| 1. |
- Lindh, Markus V., et al.
(författare)
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Consequences of increased temperature and acidification on bacterioplankton community composition during a mesocosm spring bloom in the Baltic Sea
- 2013
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Ingår i: Environmental Microbiology Reports. - : Wiley. - 1758-2229. ; 5:2, s. 252-262
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Tidskriftsartikel (refereegranskat)abstract
- Despite the paramount importance of bacteria for biogeochemical cycling of carbon and nutrients, little is known about the potential effects of climate change on these key organisms. The consequences of the projected climate change on bacterioplankton community dynamics were investigated in a Baltic Sea spring phytoplankton bloom mesocosm experiment by increasing temperature with 3°C and decreasing pH by approximately 0.4 units via CO2 addition in a factorial design. Temperature was the major driver of differences in community composition during the experiment, as shown by denaturing gradient gel electrophoresis (DGGE) of amplified 16S rRNA gene fragments. Several bacterial phylotypes belonging to Betaproteobacteria were predominant at 3°C but were replaced by members of the Bacteriodetes in the 6°C mesocosms. Acidification alone had a limited impact on phylogenetic composition, but when combined with increased temperature, resulted in the proliferation of specific microbial phylotypes. Our results suggest that although temperature is an important driver in structuring bacterioplankton composition, evaluation of the combined effects of temperature and acidification is necessary to fully understand consequences of climate change for marine bacterioplankton, their implications for future spring bloom dynamics, and their role in ecosystem functioning.
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| 2. |
- Romero-Oliva, Claudia
(författare)
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Climate-induced changes : Its effects on plankton food webs from the Baltic Sea
- 2010
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Licentiatavhandling (övrigt vetenskapligt/konstnärligt)abstract
- The Earth’s climate is determined different processes occurring in the atmosphere, land and ocean.Anthropogenic activities (mainly combustion of fossil fuels) have increased since the 1950’s, andthus the concentration of greenhouse gases that are warming up the planet. Such events have andwill likely continue to have profound impact on ocean biological processes directly affecting thephysiology of marine organisms and population dynamics.This thesis deals with the effects of climate-induced changes in seawater temperature and pH(acidification) on the development and structure of Baltic Sea plankton communities. Mesocosmexperiments were set up to expose both spring and summer Baltic Sea plankton communities totemperature and pH levels predicted by the year 2100, both isolated and in combination.Experiments lasted for 20 and 12 experimental days, for spring and summer seasons, respectively.Parameters analyzed were phytoplankton biomass (Chlorophyll a) and growth rates (Chlorophyll aaccumulation) and phytoplankton, microzooplankton (ciliates and heterotrophic nanoflagellates),mesozooplankton (copepods) and bacteriae densities. The obtained results were later compared(ANOVA test) and diversity indexes were calculated for phytoplankton, ciliate and totalcommunities. Cluster analyses were done based on species/groups composition of the planktoncommunities.The highest phytoplankton (chlorophyll a) and total plankton (Particulate organic carbon-POC)biomass were found during both experiments in the higher temperature treatments. During spring,the phytoplankton biomass found in the present conditions treatment on the last day experimentalwas achieved 3 days earlier in the higher temperature treatmtents. Thus the peak of the springbloom was accelerated by c. 1 day °C-1. Lower pH treatments increased phytoplankton biomassabove the present conditions in the spring, but did not in summer. However, higher POC wereobserved in the lower pH treatment during both spring and summer. During the spring, thecombination of lower pH and higher temperature had a greater impact on the natural planktoncommunities than each isolated factor. Spring phytoplankton communities were initiallydominated by the diatom Skeletonema costatum, while in the summer cyanobacteriae dominated(although in both cases in very low densities). In the lower pH-higher temperature treatment fromthe spring, the phytoplankton community shifted and haptophytes and dinoflagellates becamemore representative, whereas in summer potentially toxic, filamentous cyanobacteriae (includingharmful, bloom-forming Nodularia spumigena) increased in numbers.In the lower pH and high temperature treatments of the spring experiment and in all treatments ofthe summer experiment, decreases in ciliate and nanoflagellate densities were correlated to highcopepod densities. Although the phytoplankton biomass was favored by higher temperature andacidification, a slight decrease of diatoms and a shift towards a community dominated by smallsized species was observed during both experiments. Predicted changes in seawater temperatureand pH will result in more carbon being incorporated into the planktonic food webs of the BalticSea, both in spring and summer, with shifts in species composition that will likely change thecarbon pathways. Further studies are needed to clarify the transfer efficiency of the incorporatedcarbon to higher trophic levels, and the resulting net productivity of the system in face of the new conditions.
