Register      Login
Marine and Freshwater Research Marine and Freshwater Research Society
Advances in the aquatic sciences
Shopping Cart: ( empty )
You are here: Home > Journals > MF > MF07065
RESEARCH ARTICLE (Open Access)
Contents Vol 58(10)

Mapping the distribution, biomass and tissue nutrient levels of a marine benthic cyanobacteria bloom (Lyngbya majuscula)

Kathleen S. Ahern A E , Colin R. Ahern B , Greg M. Savige C and James W. Udy A D
+ Author Affiliations
- Author Affiliations

A University of Queensland, Water Studies, School of Engineering, Brisbane, Qld 4072, Australia.

B Queensland Department of Natural Resource and Water, Indooroopilly, Brisbane, Qld 4068, Australia.

C Savige Fisheries, Bribie Island, Qld 4507, Australia.

D Southeast Queensland Water Corporation, 240 Margaret Street, Brisbane, Qld 4002, Australia.

E Corresponding author. Email: k.ahern1@uq.edu.au

Marine and Freshwater Research 58(10) 883-904 https://doi.org/10.1071/MF07065
Submitted: 2 April 2007  Accepted: 11 September 2007   Published: 30 October 2007

Abstract

Benthic cyanobacteria blooms, including those of the nitrogen-fixing species Lyngbya majuscula, appear to be becoming more numerous and widespread in marine habitats worldwide, and have negative impacts on the environment and human health. The progression of a L. majuscula bloom in south-east Queensland, Australia was mapped along with intensive biomass and tissue nutrient sampling every 10–14 days over the bloom’s 3.5-month duration in summer 2005–2006. Data-integrated GIS maps illustrated the changes in biomass and tissue nutrient pool of the L. majuscula through different growth phases (incipient, rapid expansion, plateau or peak and decline) of the bloom. At the peak, L. majuscula covered 509 ha and had a mean density of 115 gdw m–2, with the maximum density recorded 503 gdw m–2. The highest mean total carbon (29.4% C), nitrogen (3.5% N) and phosphorus (0.143% P) contents in L. majuscula tissue corresponded with the peak in biomass. Three-dimensional modelling calculated that at the peak, the bloom contained 5057 tww (510 tdw) of L. majuscula; 150 000 kg C; 18 000 kg N; 720 kg P; and 5200 kg Fe. This information gives an insight into L. majuscula bloom dynamics and ecophysiology and provides quantitative data for models.

Additional keywords: Australia, harmful algae, iron, modelling, Moreton Bay, nitrogen, phosphorus.


Acknowledgements

The first author is in receipt of a University of Queensland (UQ) scholarship and Queensland Government Smart State funding. Some financial assistance was provided by South East Queensland Healthy Waterways Partnership. We acknowledge C. Vowles of Queensland Department of Natural Resources and Water (NRW) for providing dedicated GIS support, calculating areas of L. majuscula and conducting three dimensional modelling of total biomass and nutrients. G. Wobke, D. Lyons, S. Mork, L. McCullum and staff from Natural Resources Sciences Chemistry Centre, NRW undertook L. majuscula tissue, sediment and water analyses. V. Ahern assisted with cleaning, sorting and weighing L. majuscula. For helpful comments on the manuscript we acknowledge A. McElnea, B. Powell, V. Eldershaw (NRW), A. Watkinson (UQ) and P. and M. Ganley. For general support or assistance we also thank J. Savige (Savige Fisheries), M. Tanner (Commercial Fisherman), G. Shaw (Griffith University), C. Lovelock (UQ) and N. Moore (Queensland Environmental Protection Agency (EPA)). The authors acknowledge the EPA, Water Sciences Unit and Queensland Bureau of Meteorology for providing the environmental data, Queensland Department of Primary Industries and Fisheries for water temperature data and Maritime Safety Queensland for bathymetry data.


References

Abal, E. , and Dennison, W. C. (1996). Seagrass depth range and water quality in Moreton Bay, Queensland. Marine and Freshwater Research 47, 763–771.
Crossref | GoogleScholarGoogle Scholar | APHA/AWWA/WEF (2005). ‘Standard Methods for the Examination of Water and Wastewater.’ 20th edn. (American Public Health Association (APHA), American Water Works Association (AWWA) & Water Environment Federation (WEF): Washington D.C.)

Arthur, K. , Shaw, G. , Limpus, C. , and Udy, J. W. (2006a). A review of the potential role of tumour-promoting compunds produced by Lyngbya majuscula in marine turtle fibropapillomatosis. African Journal of Marine Science 2, 441–446.
Buchanan Heritage Services (2003). ‘Lyngbya – History of Occurrence.’ (Moreton Bay Waterways and Catchment Partnership: Brisbane.)

Capper, A. , Tibbetts, I. R. , O’Neil, J. M. , and Shaw, G. R. (2005). The fate of Lyngbya majuscula toxins in three potential consumers. Journal of Chemical Ecology 31, 1595–1606.
Crossref | GoogleScholarGoogle Scholar | PubMed | Dennison W. C., and Abal E. G. (1999). ‘Moreton Bay Study: a Scientific Basis for the Healthy Waterways Campaign.’ (South East Queensland Regional Water Quality Management: Brisbane.)

