Investigations into the taxonomy, toxicity and ecology of benthic cyanobacterial accumulations in Myall Lake, Australia

Dasey, Matthew; Ryan, Natasha; Wilson, Joanne; McGregor, Glenn B.; Fabbro, Larelle; Neilan, Brett A.; Burns, Brendan P.; Kankaanpää, Harri; Morrison, Louise F.; Codd, Geoffrey A.; Rissik, Dave; Bowling, Lee C.

doi:10.1071/mf04195

Cited by 36 publications

(27 citation statements)

References 28 publications

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“…High river flows have the ability to pick up rocks and pebbles, and thereby remove attached mat material from substrates (Biggs & Close 1989). Water turbulence has been previously described as a major controlling factor for benthic Cyanobacteria in river systems (Biggs 1990, Milne & Watts 2006, Wood et al 2007, lake systems (Johnson & Castenholz 2000, Dasey et al 2005, and marine environments (Thacker & Paul 2001). The ability of river flow to flush Phormidium mats has led local government agencies in the Wellington region to adopt this measure as one of the factors used to predict Phormidium mat percentage coverage (Milne & Watts 2006).…”

Section: Phormidium Mat Presence and Physicochemical Parametersmentioning

confidence: 99%

Spatial and temporal variability in Phormidium mats and associated anatoxin-a and homoanatoxin-a in two New Zealand rivers

Heath

Wood²,

Ryan³

2011

Aquat. Microb. Ecol.

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Toxic benthic cyanobacterial proliferations in freshwater are becoming increasingly prevalent, and associated animal poisonings are being reported with greater regularity. Despite this, few studies have investigated spatial and temporal variations in freshwater mat-forming Cyanobacteria and their associated toxin production. Some sections of the Hutt and Wainuiomata rivers (lower North Island, New Zealand) contain extensive Phormidium sp. proliferations that sometimes produce anatoxin-a (ATX) and homoanatoxin-a (HTX). The percentage coverage of Phormidium sp., ATX and/or HTX concentrations and a suite of physicochemical parameters were monitored at 8 sites for 12 mo. The percentage coverage of Phormidium mats was greater in the summer months and these correlated with warmer water temperatures and stable river flows. Flows in excess of 3 times the mean resulted in the removal of Phormidium mats. There was no correlation between the presence/absence of Phormidium mats and water-soluble nutrients. The presence and concentration of ATX and/or HTX and their degradation products, dihydroanatoxin-a and dihydrohomoanatoxin-a, was highly variable across all sites and over time. Anatoxin-a and HTX occurrence was restricted to periods of warm water temperatures (above 13.4°C) and below average river flows.

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Section: Phormidium Mat Presence and Physicochemical Parametersmentioning

confidence: 99%

Spatial and temporal variability in Phormidium mats and associated anatoxin-a and homoanatoxin-a in two New Zealand rivers

Heath

Wood²,

Ryan³

2011

Aquat. Microb. Ecol.

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“…Charophytes might contribute a substantial amount of organic material to gyttja where water is shallow. Dasey et al (2005) report gyttja with 14.9 g DW/l. Typically the gyttja layer is 0.25-0.5 m thick, which amounts to 3,725-7,450 g DW/m 2 .…”

Section: Patchinessmentioning

confidence: 95%

Mechanisms affecting biomass and distribution of charophytes and Najas marina in Myall Lake, New South Wales, Australia

Sanderson¹,

Asaeda

Rajapakse

et al. 2008

Hydrobiologia

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Two years of measurements are explored with a view to formulating an ecosystem model for Myall Lake. Stable physical characteristics, low catchment loads, low light attenuation, flat-bottomed hypsometry, and soft gyttja substrate allow stable charophyte biomass throughout the year in Myall Lake. Chara fibrosa dominates the total biomass and is abundant over the depth range 0.5-4 m. Nitella hyalina is found over the same depth range but has diminished biomass at depths greater than 2 m due to increased incidence of zero-biomass samples at depths greater than 1.5 m. Upper bounds for biomass densities were estimated for charophytes. Najas marina has great seasonal variability and meadows can have very high biomass in waters 1.5-2.7 m deep. High biomass of Najas marina is associated with low biomass of Nitella hyalina and may be a factor determining how the biomass of Nitella hyalina is distributed with respect to depth. Patchiness of Najas marina is particularly high. Temperature and light can support two growing seasons for Najas marina but mechanical disturbance is often high in spring and high biomass was only observed in late autumn during the present study. Less than 5% of the present-day production of submerged macrophytes would have been required to produce organic material of the gyttja over a 1,000-year period. The spatial distributions of gyttja and the dominant macrophytes are consistent with wind patterns. Downlake limits on the distributions of charophytes and Najas marina are related to a gradient in the coefficient of light attenuation that is, in turn, related to proximity to the bulk of the catchment load.

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“…The natural and conservational value of the Myall Lakes system is internationally recognised, with the area being listed as a Ramsar Wetland of International Importance (NPWS, 2002). In 1999, studies of the limnology and ecology of the Myall Lakes revealed extensive areas (800 ha) of uncompacted, cyanobacterial 'ooze', or gyttja, in the northern-most lake, Myall Lake (Dasey et al, 2004). Taxonomic examination of the gyttja indicated it was largely composed of cyanobacteria (Aphanothece) from the order Chroococcales.…”

Section: Introductionmentioning

confidence: 98%

“…Cyanobacterial accumulations, or mats, have the potential to spread over large areas within affected waterways (Bowling & Baker, 1996) and receive considerable attention from authorities in the form of water quality monitoring, clean-up programmes and public safety assessments (Dasey et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

Carbon and nitrogen stable isotope analysis indicates freshwater shrimp Paratya australiensis Kemp, 1917 (Atyidae) assimilate cyanobacterial accumulations

2008

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Large areas of uncompacted cyanobacterial accumulations (or ''gyttja'') have been observed in Myall Lake, New South Wales, Australia. To determine whether the cyanobacterial accumulations were assimilated into the local food web, carbon and nitrogen stable isotopes were used to identify the primary food sources of a primary consumer in Myall Lake, the freshwater atyid shrimp Paratya australiensis. Suspended particulate organic matter (POM) and the macrophyte Myriophyllum salsugineum were identified as major dietary sources of P. australiensis. Enriched stable isotope signatures (d 13 C and d 15 N) of shrimp from gyttja-affected sites, relative to shrimp from unaffected locations, also indicated that P. australiensis were deriving a considerable portion of their dietary carbon and nitrogen requirements from gyttja. Stable isotope mixing models estimated that cyanobacterial accumulations might constitute up to 69% of P. australiensis biomass carbon and nitrogen requirements at gyttja-affected locations. To our knowledge, this is the first study to use stable isotope analysis to trace the assimilation of potentially toxic cyanobacterial accumulations into the trophic pathways of an affected system.

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Investigations into the taxonomy, toxicity and ecology of benthic cyanobacterial accumulations in Myall Lake, Australia

Cited by 36 publications

References 28 publications

Spatial and temporal variability in Phormidium mats and associated anatoxin-a and homoanatoxin-a in two New Zealand rivers

Spatial and temporal variability in Phormidium mats and associated anatoxin-a and homoanatoxin-a in two New Zealand rivers

Mechanisms affecting biomass and distribution of charophytes and Najas marina in Myall Lake, New South Wales, Australia

Carbon and nitrogen stable isotope analysis indicates freshwater shrimp Paratya australiensis Kemp, 1917 (Atyidae) assimilate cyanobacterial accumulations

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