of global warming on oceans, fungi, Hypoxia (environmental), Ocean acidification, Coral reef, Aquatic Science, Acclimatization, Benthic zone, Environmental science, Marine ecosystem, Reef

Abstract

Marine ecosystems, particularly coastal environments, are rapidly changing due to anthropogenic impacts resulting in increased global climate change (ocean warming), ocean acidification, hypoxia, and eutrophication. On coral reefs, symbiont-bearing large benthic foraminifera (LBFs) can play a key role as reef constituents and carbonate producers, contributing up to 5% of reef-scale carbonate budgets. However, projected climate change, particularly ocean warming, has the potential to significantly alter the conditions in which marine organisms persist. While the response of LBFs to elevated thermal stress is well documented in laboratory studies, the potential influence of adaptation or acclimatization through prior environmental thermal history on this response remains largely unknown. In this study, specimens of Calcarina gaudichaudii, an LBF from the Penghu Islands, Taiwan, were collected from thermally variable intertidal and thermally stable subtidal (~ 6 m depth) environments representing thermal history. LBFs were then acclimated to laboratory conditions at ambient (25 °C) and elevated (28 °C) temperatures for three weeks, and subsequently exposed to control and heat stress treatments (25 °C, 28 °C, 30 °C, 33 °C) for an additional one week. Photosynthetic rates (determined through oxygen flux measurements) of C. gaudichaudii significantly decreased in specimens collected at subtidal depths acclimated at 25 °C when compared to those acclimated at 28 °C, whereas there was no effect of thermal history on respiration, indicating that symbiont and holobiont responses may differ in LBFs. Additionally, maximum photochemical efficiency (Fv/Fm) significantly decreased as a result of heat stress, although bleaching was not visually observed after one week. These results highlight the plastic responses of the algal microbiome and indicate that thermal history, acclimatization temperature, and heat stress interact to affect the physiological status of C. gaudichaudii. This study adds to the growing literature which highlights the larger implications of understanding thermal history as an important factor to consider to better understand how ecosystem processes (e.g., carbonate production) are altered on modern coral reefs.

Published

2021

28. Temporal and Spatial Variabilities of Chemical and Physical Parameters on the Heron Island Coral Reef Platform

Author

Bradley D. Eyre, Theodor Kindeberg, Andreas J. Andersson, Samuel A. H. Kekuewa, Travis A. Courtney, Laura Stoltenberg, and Tyler Cyronak

Subjects

Biogeochemical cycle, geography, Geophysics, Oceanography, geography.geographical_feature_category, Habitat, Geochemistry and Petrology, Benthic zone, Effects of global warming on oceans, Ocean acidification, Seawater, Coral reef, Reef

Abstract

Globally, coral reefs are threatened by ocean warming and acidification. The degree to which acidification will impact reefs is dependent on the local hydrodynamics, benthic community composition, and biogeochemical processes, all of which vary on different temporal and spatial scales. Characterizing the natural spatiotemporal variability of seawater carbonate chemistry across different reefs is critical for elucidating future impacts on coral reefs. To date, most studies have focused on select habitats, whereas fewer studies have focused on reef scale variability. Here, we investigate the temporal and spatial seawater physicochemical variability across the entire Heron Island coral reef platform, Great Barrier Reef, Australia, for a limited duration of six days. Autonomous sensor measurements at three sites across the platform were complemented by reef-wide boat surveys and discrete sampling of seawater carbonate chemistry during the morning and evening. Variability in both temporal and spatial physicochemical properties were predominantly driven by solar irradiance (and its effect on biological activity) and the semidiurnal tidal cycles but were influenced by the local geomorphology resulting in isolation of the platform during low tide and rapid flooding during rising tides. As a result, seawater from previous tidal cycles was sometimes trapped in different parts of the reef leading to unexpected biogeochemical trends in space and time. This study illustrates the differences and limitations of data obtained from high-frequency measurements in a few locations compared to low-frequency measurements at high spatial resolution and coverage, showing the need for a combined approach to develop predictive capability of seawater physicochemical properties on coral reefs.

Published

2021

29. Heterogeneity around CO2 vents obscures the effects of ocean acidification on shallow reef communities

Author

Craig A. Radford, Nick T. Shears, Caitlin O. Blain, Sara Kulins, and Mary A. Sewell

Subjects

geography, geography.geographical_feature_category, Oceanography, Ecology, Environmental science, Ocean acidification, Aquatic Science, Reef, Ecology, Evolution, Behavior and Systematics

Abstract

Studies that use CO2 vents as natural laboratories to investigate the impacts of ocean acidification (OA) typically employ control-impact designs or local-scale gradients in pH or pCO2, where impacted sites are compared to reference sites. While these strategies can accurately represent well-defined and stable vent systems in relatively homogenous environments, it may not adequately encompass the natural variability of heterogeneous coastal environments where many CO2 vents exist. Here, we assess the influence of spatial heterogeneity on the perceived impacts of OA at a vent system well established in the OA literature. Specifically, we use a multi-scale approach to investigate and map the spatial variability in seawater pH and benthic communities surrounding vents at Whakaari-White Island, New Zealand to better understand the scale and complexity of ecological impacts of an acidified environment. We found a network of vents embedded in complex topography throughout the study area, and spatially variable pH and pCO2 levels. The distribution of habitats (i.e. macroalgal forests and turfing algae) was most strongly related to substratum type and sea urchin densities, rather than pH. Epifaunal communities within turfing algae differed with sampling distance from vents, but this pattern was driven by higher abundances of a number of taxa immediately adjacent to vents, where pH and temperature gradients are steep and white bacterial mats are prevalent. Our results contrast with previous studies at White Island that have used a control-impact design and suggested significant impacts of elevated CO2 on benthic communities. Instead, we demonstrate a highly heterogeneous reef where it is difficult to separate effects of reduced pH from spatial variation in reef communities. We urge that future research carefully considers and quantifies the biological and physical complexity of venting environments, and suggest that in dynamic systems, such as White Island, the use of control-impact designs can oversimplify and potentially overestimate the future impacts of OA.

