Light rather than iron controls photosynthate production and allocation in Southern Ocean phytoplankton populations during austral autumn

The role of iron and light in controlling photosynthate production and allocation in phytoplankton populations of the Atlantic sector of the Southern Ocean was investigated in April-May 1999. The C-14 incorporation into five biochemical pools (glucan, amino acids, proteins, lipids and polysaccharide...

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Bibliographic Details
Published in:Journal of Plankton Research
Main Authors: van Oijen, T, van Leeuwe, M A, Granum, E, Weissing, F J, Bellerby, RGJ, Gieskes, W W C, de Baar, HJW
Format: Article in Journal/Newspaper
Language:English
Published: 2004
Subjects:
DIATOM SKELETONEMA-COSTATUM
EQUATORIAL PACIFIC-OCEAN
DISSOLVED ORGANIC-MATTER
MARINE EUKARYOTIC ALGAE
ATLANTIC SECTOR
ENVIRONMENTAL-FACTORS
CARBOHYDRATE SOLUTES
QUATERNARY AMMONIUM
TERTIARY SULFONIUM
OSMOTIC ADJUSTMENT
Antarctic
Austral
Pacific
Southern Ocean
The Antarctic
Antarc*
Online Access:https://hdl.handle.net/11370/fb17090d-8769-4ecd-a588-5997f983b72a
https://research.rug.nl/en/publications/fb17090d-8769-4ecd-a588-5997f983b72a
https://doi.org/10.1093/plankt/fbh088
Description
Summary:The role of iron and light in controlling photosynthate production and allocation in phytoplankton populations of the Atlantic sector of the Southern Ocean was investigated in April-May 1999. The C-14 incorporation into five biochemical pools (glucan, amino acids, proteins, lipids and polysaccharides) was measured during iron/light perturbation experiments. The diurnal Chl a-specific rates of carbon incorporation into these pools did not change in response to iron addition, yet were decreased at 20 mumol photons m(-2) s(-1), an irradiance comparable with the one at 20-45 m in situ depth. This suggests that the low phytoplankton biomass encountered (0.1-0.6 mug Chl a L-1) was mainly caused by light limitation in the deep wind mixed layer (>40 m). Regional differences in Chl a-specific carbon incorporation rates were not found in spite of differences in phytoplankton species composition: at the Antarctic Polar Front, biomass was dominated by a diatom population of Fragilariopsis kerguelensis, whereas smaller cells, including chrysophytes, were relatively more abundant in the Antarctic Circumpolar Current beyond the influence of frontal systems. Because mixing was often in excess of 100 m in the latter region, diatom cells may have been unable to fulfil their characteristically high Fe demand at low average light conditions, and thus became co-limited by both resources. Using a model that describes the C-14 incorporation, the consistency was shown between the dynamics in the glucan pool in the field experiments and in laboratory experiments with an Antarctic diatom, Chaetoceros brevis. The glucan respiration rate was almost twice as high during the dark phase as during the light phase, which is consistent with the role of glucan as a reserve supplying energy and carbon skeletons for continued protein synthesis during the night.

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