Archive Page 233

Climate change could alter undersea chemical communication

Published 19 July 2021 Web sites and blogs Closed
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Ocean acidification could tamper with marine animals’ sense of smell and the shape of signaling molecules.

A pair of spiny lobsters locks antennae as they battle on the gravel-strewn bottom of an aquarium. The two grapple, grabbing legs and jousting with their long spines. Their aggressive actions extend beyond the show of force: the crustaceans also fire off chemical signals by peeing at each other.

Small changes in pH change how female shore crabs (Carcinus maenas) care for their eggs. Credit: Mike Park/University of Hull.

A pair of spiny lobsters locks antennae as they battle on the gravel-strewn bottom of an aquarium. The two grapple, grabbing legs and jousting with their long spines. Their aggressive actions extend beyond the show of force: the crustaceans also fire off chemical signals by peeing at each other.

“They’re actively signaling as they’re fighting,” says Charles D. Derby, a sensory biologist at Georgia State University whose lab studies these underwater wrestling matches, along with other crustacean behaviors. Lobster urine, released from the face near the base of the antennae, contains an array of compounds, including chemical cues to an animal’s sex and social status.

Lobsters are just one of myriad marine animals that rely on molecular missives. Behaviors such as finding meals, choosing habitats, avoiding predators, seeking sex, and engaging in social encounters “are all driven by chemistry, at least in part,” Derby says. By playing key roles in how critters act and relate to each other, chemical signals affect the distribution of organisms in an ecosystem. Chemoreceptors are found not only in noses or mouths; in marine animals, they also show up on fins, limbs, or, as in lobsters, antennae that they flick back and forth.

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Adaptation to simultaneous warming and acidification carries a thermal tolerance cost in a marine copepod

Published 16 July 2021 Science Closed
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The ocean is undergoing warming and acidification. Thermal tolerance is affected both by evolutionary adaptation and developmental plasticity. Yet, thermal tolerance in animals adapted to simultaneous warming and acidification is unknown. We experimentally evolved the ubiquitous copepod Acartia tonsa to future combined ocean warming and acidification conditions (OWA approx. 22°C, 2000 µatm CO2) and then compared its thermal tolerance relative to ambient conditions (AM approx. 18°C, 400 µatm CO2). The OWA and AM treatments were reciprocally transplanted after 65 generations to assess effects of developmental conditions on thermal tolerance and potential costs of adaptation. Treatments transplanted from OWA to AM conditions were assessed at the F1 and F9 generations following transplant. Adaptation to warming and acidification, paradoxically, reduces both thermal tolerance and phenotypic plasticity. These costs of adaptation to combined warming and acidification may limit future population resilience.

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Water quality modeling in subtropical shallow waters to predict environmental impacts of ocean thermal energy conversion

Published 16 July 2021 Science Closed
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Ocean thermal energy conversion (OTEC) is a power generation technology that extracts energy from the temperature difference between deep seawater and surface water in the ocean. Currently, a 100 kW class OTEC demonstration project is underway on Kume Island, Okinawa, and a plan to increase water intake and introduce a 1 MW class OTEC plant is under consideration. Year-round generation of electricity by an OTEC plant requires that it be installed in tropical and subtropical regions, where the surface water has a high temperature and low nutrient content. However, the water discharged from an OTEC plant will have the opposite characteristics of low water temperature and high nutrients, as well as a low pH. One of the most concerning environmental impacts of this discharged water is its influence on corals, which are important species in tropical and subtropical marine ecosystems. In this study, we developed an ecosystem model for a subtropical shallow-water region; the model combines a pelagic submodel, a chemical equilibrium submodel, and a benthic submodel, and successfully reproduces the observed variation in pH. The model was used to predict the environmental impact of water discharged from OTEC plant. The simulation results suggest that a 1 MW class OTEC plant would cause few environmental changes that would affect corals.

