Physiological basis for high CO&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt; tolerance in marine ectothermic animals: pre-adaptation through lifestyle and ontogeny?

Melzner, Frank; Gutowska, Magdalena A.; Langenbuch, M.; Dupont, Sam; Lucassen, Magnus; Thorndyke, Mike; Bleich, Markus; Pörtner, Hans‐Otto

doi:10.5194/bg-6-2313-2009

Cited by 574 publications

(439 citation statements)

References 145 publications

(66 reference statements)

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“…117 On the other hand substantial acid-base regulatory abilities as found in most cephalopod species represents a common feature that was suggested to make ectothermic marine animals robust to seawater acidification. 45 However, metabolic data from the cuttlefish S. officinalis (acute exposure to 0.6 kPa pCO 2 ) and the squids Dosidicus gigas (acute exposure to 0.1 kPa pCO 2 ) and Sepiteuthis lessoniana (acute; 20 h medium term; 168 h 0.16 and 0.41 kPa pCO 2 ) indicated that these animals respond very differently toward environmental hypercapnia. 12,118,119 Although these studies partly used unrealistically high pCO 2 levels, in the context of environmental hypercania (usually >0.1 kPa), they could indicate a higher sensitivity in active pelagic squids compared to cuttlefish that have a benthic lifestyle.…”

Section: Role Of Ion Regulatory Epithelia During Acclimation To Envirmentioning

confidence: 99%

“…45,48,117 Environmental hypercapnia that alters positive diffusion gradients of CO 2 from the animal to the seawater will affect the acid-base physiology of all water breathing animals as intra-and extra-cellular CO 2 concentrations will increase as well to maintain a sufficient diffusion gradient to excrete metabolic CO 2 . 45 Among a range of marine species, some have been identified as more sensitive (e.g. less active calcifying species such as corals or echinoderms) whereas others (many active species such as adult fish and cephalopods) can tolerate relatively high CO 2 concentrations over long exposure times.…”

Section: Role Of Ion Regulatory Epithelia During Acclimation To Envirmentioning

confidence: 99%

“…45 Anthropogenic CO 2 emissions are predicted to lead to a rise in surface ocean pCO 2 from 0.04 kPa up to 0.08 -0.14 kPa within this century. 46 The increased hydration of CO 2 changes seawater chemistry, causing a drop in ocean pH.…”

Section: Identification Of Ion-regulation and Excretory Organs In Cepmentioning

confidence: 99%

“…49,50 A major hypothesis that had to be tested was, if the ability to compensate for a hypercapnia -induced acidosis by actively accumulating bicarbonate and eliminating protons from their body fluids is a general, unifying feature of tolerant organisms. 45 Thus, a first step was dedicated to the identification of acid-base regulatory structures in marine species and the characterization of the underlying ion-regulatory machinery including ion transporters and channels. The advances in molecular biology and available genomes and transcriptomes of the 21 st century have opened new venues to re-address the mechanisms of ion / pH regulation and excretion in non-model species like cephalopods.…”

Section: Identification Of Ion-regulation and Excretory Organs In Cepmentioning

confidence: 99%

See 3 more Smart Citations

Recent advances in understanding trans-epithelial acid-base regulation and excretion mechanisms in cephalopods

Hwang

Tseng

2015

Tissue Barriers

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Cephalopods have evolved complex sensory systems and an active lifestyle to compete with fish for similar resources in the marine environment. Their highly active lifestyle and their extensive protein metabolism has led to substantial acid-base regulatory abilities enabling these organisms to cope with CO 2 induced acid-base disturbances. In convergence to teleost, cephalopods possess an ontogeny-dependent shift in ion-regulatory epithelia with epidermal ionocytes being the major site of embryonic acid-base regulation and ammonia excretion, while gill epithelia take these functions in adults. Although the basic morphology and excretory function of gill epithelia in cephalopods were outlined almost half a century ago, modern immunohistological and molecular techniques are bringing new insights to the mechanistic basis of acidbase regulation and excretion of nitrogenous waste products (e.g. NH 3 /NH 4 C ) across ion regulatory epithelia of cephalopods. Using cephalopods as an invertebrate model, recent findings reveal partly conserved mechanisms but also novel aspects of acid-base regulation and nitrogen excretion in these exclusively marine animals. Comparative studies using a range of marine invertebrates will create a novel and exciting research direction addressing the evolution of pH regulatory and excretory systems.

