Changes in the biochemical and nutrient composition of seafood due to ocean acidification and warming

Ocean acidification and warming may threaten future seafood production, safety and quality by negatively impacting the fitness of marine species. Identifying changes in nutritional quality, as well as species most at risk, is crucial if societies are to secure food production. Here, changes in the b...

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Veröffentlicht in:	Marine environmental research 2019-01, Vol.143, p.82-92
Hauptverfasser:	Lemasson, A.J., Hall-Spencer, J.M., Kuri, V., Knights, A.M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Acidification Animals Aquaculture Biochemical composition Biochemistry Carbohydrates Carbon Dioxide Climate change Composition Crassostrea gigas Economic benefits Environmental stress Fitness Food production Food Quality Food security Foods Global change Global Warming Hydrogen-Ion Concentration Lipids Living resources Magallana gigas Marine molluscs Mineral composition Mineral nutrients Multi-stressors Ocean acidification Ostrea - chemistry Ostrea - metabolism Ostreidae - chemistry Ostreidae - metabolism Oyster Oysters Proteins Safety Seafood Seafoods Seawater - chemistry Shellfish Socioeconomic aspects Species
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description	Ocean acidification and warming may threaten future seafood production, safety and quality by negatively impacting the fitness of marine species. Identifying changes in nutritional quality, as well as species most at risk, is crucial if societies are to secure food production. Here, changes in the biochemical composition and nutritional properties of the commercially valuable oysters, Magallana gigas and Ostrea edulis, were evaluated following a 12-week exposure to six ocean acidification and warming scenarios that were designed to reflect the temperature (+3 °C above ambient) and atmospheric pCO2 conditions (increase of 350–600 ppm) predicted for the mid-to end-of-century. Results suggest that O. edulis, and especially M. gigas, are likely to become less nutritious (i.e. containing lower levels of protein, lipid, and carbohydrate), and have reduced caloric content under ocean acidification and warming. Important changes to essential mineral composition under ocean acidification and warming were evident in both species; enhanced accumulation of copper in M. gigas may be of concern regarding consumption safety. In light of these findings, the aquaculture industry may wish to consider a shift in focus toward species that are most robust to climate change and less prone to deterioration in quality, in order to secure future food provision and socio-economic benefits of aquaculture. •Ocean acidification and warming can reduce oysters nutritional quality.•Changes to nutritional composition were more pronounced in the introduced species.•Oysters displayed decreased protein, lipid, and carbohydrate contents.•Multifaceted implications for the aquaculture sector and future food security.
doi_str_mv	10.1016/j.marenvres.2018.11.006
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source	MEDLINE; Elsevier ScienceDirect Journals Complete
subjects	Acidification Animals Aquaculture Biochemical composition Biochemistry Carbohydrates Carbon Dioxide Climate change Composition Crassostrea gigas Economic benefits Environmental stress Fitness Food production Food Quality Food security Foods Global change Global Warming Hydrogen-Ion Concentration Lipids Living resources Magallana gigas Marine molluscs Mineral composition Mineral nutrients Multi-stressors Ocean acidification Ostrea - chemistry Ostrea - metabolism Ostreidae - chemistry Ostreidae - metabolism Oyster Oysters Proteins Safety Seafood Seafoods Seawater - chemistry Shellfish Socioeconomic aspects Species
title	Changes in the biochemical and nutrient composition of seafood due to ocean acidification and warming
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