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Global change differentially modulates coral physiology and suggests future shifts in Caribbean reef assemblages

Published 16 July 2021 Science Closed
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Global change driven by anthropogenic carbon emissions is altering ecosystems at unprecedented rates, especially coral reefs, whose symbiosis with algal endosymbionts ise particularly vulnerable to increasing ocean temperatures and altered carbonate chemistry. Here, we assess the physiological responses of the coral holobiont (animal host + algal symbiont) of three Caribbean coral species from two reef environments after exposure to simulated ocean warming (28, 31 °C), acidification (300 – 3290 μatm), and the combination of stressors for 93 days. We used multidimensional analyses to assess how multiple coral holobiont physiological parameters respond to ocean acidification and warming. Our results demonstrate significantly diminishing holobiont physiology in S. siderea and P. astreoides in response to projected ocean acidification, while future warming elicited severe declines in P. strigosa. Offshore S. siderea fragments exhibited higher physiological plasticity than inshore counterparts, suggesting that this offshore population has the capacity to modulate their physiology in response to changing conditions, but at a cost to the holobiont. Plasticity of P. strigosa and P. astreoides was not clearly different between natal reef environments, however, temperature evoked a greater plastic response in both species. Interestingly, while these species exhibit unique physiological responses to ocean acidification and warming, when data from all three species are modeled together, convergent stress responses to these conditions are observed, highlighting the overall sensitivities of tropical corals to these stressors. Our results demonstrate that while ocean warming is a severe acute stressor that will have dire consequences for coral reefs globally, chronic exposure to acidification may also impact coral physiology to a greater extent than previously assumed. The variety of responses to global change we observe across species will likely manifest in altered Caribbean reef assemblages in the future.

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GOA-ON Webinar Series 2021: regional changes in Southern Ocean biogeochemistry due to projected carbon uptake (text & video)

Published 16 July 2021 Presentations Closed
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Webinar speaker: Dr. Eric Mortenson, Postdoctoral Researcher at Commonwealth Scientific and Industrial Research Organization (CSIRO), Hobart, Australia

Description: The Southern Ocean accounts for nearly half of the global ocean’s sink of anthropogenic carbon. Despite this important contribution, many climate models do not represent the mesoscale features that characterize the region due to limited spatial resolution. Here we apply a high-resolution ocean model that incorporates biogeochemistry with high-emission (RCP8.5) forcing in order to identify regions of pronounced change due to carbon uptake into the near future. We find that the annual uptake of carbon in the Southern Ocean south of 40° S is projected to double over the first half of the 21st century. The changes due to the increase in carbon will lead to acidification and lowering of aragonite saturation. We will present regions where changes to carbon system variables are respectively more and less pronounced to inform the siting of near-future observations.

The GOA-ON webinar series has four sponsoring organizations:

  • (1) GOA-ON, the Global Ocean Acidification Observing Network,
  • (2) NOAA, the United States National Oceanic & Atmospheric Administration,
  • (3) IAEA OA-ICC, the International Atomic Energy Agency – Ocean Acidification International Coordination Centre, and
  • (4) IOC-UNESCO – the Intergovernmental Oceanographic Commission of the United Nations Educational, Scientific and Cultural Organization For more information, please visit www.goa-on.org
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British Columbia to southern California: making headway with ocean change

Published 16 July 2021 Web sites and blogs Closed
People bent over slightly around a CTD rosette of grey niskin bottles collecting water samples using a syringe through a valve

Seawater samples being retrieved from a CTD during the West Coast Ocean Acidification Cruise. Photo Credit: Dave Butterfield (UW CICOES/PMEL)

On June 13, scientists aboard the NOAA Ship Ronald H. Brown set out on the West Coast Ocean Acidification Research Cruise to characterize conditions along the West Coast of North America and continue to build a unique time-series of carbon and hydrographic measurements in areas expected to be highly impacted by ocean acidification. Scientists have been collecting samples from CTDs, collecting plankton and water samples for genomics analysis, and conducting the first systematic regional survey of methane gas coming out of the thousands of seeps along the west coast.

The California Current System, running along the North American west coast from British Columbia to Baja California, is a region where seasonal upwelling brings nutrient- and carbon dioxide-rich and oxygen-poor waters to the surface. Increasing levels of carbon dioxide from upwelling and anthropogenic emissions, cause a series of chemical reactions that are ultimately increasing acidity in these waters. Because it is an area with high rates of primary production by phytoplankton, air-sea carbon dioxide exchange, and carbon export to the open ocean and sediments, it is particularly susceptible to the impacts of ocean acidification and hypoxia. Understanding the progression of ocean acidification in coastal areas in the context of these other natural processes is critical for developing management, mitigation, and adaptation strategies.

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Researching climate change in Greenland

Published 16 July 2021 Web sites and blogs Closed

Hereon scientists study marine ecosystem tipping points on international research expedition

Research vessel

An international group of 20 scientists will embark on a 2-week research cruise leaving from Nuuk, Greenland, on Saturday 17 July to investigate changes in the marine environment off Greenland´s west coast, and what these changes mean for the ocean´s ability to provide fish and store carbon from the atmosphere. On board are three scientists from Helmholtz-Zentrum Hereon.