Published

2021

30. Low irradiance amplifies negative effects of ocean acidification on recruitment of coralline algae communities

Author

Lamare, Wendy A. Nelson, Anna Kluibenschedl, NG Barr, and Christopher D. Hepburn

Subjects

Oceanography, Ecology, biology, Irradiance, Environmental science, Coralline algae, Ocean acidification, Aquatic Science, Turbidity, biology.organism_classification, Ecology, Evolution, Behavior and Systematics

Abstract

Coralline algae play foundational roles in coastal ecosystems and are globally significant components of benthic habitats down to the limits of the photic zone. Despite their vulnerability to ocean acidification (OA) and importance in low light environments, there is a limited understanding of how the interplay between irradiance and OA influences coralline reproduction and recruitment. To better understand this interaction, a 212 d experiment was run exposing coralline communities to 2 pH levels (present-day pH 8.03, OA pH 7.65) and a gradient of daily light dose (0.35, 0.17 and 0.1 mol m-2 d-1), based on in situ measurements. In the highest light dose treatment, lowered seawater pH projected for 2100 (pH(T) 7.65) reduced recruitment by 56%. This OA-driven reduction in recruitment was amplified under reduced light, with recruitment near zero in the lowest light treatment. This study shows, for the first time, the increased vulnerability of coralline community recruitment to OA under low light. Coralline algae are known to be the deepest growing macroalgae and thus, in these low light zones, OA may have the potential to reduce coralline depth distribution.

Published

2021

31. Stimulation of N 2 O emission via bacterial denitrification driven by acidification in estuarine sediments

Author

Teng Wen, Xi-Mei Xue, Li Cui, Yingmu Wang, Yong-Guan Zhu, Junshi Xu, Kai Ding, Yijia Tang, Xiaoxuan Su, and Jinbo Zhang

Subjects

Abiotic component, Global and Planetary Change, Denitrification, Ecology, Reactive nitrogen, Chemistry, Ocean acidification, Nitrous oxide, Anoxic waters, Isotopes of nitrogen, chemistry.chemical_compound, Microbial population biology, Environmental chemistry, Environmental Chemistry, General Environmental Science

Abstract

Ocean acidification in nitrogen-enriched estuaries has raised global concerns. For decades, biotic and abiotic denitrification in estuarine sediments has been regarded as the major ways to remove reactive nitrogen, but they occur at the expense of releasing greenhouse gas nitrous oxide (N2 O). However, how these pathways respond to acidification remains poorly understood. Here we performed a N2 O isotopocules analysis coupled with respiration inhibition and molecular approaches to investigate the impacts of acidification on bacterial, fungal, and chemo-denitrification, as well as N2 O emission, in estuarine sediments through a series of anoxic incubations. Results showed that acidification stimulated N2 O release from sediments, which was mainly mediated by the activity of bacterial denitrifiers, whereas in neutral environments, N2 O production was dominated by fungi. We also found that the contribution of chemo-denitrification to N2 O production cannot be ignored, but was not significantly affected by acidification. The mechanistic investigation further demonstrated that acidification changed the keystone taxa of sedimentary denitrifiers from N2 O-reducing to N2 O-producing ones and reduced microbial electron-transfer efficiency during denitrification. These findings provide novel insights into how acidification stimulates N2 O emission and modulates its pathways in estuarine sediments, and how it may contribute to the acceleration of global climate change in the Anthropocene.

Published

2021

32. Capacity Building to Address Ocean Change: Organizing Across Communities of Place, Practice and Governance to Achieve Ocean Acidification and Hypoxia Resilience in Oregon

Author

Charlotte Regula Whitefield, Caren E. Braby, and John A. Barth

Subjects

Corporate governance, Hypoxia (environmental), Capacity building, Ocean acidification, Atmosphere, chemistry.chemical_compound, chemistry, Environmental protection, Greenhouse gas, Carbon dioxide, Environmental Chemistry, Environmental science, Resilience (network), General Environmental Science

Abstract

Fossil fuel combustion and related accumulation of carbon dioxide (CO2) and other greenhouse gases in the atmosphere and oceans have contributed significantly to climate and ocean change. While coa...

Published

2021

33. Introduction to Coastal Management Journal Special Issue on Ocean Acidification

Author

Jessie Turner and Eric Laschever

Subjects

Oceanography, chemistry, Greenhouse gas, Atmospheric carbon cycle, Environmental Chemistry, chemistry.chemical_element, Environmental science, Seawater, Ocean acidification, Coastal management, Carbon, General Environmental Science

Abstract

Anthropogenic carbon emissions are increasing atmospheric carbon concentrations. Global oceans absorb about one-fourth of these emissions each year (Friedlingstein et al., 2020). Seawater’s carbon ...

