Spatial and seasonal change in algal community structure and its interaction with nutrient dynamics in a gravel-bed urban river

Harmful algal blooms frequently occur in urban rivers due to intense human activities. However, little is known about the change in algal community structure and its interactions with nutrient dynamics in gravel-bed urban rivers. In present study, water samples were collected from a gravel-bed River Xin' an, China for five months over four seasons and a rainy month to measure algal community structure, dissolved nitrogen gas (N-2) and Argon (Ar) concentrations, and other water quality parameters. The results showed that the harmful Cyanophyta accounted for 31.6 +/- 24.1% of the total community in the hot season while Bacillariophyta contributed more than 60% to the community in the other three seasons. The N-2 was supersaturated in the moderate and cold seasons but it was unsaturated in the hot season, along with high concentrations of nitrogen-fixing cyanobacteria (Anabaena), indicating that the nitrogen fixation capacity was strong and even stronger than denitrification and anammox in the hot season. However, nitrogen fixation was not the main source of nitrogen in the water column. The concentrations of nutrients and Chla in the downstream river were significantly higher than those in the upstream river (p < 0.001 for nutrients and p = 0.029 for Chla), suggesting that human activities along the river greatly affected nutrient concentrations, as well as algal growth. Our study provides new insights into the algal community succession in a gravel-bed urban river and puts forward effective measures such as controlling exogenous nutrient input and dredging organic sediment for mitigating the harmful algal blooms in urban rivers.

Automated summary

The study found that harmful algal blooms in urban gravel-bed rivers are influenced by seasonal variations and nitrogen concentrations, with harmful Cyanophyta mainly present in the hot season. Additionally, downstream nutrient and Chla concentrations were significantly higher than upstream, indicating the significant impact of human activities on nutrient levels and algal growth.