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Diel Vertical Migration Thresholds of Karenia brevis (Dinophyceae).
Citation:
SCHAEFFER, B. A., D. KAMYKOWSKI, G. SINCLAIR, L. MCKAY, AND E. J. MILLIGAN. Diel Vertical Migration Thresholds of Karenia brevis (Dinophyceae). Harmful Algae 8(5):692-698, (2009).
Impact/Purpose:
This project investigated changes of Karenia brevis (C. C. Davis) G. Hansen et Moestrup intracellular carbon, nitrogen, internal nitrate (iNO3), free amino acid (FAA), and total lipid concentrations in high-light, nitrate-replete (960 µmol quanta m-2 s-1 , 80 uM NO3), and high-light, nitrate-reduced (960 µmol quanta m-2 s-1, <5 ìM NO3) mesocosms.
Description:
Light and nutrient availability change throughout dinoflagellate diel vertical migration (DVM) and/or with subpopulation location in the water column along the west Florida shelf. Typically, the vertical depth of the shelf is greater than the distance a subpopulation can vertically migrate during a diel cycle, limiting the ability of a subpopulation to photosynthetically fix carbon toward the surface and access nutrients sub-surface. This project investigated changes of Karenia brevis (C. C. Davis) G. Hansen et Moestrup intracellular carbon, nitrogen, internal nitrate (iNO3), free amino acid (FAA), and total lipid concentrations in high-light, nitrate-replete (960 µmol quanta m-2 s-1 , 80 uM NO3), and high-light, nitrate-reduced (960 µmol quanta m-2 s-1, <5 ìM NO3) mesocosms. The nitrate-reduced mesocosm had a slowed cell division rate when compared to the nitrate-replete mesocosm. Minimum intracellular carbon, nitrogen, iNO3, FAA, and total lipid concentrations during the largest surface sub-population aggregations led to the conclusion that daughter cells resulting from cell division received unequal shares of the parental resources and that this inequality influenced migration behavior. Nutrient reduced daughter cells were more strongly influenced by light and phototaxis for carbon production than their replete same cell division sister cells during vertical migration thus rapidly increasing the fulfillment of constituents through photosynthesis. Vertical migration was consistent with an optimization scheme based on simplified conceptual model describing how K. brevis is transported along the benthos of the west Florida shelf from off-shore to on-shore. Dynamic carbon thresholds are also suggested for future DVM modeling efforts on K. brevis populations transported between nitrogen replete and nitrogen reduced environmental conditions.