Physical drivers facilitating a toxigenic cyanobacterial bloom in a major Great Lakes tributary
Autor: | Thomas B. Bridgeman, Gregory L. Boyer, Douglas D. Kane, Richard P. Stumpf, Paul G. Matson, Robert Michael L. McKay, Heather A. Raymond, Brenda K. Snyder, Timothy W. Davis, George S. Bullerjahn, Katelyn M. McKindles |
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Rok vydání: | 2020 |
Předmět: |
0106 biological sciences
geography geography.geographical_feature_category 010504 meteorology & atmospheric sciences biology Discharge 010604 marine biology & hydrobiology Estuary Bacterioplankton Aquatic Science Cyanotoxin Oceanography biology.organism_classification 01 natural sciences Article Water level Microcystis Tributary Environmental science Bloom 0105 earth and related environmental sciences |
Zdroj: | Limnol Oceanogr |
ISSN: | 1939-5590 0024-3590 |
Popis: | The Maumee River is the primary source for nutrients fueling seasonal Microcystis-dominated blooms in western Lake Erie’s open waters though such blooms in the river are infrequent. The river also serves as source water for multiple public water systems and a large food services facility in northwest Ohio, USA. On 20 September 2017, an unprecedented bloom was reported in the Maumee River estuary within the Toledo metropolitan area, which triggered a recreational water advisory. Here we (1) explore physical drivers likely contributing to the bloom’s occurrence, and (2) describe the toxin concentration and bacterioplankton taxonomic composition. A historical analysis using ten-years of seasonal river discharge, water level, and local wind data identified two instances when high-retention conditions occurred over ≥10 days in the Maumee River estuary: in 2016 and during the 2017 bloom. Observation by remote sensing imagery supported the advection of cyanobacterial cells into the estuary from the lake during 2017 and the lack of an estuary bloom in 2016 due to a weak cyanobacterial bloom in the lake. A rapid-response survey during the 2017 bloom determined levels of the cyanotoxins, specifically microcystins, in excess of recreational contact limits at sites within the lower 20 km of the river while amplicon sequencing found these sites were dominated by Microcystis. These results highlight the need to broaden our understanding of physical drivers of cyanobacterial blooms within the interface between riverine and lacustrine systems, particularly as such blooms are expected to become more prominent in response to a changing climate. |
Databáze: | OpenAIRE |
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