Dennison, W. C. , O’Neil, J. M. , Duffy, E. J. , Oliver, P. E. , and Shaw, G. R. (1999). Blooms of the cyanobacterium Lyngbya majuscula in coastal waters of Queensland, Australia. Bulletin de l’Institut Oceanographique 19, 265–272.
EPA (2006). Southeast Queensland Regional Coastal Management Plan, August 2006. Environmental Protection Agency, Brisbane.

Geider, R. J. , and La Roche, J. L. (2002). Redfield revisited: variability of C : N : P in marine microalgae and its biochemical basis. European Journal of Phycology 37, 1–17.
Crossref | GoogleScholarGoogle Scholar | Lawn P. (2002). Dynamic effects of macrofauna associated with Lyngbya majuscula in Moreton Bay. Honours Thesis, University of Queensland, Brisbane.

Letelier, R. M. , and Karl, D. M. (1996). Role of Trichodesmium spp. in the productivity of the subtropical North Pacific Ocean. Marine Ecology Progress Series 133, 263–273.
Crossref | GoogleScholarGoogle Scholar | O’Neil J. M., Albert S., Osborne N., Watkinson A., Shaw G., Heil C., Mulholland M., and Bronk D. (2004). Nitrogen acquisition by the toxic marine cyanobacterium Lyngbya majuscula from Moreton Bay, Australia and Tampa Bay, Florida. In ‘Proceedings of the International Conference on Harmful Algae’. (International Society for the Study of Harmful Algae: Cape Town.)

O’Neil J. M., and Dennison W. C. (2005). Lyngbya majuscula in Southeast Queensland waterways. In ‘Healthy Catchment, Healthy Waterways: South East Queensland Regional Water Quality Strategy’. (Eds E. Abal and W. C. Dennison.) p. 143. (Brisbane City Council: Brisbane.)

Ohki, K. (1999). A possible role of temperate phage in the regulation of Trichodesmium biomass. Bulletin de L’Institut Oceanographique 19, 287–292.
Paerl H. W., and Fulton R. S., III (2006). Ecology of harmful cyanobacteria. In ‘Ecology of Harmful Algae’. (Eds E. Graneli and J. Y. Turner.) (Springer-Verlag: Berlin.)

Paerl, H. W. , and Millie, D. F. (1996). Physiological ecology of toxic aquatic cyanobacteria. Phycologia 35, 160–167.
Rayment G. E., and Higginson F. R. (1992). ‘Australian Laboratory Handbook of Soil and Water Chemical Methods.’ (Inkata Press: Melbourne.)

Redfield A. C., Ketchum B. H., and Richards F. A. (1963). The influence of organisms on the composition of seawater. In ‘In the Sea’. (Ed. N. Hill.) pp. 26–77. (Wiley: New York.)

Roelfsema, C. M. , Phinn, S. R. , Dennison, W. C. , Dekker, A. G. , and Brando, V. E. (2006). Monitoring toxic cyanobacteria Lyngbya majuscula (Gomont) in Moreton Bay, Australia by integrating satellite image data and field mapping. Harmful Algae 5, 45–56.
Crossref | GoogleScholarGoogle Scholar |

Sanudo-Wilhelmy, S. A. , Kustka, A. B. , Gobler, C. J. , Hutchins, D. A. , Yang, M. , Lwiza, K. , Burns, J. , Capone, D. G. , Raven, J. A. , and Carpenter, E. J. (2001). Phosphorus limitation of nitrogen fixation by Trichodesmium in the central Atlantic Ocean. Nature 41, 66–69.
Crossref | GoogleScholarGoogle Scholar |

Stielow, S. , and Ballantine, D. L. (2003). Benthic cyanobacterial, Microcoleus lyngbyaceus, blooms in shallow, inshore Puerto Rican seagrass habitats, Caribbean Sea. Harmful Algae 2, 127–133.


Sunda, W. , and Huntsman, S. (1997). Interrelated influence of iron, light and cell size on marine phytoplankton growth. Nature 390, 389–392.
Crossref | GoogleScholarGoogle Scholar |

Thacker, R. , and Paul, V. (2001). Are benthic cyanobacteria indicators of nutrient enrichment? Relationships between cyanobacterial abundance and environmental factors on the reef flats of Guam. Bulletin of Marine Science 69, 497–508.


Thacker, R. W. , Nagle, D. G. , and Paul, V. J. (1997). Effects of repeated exposures to marine cyanobacterial secondary metabolites on feeding by juvenile rabbitfish and parrotfish. Marine Ecology Progress Series 147, 21–29.
Crossref | GoogleScholarGoogle Scholar |

Udy, J. W. , and Dennison, W. C. (1997). Growth and physiological responses of three seagrass species to elevated sediment nutrients in Moreton Bay, Australia. Journal of Experimental Marine Biology and Ecology 217, 253–277.
Crossref | GoogleScholarGoogle Scholar |

Watkinson, A. , O’Neil, J. M. , and Dennison, W. C. (2005). Ecophysiology of the marine cyanobacterium Lyngbya majuscula (Oscillatoriacea). Harmful Algae 4, 697–715.
Crossref | GoogleScholarGoogle Scholar |

Yeomans, J. C. , and Bremmer, J. M. (1991). Carbon and nitrogen analysis of soils by automated combustion techniques. Communications in Soil Science and Plant Analysis 22, 834–850.