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Zittier, Zora M C; Bock, Christian; Sukhotin, Alexey A; Häfker, N Sören; Pörtner, Hans-Otto (2018): Data to Impact of ocean acidification on thermal tolerance and acid-base regulation of Mytilus edulis from the White Sea [dataset]. Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Bremerhaven, PANGAEA, https://doi.org/10.1594/PANGAEA.892316, Supplement to: Zittier, ZMC et al. (2018): Impact of ocean acidification on thermal tolerance and acid–base regulation of Mytilus edulis from the White Sea. Polar Biology, 41(11), 2261-2273, https://doi.org/10.1007/s00300-018-2362-x

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Abstract:
Ocean warming and acidification are two important environmental drivers affecting marine organisms. Organisms living at high latitudes might be especially threatened in near future, as current environmental changes are larger and occur faster. Therefore, we investigated the effect of hypercapnia on thermal tolerance and physiological performance of sub-Arctic Mytilus edulis from the White Sea. Mussels were exposed (2 weeks) to 390 µatm (control) and 1,120 µatm CO2 (year 2100) before respiration rate (MO2), anaerobic metabolite (succinate) level, haemolymph acid-base status, and intracellular pH (pHi) were determined during acute warming (10-28°C, 3°C over night).
In normocapnic mussels, warming induced MO2 to rise exponentially until it levelled off beyond a breakpoint temperature of 20.5°C. Concurrently, haemolymph PCO2 rose significantly >19°C followed by a decrease in PO2 indicating the pejus temperature (TP, onset of thermal limitation). Succinate started to accumulate at 28°C under normocapnia defining the critical temperature (TC). pHi was maintained during warming until it dropped at 28°C, in line with the concomitant transition to anaerobiosis. At acclimation temperature, CO2 had only a minor impact. During warming, MO2 was stimulated by CO2 resulting in an elevated breakpoint of 25.8°C. Nevertheless, alterations in haemolymph gases (>16°C) and the concomitant changes of pHi and succinate level (25°C) occurred at lower temperature under hypercapnia versus normocapnia indicating a downward shift of both thermal limits TP and TC by CO2.
Compared to temperate conspecifics, sub-Arctic mussels showed an enhanced thermal sensitivity, exacerbated further by hypercapnia, indicating their potential vulnerability to environmental changes projected for 2100.
Project(s):
European Project on Ocean Acidification (EPOCA)
Funding:
Seventh Framework Programme (FP7), grant/award no. 211384: European Project on Ocean Acidification
Coverage:
Latitude: 66.337000 * Longitude: 33.637000
Event(s):
EPOCA_White_Sea * Latitude: 66.337000 * Longitude: 33.637000 * Location: White Sea * Method/Device: Experiment (EXP)
Parameter(s):
#NameShort NameUnitPrincipal InvestigatorMethod/DeviceComment
1Experimental treatmentExp treatPörtner, Hans-OttoCO2
2Temperature, waterTemp°CPörtner, Hans-Otto
3SalinitySalPörtner, Hans-Otto
4Individual codeIndividual codePörtner, Hans-OttoRespective individual
5Respiration rate, oxygen, per dry massResp O2/dmµmol/g/hPörtner, Hans-OttoOxygen optode, flow-through respirometry
6Mytilus edulis, haemolymph, partial pressure of oxygenM. edulis pO2 (ha)kPaPörtner, Hans-OttoBlood gas analyser, Eschweiler, MT 33
7Mytilus edulis, haemolymph, partial pressure of carbon dioxideM. edulis pCO2 (ha)kPaPörtner, Hans-OttoBlood gas analyser, Eschweiler, MT 33
8Mytilus edulis, haemolymph, pHM. edulis pH (ha)Pörtner, Hans-OttoBlood gas analyser, Eschweiler, MT 33National Bureau of Standards (NBS)
9Mytilus edulis, haemolymph, carbon dioxideM. edulis CO2 (ha)mmol/lPörtner, Hans-OttoGas chromatography
10Mytilus edulis, haemolymph, bicarbonate ionM. edulis [HCO3]- (ha)mmol/lPörtner, Hans-OttoCalculated after Heisler 1986
11Mytilus edulis, extrapallial fluid partial pressure of oxygenM. edulis pO2 (epf)kPaPörtner, Hans-OttoBlood gas analyser, Eschweiler, MT 33
12Mytilus edulis, extrapallial fluid partial pressure of carbon dioxideM. edulis pCO2 (epf)kPaPörtner, Hans-OttoBlood gas analyser, Eschweiler, MT 33
13Mytilus edulis, extrapallial fluid pHM. edulis pH (epf)Pörtner, Hans-OttoBlood gas analyser, Eschweiler, MT 33NBS
14Mytilus edulis, extrapallial fluid carbon dioxideM. edulis CO2 (epf)mmol/lPörtner, Hans-OttoGas chromatography
15Mytilus edulis, mantle tissue, succinateM. edulis succinate (mt)arbitrary unitsPörtner, Hans-Otto1H NMR spectroscopy
16Mytilus edulis, mantle tissue, pHM. edulis mantle pH (mt)Pörtner, Hans-OttoHomogenate method by Pörtner et al. 1990 and pH optode, PreSens, Needle-Type-Housing-pH-Microsensor
17Mytilus edulis, mantle tissue, carbon dioxideM. edulis CO2 (mt)mmol/lPörtner, Hans-OttoGas chromatography
18Mytilus edulis, mantle tissue, partial pressure of carbon dioxideM. edulis pCO2 (mt)µatmPörtner, Hans-OttoCalculated after Heisler 1986
19Mytilus edulis, mantle tissue, bicarbonate ionM. edulis [HCO3]- (mt)mmol/lPörtner, Hans-OttoCalculated after Heisler 1986
License:
Creative Commons Attribution-NonCommercial-NoDerivs 3.0 Unported (CC-BY-NC-ND-3.0)
Size:
2034 data points

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