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| 3. |
- Romero-Oliva, Claudia, et al.
(författare)
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Effects of increased temperature and acidification on summer Baltic Sea phytoplankton communities
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Annan publikation (populärvet., debatt m.m.)abstract
- Baltic Sea summer phytoplankton communities response to increased temperature, acidification and its combination, at levels predicted for the year 2100; were studied in a mesocosm experiment. The plankton communities were collected in a coastal area of the Baltic Proper andincubated for 12 days at the following conditions of: present pH and temperature (16°C and pH 8.1, present conditions), lower pH-present temperature (16°C and pH 7.8), higher temperature-present pH (18°C and pH 8.1) and lower pH-higher temperature (18°C and pH 7.7). The nutrient depleted-seawater containing the natural plankton communities were spiked daily with 0.12 μM K3PO4 and 1.25 μM NaNO3. Phytoplankton biomass (chlorophyll a), growth rates, phytoplankton cell densities and diversity were measured through out the experiment. Phytoplankton biomass, growth rates and cell densities were significantly influenced by lower pH, higher temperature and at a greater extent when these two drivers were tested in combination. Higher temperature alone, lead to an acceleration of the summer bloom by ca. 1 days °C-1. Particulate organic carbon (POC) and particulate C:N and C:P atomic ratios were higher in all treatments than in the control condition at the end of the experiment. Higher temperatures increased phytoplankton biomass above the present temperature treatments. Shifts in phytoplankton composition were observed in all treatments. Diatoms were stimulated in the present condition, picocyanobacteriae in the lower pH-present temperature treatment and cyanobacteriae in the higher temperature treatments, including the filamentous, toxin-producer Nodularia spumigena. Highestdiversities were found in the present conditions and lower pH-higher temperature treatment, whereas lower pH alone lead to the lowest diversity found in all treatments. If seawater temperature continues to rise and pH to decrease as predicted by global climate change models, shifts in the phytoplankton community will occur and the size of the summer cyanobacteriae bloom will be bigger than already is now. The ultimate consequence will be less available edible algae to sustain the trophic foodweb and a decrease in the quality of the marine habitat. Alsosedimentation of these blooms to the deeper waters will increase oxygen depletion.
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| 4. |
- Romero-Oliva, Claudia, et al.
(författare)
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Effects of increased temperature and acidification on the development of Baltic Sea spring plankton communities.
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Annan publikation (populärvet., debatt m.m.)abstract
- The response of natural Baltic Sea spring plankton communities topredicted higher temperature and increased seawater acidification was studied in an indoor-mesocosm experiment. Plankton communities collected in a coastal area of the Baltic Sea (Kalmar Sound) were incubated for 20 days in the following conditions of: normal pH and temperature (pH=7.52, 3°C; control condition); lower pH (pH=7.14,3°C); high temperature (pH=7.52, 6°C) and lower pH-high temperature,(pH=7.14, 6 °C). Results showed that phytoplankton biomass (expressed as chlorophyll a), growth rates, plankton cell densities and community composition were significantly influenced by higher temperature, lower pH and to a greater extent subjected to both factors in combination. At higher temperature, phytoplankton biomass, particulate organic carbon(POC) and growth rates in addition to copepod densities were significantly enhanced. Highest bacteriae and heterotrophic nanoflagellates densities were observed in the higher temperature and lower pH treatment. Furthermore, the highest total phytoplankton and plankton communities diversity were found in this treatment as well. Increase in temperature and acidification accelerated the spring bloom by ca. 1 day °C-1. The phytoplankton community shifted from a dominance of Skeletonema costatum, in favor of haptophytes and dinoflagellates; and from dominance of the ciliate Myrionecta rubra in favor of tintiniids and oligotrichids. Our results suggest that the concomitant increased temperature and acidification of the Baltic Sea will increase the spring bloom biomass, and induce an early appearance of phytoplankton species typical of summer, thus decreasing the dominance of diatoms during the spring bloom. Decreased ciliates and copepod abundances will probably lead to sinking of higher amount phytoplankton biomass to deep water layers, expanding the area of oxygen depletion. If that is the case, the extra-incorporated carbon will not be channeled up the food chain.
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