Published

2021

34. Corals adapted to extreme and fluctuating seawater pH increase calcification rates and have unique symbiont communities

Author

Clément Tanvet, Emma Camp, Jill Sutton, Fanny Houlbreque, Gérard Thouzeau, Riccardo Rodolfo-Metalpa, Laboratoire des Sciences de l'Environnement Marin (LEMAR) (LEMAR), Institut de Recherche pour le Développement (IRD)-Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER)-Université de Brest (UBO)-Institut Universitaire Européen de la Mer (IUEM), Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Ecologie marine tropicale dans les Océans Pacifique et Indien (ENTROPIE [Réunion]), Institut de Recherche pour le Développement (IRD)-Université de La Réunion (UR)-Centre National de la Recherche Scientifique (CNRS), CNRS (MITI interdisciplinary programs), and ANR-17-EURE-0015,ISBlue,Interdisciplinary Graduate School for the Blue planet(2017)

Subjects

calcification, natural analogue, New Caledonia, Symbiodiniaceae, [SDV]Life Sciences [q-bio], Bourake, physiology, ocean acidification, adaptation, coral

Abstract

Ocean acidification (OA) is a severe threat to coral reefs mainly by reducing their calcification rate. Identifying the resilience factors of corals to decreasing seawater pH is of paramount importance to predict the survivability of coral reefs in the future. This study compared corals adapted to variable pHT (i.e., 7.23–8.06) from the semi-enclosed lagoon of Bouraké, New Caledonia, to corals adapted to more stable seawater pHT (i.e., 7.90–8.18). In a 100-day aquarium experiment, we examined the physiological response and genetic diversity of Symbiodiniaceae from three coral species (Acropora tenuis, Montipora digitata, and Porites sp.) from both sites under three stable pHNBS conditions (8.11, 7.76, 7.54) and one fluctuating pHNBS regime (between 7.56 and 8.07). Bouraké corals consistently exhibited higher growth rates than corals from the stable pH environment. Interestingly, A. tenuis from Bouraké showed the highest growth rate under the 7.76 pHNBS condition, whereas for M. digitata, and Porites sp. from Bouraké, growth was highest under the fluctuating regime and the 8.11 pHNBS conditions, respectively. While OA generally decreased coral calcification by ca. 16%, Bouraké corals showed higher growth rates than corals from the stable pH environment (21% increase for A. tenuis to 93% for M. digitata, with all pH conditions pooled). This superior performance coincided with divergent symbiont communities that were more homogenous for Bouraké corals. Corals adapted to variable pH conditions appear to have a better capacity to calcify under reduced pH compared to corals native to more stable pH condition. This response was not gained by corals from the more stable environment exposed to variable pH during the 100-day experiment, suggesting that long-term exposure to pH fluctuations and/or differences in symbiont communities benefit calcification under OA.

Published

2022

35. Advancing real-time pH sensing capabilities to monitor coastal acidification as measured in a productive and dynamic estuary (Ría de Arousa, NW Spain)

Author

Anton Velo, Xose Antonio Padin, Ministerio de Transición Ecológica (España), European Commission, and Interreg VA España-Portugal POCTEP

Subjects

Ría de Arousa, upwelling, IoT, Global and Planetary Change, aquaculture, coastal waters, Durafet, SIGFOX, ocean acidification, Ocean Engineering, Aquatic Science, Oceanography, Water Science and Technology

Abstract

18 pages, 9 figures.-- This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY), Ocean acidification has critical impacts on marine ecosystems, but presents knowledge gaps on the ecological impacts requiring large-scale monitoring of physicochemical conditions to predict biological responses to ocean pH projections. The threat is especially significant in coastal regions like upwelling areas which are more sensitive and appear to respond more rapidly to anthropogenic perturbations. These ecosystems, such as the northwest coast of the Iberian Peninsula are characterized by complex physical and biogeochemical interactions, supporting enormous biological productivity and productive fisheries. The distribution of pH in upwelling systems has high variability on short temporal and spatial scales preventing a complete picture of acidification, which exhibit long-term pH rates markedly different from the measured in open waters. This motivation to significantly expand the coverage of pH monitoring in coastal areas has driven us to develop an autonomous pH monitoring instrument (from now on SURCOM) based on the Honeywell Durafet® pH electrode. A relevant feature is that SURCOM transmits near real-time pH and temperature measurements every 10.5 min through SIGFOX®, a low-power, low-bandwidth network for data transmission. This very careful design allows us to achieve a very low power consumption for the complete system resulting in 3 years of full autonomy with no other need than external cleaning and calibration. In this paper we describe the setup and the data set obtained by a SURCOM instrument over 240 days in a highly productive and dynamic coastal ecosystem, the Rıá de Arousa embayment, providing valuable information on the performance of these low-cost and highly stable sensors, with potential for improving the pH variability description in nearshore systems and for reinforcing the monitoring-modeling of coastal acidification, Funding for AV was received from AtlAzul (0755_ATLAZUL_6_E) co-funded by the INTERREG V-A Spain-Portugal Cooperation Program (POCTEP) 2014-2020. Funding for XP comes from Observatorio TIAMAT project (2715-2021) funded by the Autonomous Agency of National Parks of the Ministry for Ecological Transition and Demographic Challenge. This work has also been supported from the MarRISK project (0262_MarRISK_1_E) co-funded by INTERREG V-A Spain-Portugal Cooperation Program (POCTEP) 2014-2020 and from the European Union’s Horizon 2020 research and innovation programme under grant agreement no. 820989 (COMFORT). This work was also contributed by WATER:iOS CSIC PTI

