Fisheries, low oxygen and climate change: how much do we really know?

Townhill, Bryony; Pinnegar, John K.; Righton, David; Metcalfe, Julian D.

doi:10.1111/jfb.13203

Cited by 31 publications

(12 citation statements)

References 145 publications

(254 reference statements)

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“…These geographic areas are at risk of becoming hypoxic because of the increase of nutrients and organic matter into the coastal waters (Van Den Thillart et al, 1994; Grantham et al, 2004; Chan et al, 2008). Hypoxic conditions occur naturally in nature (Ekau et al, 2010); however, there are reports of a global oceanic oxygen decline (Schmidtko et al, 2017), which is becoming a problem for marine biodiversity (Vaquer-Sunyer and Duarte, 2008) and an important environment stressor to marine species (Cosme and Hauschild, 2016; Townhill et al, 2017). Hypoxia is also a potential challenge under intensive aquaculture conditions (Brett, 1979; Delaney and Klesius, 2004; Burt et al, 2013) due to the high density of animals and because of the costs associated with keeping oxygen saturation at normal levels.…”

Section: Introductionmentioning

confidence: 99%

Hypoxic Induced Decrease in Oxygen Consumption in Cuttlefish (Sepia officinalis) Is Associated with Minor Increases in Mantle Octopine but No Changes in Markers of Protein Turnover

et al. 2017

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The common cuttlefish (Sepia officinalis), a dominant species in the north-east Atlantic ocean and Mediterranean Sea, is potentially subject to hypoxic conditions due to eutrophication of coastal waters and intensive aquaculture. Here we initiate studies on the biochemical response to an anticipated level of hypoxia. Cuttlefish challenged for 1 h at an oxygen level of 50% dissolved oxygen saturation showed a decrease in oxygen consumption of 37% associated with an 85% increase in ventilation rate. Octopine levels were increased to a small but significant level in mantle, whereas there was no change in gill or heart. There were no changes in mantle free glucose or glycogen levels. Similarly, the hypoxic period did not result in changes in HSP70 or polyubiquinated protein levels in mantle, gill, or heart. As such, it appears that although there was a decrease in metabolic rate there was only a minor increase in anaerobic metabolism as evidenced by octopine accumulation and no biochemical changes that are hallmarks of alterations in protein trafficking. Experiments with isolated preparations of mantle, gill, and heart revealed that pharmacological inhibition of protein synthesis could decrease oxygen consumption by 32 to 42% or Na+/K+ ATPase activity by 24 to 54% dependent upon tissue type. We propose that the decrease in whole animal oxygen consumption was potentially the result of controlled decreases in the energy demanding processes of both protein synthesis and Na+/K+ ATPase activity.

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Section: Introductionmentioning

confidence: 99%

Hypoxic Induced Decrease in Oxygen Consumption in Cuttlefish (Sepia officinalis) Is Associated with Minor Increases in Mantle Octopine but No Changes in Markers of Protein Turnover

et al. 2017

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“…Deoxygenation will reduce species diversity and species richness in marine ecosystems (Breitburg et al, 2018;Wu, 2002). Although certain benthic species can tolerate DO values lower than 63 μmol O 2 /L for several days to weeks (Rabalais et al, 2010;Wu, 2002), many physiological functions of aquatic organisms are seriously affected at this DO level (e.g., Breitburg et al, 2018;Townhill et al, 2017). Some sensitive species are affected even at a DO concentration of higher than this value (e.g., Díaz & Breitburg, 2009;Vaquer-Sunyer & Duarte, 2008;Wu, 2002).…”

Section: Comparison With Other Seas and Potential Effects Of Do Shortmentioning

confidence: 99%

Emergence of Summertime Hypoxia and Concurrent Carbonate Mineral Suppression in the Central Bohai Sea, China

