Differential nitrogen assimilation by Microcystis and co-occurring plankton during harmful cyanobacterial blooms across North American Lakes

Microcystis is a toxin-producing cyanobacteria that forms colonies that host distinct microbial assemblages. This study characterized microbial diversity of, and nitrogen (N) assimilation by, isolated Microcystis colonies, co-occurring free-living plankton ( 20 μm), and the whole water community, in five Microcystis bloom-prone lakes: three larger eutrophic lakes, including Lake Erie, and two smaller, hypereutrophic systems near New York City, using high throughput sequencing of 16S rRNA and 15 N-labeled nutrients. Bacterial and cyanobacterial community composition differed between colony and free-living fractions ( p 0.05), with Microcystis comprising the majority of cyanobacterial sequences (66–84%) within the colony fraction in four of five systems. Microcystis colony fractions had volumetric N uptake rates that were 2-to-22-fold higher than free-living plankton in all systems ( p 0.05). Urea dominated N uptake across most fractions and ecosystems, comprising 52–72% of N uptake in larger lakes and 21–52% in the smaller, hypereutrophic lakes where nitrate and ammonium were more important. N uptake rates were highly associated with lake trophic state index (TSI) as uptake rates in hypereutrophic lakes were two-to-five-fold higher than eutrophic systems. Volumetric uptake rates of urea and glutamic acid by free-living fractions were significantly and inversely correlated with TN, TP, and microcystin, suggesting blooms intensified N competition. N-specific uptake rates by colonies were significantly and inversely correlated with TN, TP, TSI, microcystin, and chlorophyll- a , suggesting that intensification of blooms slowed biomass-adjusted N uptake. Canonical correlation analyses (CCA) revealed Microcystis was associated with volumetric uptake rates of all N compounds and urea- and glutamic acid-specific uptake rates, suggesting that Microcystis and associated colony microbes were the dominant N assimilation pathway during blooms. This study highlights the importance of urea for Microcystis blooms, and demonstrates that N uptake rates of communities associated with Microcystis colonies differ from free-living plankton and varies as a function of lake trophic status.