Published

2022

36. Photorespiration in eelgrass (Zostera marina L.): A photoprotection mechanism for survival in a CO2-limited world

Author

Billur Celebi-Ergin, Richard C. Zimmerman, Victoria J. Hill, Ergin, Billur Çelebi (ORCID 0000-0002-9949-1617 & YÖK ID 261792), Zimmerman, Richard C. C., Hill, Victoria J. J., College of Sciences, and Department of Molecular Biology and Genetics

Subjects

CO2, Non-photochemical quenching, Ocean acidification, Photorespiration, Photosynthesis, Quantum yield, Seagrass, Plant Science, Plant sciences

Abstract

Photorespiration, commonly viewed as a loss in photosynthetic productivity of C3 plants, is expected to decline with increasing atmospheric CO2, even though photorespiration plays an important role in the oxidative stress responses. This study aimed to quantify the role of photorespiration and alternative photoprotection mechanisms in Zostera marina L. (eelgrass), a carbon-limited marine C3 plant, in response to ocean acidification. Plants were grown in controlled outdoor aquaria at different [CO2]aq ranging from ~55 (ambient) to ~2121 ?M for 13 months and compared for differences in leaf photochemistry by simultaneous measurements of O2 flux and variable fluorescence. At ambient [CO2], photosynthesis was carbon limited and the excess photon absorption was diverted both to photorespiration and non-photochemical quenching (NPQ). The dynamic range of NPQ regulation in ambient grown plants, in response to instantaneous changes in [CO2]aq, suggested considerable tolerance for fluctuating environmental conditions. However, 60 to 80% of maximum photosynthetic capacity of ambient plants was diverted to photorespiration resulting in limited carbon fixation. The photosynthesis to respiration ratio (PE : RD) of ambient grown plants increased 6-fold when measured under high CO2 because photorespiration was virtually suppressed. Plants acclimated to high CO2 maintained 4-fold higher PE : RD than ambient grown plants as a result of a 60% reduction in photorespiration. The O2 production efficiency per unit chlorophyll was not affected by the CO2 environment in which the plants were grown. Yet, CO2 enrichment decreased the light level to initiate NPQ activity and downregulated the biomass specific pigment content by 50% and area specific pigment content by 30%. Thus, phenotypic acclimation to ocean carbonation in eelgrass, indicating the coupling between the regulation of photosynthetic structure and metabolic carbon demands, involved the downregulation of light harvesting by the photosynthetic apparatus, a reduction in the role of photorespiration and an increase in the role of NPQ in photoprotection. The quasi-mechanistic model developed in this study permits integration of photosynthetic and morphological acclimation to ocean carbonation into seagrass productivity models, by adjusting the limits of the photosynthetic parameters based on substrate availability and physiological capacity., Financial support for this research was provided by the National Science Foundation (Award OCE-1061823 to RZ and VH), Virginia Sea Grant/NOAA (Award NA14OAR4170093 to RZ and BC-E) and the Department of Ocean, Earth & Atmospheric Sciences, Old Dominion University (to BC-E). This research was performed in partial completion of the requirements for the Ph.D. degree (Oceanography) at Old Dominion University.

Published

2022

37. CAGE21-2 Cruise Report: Planktic foraminifera sampling for culturing experiments, central Greenland Sea 75°N

Author

Mohamed Ezat, Julie Meilland, Adele Westgård, Thomas Chalk, Tine L. Rasmussen, Naima El Bani Altuna, and Christine Lockwood-Ireland

Subjects

proxy calibrations, planktic foraminifera, ocean acidification, Greenland Sea

Abstract

From the morning of June 28th to the morning of July 3rd 2021, the Department of Geosciences at UiT The Arctic University of Norway, arranged a scientific cruise on R/V “Helmer Hanssen aimed at sampling living planktic foraminifera (primarily Neogloboquadrina pachyderma) for culturing experiments both onboard and continued at the culturing laboratory at the Department. The purpose is to investigate the physiological and calcification responses of this species to a wide range of temperature, salinity and carbonate chemistry as well as to establish proxy calibration for paleoceanographic reconstructions. The cruise may be known as: CAGE21_2

Published

2022

38. Ocean acidification research in the Mediterranean Sea: Status, trends and next steps

Author

Abed El Rahman Hassoun, Ashley Bantelman, Donata Canu, Steeve Comeau, Charles Galdies, Jean-Pierre Gattuso, Michele Giani, Michaël Grelaud, Iris Eline Hendriks, Valeria Ibello, Mohammed Idrissi, Evangelia Krasakopoulou, Nayrah Shaltout, Cosimo Solidoro, Peter W. Swarzenski, Patrizia Ziveri, Principality of Monaco, International Atomic Energy Agency, Ministerio de Ciencia, Innovación y Universidades (España), and Agencia Estatal de Investigación (España)

Subjects

Ocean acidification -- Research, Global and Planetary Change, Ocean acidification, Mediterranean Sea, Ocean acidification -- Mediterranean Sea, Socio-economy, policies, Climate change, Ocean Engineering, UN ocean decade, Aquatic Science, Oceanography, Water Science and Technology, Marine organisms -- Effect of water acidification on

