The biomass of bloom-forming colonial Microcystis affects its response to aeration disturbance

The algal succession in Microcystis blooms of varying biomass under continuous aeration was studied in a greenhouse. There were four treatments (control, Low, Medium, and High) with initial chlorophyll a (Chl-a) of 32.5, 346.8, 1413.7, and 14,250.0 mu g L-1, respectively. During the experiment, Cyanophyta biomass was the lowest in the Medium treatment (P < 0.05), while its Chlorophyta biomass was the highest (P < 0.05). Both Chlorophyta and Bacillariophyta biomass were the lowest in the High treatment (P < 0.05). Bacillariophyta biomass, particularly the diatom Nitzschia palea was the highest in the Low treatment (P < 0.05), and Nitzschia palea cells were attached to the Microcystis colonies. Thus, the algal shift in Microcystis blooms under aeration disturbance depends on its initial biomass, and it shift to green algae or/and diatom dominance in the control, Low, Medium treatments. Diatom cells, particularly N. palea, grew in an attached form on Microcystis colonies in treatment Low, in which the colonies provided media for the adherence. The mechanism of the algal shift with different biomass must be related to the nutrient level, low light and aerobic conditions under aeration disturbance as well as the aeration itself, which destroyed the Microcystis colonies' advantage of floating on the water.

Automated summary

The algal succession in Microcystis blooms of varying biomass under continuous aeration was studied. The results showed that the biomass of Cyanophyta was the lowest in the Medium treatment, while the biomass of Chlorophyta was the highest. Both Chlorophyta and Bacillariophyta biomass were the lowest in the High treatment. The presence of diatom Nitzschia palea in the Low treatment suggests that the algal shift in Microcystis blooms under aeration disturbance is dependent on its initial biomass.