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Autores principales: Deppeler, Stacy, Schulz, Kai Georg, Hancock, Alyce M, Pascoe, Penelope, McKinlay, John, Davidson, Andrew T
Formato: Dataset Open Access
Lenguaje:en
Publicado: PANGAEA 2020
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Acceso en línea:https://doi.org/10.1594/PANGAEA.926447
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author Deppeler, Stacy
Schulz, Kai Georg
Hancock, Alyce M
Pascoe, Penelope
McKinlay, John
Davidson, Andrew T
author_facet Deppeler, Stacy
Schulz, Kai Georg
Hancock, Alyce M
Pascoe, Penelope
McKinlay, John
Davidson, Andrew T
collection Datos científicos de ciencias marinas y ambientales
contents High-latitude oceans have been identified as particularly vulnerable to ocean acidification if anthropogenic CO2 emissions continue. Marine microbes are an essential part of the marine food web and are a critical link in biogeochemical processes in the ocean, such as the cycling of nutrients and carbon. Despite this, the response of Antarctic marine microbial communities to ocean acidification is poorly understood. We investigated the effect of increasing fCO2 on the growth of heterotrophic nanoflagellates (HNFs), nano- and picophytoplankton, and prokaryotes (heterotrophic Bacteria and Archaea) in a natural coastal Antarctic marine microbial community from Prydz Bay, East Antarctica. At CO2 levels ≥634 µatm, HNF abundance was reduced, coinciding with increased abundance of picophytoplankton and prokaryotes. This increase in picophytoplankton and prokaryote abundance was likely due to a reduction in top-down control of grazing HNFs. Nanophytoplankton abundance was elevated in the 634 µatm treatment, suggesting that moderate increases in CO2 may stimulate growth. The taxonomic and morphological differences in CO2 tolerance we observed are likely to favour dominance of microbial communities by prokaryotes, nanophytoplankton, and picophytoplankton. Such changes in predator–prey interactions with ocean acidification could have a significant effect on the food web and biogeochemistry in the Southern Ocean, intensifying organic-matter recycling in surface waters; reducing vertical carbon flux; and reducing the quality, quantity, and availability of food for higher trophic levels.
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institution PANGAEA
language en
publishDate 2020
publisher PANGAEA
record_format pangaea
spellingShingle Seawater carbonate chemistry and growth and grazing impact of Antarctic heterotrophic nanoflagellates
Deppeler, Stacy
Schulz, Kai Georg
Hancock, Alyce M
Pascoe, Penelope
McKinlay, John
Davidson, Andrew T
Alkalinity, total; Ammonium; Antarctic; Aragonite saturation state; Bicarbonate ion; Calcite saturation state; Calculated using seacarb after Nisumaa et al. (2010); Carbon, inorganic, dissolved; Carbonate ion; Carbonate system computation flag; Carbon dioxide; Cell density; Cell density, standard error; Chlorophyll a; Community composition and diversity; Containers and aquaria (20-1000 L or < 1 m**2); Date; Duration, number of days; Entire community; EXP; Experiment; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Identification; Irradiance; Laboratory experiment; Light attenuation, vertical; Nanoflagellates, heterotrophic; Nanophytoplankton; Nitrogen oxide; OA-ICC; Ocean acidification; Ocean Acidification International Coordination Centre; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air); Pelagos; pH, total scale; Phosphate; Picophytoplankton; Polar; Position; Prokaryotes; Prydz_Bay_OA; Replicate; Salinity; Silicate; Species; Temperature, water; Treatment; Type
High-latitude oceans have been identified as particularly vulnerable to ocean acidification if anthropogenic CO2 emissions continue. Marine microbes are an essential part of the marine food web and are a critical link in biogeochemical processes in the ocean, such as the cycling of nutrients and carbon. Despite this, the response of Antarctic marine microbial communities to ocean acidification is poorly understood. We investigated the effect of increasing fCO2 on the growth of heterotrophic nanoflagellates (HNFs), nano- and picophytoplankton, and prokaryotes (heterotrophic Bacteria and Archaea) in a natural coastal Antarctic marine microbial community from Prydz Bay, East Antarctica. At CO2 levels ≥634 µatm, HNF abundance was reduced, coinciding with increased abundance of picophytoplankton and prokaryotes. This increase in picophytoplankton and prokaryote abundance was likely due to a reduction in top-down control of grazing HNFs. Nanophytoplankton abundance was elevated in the 634 µatm treatment, suggesting that moderate increases in CO2 may stimulate growth. The taxonomic and morphological differences in CO2 tolerance we observed are likely to favour dominance of microbial communities by prokaryotes, nanophytoplankton, and picophytoplankton. Such changes in predator–prey interactions with ocean acidification could have a significant effect on the food web and biogeochemistry in the Southern Ocean, intensifying organic-matter recycling in surface waters; reducing vertical carbon flux; and reducing the quality, quantity, and availability of food for higher trophic levels.
title Seawater carbonate chemistry and growth and grazing impact of Antarctic heterotrophic nanoflagellates
topic Alkalinity, total; Ammonium; Antarctic; Aragonite saturation state; Bicarbonate ion; Calcite saturation state; Calculated using seacarb after Nisumaa et al. (2010); Carbon, inorganic, dissolved; Carbonate ion; Carbonate system computation flag; Carbon dioxide; Cell density; Cell density, standard error; Chlorophyll a; Community composition and diversity; Containers and aquaria (20-1000 L or < 1 m**2); Date; Duration, number of days; Entire community; EXP; Experiment; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Identification; Irradiance; Laboratory experiment; Light attenuation, vertical; Nanoflagellates, heterotrophic; Nanophytoplankton; Nitrogen oxide; OA-ICC; Ocean acidification; Ocean Acidification International Coordination Centre; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air); Pelagos; pH, total scale; Phosphate; Picophytoplankton; Polar; Position; Prokaryotes; Prydz_Bay_OA; Replicate; Salinity; Silicate; Species; Temperature, water; Treatment; Type
url https://doi.org/10.1594/PANGAEA.926447