The research cruise aboard DANA, Denmark´s largest research vessel, will include scientists from Helmholtz-Zentrum Hereon, Denmark´s Technical University, Aarhus University, the Arctic University of Norway, Åbo Akademi and the University of Vienna. DANA plans to arrive in Nuuk from Reykjavik, Iceland on the 13 July and set sail on 17 July once all scientists have arrived and are all installed. The Dana will return to Nuuk on the 30 July. The cruise is financed through the European Horizon 2020 research project ECOTIP.

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New report highlights why the ocean matters in climate negotiations & suggests positive actions nations can take as the countdown to COP26 is underway

Published 15 July 2021 Newsletters and reports Closed
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Leading UK experts shine a spotlight on the critical role the ocean plays in greatly slowing the rate of climate change but also the subsequent impacts of this and why support from nations for better inclusion of the ocean at the United Nations climate negotiations, such as COP26 in Glasgow this November, is so important.

The briefing, led by Plymouth Marine Laboratory, summarises the latest research and knowledge on the importance of the ocean, as well as offering a range of opportunities to nations in order to ensure that the ocean can be developed sustainably for the benefits it provides to people around the world.

Developed by a team of experts from leading UK marine and environmental science universities and centres and published in association with the COP26 Universities Network, the briefing also makes suggestions on how the ocean can be better incorporated in the United Nations Framework Convention on Climate Change (UNFCCC) process.

The key messages are:

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Environmental legacy effects and acclimatization of a crustose coralline alga to ocean acidification

Published 15 July 2021 Science Closed
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Prior exposure to variable environmental conditions is predicted to influence the resilience of marine organisms to global change. We conducted complementary 4-month field and laboratory experiments to understand how a dynamic, and sometimes extreme, environment influences growth rates of a tropical reef-building crustose coralline alga and its responses to ocean acidification (OA). Using a reciprocal transplant design, we quantified calcification rates of the Caribbean coralline Lithophyllum sp. at sites with a history of either extreme or moderate oxygen, temperature, and pH regimes. Calcification rates of in situ corallines at the extreme site were 90% lower than those at the moderate site, regardless of origin. Negative effects of corallines originating from the extreme site persisted even after transplanting to more optimal conditions for 20 weeks. In the laboratory, we tested the separate and combined effects of stress and variability by exposing corallines from the same sites to either ambient (Amb: pH 8.04) or acidified (OA: pH 7.70) stable conditions or variable (Var: pH 7.80-8.10) or acidified variable (OA-Var: pH 7.45-7.75) conditions. There was a negative effect of all pH treatments on Lithophyllum sp. calcification rates relative to the control, with lower calcification rates in corallines from the extreme site than from the moderate site in each treatment, indicative of a legacy effect of site origin on subsequent response to laboratory treatment. Our study provides ecologically relevant context to understanding the nuanced effects of OA on crustose coralline algae, and illustrates how local environmental regimes may influence the effects of global change.

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Calcifying phytoplankton in natural laboratories for understanding ocean acidification

