Changes in nitrogen metabolism of phosphorus-starved bloom-forming cyanobacterium Microcystis aeruginosa: Implications for nutrient management

The surplus of nitrogen plays a key role in the maintenance of cyanobacterial bloom when phosphorus has already been limited. However, the interplay between high nitrogen and low phosphorus conditions is not fully understood. Nitrogen metabolism is critical for the metabolism of cyanobacteria. Transcriptomic analysis in the present study suggested that nitrogen metabolism and ribosome biogenesis were the two most significantly changed pathways in long-term phosphorus-starved bloom-forming cyanobacteria Microcystis aeruginosa FACHB905. Notably, the primary glutamine synthetase/glutamate synthase cycle, crucial for nitrogen metabolism, was significantly downregulated. Concurrently, nitrogen uptake showed a marked decrease due to reduced expression of nitrogen source transporters. The content of intracellular nitrogen reservoir phycocyanin also showed a drastic decrease upon phosphorus starvation. Our study demonstrated that long-term phosphorus-starved cells also suffered from nitrogen deficiency because of the reduction in nitrogen assimilation, which might be limited by the reduced ribosome biogenesis and the shortage of adenosine triphosphate. External nitrogen supply will not change the transcriptions of nitrogen metabolism-related genes significantly like that under phosphorus-rich conditions, but still help to maintain the survival of phosphorus-starved cells. The study deepens our under- standing about the survival strategies of Microcystis cells under phosphorus starvation and the mutual depen- dence between nitrogen and phosphorus, which would provide valuable information for nutrient management in the eutrophicated water body.

Automated summary

This study investigated the changes in nitrogen metabolism in phosphorus-starved bloom-forming cyanobacteria. The results showed that decreased expression of nitrogen source transporters led to reduced nitrogen uptake and nitrogen deficiency. Additionally, phosphorus starvation resulted in a drastic decrease in phycocyanin content. While external nitrogen supply did not significantly alter the transcription of nitrogen metabolism-related genes, it still helped to maintain the survival of phosphorus-starved cells.