Abstract
In May 2016, the remote-controlled Automated Filtration System for Marine Microbes (AUTOFIM) was implemented in parallel to the Long Term Ecological Research (LTER) observatory Helgoland Roads in the German Bight. We collected samples for characterization of dynamics within the eukaryotic microbial communities at the end of a phytoplankton bloom via 18S meta-barcoding. Understanding consequences of environmental change for key marine ecosystem processes, such as phytoplankton bloom dynamics requires information on biodiversity and species occurrences with adequate temporal and taxonomic resolution via time series observations. Sampling automation and molecular high throughput methods can serve these needs by improving the resolution of current conventional marine time series observations. A technical evaluation based on an investigation of eukaryotic microbes using the partial 18S rRNA gene suggests that automated filtration with the AUTOFIM device and preservation of the plankton samples leads to highly similar 18S community profiles, compared to manual filtration and snap freezing. The molecular data were correlated with conventional microscopic counts. Overall, we observed substantial change in the eukaryotic microbial community structure during the observation period. A simultaneous decline of diatom and ciliate sequences succeeded a peak of Miracula helgolandica, suggesting a potential impact of these oomycete parasites on diatom bloom dynamics and phenology in the North Sea. As oomycetes are not routinely counted at Helgoland Roads LTER, our findings illustrate the benefits of combining automated filtration with metabarcodingto augment classical time series observations, particularly for taxa currently neglected due to methodological constraints.
Highlights
Recurring spring phytoplankton blooms with high net primary production characterize coastal seas such as the North Sea
A MANTEL-test revealed that physicochemical conditions (T; S; NO2; chlorophyll a (Chla)) at the two sampling sites FerryBox-intake and Kabeltonne were highly similar (R = 0.93 and p = 0.001) during the observation period. This suggests that samples collected at “Kabeltonne” and the “FerryBox- sampling site” originated from the same water mass and justifies a direct comparison of the microscopic count data from “Kabeltonne” with molecular data obtained from the FerryBox-intake later on in this study
Based on our integrated approach we provided novel insights into the eukaryotic microbial community composition and dynamics at Helgoland Roads towards the end of the spring bloom in May 2016
Summary
Long-term investigations of the composition of the marine microbial communities are a valuable approach for the overall understanding of impacts of environmental change on plankton communities and related marine ecosystem processes Such data collections are ideal for illustration of patterns in phytoplankton bloom dynamics and for the elucidation of the underlying mechanisms such as environmental forcing or nutrient availability at historical time scales. The high sampling frequency of the Helgoland Roads time series has provided a unique opportunity to study long-term trends This includes abiotic and biotic parameters, and ecological phenomena such as dynamics and timing of the spring bloom, seasonal interactions between different food web components, niche properties, and the effects of newly introduced species [2;3;7]. Decreasing analysis costs in this field coupled with considerable progress towards a greater level of automation into the sampling and analysis process facilitate integration of molecular based observations into LTERs in order to refine regular observations of marine microbes
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