Evaluating the resistance of phytoplankton to copper sulfate pentahydrate

Authors: HENNESSEY, A - Auburn University; MCDONALD, M - Auburn University; JOHNSON, P - Auburn University; GLADFELTER, M - Auburn University; MERRILL, K - Auburn University; TENISON, S - Auburn University; GANEGODA, J - Auburn University; HOANG, T - Auburn University; Torbert, Henry - Allen; Beck, Benjamin; WILSON, A - Auburn University

Submitted to: Meeting Abstract
Publication Type: Abstract Only
Publication Acceptance Date: 4/26/2024
Publication Date: 4/26/2024
Citation: Hennessey, A.V., Mcdonald, M.B., Johnson, P.P., Gladfelter, M.F., Merrill, K.L., Tenison, S.E., Ganegoda, J.S., Hoang, T.C., Torbert III, H.A., Beck, B.H., Wilson, A.E. 2024. Evaluating the resistance of phytoplankton to copper sulfate pentahydrate [abstract]. Society of Environmental Toxicology and Chemistry, April 26-27, Gainesville, FL.

Interpretive Summary:

Technical Abstract: Harmful algal blooms can cause severe economic and ecological problems, including fish mortality and the production of toxins and off-flavor compounds. These blooms often require chemical treatments such as copper sulfate pentahydrate (CuSO4·5H2O) to mitigate damaging effects. Phytoplankton communities treated with copper sulfate pentahydrate are expected to become more resistant to CuSO4·5H2O treatment, which could make blooms difficult to manage over time. To test this hypothesis, the toxic effects of CuSO4·5H2O were evaluated at a standard dose (348 µg/L Cu) and a low dose (174 µg/L Cu) relative to an untreated control. Treatments were applied once to 1,000 L mesocosm enclosures installed in a productive aquaculture pond at the start of the experiment and monitored for 28 days using the pollution-induced community tolerance (PICT) methodology, which measures photosynthetic efficiency across a broad range of 5 µg/L to 300,000 µg/L copper concentrations in acute short-term bioassays via effective quantum yield (QY), a measure of photosystem II efficiency. The results of the bioassay were applied to create half-maximal effective concentration (EC50) dose-response curves that can be utilized to determine tolerance to copper. Results from this experiment indicated that both doses of CuSO4·5H2O resulted in >99% removal of cyanobacteria in the first 7 days and reduced cyanobacteria by at least 70% throughout the experiment. The low dose was 5 times more tolerant, and the standard dose was 12 times more tolerant than the untreated communities in the first 7 days. Resistance peaked three days after the treatments were applied and remained high for at least fourteen days. These data suggest that a lower dose of copper sulfate is equally effective at treating harmful algal blooms dominated by cyanobacteria and that repeated treatments of copper sulfate might be least effective during the fourteen days after treatment.