Grazer Impacts on Synechococcus Populations in the Coastal Gulf of Maine; Identifying Specific Microbial Interactions to Understand Bloom Dynamics

Peter D. Countway1, Nicole Poulton1, Michael Sieracki2, Alicia Hoeglund1, Sean Anderson3 and Wilton Gray Burns4, (1)Bigelow Laboratory for Ocean Sciences, East Boothbay, ME, United States, (2)National Science Foundation, Arlington, VA, United States, (3)Skidaway Institute of Oceanography at the University of Georgia, Marine Sciences, Savannah, GA, United States, (4)University of New Hampshire, Ocean Process Analysis Laboratory, Durham, NH, United States
Abstract:
Protistan grazers help to shape the diversity, abundance, and composition of bacterial and phytoplankton communities, yet very little is known about the specific interactions between grazers and their prey. Grazers play key roles in the demise of phytoplankton blooms, with the abundance of grazers often increasing dramatically as prey-species decline. The timing and fate of Synechococcus blooms was investigated over a two-year period in Booth Bay, Maine (USA). The Synechococcus bloom in this region is characterized by several peaks in cell abundance, followed by periods of rapid decline. Two clades of Synechococcus (rpoC1 gene clades I and IV) were detected at our study site, with clade I typically present at higher abundance than clade IV. Modified grazing experiments were conducted at different stages of the Synechococcus bloom in which the natural plankton community was diluted with either 0.45 µm (grazer-free) or 30 kDa (grazer- and virus-free) filtered seawater. In general, the impact of grazers on Synechococcus populations was greater than the impact due to encounters with viruses during 24-hour in situ incubations. Interactions between grazers and Synechococcus were investigated using Fluorescence Activated Cell Sorting (FACS) combined with single-cell genomics to identify specific associations between sorted-grazers and their prey. Single-cell sequencing revealed a diverse array of heterotrophic protists on sampling dates that occurred after periods of rapid decrease in the abundance of Synechococcus. Cultures of Synechococcus were added to natural plankton communities to stimulate grazers, which were subsequently cell-sorted in bulk mode and sequenced. These experiments revealed similar taxonomic affiliations of putative grazer types (e.g., Cercozoa) that responded to the presence of Synechococcus prey. Protistan grazers appear to exert a strong degree of control on the abundance and duration of the annual Synechococcus bloom in the coastal Gulf of Maine.