Published 15 July 2021 Science Closed
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Coccolithophores are unicellular phytoplanktonic organisms characterized by a covering of calcite plates, the coccoliths, which are produced intracellularly. These calcifiers, as one of the main planktonic functional groups, play an important role in the inorganic carbon cycle and possibly as ballast that sinks organic carbon to the deep-sea. Most efforts to understanding coccolithophore response to ocean acidification (OA) –or the raise in atmospheric CO2 reduces ocean pH and saturation states (Ω) of CaCO3– have been through lab experiments, mostly using a small set of strains of the cosmopolitan, easily cultivated species Emiliania huxleyi. This species is especially interesting because it is young (~ 291,000 years) and has adapted to a wide range of marine environments. However, it is not the only coccolithophore and even within that species there is a lot of phenotypic and genetic diversity and diverse responses to OA in the lab. Despite the efforts made it is unclear how the physiological effects under controlled conditions translate to community-level responses in the field. This thesis aimed to contribute to understanding this issue by studying the distribution, composition and realized niches of coccolithophore assemblages and E. huxleyi morphotypes in contrasting pCO2/pH/Ωcalcite environments of the Eastern South Pacific, and to evaluate the responses of different E. huxleyi23 morphotypes to targeted pCO2/pH levels set in the lab. For this, the coccolithophores were surveyed in a coastal-oceanic section, mesotrophic waters, upwelling systems, and fjords-channels of Patagonia. From a total of 40 species, E. huxleyi was the most prevalent (30-100 % relative abundance). Within this taxon, several morphotypes has been described as stable in culture and genetically differentiated (e.g., the A and R morphotypes). The moderately-calcified A morphotype dominated the E. huxleyi populations being only surpassed by the R hyper-calcified morphotype in upwelling systems with high pCO2/low pH. This abrupt shift in the composition of E. huxleyi populations suggested that these coastal environments hold genetic reservoirs for their adaptation to OA. Therefore, the hypothesis was tested that these forms are adapted to resist high pCO2/low pH conditions. Unexpectedly, the morphotypes from the Eastern South Pacific were not more sensitive than the R hyper-calcified strains from neighboring high pCO2/low pH waters (lowering growth rates and PIC/POC ratios). On the other hand, realized-niche analysis showed that the A morphotype has a broader niche that is more tolerant to environmental-change (i.e., generalist) than the R morphotype’s niche, specialized to high pCO2/low pH waters. The lack of evidence for local adaptation to high pCO2/low pH conditions in E. huxleyi, might be explained by a narrow unimodal niche response to Ωcalcite revealed by niche analysis that was not tested experimentally. Alternatively, the R hyper-calcified morphotype might be selected by an unidentified condition particular to the Eastern South Pacific that correlates with temperature, salinity, and Ωcalcite of its realized-niche. Overall, despite their rapid turnover and large population sizes, oceanic planktonic microorganisms do not necessarily exhibit adaptations to high-pCO2 upwelled waters, and this ubiquitous coccolithophore may be near the limit of its capacity to adapt to ongoing OA.

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Chapter 22 – Legal tools in combating marine pollution and mitigating the effects of acidification (1st edition)

Published 15 July 2021 Science Closed
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After almost three decades, too little progress has been achieved in protecting, preserving, and promoting the sustainable use of the ocean and its resources for the benefit of mankind. Many efforts, however, have been deployed within conferences, summits, and meetings with highly competent experts, such as scientists, diplomats, and international lawyers covering a wide range of fields. After all these years, the state of the marine environment is not improving as fast as it should be. The question to ask is why has so little progress been achieved? The answer belongs once more to the international community, as well as to national policymakers. They should take more forceful actions in implementing the Sustainable Development Goals (SDGs) contained in the 2030 Agenda. 

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Savannah State University presents: the effects of ocean acidification in virtual reality

Published 15 July 2021 Events Closed

Date: 16 July 2021

Time: 9 am – 4 pm

Location: 3219 College Street in Hubert Building D, third floor, Room 444

Entry: free and open to the public.

SAVANNAH, GA – Savannah State University’s Visual Immersive Tangible Applications Learning (VITAL) Research Lab is hosting “The Effects of Ocean Acidification”.

There will be four 1-hour sessions. Participants will see firsthand the impact and effects of carbon emissions on the ocean in virtual reality. To schedule a session, visit https://calendly.com/vital-ssu/ocean-acidification-virtual-reality-event.

“The National Oceanic and Atmospheric Administration affirms that in the 200-plus years since the industrial revolution began, the concentration of Carbon Dioxide (CO2) in the atmosphere has increased due to human actions,” said Mykela Zumbrum, VITAL research lab technician. “During this time, the pH of surface ocean waters has increased by nearly 30 percent in acidity. This increase has far-reaching implications for the ocean and the creatures that live there.”

An extension of the College of Sciences and Technology, the VITAL Research Lab operates within the Chemistry and Forensic Sciences department. This event is made possible by the Office of Title III, a federally funded program designed to support the infrastructure of Historically Black Colleges or Universities. For more information, contact Zumbrum by calling 912-358-4154.

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Macroalgal calcification and the effects of ocean acidification and global warming

Published 14 July 2021 Science Closed
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Calcification by calcified marine macroalgae is crucial to algal growth, and the formation and maintenance of coral reefs. It involves complex processes, such as the uptake, transport and storage of Ca2+, HCO3- or CO32-, and formation of crystals responsible for calcium depositions. Calcification is vulnerable to changes in global climate, including ocean acidification (OA) and warming (OW). Studies investigating the mechanisms of macroalgal calcification are limited and restricted to the physiology level; however, the application of new approaches, i.e. genomics, provide avenues for new understanding. We review the literature on macroalgal calcification from the physiological to the molecular level, and present in a list of key issues to be resolved in order to understand the mechanism of calcification. The review offers insights into the potential impacts of changing climate conditions on algal calcification to provide an accurate prediction of future changes in the reef ecosystems.

