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Vertical migration of the toxic dinoflagellate Gymnodinium catenatum under differnt concentrations of nutrients and humic substances in culture


Doblin, M and Thompson, PA and Revill, AT and Butler, ECV and Blackburn, SI and Hallegraeff, GM, Vertical migration of the toxic dinoflagellate Gymnodinium catenatum under differnt concentrations of nutrients and humic substances in culture, Harmful Algae, 5, (6) pp. 665-677. ISSN 1568-9883 (2006) [Refereed Article]

DOI: doi:10.1016/j.hal.2006.02.002


Vertical migration behaviour by the chainforming dinoflagellate Gymnodinium catenatum Graham was investigated using vertically-stratified laboratory columns. Under surface nutrient-deplete conditions, with nutrients added only at depth, 100% of cells underwent vertical migration (VM), starting downwards migration 3 h before the end of the light period and beginning upwards migration 3 h before the start of the light period. Cells in nutrient-replete columns showed no VM, but they were more dispersed in the upper layer during the dark compared to the light period. When surface layers (S) were nitrate-deplete (-N) and enriched with humic substances (H) contained in Huon River water and bottom waters (B) were nutrient replete (R) (SH-NBR), the pattern of VM was altered-50% of cells underwent migration and 50% remained at the pycnocline. In columns with nitrate-replete and humic-enriched surface layers (SHRBR), most cells underwent VM, while 30% remained at the surface. Cells in SH-NBR columns showed increased N quotas and intra-cellular nitrate concentrations after 4 days, indicating nitrate uptake by G. catenatum in bottom layers. The concomitant increase in particulate organic nitrogen (PON) with the decrease in external nitrate concentrations in bottom layers provide convincing evidence that VM by G. catenatum facilitates nutrient retrieval at depth. However, addition of humic substances (a potential source of organic nitrogen) to surface layers did not ameliorate G. catenatum N depletion sufficiently to preclude the need for NO3 - uptake at depth. Furthermore, there was no detectable pattern of increasing carbon (C) quota during the day (photosynthate accumulation) or increasing N quota during the night (nitrate assimilation). Toxic dinoflagellate G. catenatum blooms are commonly associated with nitrate depletion in surface waters in south-east Tasmanian waters (Australia). Therefore, vertical migration, facilitating N uptake at depth, could play an important role in this organism's ecological strategy, enabling it to exploit environments where light and nutrients are vertically separated. © 2006 Elsevier B.V. All rights reserved.

Item Details

Item Type:Refereed Article
Research Division:Biological Sciences
Research Group:Plant biology
Research Field:Phycology (incl. marine grasses)
Objective Division:Animal Production and Animal Primary Products
Objective Group:Fisheries - aquaculture
Objective Field:Fisheries - aquaculture not elsewhere classified
UTAS Author:Doblin, M (Ms Martina Doblin)
UTAS Author:Hallegraeff, GM (Professor Gustaaf Hallegraeff)
ID Code:41717
Year Published:2006
Web of Science® Times Cited:36
Deposited By:Plant Science
Deposited On:2006-08-01
Last Modified:2010-06-04

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