Zhai

Zhao

et al. 2019

JGR Biogeosciences

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The Bohai Sea to the west of the North Yellow Sea in the Northwest Pacific is a semienclosed shallow‐water marginal sea on a critical path of eutrophication and environmental degradation. To better understand the Bohai Sea metabolism‐induced summertime dissolved oxygen (DO) decline and acidification, eight field surveys were conducted between August 2011 and September 2017, investigating seasonal and interannual variations in DO and carbonate system parameters in the central Bohai Sea. The historically lowest Bohai Sea DO was recorded at 66 μmol O2/kg in subsurface waters in early September 2015. By comparing our data set with literature data obtained in the 1980s, 1990s, and 2000s, the emergence history of summertime hypoxia in this marginal sea was shown. Associated with the seasonal DO shortage, the metabolism‐enhanced CO2 accumulation in subsurface waters in summer resulted in critical aragonite saturation states of close to or even less than 1.5, threatening calcifiers with potentially severe consequences for valuable shellfish fisheries. Based on model results combining the aerobic respiration (as indicated by apparent oxygen utilization) and the given wintertime/springtime atmospheric CO2 level of the time, this study suggests that combined stresses of the seasonal DO shortage and CO2 acidification capable of threatening Bohai Sea ecosystems could develop within decades.

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“…Up to one third of global carbon dioxide emissions are absorbed by the oceans (Borunda, 2019;Ülker et al, 2018;Townhill et al, 2017). The ocean is a natural sink for carbon dioxide (CO2); however, the increase of anthropogenic emissions is changing the ocean chemistry by lowering the seawater pH, and causing a reduction in the availability of carbonates (CO32-) and biogenic calcium carbonate (CaCO3), a process widely known as ocean acidification (Caldeira and Wickett, 2003;Feely et al, 2009;Gattuso and Hansson, 2011;Gazioğlu and Okutan, 2016).…”

Section: Climate Change Effect On Musselmentioning

confidence: 99%

Mussel: a potential pollution indicator in the aquatic ecosystem and effect of climate change

Şahin

Khan

Terzi

et al. 2020

International Journal of Environment and Geoinformatics

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The study of ecological indicators, defining and establishing the means of measuring the health of the environment, is of great importance. The most important elements of ecosystems are the biological components, and environmental impact assessment of ecosystems will therefore require that these components are seriously laid out. It is, for example, not sufficient to assess the water quality by the use of physicochemical parameters, although their determination can be carried out much more rapidly. There exists, in general, a relation between species composition and water quality. It is well known that mussels are extensively utilized as a biological indicator of pollution of both marine and freshwater ecosystems. The reason is that the mussel is a sessile, filter-feeding, and able to accumulate within its tissues many of the contaminants. In addition, mussels show a wide geographical distribution as they permit the survey of extensive coastal and inland areas. The contaminants accumulated in the tissues of mussels may cause a "stress syndrome" with alteration to their physiology. On the other hand, global warming does affect the pH level, especially the marine water resulting increase in acidity. This can be the outcome of the existing genetic variation in natural populations of mussels. They because allow themselves to adapt to declining pH levels in the aquatic ecosystem caused by carbon emissions. We, therefore, focus on the factors that possibly affect the mussel biodiversity in aquatic ecosystems in relation to climate change as well as pollution concerned.

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Fisheries, low oxygen and climate change: how much do we really know?

Cited by 31 publications

References 145 publications

Hypoxic Induced Decrease in Oxygen Consumption in Cuttlefish (Sepia officinalis) Is Associated with Minor Increases in Mantle Octopine but No Changes in Markers of Protein Turnover

Hypoxic Induced Decrease in Oxygen Consumption in Cuttlefish (Sepia officinalis) Is Associated with Minor Increases in Mantle Octopine but No Changes in Markers of Protein Turnover

Emergence of Summertime Hypoxia and Concurrent Carbonate Mineral Suppression in the Central Bohai Sea, China

Mussel: a potential pollution indicator in the aquatic ecosystem and effect of climate change

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