Abstract
Planktothrix rubescens is distinct from other cyanobacterial harmful algal bloom (cHAB) genera: the crimson-red cHAB thrives in the cold, low-light, nutrient-limited metalimnion. Studies have attributed this ecological success to buoyancy regulation, low-light adaptations, and the uptake of nitrogen-rich amino acids. Yet, it remains to be mechanistically determined how this cHAB maintains physiological nutrient quotas in the metalimnion due to limited in situ molecular studies. We employed metagenomics and metabolomics to generate hypotheses concerning a toxigenic P. rubescens bloom in Mead's Quarry (Knoxville, TN, USA) observed in two separate years. Our results suggest a perennial, metalimnic P. rubescens population may exist, with spring turnover facilitating seasonal migration to the epilimnion. Although P. rubescens dominated the epilimnion and metalimnion, intracellular metabolite pools grouped by depth and suggested depth-discrete partitioning of the arginine deiminase-mediated ornithine-arginine cycle (OAC, i.e., urea cycle) - while further indicating the presence of the arginine catabolic pathway. Though the arginine influx driving the OAC is unclear, we hypothesize this input is provided via the uptake of urea or nitrogen-rich amino acids. Further, we demonstrate arginine deiminase (agrE/argZ) is broadly distributed in Planktothrix genera and known microcystin producers, suggesting agrE/argZ-mediated arginine metabolism and the OAC may influence the fitness of toxigenic cHAB genera which require ample nitrogen to synthesize microcystins. Cumulatively, our results serve as a case study to provide insight on the metabolic pathways driving the ecological success of metalimnic P. rubescens blooms. On a broader scale, this work strengthens the case that alternative nitrogen metabolism - including urea utilization, amino acid catabolism, and the OAC - is a driver of toxigenic cHABs in fresh waters.