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The effect of global warming and acidification on PAHs bioaccumulation in pearl oyster Pinctada radiate

Published 14 July 2021 Science Closed
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Warming and acidification are expected impact of climate change that will affect marine areas in the future. These areas are, furthermore, vulnerable to strong anthropogenic stresses such as chemical pollutants. Nevertheless, the consequences of both stressors for marine ecosystems and organisms are still unidentified. The present study aims to examine, for the first time, the effect of temperature and CO2 pressure increase on bioaccumulation of phenanthrene as a PAHs model in four tissues, gills, digestive gland, muscle and mantle of a commercially important pearl oyster Pinctada radiata. Oysters were exposed to various combination of the ambient temperature and pH currently measured in Persian Gulf (T = 24 ºC and pH = 8.1) and the expected ocean warming and acidification (T = 28 ºC and pH = 7.6), as well as proper PhE concentration (0.8 ng.l− 1) during 28 days. In all exposures, higher PhE contents were observed under hypercapnia and warming condition in the digestive gland and gills, followed by the mantle and muscle. Generally, the results visibly reveal that longer exposure period led to promote PhE bioaccumulation in all tissues under ocean warming and acidification environment which was time-dependent pattern of PhE accumulation in P.radiata. Present-day PhE environmental concentrations, which combined with ocean warming and acidification, may lead to rigorous interruption of physiological functions can be extra threatened the ecological fitness of pearl oysters.

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Long-term effects of high CO2 on growth and survival of juveniles of the striped venus clam Chamelea gallina: implications of seawater carbonate chemistry

Published 14 July 2021 Science Closed
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Ocean acidification (OA) will decrease shellfish growth and survival, with ecological and economic consequences for fisheries and aquaculture. However, the high variability of results among experiments, and the lack of long-term studies, make it difficult to predict the effect that OA will have on bivalve species. We tested the long-term effect of high CO2 on growth, calcification rates, and survival of juveniles of the commercial bivalve species Chamelea gallina from Southern Portugal. The local high alkalinity of seawater probably buffered the negative effect of the pH drop, and after 75 days juveniles increased their growth and calcification rates with CO2. However, after 217 days, the situation reversed, bivalves under control conditions had the highest growth and calcification rates, while individuals under high CO2 presented negative calcification rates. The biometric variable that responded first was the width of the individuals, followed by the height and length of the shells. Survival was unaffected except for a mortality peak of juveniles under control and intermediate conditions as a consequence of a temperature drop. In the short term, C. gallina will increase their calcification rates to compensate for OA. However, in the long term, the additional energy expended will be translated into growth losses with negative repercussions for the fisheries and aquaculture. The cultivation of shellfish on high alkaline seawater should be further explored as a bioremediation measure to mitigate the negative effect of OA on shellfish aquaculture.

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Sculpture and new technologies in scientific educational outreach: 3D foraminiferal models as a referent of ocean acidification and climate change

Published 14 July 2021 Projects , Science Closed
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The Foraminifera Project is a collaboration between researchers of the Faculty of Fine Arts and the Faculty of Geological Sciences at the Complutense University (UCM, Madrid, Spain). The work, based on scientific dissemination through art, is framed in the theme “Climate change and Ocean Acidification” as part of the course “Art, Science and Nature” of the Master’s Degree in Research in Art and Creation (Faculty of Fine Arts, UCM). The team used recent sediment samples from Indian Ocean and Red Sea that contained healthy and unhealthy foraminifera specimens to create 3D specimen models. These models were made using traditional sculpture techniques, photogrammetry, and 3D printing to show different states of foraminifera dissolution and corrosion from ocean acidification. The end result of this project resulted in nine interactive pieces which were part of the exhibition “Drift & Migrate” open to the public during the month of November 2019 in the exhibition hall of the Faculty of Fine Arts (UCM). The 3D models of foraminifera were displayed with educational graphics and blind-accesible explanatory signage (Braille) to share the scientific facts of foraminifera and their role in the ocean ecosystem. The main objective of the collaboration is to raise awareness of anthropogenic effects on foraminifera and the marine ecosystems in general and to expand research opportunities between the arts and sciences at the university.

