Data to Impact of ocean acidification on thermal tolerance and acid-base regulation of Mytilus edulis from the White Sea

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...

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Main Authors: Zittier, Zora M C, Bock, Christian, Sukhotin, Alexey A, Häfker, N Sören, Pörtner, Hans-Otto
Format: Dataset
Language:English
Published: PANGAEA 2018
Subjects:
1H NMR spectroscopy
Blood gas analyser
Eschweiler
MT 33
Calculated after Heisler 1986
EPOCA
EPOCA_White_Sea
European Project on Ocean Acidification
EXP
Experiment
Experimental treatment
Gas chromatography
Homogenate method by Pörtner et al. 1990 and pH optode
PreSens
Needle-Type-Housing-pH-Microsensor
Individual code
Mytilus edulis
extrapallial fluid carbon dioxide
extrapallial fluid partial pressure of carbon dioxide
extrapallial fluid partial pressure of oxygen
extrapallial fluid pH
haemolymph
bicarbonate ion
carbon dioxide
partial pressure of carbon dioxide
partial pressure of oxygen
pH
mantle tissue
Arctic
White Sea
Ocean acidification
Polar Biology
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.892316
https://doi.org/10.1594/PANGAEA.892316
id ftpangaea:oai:pangaea.de:doi:10.1594/PANGAEA.892316
record_format openpolar
spelling ftpangaea:oai:pangaea.de:doi:10.1594/PANGAEA.892316 2023-05-15T15:03:53+02:00 Data to Impact of ocean acidification on thermal tolerance and acid-base regulation of Mytilus edulis from the White Sea Zittier, Zora M C Bock, Christian Sukhotin, Alexey A Häfker, N Sören Pörtner, Hans-Otto LATITUDE: 66.337000 * LONGITUDE: 33.637000 2018-07-11 text/tab-separated-values, 2034 data points https://doi.pangaea.de/10.1594/PANGAEA.892316 https://doi.org/10.1594/PANGAEA.892316 en eng PANGAEA https://doi.pangaea.de/10.1594/PANGAEA.892316 https://doi.org/10.1594/PANGAEA.892316 CC-BY-NC-ND-3.0: Creative Commons Attribution-NonCommercial-NoDerivs 3.0 Unported Access constraints: unrestricted info:eu-repo/semantics/openAccess CC-BY-NC-ND Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Bremerhaven Supplement to: Zittier, Zora M C; Bock, Christian; Sukhotin, Alexey A; Häfker, N Sören; Pörtner, Hans-Otto (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 1H NMR spectroscopy Blood gas analyser Eschweiler MT 33 Calculated after Heisler 1986 EPOCA EPOCA_White_Sea European Project on Ocean Acidification EXP Experiment Experimental treatment Gas chromatography Homogenate method by Pörtner et al. 1990 and pH optode PreSens Needle-Type-Housing-pH-Microsensor Individual code Mytilus edulis extrapallial fluid carbon dioxide extrapallial fluid partial pressure of carbon dioxide extrapallial fluid partial pressure of oxygen extrapallial fluid pH haemolymph bicarbonate ion carbon dioxide partial pressure of carbon dioxide partial pressure of oxygen pH mantle tissue Dataset 2018 ftpangaea https://doi.org/10.1594/PANGAEA.892316 https://doi.org/10.1007/s00300-018-2362-x 2023-01-20T09:11:18Z 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. Dataset Arctic Ocean acidification Polar Biology White Sea PANGAEA - Data Publisher for Earth & Environmental Science Arctic White Sea ENVELOPE(33.637000,33.637000,66.337000,66.337000)
institution Open Polar
collection PANGAEA - Data Publisher for Earth & Environmental Science
op_collection_id ftpangaea
language English
topic 1H NMR spectroscopy
Blood gas analyser
Eschweiler
MT 33
Calculated after Heisler 1986
EPOCA
EPOCA_White_Sea
European Project on Ocean Acidification
EXP
Experiment
Experimental treatment
Gas chromatography
Homogenate method by Pörtner et al. 1990 and pH optode
PreSens
Needle-Type-Housing-pH-Microsensor
Individual code
Mytilus edulis
extrapallial fluid carbon dioxide
extrapallial fluid partial pressure of carbon dioxide
extrapallial fluid partial pressure of oxygen
