Ocean acidification changes the structure of an Antarctic coastal protistan community

Antarctic near-shore waters are amongst the most sensitive in the world to ocean acidification. Microbes occupying these waters are critical drivers of ecosystem productivity, elemental cycling and ocean biogeochemistry, yet little is known about their sensitivity to ocean acidification. A six-level...

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Bibliographic Details
Published in:Biogeosciences
Main Authors: Hancock, AM, Davidson, AT, McKinlay, J, McMinn, A, Schulz, KG, van den Enden, RL
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus GmbH 2018
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Online Access:https://doi.org/10.5194/bg-15-2393-2018
http://ecite.utas.edu.au/129023
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Summary:Antarctic near-shore waters are amongst the most sensitive in the world to ocean acidification. Microbes occupying these waters are critical drivers of ecosystem productivity, elemental cycling and ocean biogeochemistry, yet little is known about their sensitivity to ocean acidification. A six-level, doseresponse experiment was conducted using 650 L incubation tanks (minicosms) adjusted to a gradient in fugacity of carbon dioxide ( f CO 2 ) from 343 to 1641 atm. The six minicosms were filled with near-shore water from Prydz Bay, East Antarctica, and the protistan composition and abundance was determined by microscopy during 18days of incubation. No CO 2 -related change in the protistan community composition was observed during the initial 8day acclimation period under low light. Thereafter, the response of both autotrophic and heterotrophic protists to f CO 2 was species-specific. The response of diatoms was mainly cell size related; microplanktonic diatoms ( > 20 m) increased in abundance with low to moderate f CO 2 (343634 atm) but decreased at f CO 2 ≥ 953 atm. Similarly, the abundance of Phaeocystis antarctica increased with increasing f CO 2 peaking at 634 atm. Above this threshold the abundance of micro-sized diatoms and P.antarctica fell dramatically, and nanoplanktonic diatoms ( ≤ 20 m) dominated, therefore culminating in a significant change in the protistan community composition. Comparisons of these results with previous experiments conducted at this site show that the f CO 2 thresholds are similar, despite seasonal and interannual differences in the physical and biotic environment. This suggests that near-shore microbial communities are likely to change significantly near the end of this century if anthropogenic CO 2 release continues unabated, with profound ramifications for near-shore Antarctic ecosystem food webs and biogeochemical cycling.