Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification?, supplement to: Collard, Marie; De Ridder, Chantal; David, Bruno; Dehairs, Frank; Dubois, Philippe (2014): Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification? Global Change Biology

Increasing atmospheric carbon dioxide concentration alters the chemistry of the oceans towards more acidic conditions. Polar oceans are particularly affected due to their low temperature, low carbonate content and mixing patterns, for instance upwellings. Calcifying organisms are expected to be high...

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Main Authors:	Collard, Marie, De Ridder, Chantal, David, Bruno, Dehairs, Frank, Dubois, Philippe
Format:	Dataset
Language:	English
Published:	PANGAEA - Data Publisher for Earth & Environmental Science 2015
Subjects:	Abatus cavernosus Acid-base regulation Amphipneustes lorioli Amphipneustes rostratus Amphipneustes similis Animalia Antarctic Aporocidaris eltaniana Benthic animals Benthos Coast and continental shelf Ctenocidaris gigantea Echinodermata Field observation Notocidaris gaussensis Polar Single species Sterechinus antarcticus Sterechinus neumayeri Event label DATE/TIME Station label LONGITUDE LATITUDE Species Size Coelomic fluid, pH pH pH, standard deviation Difference Coelomic fluid, alkalinity Alkalinity, total Alkalinity, total, standard deviation Coelomic fluid, carbon, inorganic, dissolved Carbon, inorganic, dissolved δ13C Temperature, water Salinity Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide, standard deviation Carbon dioxide Carbon dioxide, standard deviation Bicarbonate ion Bicarbonate ion, standard deviation Carbonate ion Carbonate ion, standard deviation Calcite saturation state Calcite saturation state, standard deviation Aragonite saturation state Aragonite saturation state, standard deviation Carbonate system computation flag Fugacity of carbon dioxide water at sea surface temperature wet air Experiment Potentiometric Calculated Potentiometric titration Coulometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC DuBois Collard Antarc* antarcticus Ocean acidification
Online Access:	https://dx.doi.org/10.1594/pangaea.839887 https://doi.pangaea.de/10.1594/PANGAEA.839887

id	ftdatacite:10.1594/pangaea.839887
record_format	openpolar
institution	Open Polar
collection	DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id	ftdatacite
language	English
topic	Abatus cavernosus Acid-base regulation Amphipneustes lorioli Amphipneustes rostratus Amphipneustes similis Animalia Antarctic Aporocidaris eltaniana Benthic animals Benthos Coast and continental shelf Ctenocidaris gigantea Echinodermata Field observation Notocidaris gaussensis Polar Single species Sterechinus antarcticus Sterechinus neumayeri Event label DATE/TIME Station label LONGITUDE LATITUDE Species Size Coelomic fluid, pH pH pH, standard deviation Difference Coelomic fluid, alkalinity Alkalinity, total Alkalinity, total, standard deviation Coelomic fluid, carbon, inorganic, dissolved Carbon, inorganic, dissolved δ13C Temperature, water Salinity Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide, standard deviation Carbon dioxide Carbon dioxide, standard deviation Bicarbonate ion Bicarbonate ion, standard deviation Carbonate ion Carbonate ion, standard deviation Calcite saturation state Calcite saturation state, standard deviation Aragonite saturation state Aragonite saturation state, standard deviation Carbonate system computation flag Fugacity of carbon dioxide water at sea surface temperature wet air Experiment Potentiometric Calculated Potentiometric titration Coulometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC
spellingShingle	Abatus cavernosus Acid-base regulation Amphipneustes lorioli Amphipneustes rostratus Amphipneustes similis Animalia Antarctic Aporocidaris eltaniana Benthic animals Benthos Coast and continental shelf Ctenocidaris gigantea Echinodermata Field observation Notocidaris gaussensis Polar Single species Sterechinus antarcticus Sterechinus neumayeri Event label DATE/TIME Station label LONGITUDE LATITUDE Species Size Coelomic fluid, pH pH pH, standard deviation Difference Coelomic fluid, alkalinity Alkalinity, total Alkalinity, total, standard deviation Coelomic fluid, carbon, inorganic, dissolved Carbon, inorganic, dissolved δ13C Temperature, water Salinity Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide, standard deviation Carbon dioxide Carbon dioxide, standard deviation Bicarbonate ion Bicarbonate ion, standard deviation Carbonate ion Carbonate ion, standard deviation Calcite saturation state Calcite saturation state, standard deviation Aragonite saturation state Aragonite saturation state, standard deviation Carbonate system computation flag Fugacity of carbon dioxide water at sea surface temperature wet air Experiment Potentiometric Calculated Potentiometric titration Coulometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC Collard, Marie De Ridder, Chantal David, Bruno Dehairs, Frank Dubois, Philippe Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification?, supplement to: Collard, Marie; De Ridder, Chantal; David, Bruno; Dehairs, Frank; Dubois, Philippe (2014): Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification? Global Change Biology
