Cell Damage, Toxicity and Bacterial Diversity Shifts of Microcystis and Oscillatoria Cultures Treated with Bacterial Isolates

The mitigation of toxic cyanobacterial blooms is a much researched and ongoing challenge. Seasonal influences, microbial diversity and the wide range of cyanotoxins known to be associated with cyanobacterial blooms add layers of complexity to these environmental threats. Strategies to remediate blooms must avoid inducing widespread cell lysis and release of cyanotoxins which would compound rather than address the problem. The present study reports on the exposure non-axenic cultures of colonial Microcystis sp. and filamentous Oscillatoria sp isolated from dams in South Africa to low ratios of four predatory bacterial isolates for 4 days. TEM was used to assess ultrastructural changes, HPLC to determine the relative concentrations of microcystin-LR and RR, and Next Generation Sequencing to explore possible shifts in diversity, from control samples as a result of the exposure to the biological control bacterial isolates used. Ultrastructurally, Microcystis showed greater signs of stress than cells of Oscillatoria, with isolate 1 (Aeromonas lacus) having overall the least effect, whilst Isolate B (Lysinibacillus) and 3Y (Pseudomonas rhodesiae) inducing cell lysis in Microcystis. All isolates reduced the concentration of the toxic microcystin-LR, while the –RR variant often increased after 4 days. Minimal diversity shifts were noted in Microcystis treated cultures, whilst those of Oscillatoria showed a greater diversity shift, indicating an increase of families containing isolates linked to bloom decline.