Abstract

Ocean acidification (OA) is a serious consequence of climate change with complex organism-to-ecosystem effects that have been observed through field observations but are mainly derived from experimental studies. Although OA trends and the resulting biological impacts are likely exacerbated in the semi-enclosed and highly populated Mediterranean Sea, some fundamental knowledge gaps still exist. These gaps are at tributed to both the uneven capacity for OA research that exists between Mediterranean countries, as well as to the subtle and long-term biological, physical and chemical interactions that define OA impacts. In this paper, we systematically analyzed the different aspects of OA research in the Mediterranean region based on two sources: the United Nation’s International Atomic Energy Agency’s (IAEA) Ocean Acidification International Coordination Center (OA-ICC) database, and an extensive survey. Our analysis shows that 1) there is an uneven geographic capacity in OA research, and illustrates that both the Algero-Provencal and Ionian sub-basins are currently the least studied Mediterranean areas, 2) the carbonate system is still poorly quantified in coastal zones, and long-term time-series are still sparse across the Mediterranean Sea, which is a challenge for studying its variability and assessing coastal OA trends, 3) the most studied groups of organisms are autotrophs (algae, phanerogams, phytoplankton), mollusks, and corals, while microbes, small mollusks (mainly pteropods), and sponges are among the least studied, 4) there is an overall paucity in socio-economic, paleontological, and modeling studies in the Mediterranean Sea, and 5) in spite of general resource availability and the agreement for improved and coordinated OA governance, there is a lack of consistent OA policies in the Mediterranean Sea. In addition to highlighting the current status, trends and gaps of OA research, this work also provides recommendations, based on both our literature assessment and a survey that targeted the Mediterranean OA scientific community. In light of the ongoing 2021-2030 United Nations Decade of Ocean Science for Sustainable Development, this work might provide a guideline to close gaps of knowledge in the Mediterranean OA research. Systematic Review Registration: https://www.oceandecade.org/., The IAEA is grateful for the support provided to its Marine Environment Laboratories by the Government of the Principality of Monaco. This is a contribution of the IAEA’s Ocean Acidification International Coordination Centre (OA-ICC), a project generously funded through the Peaceful Uses Initiative of the IAEA. The authors would like to thank the OA-ICC for supporting the OA Med-Hub in expanding its activities and visibility. MG and PZ acknowledge funding from MINECO (BIOCAL Project - PID2020-113526RB-I00.

Published

2022

39. Coastal freshening drives acidification state in Greenland fjords

Author

Henry C. Henson, Johnna M. Holding, Lorenz Meire, Søren Rysgaard, Colin A. Stedmon, Alice Stuart-Lee, Jørgen Bendtsen, and Mikael Sejr

Subjects

History, Environmental Engineering, Seawater chemistry, Greenland fjords, Polymers and Plastics, Caustics, Greenland, Carbonates, Biological pump, Industrial and Manufacturing Engineering, Calcium Carbonate, Arctic, Arctic Freshening, SDG 13 - Climate Action, Environmental Chemistry, Climate change, Freshering, Seawater, SDG 14 - Life Below Water, Business and International Management, Freshening, Waste Management and Disposal, Ecosystem, SDG 15 - Life on Land, Carbonate saturation state, Ocean acidification, Hydrogen-Ion Concentration, Arctic Climate Change, Pollution, Carbon, CO, Dacarbazine, Carbon dioxide, Biological jump, Estuaries, Greenland fjord

Abstract

Greenland's fjords and coastal waters are highly productive and sustain important fisheries. However, retreating glaciers and increasing meltwater are changing fjord circulation and biogeochemistry , which may threaten future productivity. The freshening of Greenland fjords caused by unprecedented melting of the Greenland Ice Sheet may alter carbonate chemistry in coastal waters, influencing CO2 uptake and causing biological consequences from acidification . However, few studies to date explore the current acidification state in Greenland coastal waters. Here we present the first-ever large-scale measurements of carbonate system parameters in 16 Greenlandic fjords and seek to identify the drivers of acidification state in these freshening ecosystems. Aragonite saturation state (Ω), a proxy for ocean acidification , was calculated from dissolved inorganic carbon (DIC) and total alkalinity from fjords along the east and west coast of Greenland spanning 68–75°N. Aragonite saturation was primarily >1 in the surface mixed layer. However, undersaturated—or corrosive––conditions (Ω < 1) were observed on both coasts (west: Ω = 0.28–3.11, east: Ω = 0.70–3.07), albeit at different depths. West Greenland fjords were largely corrosive at depth while undersaturation in East Greenland fjords was only observed in surface waters. This reflects a difference in the coastal boundary conditions and mechanisms driving acidification state. We suggest that advection of Sub Polar Mode Water and accumulation of DIC from organic matter decomposition drive corrosive conditions in the West, while freshwater alkalinity dilution drives acidification in the East. The presence of marine terminating glaciers also impacted local acidification states by influencing fjord circulation: upwelling driven by subglacial discharge brought corrosive bottom waters to shallower depths. Meanwhile, discharge from land terminating glaciers strengthened stratification and diluted alkalinity. Regardless of the drivers in each system, increasing freshwater discharge will likely lower carbonate saturation states and impact biotic and abiotic carbon uptake in the future.

