Assessing risks of ocean acidification in south-central and southeast Alaska

Tom Hurst - NOAA Alaska Fisheries Science Center

Evaluating ocean acidification vulnerability and interactions among traditional and coastal Alaska industries

Why we care
Many marine species affected by ocean acidification (OA) contribute to Alaska’s highly productive commercial fisheries and traditional subsistence ways of life. Concern exists that acidification will cause ecosystem-level shifts, diminishing the overall economic value of commercial fisheries and reducing food security for communities relying on subsistence harvests. 

What we are doing
This project addresses acidification threats in south-central and southeast Alaska. It involves the development of decision support tools incorporating acidification risks into localized socio-ecological systems. The tools are based on a network of models representing acidification hazards, bio-ecological systems, and socioeconomic systems linked to adaptive actions.

Benefits of our work
This project is an exchange of knowledge between scientists, policy makers, and community stakeholders. The network of models creates decision support tools responsive to stakeholder concerns that reflect regional variation in community priorities and their ecological social and management context. The project synthesizes the best available science to determine the risks posed by ocean acidification.

Thursday, June 23, 2022

Next-Gen gene sequencing to understand effects of ocean acidification on Alaskan crab and fish

Chris Long - NOAA/NMFS Alaska Fisheries Science Center

Using next-generation sequencing techniques to assess adaptive capacity and illuminate mechanisms underlying the effects of high pCO2 on Alaskan crab and fish species

Why we care
Many economically important crab and fish species are negatively affected by exposure to ocean acidification predicted to occur throughout their ranges in the coming decades. Ocean acidification results in decreased growth, altered development, weaker exoskeletons, increased energy outputs, altered immune systems, altered behavior, and increased mortality in some of these species. Other stressors such as increased temperature can have interactive negative effects when combined with ocean acidification. Traditional laboratory experiments cannot duplicate the gradual changes that will affect species populations over multiple life-history stages and generations, so using next-generation genetic approaches provide insight into effects beyond specific life stages.

What we are doing 
This study will use next-generation sequencing techniques to identify specific alterations in the molecular, metabolic, and physiological pathways of individuals exposed to ocean acidification. This is a way to identify pathways that impart tolerance to ocean acidification and warming. This project determines the effect of ocean acidification and thermal stress on gene expression in Pacific cod larvae and juvenile Tanner crab and identifies genetic markers indicating ocean acidification resilience. 

Benefits of our work
Investigators will identify the cellular pathways that impart tolerance to ocean acidification. By comparing individuals that demonstrate low sensitivity to ocean acidification and with the general population, we enhance the ability to predict how adaptation will alter the species’ response to future ocean conditions. This research will inform the fishing industry and coastal, fisheries-dependent Alaskan communities about potential effects of ocean change on commercially important species. Outcomes can be used to drive future responses and adaptations in these industries regarding affected fisheries.

Thursday, May 26, 2022

Research to inform adaptation decisions for Alaska’s Salmon Fisheries

David Finnoff, University of Wyoming

Alaska is expected to experience ocean acidification faster than any other United States coastal waters, primarily due to its colder water which absorbs more carbon dioxide than warmer waters. With seafood industry job incomes over $1.5 billion annually and a communities that rely on healthy oceans for subsistence, nutrition, and culture, increased ocean acidification is expected to have significant implications. Research on the potential impact to salmon has emerged as one of the top priorities, identified during a 2016 statewide workshop and stakeholder survey. Despite the economic importance of salmon, little research has been done on the effects of ocean acidification on salmon and the fishing industry and communities that depends on salmon. Acidification has been shown to impair coho salmon’s ability to smell and detect their prey. It has also been shown to reduce pink salmon growth rates. In addition, future ocean acidification is expected to affect salmon prey species, which is expected to affect Pacific salmon survival, abundance and productivity. This project will investigate the implication of ocean acidification thresholds and major ecosystem shifts in the Gulf of Alaska on salmon. Integrated human-ecological models will be developed to simulate management scenarios to assess the benefits of pre-emptive adaptation planning and policy making. The information from modeling these scenarios will help create decision tools for salmon managers.
Tuesday, October 2, 2018
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