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Physical scientist, ZP-1301-3/4 (direct hire)

Published 14 July 2021 Jobs Closed

Open & closing dates: 13/07/2021 to 27/07/2021

Appointment type: permanent

Work schedule: full-time

Salary: $55,756 to $122,077 per year

Location: location negotiable after selection, United States

Apply

Summary: This is a Direct Hire Public Notice. Please read this Public Notice in its entirety prior to submitting your application for consideration. This position is located in the National Oceanic and Atmospheric Administration (NOAA), Office of Oceanic and Atmospheric Research (OAR), Ocean Acidification Program (OAP), with one vacancy in a Negotiable Location.

Responsibilities: as a Physical Scientist, you will perform the following duties:

  • Develop and coordinate the National Oceanic and Atmospheric Administration’s (NOAA) ocean acidification science outreach and education. Lead a team charged with coordinating across NOAA and the broader science communication community in the development and dissemination of ocean acidification messages and materials derived from program-sponsored research. Lead team development of new approaches for dissemination of research findings.
  • Monitor and direct the organization’s ocean acidification education activities. Oversee the development of educational materials. Manage major ocean acidification website enhancements. Coordinate execution of ocean acidification-related public webinars. Oversee program communication and educational investments and track program milestones and performance.
  • Coordinate presentation of program-sponsored research findings to lay, managerial and expert audiences within and beyond NOAA using various software packages and social media platforms. Produce original written materials on ocean acidification summarizing program-sponsored research findings for agency, national, and international assessments.
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Ocean acidification at Point Reyes National Seashore (text & video)

Published 14 July 2021 Presentations Closed

For video see link: https://www.nps.gov/media/video/embed.htm?id=F86474A0-52B9-4603-A725-8D265A8AB39A

Ocean acidification is rapidly changing the chemistry of ocean water worldwide and making it more difficult for many organisms to build their shells and skeletons. This video explores how park staff at Point Reyes National Seashore are working with local scientists to better understand the effects of ocean acidification, specifically on shellfish and other marine organisms.

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Lunch & learn series – Ocean acidification in the Gulf of Maine: issue and solutions

Published 14 July 2021 Events Closed

Date: 30 Jul 2021

Time: 12:30 PM in Eastern Time (US and Canada)

Webinar registration

Description:

Join us for a one-hour panel discussion on ocean and coastal acidification’s impact on scallops and softshell clams, methods of remediation, and future projections for the Gulf of Maine.

This online talk will be moderated by Dr. Libby Jewett, Director of the NOAA Ocean Acidification Program. Panelists include, Dr. Samantha Siedlecki, University of Connecticut; Dr. Nichole Price, Bigelow Laboratory for Ocean Sciences; and Dr. Robert J Holmberg, Downeast Institute.

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Expanding evaluation of ocean acidification responses in a marine gadid: elevated CO2 impacts development, but not size of larval walleye pollock

Published 13 July 2021 Science Closed
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Responses of marine populations to climate conditions reflect the integration of a suite of complex and interrelated physiological and behavioral responses at the individual level. Many of these responses are not immediately reflected in changes to survival, but may impact growth or survival at later life stages. Understanding the broad range of impacts of rising CO2 concentrations on marine fishes is critical to predicting the consequences of ongoing ocean acidification. Walleye pollock (Gadus chalcogrammus) support the largest single-species fishery in the world and provide a critical forage base throughout north Pacific ecosystems. Previous studies of high CO2 effects on early life stages of walleye pollock have suggested a general resiliency in this species, but those studies focused primarily on growth and survival rates. Here, we expand on earlier studies with an independent experiment focused on walleye pollock larval development, swimming behavior, and lipid composition from fertilization to 4 weeks post-hatch at ambient (~ 425 µatm) and elevated (~ 1230 µatm) CO2 levels. Consistent with previous observations, size metrics of walleye pollock were generally insensitive to CO2 treatment. However, 4-week post-hatch larvae had significantly reduced rates of swim bladder inflation. A modest change in the swimming behavior of post-feeding larvae was observed at four, but not at 2 weeks post-hatch. Although there were no differences in overall lipid levels between CO2 treatments, the ratio of energy storage lipids (triacylglycerols) to structural membrane lipids (sterols) was lower among larvae reared at high CO2 levels. Although we observed higher survival to 4 weeks post-hatch among fish reared at high CO2 levels, the observations of reduced swim bladder inflation rates and changes in lipid cycling suggest the presence of sub-lethal effects of acidification that may carry over and manifest in later life stages. These observations support the continued need to evaluate the impacts of ocean acidification on marine fishes across a wide range of traits and life stages with replicated, independent experiments.

Continue reading ‘Expanding evaluation of ocean acidification responses in a marine gadid: elevated CO2 impacts development, but not size of larval walleye pollock’

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