topic_facet	Abatus cavernosus Acid-base regulation Amphipneustes lorioli Amphipneustes rostratus Amphipneustes similis Animalia Antarctic Aporocidaris eltaniana Benthic animals Benthos Coast and continental shelf Ctenocidaris gigantea Echinodermata Field observation Notocidaris gaussensis Polar Single species Sterechinus antarcticus Sterechinus neumayeri Event label DATE/TIME Station label LONGITUDE LATITUDE Species Size Coelomic fluid, pH pH pH, standard deviation Difference Coelomic fluid, alkalinity Alkalinity, total Alkalinity, total, standard deviation Coelomic fluid, carbon, inorganic, dissolved Carbon, inorganic, dissolved δ13C Temperature, water Salinity Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide, standard deviation Carbon dioxide Carbon dioxide, standard deviation Bicarbonate ion Bicarbonate ion, standard deviation Carbonate ion Carbonate ion, standard deviation Calcite saturation state Calcite saturation state, standard deviation Aragonite saturation state Aragonite saturation state, standard deviation Carbonate system computation flag Fugacity of carbon dioxide water at sea surface temperature wet air Experiment Potentiometric Calculated Potentiometric titration Coulometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC
description	Increasing atmospheric carbon dioxide concentration alters the chemistry of the oceans towards more acidic conditions. Polar oceans are particularly affected due to their low temperature, low carbonate content and mixing patterns, for instance upwellings. Calcifying organisms are expected to be highly impacted by the decrease in the oceans' pH and carbonate ions concentration. In particular, sea urchins, members of the phylum Echinodermata, are hypothesized to be at risk due to their high-magnesium calcite skeleton. However, tolerance to ocean acidification in metazoans is first linked to acid-base regulation capacities of the extracellular fluids. No information on this is available to date for Antarctic echinoderms and inference from temperate and tropical studies needs support. In this study, we investigated the acid-base status of 9 species of sea urchins (3 cidaroids, 2 regular euechinoids and 4 irregular echinoids). It appears that Antarctic regular euechinoids seem equipped with similar acid-base regulation systems as tropical and temperate regular euechinoids but could rely on more passive ion transfer systems, minimizing energy requirements. Cidaroids have an acid-base status similar to that of tropical cidaroids. Therefore Antarctic cidaroids will most probably not be affected by decreasing seawater pH, the pH drop linked to ocean acidification being negligible in comparison of the naturally low pH of the coelomic fluid. Irregular echinoids might not suffer from reduced seawater pH if acidosis of the coelomic fluid pH does not occur but more data on their acid-base regulation are needed. Combining these results with the resilience of Antarctic sea urchin larvae strongly suggests that these organisms might not be the expected victims of ocean acidification. However, data on the impact of other global stressors such as temperature and of the combination of the different stressors needs to be acquired to assess the sensitivity of these organisms to global change. : In order to allow full comparability with other ocean acidification data sets, the R package seacarb (Lavigne et al, 2014) was used to compute a complete and consistent set of carbonate system variables, as described by Nisumaa et al. (2010). In this dataset the original values were archived in addition with the recalculated parameters (see related PI). The date of carbonate chemistry calculation is 2014-12-01.
format	Dataset
author	Collard, Marie De Ridder, Chantal David, Bruno Dehairs, Frank Dubois, Philippe
author_facet	Collard, Marie De Ridder, Chantal David, Bruno Dehairs, Frank Dubois, Philippe
author_sort	Collard, Marie
title	Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification?, supplement to: Collard, Marie; De Ridder, Chantal; David, Bruno; Dehairs, Frank; Dubois, Philippe (2014): Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification? Global Change Biology
title_short	Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification?, supplement to: Collard, Marie; De Ridder, Chantal; David, Bruno; Dehairs, Frank; Dubois, Philippe (2014): Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification? Global Change Biology
title_full	Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification?, supplement to: Collard, Marie; De Ridder, Chantal; David, Bruno; Dehairs, Frank; Dubois, Philippe (2014): Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification? Global Change Biology
title_fullStr	Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification?, supplement to: Collard, Marie; De Ridder, Chantal; David, Bruno; Dehairs, Frank; Dubois, Philippe (2014): Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification? Global Change Biology
title_full_unstemmed	Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification?, supplement to: Collard, Marie; De Ridder, Chantal; David, Bruno; Dehairs, Frank; Dubois, Philippe (2014): Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification? Global Change Biology
title_sort	could the acid-base status of antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification?, supplement to: collard, marie; de ridder, chantal; david, bruno; dehairs, frank; dubois, philippe (2014): could the acid-base status of antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification? global change biology
publisher	PANGAEA - Data Publisher for Earth & Environmental Science
publishDate	2015
url	https://dx.doi.org/10.1594/pangaea.839887 https://doi.pangaea.de/10.1594/PANGAEA.839887
long_lat	ENVELOPE(-67.166,-67.166,-66.266,-66.266) ENVELOPE(31.117,31.117,-72.633,-72.633)
