Seawater carbonate chemistry and microbioerosion of coral skeletons, supplement to: Reyes-Nivia, Catalina; Diaz-Pulido, Guillermo; Kline, David I; Hoegh-Guldberg, Ove; Dove, Sophie (2013): Ocean acidification and warming scenarios increase microbioerosion of coral skeletons. Global Change Biology, 19(6), 1919-1929

Biological mediation of carbonate dissolution represents a fundamental component of the destructive forces acting on coral reef ecosystems. Whereas ocean acidification can increase dissolution of carbonate substrates, the combined impact of ocean acidification and warming on the microbioerosion of c...

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Main Authors:	Reyes-Nivia, Catalina, Diaz-Pulido, Guillermo, Kline, David I, Hoegh-Guldberg, Ove, Dove, Sophie
Format:	Dataset
Language:	English
Published:	PANGAEA - Data Publisher for Earth & Environmental Science 2013
Subjects:	Animalia Benthic animals Benthos Bottles or small containers/Aquaria <20 L Calcification/Dissolution Cnidaria Coast and continental shelf Hyella sp Isopora cuneata Laboratory experiment Mastigocoleus testarum Oscillatoria spp Ostreobium spp Plectonema terebrans Porites cylindrica Respiration Single species South Pacific Spirulina sp. Temperate Temperature Identification Species Treatment Irradiance Dissolution/calcification Dissolution/calcification, standard error Biomass Biomass, standard error Abundance Abundance, standard error Dissolution rate of calcium carbonate Respiration rate, oxygen pH Distance Temperature, water Temperature, water, standard error Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide water at sea surface temperature wet air, standard error Alkalinity, total Alkalinity, total, standard error pH, standard error Aragonite saturation state Aragonite saturation state, standard error Bicarbonate ion Bicarbonate ion, standard error Carbonate ion Carbonate ion, standard error Salinity Salinity, standard error Carbonate system computation flag Carbon dioxide Fugacity of carbon dioxide water at sea surface temperature wet air Carbon, inorganic, dissolved Calcite saturation state Loss of ignition analysis Buoyant weighing technique Davies, 1989 Potentiometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC Catalina Diaz Hoegh Pacific Ocean acidification
Online Access:	https://dx.doi.org/10.1594/pangaea.830261 https://doi.pangaea.de/10.1594/PANGAEA.830261

id	ftdatacite:10.1594/pangaea.830261
record_format	openpolar
institution	Open Polar
collection	DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id	ftdatacite
language	English
topic	Animalia Benthic animals Benthos Bottles or small containers/Aquaria <20 L Calcification/Dissolution Cnidaria Coast and continental shelf Hyella sp Isopora cuneata Laboratory experiment Mastigocoleus testarum Oscillatoria spp Ostreobium spp Plectonema terebrans Porites cylindrica Respiration Single species South Pacific Spirulina sp. Temperate Temperature Identification Species Treatment Irradiance Dissolution/calcification Dissolution/calcification, standard error Biomass Biomass, standard error Abundance Abundance, standard error Dissolution rate of calcium carbonate Respiration rate, oxygen pH Distance Temperature, water Temperature, water, standard error Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide water at sea surface temperature wet air, standard error Alkalinity, total Alkalinity, total, standard error pH, standard error Aragonite saturation state Aragonite saturation state, standard error Bicarbonate ion Bicarbonate ion, standard error Carbonate ion Carbonate ion, standard error Salinity Salinity, standard error Carbonate system computation flag Carbon dioxide Fugacity of carbon dioxide water at sea surface temperature wet air Carbon, inorganic, dissolved Calcite saturation state Loss of ignition analysis Buoyant weighing technique Davies, 1989 Potentiometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC
spellingShingle	Animalia Benthic animals Benthos Bottles or small containers/Aquaria <20 L Calcification/Dissolution Cnidaria Coast and continental shelf Hyella sp Isopora cuneata Laboratory experiment Mastigocoleus testarum Oscillatoria spp Ostreobium spp Plectonema terebrans Porites cylindrica Respiration Single species South Pacific Spirulina sp. Temperate Temperature Identification Species Treatment Irradiance Dissolution/calcification Dissolution/calcification, standard error Biomass Biomass, standard error Abundance Abundance, standard error Dissolution rate of calcium carbonate Respiration rate, oxygen pH Distance Temperature, water Temperature, water, standard error Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide water at sea surface temperature wet air, standard error Alkalinity, total Alkalinity, total, standard error pH, standard error Aragonite saturation state Aragonite saturation state, standard error Bicarbonate ion Bicarbonate ion, standard error Carbonate ion Carbonate ion, standard error Salinity Salinity, standard error Carbonate system computation flag Carbon dioxide Fugacity of carbon dioxide water at sea surface temperature wet air Carbon, inorganic, dissolved Calcite saturation state Loss of ignition analysis Buoyant weighing technique Davies, 1989 Potentiometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC Reyes-Nivia, Catalina Diaz-Pulido, Guillermo Kline, David I Hoegh-Guldberg, Ove Dove, Sophie Seawater carbonate chemistry and microbioerosion of coral skeletons, supplement to: Reyes-Nivia, Catalina; Diaz-Pulido, Guillermo; Kline, David I; Hoegh-Guldberg, Ove; Dove, Sophie (2013): Ocean acidification and warming scenarios increase microbioerosion of coral skeletons. Global Change Biology, 19(6), 1919-1929
topic_facet	Animalia Benthic animals Benthos Bottles or small containers/Aquaria <20 L Calcification/Dissolution Cnidaria Coast and continental shelf Hyella sp Isopora cuneata Laboratory experiment Mastigocoleus testarum Oscillatoria spp Ostreobium spp Plectonema terebrans Porites cylindrica Respiration Single species South Pacific Spirulina sp. Temperate Temperature Identification Species Treatment Irradiance Dissolution/calcification Dissolution/calcification, standard error Biomass Biomass, standard error Abundance Abundance, standard error Dissolution rate of calcium carbonate Respiration rate, oxygen pH Distance Temperature, water Temperature, water, standard error Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide water at sea surface temperature wet air, standard error Alkalinity, total Alkalinity, total, standard error pH, standard error Aragonite saturation state Aragonite saturation state, standard error Bicarbonate ion Bicarbonate ion, standard error Carbonate ion Carbonate ion, standard error Salinity Salinity, standard error Carbonate system computation flag Carbon dioxide Fugacity of carbon dioxide water at sea surface temperature wet air Carbon, inorganic, dissolved Calcite saturation state Loss of ignition analysis Buoyant weighing technique Davies, 1989 Potentiometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC
description	Biological mediation of carbonate dissolution represents a fundamental component of the destructive forces acting on coral reef ecosystems. Whereas ocean acidification can increase dissolution of carbonate substrates, the combined impact of ocean acidification and warming on the microbioerosion of coral skeletons remains unknown. Here, we exposed skeletons of the reef-building corals, Porites cylindrica and Isopora cuneata, to present-day (Control: 400 µatm - 24 °C) and future pCO2-temperature scenarios projected for the end of the century (Medium: +230 µatm - +2 °C; High: +610 µatm - +4 °C). Skeletons were also subjected to permanent darkness with initial sodium hypochlorite incubation, and natural light without sodium hypochlorite incubation to isolate the environmental effect of acidic seawater (i.e., Omega aragonite <1) from the biological effect of photosynthetic microborers. Our results indicated that skeletal dissolution is predominantly driven by photosynthetic microborers, as samples held in the dark did not decalcify. In contrast, dissolution of skeletons exposed to light increased under elevated pCO2-temperature scenarios, with P. cylindrica experiencing higher dissolution rates per month (89%) than I. cuneata (46%) in the high treatment relative to control. The effects of future pCO2-temperature scenarios on the structure of endolithic communities were only identified in P. cylindrica and were mostly associated with a higher abundance of the green algae Ostreobium spp. Enhanced skeletal dissolution was also associated with increased endolithic biomass and respiration under elevated pCO2-temperature scenarios. Our results suggest that future projections of ocean acidification and warming will lead to increased rates of microbioerosion. However, the magnitude of bioerosion responses may depend on the structural properties of coral skeletons, with a range of implications for reef carbonate losses under warmer and more acidic oceans. : In order to allow full comparability with other ocean acidification data sets, the R package seacarb (Lavigne and Gattuso, 2011) 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 by seacarb is 2014-03-03.