Published

2022

40. pCO

Author

Zitao, Xiao, Liang, Cao, Jinhu, Liu, Wenting, Cui, and Shuozeng, Dou

Subjects

Ocean Acidification, Animals, Seawater, Flounder, Hydrogen-Ion Concentration, Copper, Antioxidants

Abstract

Ocean acidification potentially influences the biotoxicity of metals and the antioxidant defense systems of marine organisms. This study investigated how pCO

Published

2022

41. Diel p CO 2 fluctuations alter the molecular response of coral reef fishes to ocean acidification conditions

Author

Timothy Ravasi, Philip L. Munday, Michael D. Jarrold, and Celia Schunter

Subjects

Fishery, geography, geography.geographical_feature_category, Aquaculture, business.industry, Genetics, Ocean acidification, Coral reef, Biology, Start up, business, Diel vertical migration, Ecology, Evolution, Behavior and Systematics

Abstract

This study was supported by the start up fund of the University of Hong Kong (C.S.), the Fisheries Society of the British Isles (M.D.J.) and the ARC Centre of Excellence for Coral Reef Studies (P.L.M). This project was completed under approval of the James Cook University animal ethics committee (permit: A2210) and according to the University’s animal ethics guidelines. We thank the Marine and Aquaculture Research Facilities Unit (JCU) and the Integrative Systems Biology Laboratory (KAUST). Special thanks go to Damien Lightfoot for extracting RNA from . brains and Robert Lehmann for aiding with the genome mapping of . sequences. Am percula Am percula

Published

2021

42. Larval development in the Pacific oyster and the impacts of ocean acidification: Differential genetic effects in wild and domesticated stocks

Author

Evan Durland, Pierre De Wit, Chris Langdon, and Eli Meyer

Subjects

Larva, Oyster, biology, Evolution, fungi, Zoology, ocean acidification, Context (language use), Original Articles, adaptation, Broodstock, Pacific oyster, biology.organism_classification, domestication, Genetic marker, biology.animal, QH359-425, Genetics, Crassostrea, Original Article, oysters, Adaptation, General Agricultural and Biological Sciences, Ecology, Evolution, Behavior and Systematics

Abstract

The adaptive capacity of marine calcifiers to ocean acidification (OA) is a topic of great interest to evolutionary biologists and ecologists. Previous studies have provided evidence to suggest that larval resilience to high pCO2 seawater for these species is a trait with a genetic basis and variability in natural populations. To date, however, it remains unclear how the selective effects of OA occur within the context of complex genetic interactions underpinning larval development in many of the most vulnerable taxa. Here we evaluated phenotypic and genetic changes during larval development of Pacific oysters (Crassostrea gigas) reared in ambient (~400 µatm) and high (~1600 µatm) pCO2 conditions, both in domesticated and naturalized “wild” oysters from the Pacific Northwest, USA. Using pooled DNA samples, we determined changes in allele frequencies across larval development, from early “D‐stage” larvae to metamorphosed juveniles (spat), in both groups and environments. Domesticated larvae had ~26% fewer loci with changing allele frequencies across developmental stages and

Published

2021

43. Human impact on symbioses between aquatic organisms and microbes

Author

V Delnat, Ellen Decaestecker, Robby Stoks, M Coone, Koen Sabbe, C Theys, N Goel, S Houwenhuyse, Ester M. Eckert, A Boudry, Cecilia Laspoumaderes, L De Meester, Martijn Callens, Hans-Peter Grossart, Willem Stock, and R Schols

Subjects

INFECTIOUS-DISEASE, GRADED-LEVELS, ECO-EVOLUTIONARY DYNAMICS, Aquatic Science, Biology, ENVIRONMENTAL CONCENTRATIONS, Aquatic organisms, Mutualism, Symbiosis, SALINITY, FED, TOLERANCE, PLASTICITY, PHENOTYPIC, Ecology, Evolution, Behavior and Systematics, Mutualism (biology), Host-symbiont interactions, Ecology, GUT MICROBIOTA, OCEAN ACIDIFICATION, fungi, Biology and Life Sciences, food and beverages, Aquatic microbial symbioses, Anthropogenic disturbances, INTESTINAL ENZYME-ACTIVITIES, BACTERIAL COMMUNITIES

Abstract

Aquatic organisms rely on microbial symbionts for coping with various challenges they encounter during stress and for defending themselves against predators, pathogens and parasites. Microbial symbionts are also often indispensable for the host’s development or life cycle completion. Many aquatic ecosystems are currently under pressure due to diverse human activities that have a profound impact on ecosystem functioning. These human activities are also ex pected to alter interactions between aquatic hosts and their associated microbes. This can directly impact the host’s health and — given the importance and widespread occurrence of microbial symbiosis in aquatic systems — the ecosystem at large. In this review, we provide an overview of the importance of microbial symbionts for aquatic organisms, and we consider how the beneficial services provided by microbial symbionts can be affected by human activities. The scarcity of available studies that assess the functional consequences of human impacts on aquatic microbial symbioses shows that our knowledge on this topic is currently limited, making it difficult to draw general conclusions and predict future changes in microbial symbiont−host relationships in a changing world. To address this important knowledge gap, we provide an overview of ap proaches that can be used to assess the impact of human disturbances on the functioning of aquatic microbial symbioses. ispartof: AME vol:87 issue:Special 7 pages:113-138 status: published

