The carbohydrates of Phaeocystis and their degradation in the microbial food web

The ubiquity and high productivity associated with blooms of colonial Phaeocystis makes it an important contributor to the global carbon cycle. During blooms organic matter that is rich in carbohydrates is produced. We distinguish five different pools of carbohydrates produced by Phaeocystis. Like a...

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Bibliographic Details
Published in:Biogeochemistry
Main Authors: Alderkamp, Anne-Carlijn, Buma, Anita G. J., van Rijssel, Marion
Format: Article in Journal/Newspaper
Language:English
Published: 2007
Subjects:
carbohydrates
glucan
hydrogels
mucilage
Phaeocystis
TEP
DISSOLVED ORGANIC-MATTER
DIATOM SKELETONEMA-COSTATUM
BELGIAN COASTAL WATERS
SOUTHERN-OCEAN PHYTOPLANKTON
DOMINATED SPRING BLOOM
NORTH-SEA
ROSS SEA
GLOBOSA PRYMNESIOPHYCEAE
POUCHETII HAPTOPHYCEAE
MARINE-PHYTOPLANKTON
Ross Sea
Southern Ocean
Online Access:https://hdl.handle.net/11370/fe1b4974-5cd9-4947-bdcc-708c6b2c0a50
https://research.rug.nl/en/publications/fe1b4974-5cd9-4947-bdcc-708c6b2c0a50
https://doi.org/10.1007/s10533-007-9078-2
https://pure.rug.nl/ws/files/6705873/2007BiogeochemAlderkamp.pdf
Description
Summary:The ubiquity and high productivity associated with blooms of colonial Phaeocystis makes it an important contributor to the global carbon cycle. During blooms organic matter that is rich in carbohydrates is produced. We distinguish five different pools of carbohydrates produced by Phaeocystis. Like all plants and algal cells, both solitary and colonial cells produce (1) structural carbohydrates, (hetero) polysaccharides that are mainly part of the cell wall, (2) mono- and oligosaccharides, which are present as intermediates in the synthesis and catabolism of cell components, and (3) intracellular storage glucan. Colonial cells of Phaeocystis excrete (4) mucopolysaccharides, heteropolysaccharides that are the main constituent of the mucous colony matrix and (5) dissolved organic matter (DOM) rich in carbohydrates, which is mainly excreted by colonial cells. In this review the characteristics of these pools are discussed and quantitative data are summarized. During the exponential growth phase, the ratio of carbohydrate-carbon (C) to particulate organic carbon (POC) is approximately 0.1. When nutrients are limited, Phaeocystis blooms reach a stationary growth phase, during which excess energy is stored as carbohydrates. This so-called overflow metabolism increases the ratio of carbohydrate-C to POC to 0.4-0.6 during the stationary phase, leading to an increase in the C/N and C/P ratios of Phaeocystis organic matter. Overflow metabolism can be channeled towards both glucan and mucopolysaccharides. Summarizing the available data reveals that during the stationary phase of a bloom glucan contributes 0-51% to POC, whereas mucopolysaccharides contribute 5-60%. At the end of a bloom, lysis of Phaeocystis cells and deterioration of colonies leads to a massive release of DOM rich in glucan and mucopolysaccharides. Laboratory studies have revealed that this organic matter is potentially readily degradable by heterotrophic bacteria. However, observations in the field of accumulation of DOM and foam indicate that microbial ...

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