format	Dataset
author	Reyes-Nivia, Catalina Diaz-Pulido, Guillermo Kline, David I Hoegh-Guldberg, Ove Dove, Sophie
author_facet	Reyes-Nivia, Catalina Diaz-Pulido, Guillermo Kline, David I Hoegh-Guldberg, Ove Dove, Sophie
author_sort	Reyes-Nivia, Catalina
title	Seawater carbonate chemistry and microbioerosion of coral skeletons, supplement to: Reyes-Nivia, Catalina; Diaz-Pulido, Guillermo; Kline, David I; Hoegh-Guldberg, Ove; Dove, Sophie (2013): Ocean acidification and warming scenarios increase microbioerosion of coral skeletons. Global Change Biology, 19(6), 1919-1929
title_short	Seawater carbonate chemistry and microbioerosion of coral skeletons, supplement to: Reyes-Nivia, Catalina; Diaz-Pulido, Guillermo; Kline, David I; Hoegh-Guldberg, Ove; Dove, Sophie (2013): Ocean acidification and warming scenarios increase microbioerosion of coral skeletons. Global Change Biology, 19(6), 1919-1929
title_full	Seawater carbonate chemistry and microbioerosion of coral skeletons, supplement to: Reyes-Nivia, Catalina; Diaz-Pulido, Guillermo; Kline, David I; Hoegh-Guldberg, Ove; Dove, Sophie (2013): Ocean acidification and warming scenarios increase microbioerosion of coral skeletons. Global Change Biology, 19(6), 1919-1929
title_fullStr	Seawater carbonate chemistry and microbioerosion of coral skeletons, supplement to: Reyes-Nivia, Catalina; Diaz-Pulido, Guillermo; Kline, David I; Hoegh-Guldberg, Ove; Dove, Sophie (2013): Ocean acidification and warming scenarios increase microbioerosion of coral skeletons. Global Change Biology, 19(6), 1919-1929
title_full_unstemmed	Seawater carbonate chemistry and microbioerosion of coral skeletons, supplement to: Reyes-Nivia, Catalina; Diaz-Pulido, Guillermo; Kline, David I; Hoegh-Guldberg, Ove; Dove, Sophie (2013): Ocean acidification and warming scenarios increase microbioerosion of coral skeletons. Global Change Biology, 19(6), 1919-1929
title_sort	seawater carbonate chemistry and microbioerosion of coral skeletons, supplement to: reyes-nivia, catalina; diaz-pulido, guillermo; kline, david i; hoegh-guldberg, ove; dove, sophie (2013): ocean acidification and warming scenarios increase microbioerosion of coral skeletons. global change biology, 19(6), 1919-1929
publisher	PANGAEA - Data Publisher for Earth & Environmental Science
publishDate	2013
url	https://dx.doi.org/10.1594/pangaea.830261 https://doi.pangaea.de/10.1594/PANGAEA.830261
long_lat	ENVELOPE(-59.633,-59.633,-62.333,-62.333) ENVELOPE(-60.667,-60.667,-63.783,-63.783) ENVELOPE(-62.777,-62.777,-64.830,-64.830)
geographic	Catalina Diaz Hoegh Pacific
geographic_facet	Catalina Diaz Hoegh Pacific
genre	Ocean acidification
genre_facet	Ocean acidification
op_relation	https://cran.r-project.org/package=seacarb https://dx.doi.org/10.1111/gcb.12158 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.830261 https://doi.org/10.1111/gcb.12158
_version_	1766156676184932352
spelling	ftdatacite:10.1594/pangaea.830261 2023-05-15T17:50:05+02:00 Seawater carbonate chemistry and microbioerosion of coral skeletons, supplement to: Reyes-Nivia, Catalina; Diaz-Pulido, Guillermo; Kline, David I; Hoegh-Guldberg, Ove; Dove, Sophie (2013): Ocean acidification and warming scenarios increase microbioerosion of coral skeletons. Global Change Biology, 19(6), 1919-1929 Reyes-Nivia, Catalina Diaz-Pulido, Guillermo Kline, David I Hoegh-Guldberg, Ove Dove, Sophie 2013 text/tab-separated-values https://dx.doi.org/10.1594/pangaea.830261 https://doi.pangaea.de/10.1594/PANGAEA.830261 en eng PANGAEA - Data Publisher for Earth & Environmental Science https://cran.r-project.org/package=seacarb https://dx.doi.org/10.1111/gcb.12158 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 Animalia Benthic animals Benthos Bottles or small containers/Aquaria <20 L Calcification/Dissolution Cnidaria Coast and continental shelf Hyella sp Isopora cuneata Laboratory experiment Mastigocoleus testarum Oscillatoria spp