Published

2021

44. Eutrophication overcoming carbonate precipitation in a tropical hypersaline coastal lagoon acting as a CO2 sink (Araruama Lagoon, SE Brazil)

Author

Daniel Tremmel, Carolina Ramos Régis, Gwenaël Abril, Suzan Costa-Santos, Luiz C. Cotovicz, Bastiaan A. Knoppers, Universidade Federal Fluminense [Rio de Janeiro] (UFF), Universidade Federal do Ceará = Federal University of Ceará (UFC), Biologie des Organismes et Ecosystèmes Aquatiques (BOREA), Université de Caen Normandie (UNICAEN), and Normandie Université (NU)-Normandie Université (NU)-Muséum national d'Histoire naturelle (MNHN)-Institut de Recherche pour le Développement (IRD)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université des Antilles (UA)

Subjects

0106 biological sciences, Chlorophyll a, 010504 meteorology & atmospheric sciences, [SDE.MCG]Environmental Sciences/Global Changes, Alkalinity, Hypersaline waters, 01 natural sciences, Sink (geography), chemistry.chemical_compound, Dissolved organic carbon, Climate change, Environmental Chemistry, 14. Life underwater, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology, geography, geography.geographical_feature_category, 010604 marine biology & hydrobiology, Ocean acidification, 6. Clean water, Coastal eutrophication, chemistry, 13. Climate action, Environmental chemistry, [SDE]Environmental Sciences, Environmental science, Carbonate, Atmospheric CO2 sink, Seawater, Carbonate chemistry, Eutrophication

Abstract

International audience; The carbonate chemistry was investigated in the semiarid eutrophic Araruama Lagoon (Brazil), one of the largest hypersaline coastal lagoons in the world. Spatial surveys during winter and summer periods were performed, in addition to a diurnal sampling in summer. The hypersaline waters have higher concentrations of total alkalinity (TA) and dissolved inorganic carbon (DIC) than the seawater that feed the lagoon, due to evaporation. However, TA and DIC concentrations were lower than those expected from evaporation. Calcium carbonate (CaCO3) precipitation partially explained these deficits. The negative correlation between the partial pressure of CO2 (pCO2) and chlorophyll a (Chl a) indicated that DIC was also consumed by primary producers. The uptake by photosynthesis contributes to 57–63% of DIC deviation from evaporation, the remaining credited to CaCO3 precipitation. Marked pCO2 undersaturation was prevalent at the innermost region with shallow, confined, and phytoplankton-dominated waters, with a strong enrichment of heavier carbon isotope (δ13C-DIC up to 5.55‰), and highest pH (locally counter-acting the process of ocean acidification). Oversaturation was restricted to an urbanized region, and during night-time. The lagoon behaved as a marked CO2 sink during winter (− 15.32 to − 10.15 mmolC m−2 day−1), a moderate sink during summer (− 5.50 to − 4.67 mmolC m−2 day−1), with a net community production (NCP) of 93.7 mmolC m−2 day−1 and prevalence of net autotrophic metabolism. A decoupling between CO2 and O2 exchange rate at the air–water interface was attributed to differences in gas solubility, and high buffering capacity. The carbonate chemistry reveals simultaneous and antagonistic actions of CaCO3 precipitation and autotrophic metabolism on CO2 fluxes, and could reflect future conditions in populated and semiarid coastal ecosystems worldwide.

Published

2021

45. International and Domestic Leadership by U.S. States on Ocean Acidification

Author

Whitney Berry, Melissa R. McCutcheon, Sarah R. Cooley, and Anna Zivian

Subjects

chemistry.chemical_compound, chemistry, Environmental protection, Carbon dioxide, Environmental Chemistry, Environmental science, Climate change, Ocean acidification, General Environmental Science

Abstract

Reducing global carbon dioxide emissions is the fundamental action required to make progress on climate change and to reduce ocean acidification. Acting on climate this way is acting on acidificati...

Published

2021

46. The Brown Algae Saccharina japonica and Sargassum horneri Exhibit Species-Specific Responses to Synergistic Stress of Ocean Acidification and Eutrophication

Author

Qingli Gong, Jingyu Li, Yaoyao Chu, Jiazhen Cao, Yuxin Liu, Qiaohan Wang, and Yan Liu

Subjects

fungi, food and beverages, Ocean Engineering, Ocean acidification, Biology, Saccharina japonica, Oceanography, biology.organism_classification, Japonica, Brown algae, chemistry.chemical_compound, Nutrient, chemistry, Chlorophyll, Botany, Sargassum horneri, Eutrophication

Abstract

Ocean acidification and eutrophication are two important environmental stressors. They inevitably impact marine macroalgae, and hence the coastal ecosystem of China. Saccharina japonica, as the main culture species in China, is suffering the harmful golden tide caused by Sargassum horneri. However, it remains unclear whether the detrimental effects of S. horneri on S. japonica cultivation become more severe in future acidified and eutrophic scenario. In this study, we respectively investigated the effects of pCO2 (400 µatm and 1000 µatm) and nutrients (non-enriched and enriched seawater) on the growth, photosynthesis, respiration, chlorophyll contents, and tissue nitrogen of S. japonica and S. horneri. Results indicated that enrichment of nutrients contributed S. horneri to utilize HCO3−. The carbon acquisition pathway shifted from HCO3− to CO2 in S. japonica, while S. horneri remained using HCO3− regulated by nutrient enrichment. S. horneri exhibited better photosynthetic traits than S. japonica, with a higher level of net photosynthetic rate and chlorophyll contents at elevated pCO2 and enriched nutrients. Tissue nitrogen also accumulated richly in the thalli of S. horneri under higher pCO2 and nutrients. Significant enhancement in growth was only detected in S. horneri under synergistic stress. Together, S. horneri showed competitive dominance in current study. These findings suggest that increasing risk of golden tide in acidified and eutrophic ocean can most likely result in great damage to S. japonica cultivation.