extrapallial fluid pH
haemolymph
bicarbonate ion
carbon dioxide
partial pressure of carbon dioxide
partial pressure of oxygen
pH
mantle tissue
spellingShingle 1H NMR spectroscopy
Blood gas analyser
Eschweiler
MT 33
Calculated after Heisler 1986
EPOCA
EPOCA_White_Sea
European Project on Ocean Acidification
EXP
Experiment
Experimental treatment
Gas chromatography
Homogenate method by Pörtner et al. 1990 and pH optode
PreSens
Needle-Type-Housing-pH-Microsensor
Individual code
Mytilus edulis
extrapallial fluid carbon dioxide
extrapallial fluid partial pressure of carbon dioxide
extrapallial fluid partial pressure of oxygen
extrapallial fluid pH
haemolymph
bicarbonate ion
carbon dioxide
partial pressure of carbon dioxide
partial pressure of oxygen
pH
mantle tissue
Zittier, Zora M C
Bock, Christian
Sukhotin, Alexey A
Häfker, N Sören
Pörtner, Hans-Otto
Data to Impact of ocean acidification on thermal tolerance and acid-base regulation of Mytilus edulis from the White Sea
topic_facet 1H NMR spectroscopy
Blood gas analyser
Eschweiler
MT 33
Calculated after Heisler 1986
EPOCA
EPOCA_White_Sea
European Project on Ocean Acidification
EXP
Experiment
Experimental treatment
Gas chromatography
Homogenate method by Pörtner et al. 1990 and pH optode
PreSens
Needle-Type-Housing-pH-Microsensor
Individual code
Mytilus edulis
extrapallial fluid carbon dioxide
extrapallial fluid partial pressure of carbon dioxide
extrapallial fluid partial pressure of oxygen
extrapallial fluid pH
haemolymph
bicarbonate ion
carbon dioxide
partial pressure of carbon dioxide
partial pressure of oxygen
pH
mantle tissue
description 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.
format Dataset
author Zittier, Zora M C
Bock, Christian
Sukhotin, Alexey A
Häfker, N Sören
Pörtner, Hans-Otto
author_facet Zittier, Zora M C
Bock, Christian
Sukhotin, Alexey A
Häfker, N Sören
Pörtner, Hans-Otto
author_sort Zittier, Zora M C
title Data to Impact of ocean acidification on thermal tolerance and acid-base regulation of Mytilus edulis from the White Sea
title_short Data to Impact of ocean acidification on thermal tolerance and acid-base regulation of Mytilus edulis from the White Sea
title_full Data to Impact of ocean acidification on thermal tolerance and acid-base regulation of Mytilus edulis from the White Sea
title_fullStr Data to Impact of ocean acidification on thermal tolerance and acid-base regulation of Mytilus edulis from the White Sea
title_full_unstemmed Data to Impact of ocean acidification on thermal tolerance and acid-base regulation of Mytilus edulis from the White Sea
title_sort data to impact of ocean acidification on thermal tolerance and acid-base regulation of mytilus edulis from the white sea
publisher PANGAEA
publishDate 2018
url https://doi.pangaea.de/10.1594/PANGAEA.892316
https://doi.org/10.1594/PANGAEA.892316
op_coverage LATITUDE: 66.337000 * LONGITUDE: 33.637000
long_lat ENVELOPE(33.637000,33.637000,66.337000,66.337000)
geographic Arctic
White Sea
geographic_facet Arctic
White Sea
genre Arctic
Ocean acidification
Polar Biology
White Sea
genre_facet Arctic
Ocean acidification
Polar Biology
White Sea
op_source Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Bremerhaven
Supplement to: Zittier, Zora M C; Bock, Christian; Sukhotin, Alexey A; Häfker, N Sören; Pörtner, Hans-Otto (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
op_relation https://doi.pangaea.de/10.1594/PANGAEA.892316
https://doi.org/10.1594/PANGAEA.892316
op_rights CC-BY-NC-ND-3.0: Creative Commons Attribution-NonCommercial-NoDerivs 3.0 Unported
Access constraints: unrestricted
info:eu-repo/semantics/openAccess
op_rightsnorm CC-BY-NC-ND
op_doi https://doi.org/10.1594/PANGAEA.892316
https://doi.org/10.1007/s00300-018-2362-x
_version_ 1766335734837411840

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