Ostreobium spp Plectonema terebrans Porites cylindrica Respiration Single species South Pacific Spirulina sp. Temperate Temperature Identification Species Treatment Irradiance Dissolution/calcification Dissolution/calcification, standard error Biomass Biomass, standard error Abundance Abundance, standard error Dissolution rate of calcium carbonate Respiration rate, oxygen pH Distance Temperature, water Temperature, water, standard error Partial pressure of carbon dioxide water at sea surface temperature wet air Partial pressure of carbon dioxide water at sea surface temperature wet air, standard error Alkalinity, total Alkalinity, total, standard error pH, standard error Aragonite saturation state Aragonite saturation state, standard error Bicarbonate ion Bicarbonate ion, standard error Carbonate ion Carbonate ion, standard error Salinity Salinity, standard error Carbonate system computation flag Carbon dioxide Fugacity of carbon dioxide water at sea surface temperature wet air Carbon, inorganic, dissolved Calcite saturation state Loss of ignition analysis Buoyant weighing technique Davies, 1989 Potentiometric titration Calculated using CO2SYS Calculated using seacarb after Nisumaa et al. 2010 Ocean Acidification International Coordination Centre OA-ICC Supplementary Dataset dataset Dataset 2013 ftdatacite https://doi.org/10.1594/pangaea.830261 https://doi.org/10.1111/gcb.12158 2021-11-05T12:55:41Z Biological mediation of carbonate dissolution represents a fundamental component of the destructive forces acting on coral reef ecosystems. Whereas ocean acidification can increase dissolution of carbonate substrates, the combined impact of ocean acidification and warming on the microbioerosion of coral skeletons remains unknown. Here, we exposed skeletons of the reef-building corals, Porites cylindrica and Isopora cuneata, to present-day (Control: 400 µatm - 24 °C) and future pCO2-temperature scenarios projected for the end of the century (Medium: +230 µatm - +2 °C; High: +610 µatm - +4 °C). Skeletons were also subjected to permanent darkness with initial sodium hypochlorite incubation, and natural light without sodium hypochlorite incubation to isolate the environmental effect of acidic seawater (i.e., Omega aragonite <1) from the biological effect of photosynthetic microborers. Our results indicated that skeletal dissolution is predominantly driven by photosynthetic microborers, as samples held in the dark did not decalcify. In contrast, dissolution of skeletons exposed to light increased under elevated pCO2-temperature scenarios, with P. cylindrica experiencing higher dissolution rates per month (89%) than I. cuneata (46%) in the high treatment relative to control. The effects of future pCO2-temperature scenarios on the structure of endolithic communities were only identified in P. cylindrica and were mostly associated with a higher abundance of the green algae Ostreobium spp. Enhanced skeletal dissolution was also associated with increased endolithic biomass and respiration under elevated pCO2-temperature scenarios. Our results suggest that future projections of ocean acidification and warming will lead to increased rates of microbioerosion. However, the magnitude of bioerosion responses may depend on the structural properties of coral skeletons, with a range of implications for reef carbonate losses under warmer and more acidic oceans. : In order to allow full comparability with other ocean acidification data sets, the R package seacarb (Lavigne and Gattuso, 2011) 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 by seacarb is 2014-03-03. Dataset Ocean acidification DataCite Metadata Store (German National Library of Science and Technology) Catalina ENVELOPE(-59.633,-59.633,-62.333,-62.333) Diaz ENVELOPE(-60.667,-60.667,-63.783,-63.783) Hoegh ENVELOPE(-62.777,-62.777,-64.830,-64.830) Pacific

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