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Section: Role Of Ion Regulatory Epithelia During Acclimation To Envirmentioning

confidence: 99%

Section: Role Of Ion Regulatory Epithelia During Acclimation To Envirmentioning

confidence: 99%

Section: Identification Of Ion-regulation and Excretory Organs In Cepmentioning

confidence: 99%

Section: Identification Of Ion-regulation and Excretory Organs In Cepmentioning

confidence: 99%

See 2 more Smart Citations

Recent advances in understanding trans-epithelial acid-base regulation and excretion mechanisms in cephalopods

Hwang

Tseng

2015

Tissue Barriers

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“…(Keul et al, 2013), and larvae of the Pacific oyster Crassostrea gigas (Gazeau et al, 2011) an inhibitor (Bach et al, 2011(Bach et al, , 2013(Bach et al, , 2015Jokiel, 2011aJokiel, , b, 2013Jokiel et al, 2014 (Bach et al, 2015). Indeed, HCO − 3 uptake is a common mechanism to buffer acidosis and might be facilitated at higher HCO − 3 availability (Boron, 2004;Melzner et al, 2009;Stumpp et al, 2012).…”

Section: Stabilitymentioning

confidence: 99%

Reconsidering the role of carbonate ion concentration in calcification by marine organisms

Bach

2015

Biogeosciences

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Abstract. Marine organisms precipitate 0.5-2.0 Gt of carbon as calcium carbonate (CaCO 3 ) every year with a profound impact on global biogeochemical element cycles. Biotic calcification relies on calcium ions (Ca 2+ ) and usually on bicarbonate ions (HCO − 3 ) as CaCO 3 substrates and can be inhibited by high proton (H + ) concentrations. The seawater concentration of carbonate ions (CO 2− 3 ) and the CO 2− 3 -dependent CaCO 3 saturation state ( CaCO 3 ) seem to be irrelevant in this production process. Nevertheless, calcification rates and the success of calcifying organisms in the oceans often correlate surprisingly well with these two carbonate system parameters. This study addresses this dilemma through the rearrangement of carbonate system equations which revealed an important proportionality between [CO

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Long‐Term and Seasonal Trends in Estuarine and Coastal Carbonate Systems

Carstensen

Chierici

Gustafsson

et al. 2018

Global Biogeochemical Cycles

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Coastal pH and total alkalinity are regulated by a diverse range of local processes superimposed on global trends of warming and ocean acidification, yet few studies have investigated the relative importance of different processes for coastal acidification. We describe long‐term (1972–2016) and seasonal trends in the carbonate system of three Danish coastal systems demonstrating that hydrological modification, changes in nutrient inputs from land, and presence/absence of calcifiers can drastically alter carbonate chemistry. Total alkalinity was mainly governed by conservative mixing of freshwater (0.73–5.17 mmol kg−1) with outer boundary concentrations (~2–2.4 mmol kg−1), modulated seasonally and spatially (~0.1–0.2 mmol kg−1) by calcifiers. Nitrate assimilation by primary production, denitrification, and sulfate reduction increased total alkalinity by almost 0.6 mmol kg−1 in the most eutrophic system during a period without calcifiers. Trends in pH ranged from −0.0088 year−1 to 0.021 year−1, the more extreme of these mainly driven by salinity changes in a sluice‐controlled lagoon. Temperature increased 0.05°C yr−1 across all three systems, which directly accounted for a pH decrease of 0.0008 year−1. Accounting for mixing, salinity, and temperature effects on dissociation and solubility constants, the resulting pH decline (0.0040 year−1) was about twice the ocean trend, emphasizing the effect of nutrient management on primary production and coastal acidification. Coastal pCO2 increased ~4 times more rapidly than ocean rates, enhancing CO2 emissions to the atmosphere. Indeed, coastal systems undergo more drastic changes than the ocean and coastal acidification trends are substantially enhanced from nutrient reductions to address coastal eutrophication.

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Physiological basis for high CO<sub>2</sub> tolerance in marine ectothermic animals: pre-adaptation through lifestyle and ontogeny?

Cited by 574 publications

References 145 publications

Recent advances in understanding trans-epithelial acid-base regulation and excretion mechanisms in cephalopods

Recent advances in understanding trans-epithelial acid-base regulation and excretion mechanisms in cephalopods

Reconsidering the role of carbonate ion concentration in calcification by marine organisms

Long‐Term and Seasonal Trends in Estuarine and Coastal Carbonate Systems

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