Abstract
The objective of this study was to identify correlations between environmental variables and cyanobacterial diversity, succession and dominance in three Australian water supply reservoirs. We assessed up to 15 years of in-lake water quality monitoring data from Lake Wivenhoe and Lake Tingalpa (Queensland), and Lake Myponga (South Australia). Lakes Wivenhoe and Tingalpa, subject to a subtropical climate, had higher cyanobacterial richness than Lake Myponga in temperate South Australia. Richness in the subtropical lakes was positively correlated (P < 0.05) with total cyanobacteria biomass, and cyanobacteria biovolume > 0.03 mm3/l (Alert level 1; World Health Organization) was often composed of multiple cyanobacteria species. Peaks in total cyanobacteria biomass and diversity occurred in all three lakes from late spring to early autumn. Unicellular picocyanobacterial dominance was negatively correlated (P < 0.05) with total nitrogen while dominance of colonial and filamentous species with larger cells (e.g. Microcystis spp., Raphidiopsis spp., Dolichospermum circinale) was positively correlated (P < 0.05) with total phosphorus. Among the species with larger cells, diazotrophic D. circinale often dominated when total nitrogen was at low concentrations. Our results support decision making for selecting cyanoHAB control strategies based on single- or multi-species dominance and reinforce that new monitoring technologies could support species-level assessments.
Highlights
Phytoplankton regulate many ecological processes in waterbodies, and understanding their dynamics is, essential to optimize water resources management and support aquatic ecosystem health (Willen, 2000)
We found that when picocyanobacteria dominated, larger cyanobacteria species were not present, but when larger cyanobacteria dominated, they tended to coexist with picocyanobacterial, albeit at reduced levels
We recommend that biovolume or biomass is used for phenological assessments of cyanobacteria, which aligns with recent Alert Level Frameworks for cyanoHABs assessment risk
Summary
Phytoplankton regulate many ecological processes in waterbodies, and understanding their dynamics is, essential to optimize water resources management and support aquatic ecosystem health (Willen, 2000). CyanoHABs impact the ecology and economics of water resources, and human health, especially when associated with production of cyanotoxins (Metcalf & Codd, 2012) and taste and odour compounds (Watson et al, 2016). Their ecological impacts include changes in community structure, trophic cascades and biogeochemical cycles of waterbodies (Sukenik et al, 2015). Current scientific understanding of cyanoHABs derives mostly from field observations of cyanobacteria succession or laboratory experiments focused on their physiology
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