geographic	Antarctic DuBois Collard
geographic_facet	Antarctic DuBois Collard
genre	Antarc* Antarctic antarcticus Ocean acidification
genre_facet	Antarc* Antarctic antarcticus Ocean acidification
op_relation	https://cran.r-project.org/package=seacarb https://dx.doi.org/10.1111/gcb.12735 https://cran.r-project.org/package=seacarb
op_rights	Creative Commons Attribution 3.0 Unported https://creativecommons.org/licenses/by/3.0/legalcode cc-by-3.0
op_rightsnorm	CC-BY
op_doi	https://doi.org/10.1594/pangaea.839887 https://doi.org/10.1111/gcb.12735
_version_	1766066616925159424
spelling	ftdatacite:10.1594/pangaea.839887 2023-05-15T13:35:31+02:00 Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification?, supplement to: Collard, Marie; De Ridder, Chantal; David, Bruno; Dehairs, Frank; Dubois, Philippe (2014): Could the acid-base status of Antarctic sea urchins indicate a better-than-expected resilience to near-future ocean acidification? Global Change Biology Collard, Marie De Ridder, Chantal David, Bruno Dehairs, Frank Dubois, Philippe 2015 text/tab-separated-values https://dx.doi.org/10.1594/pangaea.839887 https://doi.pangaea.de/10.1594/PANGAEA.839887 en eng PANGAEA - Data Publisher for Earth & Environmental Science https://cran.r-project.org/package=seacarb https://dx.doi.org/10.1111/gcb.12735 https://cran.r-project.org/package=seacarb Creative Commons Attribution 3.0 Unported https://creativecommons.org/licenses/by/3.0/legalcode cc-by-3.0 CC-BY Abatus cavernosus Acid-base regulation Amphipneustes lorioli Amphipneustes rostratus Amphipneustes similis Animalia Antarctic Aporocidaris eltaniana Benthic animals Benthos Coast and continental shelf Ctenocidaris gigantea Echinodermata Field observation Notocidaris gaussensis Polar Single species Sterechinus antarcticus Sterechinus neumayeri Event label DATE/TIME Station label LONGITUDE LATITUDE Species Size Coelomic fluid, pH pH pH, standard deviation Difference Coelomic fluid, alkalinity Alkalinity, total Alkalinity, total, standard deviation Coelomic fluid, carbon, inorganic, dissolved Carbon, inorganic, dissolved δ13C Temperature, water Salinity Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide, standard deviation Carbon dioxide Carbon dioxide, standard deviation Bicarbonate ion Bicarbonate ion, standard deviation Carbonate ion Carbonate ion, standard deviation Calcite saturation state Calcite saturation state, standard deviation Aragonite saturation state Aragonite saturation state, standard deviation Carbonate system computation flag Fugacity of carbon dioxide water at sea surface temperature wet air Experiment Potentiometric Calculated Potentiometric titration Coulometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC Supplementary Dataset dataset Dataset 2015 ftdatacite https://doi.org/10.1594/pangaea.839887 https://doi.org/10.1111/gcb.12735 2021-11-05T12:55:41Z Increasing atmospheric carbon dioxide concentration alters the chemistry of the oceans towards more acidic conditions. Polar oceans are particularly affected due to their low temperature, low carbonate content and mixing patterns, for instance upwellings. Calcifying organisms are expected to be highly impacted by the decrease in the oceans' pH and carbonate ions concentration. In particular, sea urchins, members of the phylum Echinodermata, are hypothesized to be at risk due to their high-magnesium calcite skeleton. However, tolerance to ocean acidification in metazoans is first linked to acid-base regulation capacities of the extracellular fluids. No information on this is available to date for Antarctic echinoderms and inference from temperate and tropical studies needs support. In this study, we investigated the acid-base status of 9 species of sea urchins (3 cidaroids, 2 regular euechinoids and 4 irregular echinoids). It appears that Antarctic regular euechinoids seem equipped with similar acid-base regulation systems as tropical and temperate regular euechinoids but could rely on more passive ion transfer systems, minimizing energy requirements. Cidaroids have an acid-base status similar to that of tropical cidaroids. Therefore Antarctic cidaroids will most probably not be affected by decreasing seawater pH, the pH drop linked to ocean acidification being negligible in comparison of the naturally low pH of the coelomic fluid. Irregular echinoids might not suffer from reduced seawater pH if acidosis of the coelomic fluid pH does not occur but more data on their acid-base regulation are needed. Combining these results with the resilience of Antarctic sea urchin larvae strongly suggests that these organisms might not be the expected victims of ocean acidification. However, data on the impact of other global stressors such as temperature and of the combination of the different stressors needs to be acquired to assess the sensitivity of these organisms to global change. : In order to allow full comparability with other ocean acidification data sets, the R package seacarb (Lavigne et al, 2014) was used to compute a complete and consistent set of carbonate system variables, as described by Nisumaa et al. (2010). In this dataset the original values were archived in addition with the recalculated parameters (see related PI). The date of carbonate chemistry calculation is 2014-12-01. Dataset Antarc* Antarctic antarcticus Ocean acidification DataCite Metadata Store (German National Library of Science and Technology) Antarctic DuBois ENVELOPE(-67.166,-67.166,-66.266,-66.266) Collard ENVELOPE(31.117,31.117,-72.633,-72.633)

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