Published

2021

47. Ocean acidification alters the thermal performance curves of brooded larvae from the reef coral Pocillopora damicornis

Author

You-Fang Sun, Tao Yuan, Lei Jiang, Xinming Lei, Guo-Wei Zhou, Hui Huang, Sheng Liu, Yuan Tian, Yuyang Zhang, and Xiangcheng Yuan

Subjects

geography, education.field_of_study, geography.geographical_feature_category, biology, Chemistry, Ecology, Coral, fungi, Population, Ocean acidification, Pocillopora damicornis, Aquatic Science, Photosynthesis, biology.organism_classification, Acclimatization, Respiration, education, Reef

Abstract

Establishing the thermal reaction norm of coral larvae under elevated pCO2 is crucial to anticipate how larval dispersal and population maintenance may be affected by future climate change. Here, we characterized the functional relationship between temperature (27−33 °C) and larval performance of the reef coral Pocillopora damicornis under two pCO2 levels. The results showed that the temperature threshold of larvae was between 32 and 33 °C, as evidenced by the abrupt declines in photochemical efficiency and symbiont density, whereas no oxidative damage was observed between 27 and 33 °C and elevated pCO2 did not influence any of these parameters. In addition, larval respiration and photosynthesis rates exhibited parabolic responses to temperature, and this relationship conformed to the Gaussian–Gompertz model with an optimal temperature around 31.5 °C, which was approximately 2.5 °C above the summer mean temperature, suggesting the potential for thermal acclimation. Most importantly, elevated pCO2 significantly enhanced the larval photosynthesis and the stimulatory effect of elevated pCO2 on the photosynthetic rates and capacity was more pronounced in cool and warm temperatures, indicative of shifted thermal sensitivity under high pCO2. These results suggest that ocean acidification could alter the thermal performance curves and tolerance window of brooded P. damicornis larvae, with profound and important implications for larval ecology in a future changing ocean.

Published

2021

48. Impact of ocean carbonation on long-term regulation of light harvesting in eelgrass Zostera marina

Author

Billur Celebi-Ergin, Victoria Hill, and Richard C. Zimmerman

Subjects

Ecology, biology, Carbonation, Ocean acidification, Aquatic Science, Photosynthesis, biology.organism_classification, Term (time), Oceanography, Seagrass, Photoprotection, Zostera marina, Environmental science, Ecology, Evolution, Behavior and Systematics

Abstract

Seagrasses account for approximately 10% of the total carbon stored in the ocean, although photosynthesis of seagrasses is carbon-limited at present oceanic pH levels. Therefore, increasing atmospheric CO2 concentration, which results in ocean acidification/carbonation, is predicted to have a positive impact on seagrass productivity. Previous studies have confirmed the positive influence of increasing CO2 on photosynthesis and survival of the temperate eelgrass Zostera marina, but the acclimation of photoprotective mechanisms in this context has not been characterized. We aimed to quantify the long-term impacts of ocean acidification on photochemical control mechanisms that promote photosynthesis while simultaneously protecting eelgrass from photodamage. Eelgrass were grown in controlled outdoor aquaria at different aqueous CO2 concentrations ranging from ~50 to ~2100 µM from May 2013 to October 2014 and examined for differences in leaf optical properties. Even with daily and seasonal variations of temperature and light, CO2 enrichment consistently increased plant size, leaf thickness and chlorophyll use efficiency, and decreased pigment content and the package effect while maintaining similar light-harvesting efficiency. These acclimation responses suggest that a common photosynthetic sensory function, such as redox regulation, can be manipulated by CO2 availability, as well as light, and may serve to optimize photosynthetic carbon gain by seagrasses into the Anthropocene.

Published

2021

49. Consider the following: A pilot study of the effects of an educational television program on viewer perceptions of anthropogenic climate change and ocean acidification

Author

Don Haas, Chris Ebey, Brendan M. Anderson, and Katherine C. Herleman

Subjects

Geography, business.industry, Perception, media_common.quotation_subject, Global warming, Environmental resource management, General Earth and Planetary Sciences, Ocean acidification, Educational television, business, Education, media_common

Published

2021

50. Opportunities for U.S. State Governments and in-Region Partners to Address Ocean Acidification through Management and Policy Frameworks

Author

Jessie Turner, Eric Laschever, Charlotte Dohrn, Hanna Miller, Parker Gassett, and Chris Boylan

Subjects

Natural resource economics, Corporate governance, Environmental Chemistry, Ecosystem, Ocean acidification, Business, Climate policy, Marine species, General Environmental Science

Abstract

Increasing OA, combined with other stressors like warming and loss of oxygen, threatens marine species and ecosystems, including those that sustain jobs and support coastal economies. For the last ...

Published

2021