Effect of elevated CO2 on the dynamics of particle attached and free living bacterioplankton communities in an Arctic fjord.

The increase in atmospheric carbon dioxide (CO₂) results in acidification of the oceans, expected to lead to the fastest drop in ocean pH in the last 300 million years, if anthropogenic emissions are continued at present rate. Due to higher solubility of gases in cold waters and increased exposure to the atmosphere by decreasing ice cover, the Arctic Ocean will be among the areas most strongly affected by ocean acidification. Yet, the response of the plankton community of high latitudes to ocean acidification has not been studied so far. This work is part of the Arctic campaign of the European Project on Ocean Acidification (EPOCA) in 2010, employing 9 in situ mesocosms of about 45 000 l each to simulate ocean acidification in Kongsfjorden, Svalbard (78° 56.20 N 11 ° 53.60 E). In the present study, we investigated effects of elevated CO₂ on the composition and richness of particle attached (PA; >3 µm) and free living (FL; < 3 µm > 0.2 µm) bacterial communities by Automated Ribosomal Intergenic Spacer Analysis (ARISA) in 6 of the mesocosms and the surrounding fjord, ranging from 185 to 1050 initial µatm pCO₂. ARISA was able to resolve about 20-30 bacterial band-classes per sample and allowed for a detailed investigation of the explicit richness. Both, the PA and the FL bacterioplankton community exhibited a strong temporal development, which was driven mainly by temperature and phytoplankton development. In response to the breakdown of a picophytoplankton bloom (phase 3 of the experiment), number of ARISA-band classes in the PA-community were reduced at low and medium CO₂ (∼180-600 µatm) by about 25%, while it was more or less stable at high CO₂ (∼650-800 µatm). We hypothesise that enhanced viral lysis and enhanced availability of organic substrates at high CO₂ resulted in a more diverse PA-bacterial community in the post-bloom phase. Despite lower cell numbers and extracellular enzyme activities in the post-bloom phase, bacterial protein production was enhanced in high CO₂-treatments, suggesting a positive effect of community richness on this function and on carbon cycling by bacteria. [ABSTRACT FROM AUTHOR]